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path: root/managemon.c
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/*
 * The management thread for monitoring active md arrays.
 * This thread does things which might block such as memory
 * allocation.
 * In particular:
 *
 * - Find out about new arrays in this container.
 *   Allocate the data structures and open the files.
 *
 *   For this we watch /proc/mdstat and find new arrays with
 *   metadata type that confirms sharing. e.g. "md4"
 *   When we find a new array we slip it into the list of
 *   arrays and signal 'monitor' by writing to a pipe.
 *
 * - Respond to reshape requests by allocating new data structures
 *   and opening new files.
 *
 *   These come as a change to raid_disks.  We allocate a new
 *   version of the data structures and slip it into the list.
 *   'monitor' will notice and release the old version.
 *   Changes to level, chunksize, layout.. do not need re-allocation.
 *   Reductions in raid_disks don't really either, but we handle
 *   them the same way for consistency.
 *
 * - When a device is added to the container, we add it to the metadata
 *   as a spare.
 *
 * - Deal with degraded array
 *    We only do this when first noticing the array is degraded.
 *    This can be when we first see the array, when sync completes or
 *    when recovery completes.
 *
 *    Check if number of failed devices suggests recovery is needed, and
 *    skip if not.
 *    Ask metadata to allocate a spare device
 *    Add device as not in_sync and give a role
 *    Update metadata.
 *    Open sysfs files and pass to monitor.
 *    Make sure that monitor Starts recovery....
 *
 * - Pass on metadata updates from external programs such as
 *   mdadm creating a new array.
 *
 *   This is most-messy.
 *   It might involve adding a new array or changing the status of
 *   a spare, or any reconfig that the kernel doesn't get involved in.
 *
 *   The required updates are received via a named pipe.  There will
 *   be one named pipe for each container. Each message contains a
 *   sync marker: 0x5a5aa5a5, A byte count, and the message.  This is
 *   passed to the metadata handler which will interpret and process it.
 *   For 'DDF' messages are internal data blocks with the leading
 *   'magic number' signifying what sort of data it is.
 *
 */

/*
 * We select on /proc/mdstat and the named pipe.
 * We create new arrays or updated version of arrays and slip
 * them into the head of the list, then signal 'monitor' via a pipe write.
 * 'monitor' will notice and place the old array on a return list.
 * Metadata updates are placed on a queue just like they arrive
 * from the named pipe.
 *
 * When new arrays are found based on correct metadata string, we
 * need to identify them with an entry in the metadata.  Maybe we require
 * the metadata to be mdX/NN  when NN is the index into an appropriate table.
 *
 */

/*
 * List of tasks:
 * - Watch for spares to be added to the container, and write updated
 *   metadata to them.
 * - Watch for new arrays using this container, confirm they match metadata
 *   and if so, start monitoring them
 * - Watch for spares being added to monitored arrays.  This shouldn't
 *   happen, as we should do all the adding.  Just remove them.
 * - Watch for change in raid-disks, chunk-size, etc.  Update metadata and
 *   start a reshape.
 */
#ifndef _GNU_SOURCE
#define _GNU_SOURCE
#endif
#include	"mdadm.h"
#include	"mdmon.h"
#include	<sys/syscall.h>
#include	<sys/socket.h>
#include	<signal.h>

static void close_aa(struct active_array *aa)
{
	struct mdinfo *d;

	for (d = aa->info.devs; d; d = d->next)
		close(d->state_fd);

	close(aa->action_fd);
	close(aa->info.state_fd);
	close(aa->resync_start_fd);
}

static void free_aa(struct active_array *aa)
{
	/* Note that this doesn't close fds if they are being used
	 * by a clone.  ->container will be set for a clone
	 */
	dprintf("%s: devnum: %d\n", __func__, aa->devnum);
	if (!aa->container)
		close_aa(aa);
	while (aa->info.devs) {
		struct mdinfo *d = aa->info.devs;
		aa->info.devs = d->next;
		free(d);
	}
	free(aa);
}

static struct active_array *duplicate_aa(struct active_array *aa)
{
	struct active_array *newa = malloc(sizeof(*newa));
	struct mdinfo **dp1, **dp2;

	*newa = *aa;
	newa->next = NULL;
	newa->replaces = NULL;
	newa->info.next = NULL;

	dp2 = &newa->info.devs;

	for (dp1 = &aa->info.devs; *dp1; dp1 = &(*dp1)->next) {
		struct mdinfo *d;
		if ((*dp1)->state_fd < 0)
			continue;

		d = malloc(sizeof(*d));
		*d = **dp1;
		*dp2 = d;
		dp2 = & d->next;
	}
	*dp2 = NULL;

	return newa;
}

static void wakeup_monitor(void)
{
	/* tgkill(getpid(), mon_tid, SIGUSR1); */
	int pid = getpid();
	syscall(SYS_tgkill, pid, mon_tid, SIGUSR1);
}

static void remove_old(void)
{
	if (discard_this) {
		discard_this->next = NULL;
		free_aa(discard_this);
		if (pending_discard == discard_this)
			pending_discard = NULL;
		discard_this = NULL;
	}
}

static void replace_array(struct supertype *container,
			  struct active_array *old,
			  struct active_array *new)
{
	/* To replace an array, we add it to the top of the list
	 * marked with ->replaces to point to the original.
	 * 'monitor' will take the original out of the list
	 * and put it on 'discard_this'.  We take it from there
	 * and discard it.
	 */
	remove_old();
	while (pending_discard) {
		wakeup_monitor();
		while (discard_this == NULL)
			sleep(1);
		remove_old();
	}
	pending_discard = old;
	new->replaces = old;
	new->next = container->arrays;
	container->arrays = new;
	wakeup_monitor();
}

struct metadata_update *update_queue = NULL;
struct metadata_update *update_queue_handled = NULL;
struct metadata_update *update_queue_pending = NULL;

void check_update_queue(struct supertype *container)
{
	while (update_queue_handled) {
		struct metadata_update *this = update_queue_handled;
		update_queue_handled = this->next;
		free(this->buf);
		if (this->space)
			free(this->space);
		free(this);
	}
	if (update_queue == NULL &&
	    update_queue_pending) {
		update_queue = update_queue_pending;
		update_queue_pending = NULL;
		wakeup_monitor();
	}
}

static void queue_metadata_update(struct metadata_update *mu)
{
	struct metadata_update **qp;

	qp = &update_queue_pending;
	while (*qp)
		qp = & ((*qp)->next);
	*qp = mu;
}

void wait_update_handled(void)
{
	/* Wait for any pending update to be handled by monitor.
	 * i.e. wait until update_queue is NULL
	 */
	while (update_queue)
		usleep(100 * 1000);
}

static void manage_container(struct mdstat_ent *mdstat,
			     struct supertype *container)
{
	/* The only thing of interest here is if a new device
	 * has been added to the container.  We add it to the
	 * array ignoring any metadata on it.
	 * FIXME should we look for compatible metadata and take hints
	 * about spare assignment.... probably not.
	 */
	if (mdstat->devcnt != container->devcnt) {
		/* read /sys/block/NAME/md/dev-??/block/dev to find out
		 * what is there, and compare with container->info.devs
		 * To see what is removed and what is added.
		 * These need to be remove from, or added to, the array
		 */
		// FIXME
		container->devcnt = mdstat->devcnt;
	}
}

static void manage_member(struct mdstat_ent *mdstat,
			  struct active_array *a)
{
	/* Compare mdstat info with known state of member array.
	 * We do not need to look for device state changes here, that
	 * is dealt with by the monitor.
	 *
	 * We just look for changes which suggest that a reshape is
	 * being requested.
	 * Unfortunately decreases in raid_disks don't show up in
	 * mdstat until the reshape completes FIXME.
	 *
	 * Actually, we also want to handle degraded arrays here by
	 * trying to find and assign a spare.
	 * We do that whenever the monitor tells us too.
	 */
	// FIXME
	a->info.array.raid_disks = mdstat->raid_disks;
	a->info.array.chunk_size = mdstat->chunk_size;
	// MORE

	if (a->check_degraded) {
		struct metadata_update *updates = NULL;
		struct mdinfo *newdev;
		struct active_array *newa;
		wait_update_handled();
		a->check_degraded = 0;

		/* The array may not be degraded, this is just a good time
		 * to check.
		 */
		newdev = a->container->ss->activate_spare(a, &updates);
		if (newdev) {
			struct mdinfo *d;
			/* Cool, we can add a device or several. */
			newa = duplicate_aa(a);
			/* suspend recovery - maybe not needed */

			/* Add device to array and set offset/size/slot.
			 * and open files for each newdev */
			for (d = newdev; d ; d = d->next) {
				struct mdinfo *newd;
				if (sysfs_add_disk(&newa->info, d))
					continue;
				newd = newa->info.devs;
				newd->state_fd = sysfs_open(a->devnum,
							    newd->sys_name,
							    "state");
				newd->prev_state
					= read_dev_state(newd->state_fd);
				newd->curr_state = newd->prev_state;
			}
			queue_metadata_update(updates);
			replace_array(a->container, a, newa);
			sysfs_set_str(&a->info, NULL, "sync_action", "repair");
		}
	}
}

static void manage_new(struct mdstat_ent *mdstat,
		       struct supertype *container,
		       struct active_array *victim)
{
	/* A new array has appeared in this container.
	 * Hopefully it is already recorded in the metadata.
	 * Check, then create the new array to report it to
	 * the monitor.
	 */

	struct active_array *new;
	struct mdinfo *mdi, *di;
	char *inst;
	int i;

	new = malloc(sizeof(*new));

	memset(new, 0, sizeof(*new));

	new->devnum = mdstat->devnum;
	strcpy(new->info.sys_name, devnum2devname(new->devnum));

	new->prev_state = new->curr_state = new->next_state = inactive;
	new->prev_action= new->curr_action= new->next_action= idle;

	new->container = container;

	inst = &mdstat->metadata_version[10+strlen(container->devname)+1];

	mdi = sysfs_read(-1, new->devnum,
			 GET_LEVEL|GET_CHUNK|GET_DISKS|
			 GET_DEVS|GET_OFFSET|GET_SIZE|GET_STATE);
	if (!mdi) {
		/* Eeek. Cannot monitor this array.
		 * Mark it to be ignored by setting container to NULL
		 */
		new->container = NULL;
		replace_array(container, victim, new);
		return;
	}

	new->info.array = mdi->array;

	for (i = 0; i < new->info.array.raid_disks; i++) {
		struct mdinfo *newd = malloc(sizeof(*newd));

		for (di = mdi->devs; di; di = di->next)
			if (i == di->disk.raid_disk)
				break;

		if (di) {
			memcpy(newd, di, sizeof(*newd));

			newd->state_fd = sysfs_open(new->devnum,
						    newd->sys_name,
						    "state");

			newd->prev_state = read_dev_state(newd->state_fd);
			newd->curr_state = newd->prev_state;
		} else {
			newd->state_fd = -1;
			newd->disk.raid_disk = i;
			newd->prev_state = DS_REMOVE;
			newd->curr_state = DS_REMOVE;
		}
		sprintf(newd->sys_name, "rd%d", i);
		newd->next = new->info.devs;
		new->info.devs = newd;
	}
	new->action_fd = sysfs_open(new->devnum, NULL, "sync_action");
	new->info.state_fd = sysfs_open(new->devnum, NULL, "array_state");
	new->resync_start_fd = sysfs_open(new->devnum, NULL, "resync_start");
	new->resync_start = 0;
	dprintf("%s: inst: %d action: %d state: %d\n", __func__, atoi(inst),
		new->action_fd, new->info.state_fd);

	sysfs_free(mdi);
	// finds and compares.
	if (container->ss->open_new(container, new, inst) < 0) {
		// FIXME close all those files
		new->container = NULL;
		replace_array(container, victim, new);
		return;
	}
	replace_array(container, victim, new);
	return;
}

void manage(struct mdstat_ent *mdstat, struct supertype *container)
{
	/* We have just read mdstat and need to compare it with
	 * the known active arrays.
	 * Arrays with the wrong metadata are ignored.
	 */

	for ( ; mdstat ; mdstat = mdstat->next) {
		struct active_array *a;
		if (mdstat->devnum == container->devnum) {
			manage_container(mdstat, container);
			continue;
		}
		if (mdstat->metadata_version == NULL ||
		    strncmp(mdstat->metadata_version, "external:/", 10) != 0 ||
		    strncmp(mdstat->metadata_version+10, container->devname,
			    strlen(container->devname)) != 0 ||
		    mdstat->metadata_version[10+strlen(container->devname)]
		      != '/')
			/* Not for this array */
			continue;
		/* Looks like a member of this container */
		for (a = container->arrays; a; a = a->next) {
			if (mdstat->devnum == a->devnum) {
				if (a->container)
					manage_member(mdstat, a);
				break;
			}
		}
		if (a == NULL || !a->container)
			manage_new(mdstat, container, a);
	}
}

static int handle_message(struct supertype *container, struct md_message *msg)
{
	return -1;
}

void read_sock(struct supertype *container)
{
	int fd;
	struct md_message msg;
	int terminate = 0;
	long fl;
	int tmo = 3; /* 3 second timeout before hanging up the socket */

	fd = accept(container->sock, NULL, NULL);
	if (fd < 0)
		return;

	fl = fcntl(fd, F_GETFL, 0);
	fl |= O_NONBLOCK;
	fcntl(fd, F_SETFL, fl);

	do {
		int err;

		msg.buf = NULL;

		/* read and validate the message */
		if (receive_message(fd, &msg, tmo) == 0) {
			err = handle_message(container, &msg);
			if (!err)
				ack(fd, msg.seq, tmo);
			else
				nack(fd, err, tmo);
		} else {
			terminate = 1;
			nack(fd, -1, tmo);
		}

		if (msg.buf)
			free(msg.buf);
	} while (!terminate);

	close(fd);
}

int exit_now = 0;
int manager_ready = 0;
void do_manager(struct supertype *container)
{
	struct mdstat_ent *mdstat;
	sigset_t set;

	sigprocmask(SIG_UNBLOCK, NULL, &set);
	sigdelset(&set, SIGUSR1);

	do {

		if (exit_now)
			exit(0);

		mdstat = mdstat_read(1, 0);

		manage(mdstat, container);

		read_sock(container);

		free_mdstat(mdstat);

		remove_old();

		check_update_queue(container);

		manager_ready = 1;

		mdstat_wait_fd(container->sock, &set);
	} while(1);
}