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|
/* block-remus.c
*
* This disk sends all writes to a backup via a network interface before
* passing them to an underlying device.
* The backup is a bit more complicated:
* 1. It applies all incoming writes to a ramdisk.
* 2. When a checkpoint request arrives, it moves the ramdisk to
* a committing state and uses a new ramdisk for subsequent writes.
* It also acknowledges the request, to let the sender know it can
* release output.
* 3. The ramdisk flushes its contents to the underlying driver.
* 4. At failover, the backup waits for the in-flight ramdisk (if any) to
* drain before letting the domain be activated.
*
* The driver determines whether it is the client or server by attempting
* to bind to the replication address. If the address is not local,
* the driver acts as client.
*
* The following messages are defined for the replication stream:
* 1. write request
* "wreq" 4
* num_sectors 4
* sector 8
* buffer (num_sectors * sector_size)
* 2. submit request (may be used as a barrier
* "sreq" 4
* 3. commit request
* "creq" 4
* After a commit request, the client must wait for a competion message:
* 4. completion
* "done" 4
*/
/* due to architectural choices in tapdisk, block-buffer is forced to
* reimplement some code which is meant to be private */
#define TAPDISK
#include "tapdisk.h"
#include "tapdisk-server.h"
#include "tapdisk-driver.h"
#include "tapdisk-interface.h"
#include "hashtable.h"
#include "hashtable_itr.h"
#include "hashtable_utility.h"
#include <errno.h>
#include <inttypes.h>
#include <fcntl.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <sys/time.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <netdb.h>
#include <netinet/in.h>
#include <arpa/inet.h>
#include <sys/param.h>
#include <sys/sysctl.h>
#include <unistd.h>
#include <sys/stat.h>
/* timeout for reads and writes in ms */
#define HEARTBEAT_MS 1000
#define RAMDISK_HASHSIZE 128
/* connect retry timeout (seconds) */
#define REMUS_CONNRETRY_TIMEOUT 10
#define RPRINTF(_f, _a...) syslog (LOG_DEBUG, "remus: " _f, ## _a)
enum tdremus_mode {
mode_invalid = 0,
mode_unprotected,
mode_primary,
mode_backup
};
struct tdremus_req {
uint64_t sector;
int nb_sectors;
char buf[4096];
};
struct req_ring {
/* waste one slot to distinguish between empty and full */
struct tdremus_req requests[MAX_REQUESTS * 2 + 1];
unsigned int head;
unsigned int tail;
};
/* TODO: This isn't very pretty, but to properly generate our own treqs (needed
* by the backup) we need to know our td_vbt_t and td_image_t (blktap2
* internals). As a proper fix, we should consider extending the tapdisk
* interface with a td_create_request() function, or something similar.
*
* For now, we just grab the vbd in the td_open() command, and the td_image_t
* from the first read request.
*/
td_vbd_t *device_vbd = NULL;
td_image_t *remus_image = NULL;
struct ramdisk {
size_t sector_size;
struct hashtable* h;
/* when a ramdisk is flushed, h is given a new empty hash for writes
* while the old ramdisk (prev) is drained asynchronously. To avoid
* a race where a read request points to a sector in prev which has
* not yet been flushed, check prev on a miss in h */
struct hashtable* prev;
/* count of outstanding requests to the base driver */
size_t inflight;
};
/* the ramdisk intercepts the original callback for reads and writes.
* This holds the original data. */
/* Might be worth making this a static array in struct ramdisk to avoid
* a malloc per request */
struct tdremus_state;
struct ramdisk_cbdata {
td_callback_t cb;
void* private;
char* buf;
struct tdremus_state* state;
};
struct ramdisk_write_cbdata {
struct tdremus_state* state;
char* buf;
};
typedef void (*queue_rw_t) (td_driver_t *driver, td_request_t treq);
/* poll_fd type for blktap2 fd system. taken from block_log.c */
typedef struct poll_fd {
int fd;
event_id_t id;
} poll_fd_t;
struct tdremus_state {
// struct tap_disk* driver;
void* driver_data;
/* XXX: this is needed so that the server can perform operations on
* the driver from the stream_fd event handler. fix this. */
td_driver_t *tdremus_driver;
/* TODO: we may wish to replace these two FIFOs with a unix socket */
char* ctl_path; /* receive flush instruction here */
poll_fd_t ctl_fd; /* io_fd slot for control FIFO */
char* msg_path; /* output completion message here */
poll_fd_t msg_fd;
/* replication host */
struct sockaddr_in sa;
poll_fd_t server_fd; /* server listen port */
poll_fd_t stream_fd; /* replication channel */
/* queue write requests, batch-replicate at submit */
struct req_ring write_ring;
/* ramdisk data*/
struct ramdisk ramdisk;
/* mode methods */
enum tdremus_mode mode;
int (*queue_flush)(td_driver_t *driver);
};
typedef struct tdremus_wire {
uint32_t op;
uint64_t id;
uint64_t sec;
uint32_t secs;
} tdremus_wire_t;
#define TDREMUS_READ "rreq"
#define TDREMUS_WRITE "wreq"
#define TDREMUS_SUBMIT "sreq"
#define TDREMUS_COMMIT "creq"
#define TDREMUS_DONE "done"
#define TDREMUS_FAIL "fail"
/* primary read/write functions */
static void primary_queue_read(td_driver_t *driver, td_request_t treq);
static void primary_queue_write(td_driver_t *driver, td_request_t treq);
/* backup read/write functions */
static void backup_queue_read(td_driver_t *driver, td_request_t treq);
static void backup_queue_write(td_driver_t *driver, td_request_t treq);
/* unpritected read/write functions */
static void unprotected_queue_read(td_driver_t *driver, td_request_t treq);
static void unprotected_queue_write(td_driver_t *driver, td_request_t treq);
static int tdremus_close(td_driver_t *driver);
static int switch_mode(td_driver_t *driver, enum tdremus_mode mode);
static int ctl_respond(struct tdremus_state *s, const char *response);
/* ring functions */
static inline unsigned int ring_next(struct req_ring* ring, unsigned int pos)
{
if (++pos >= MAX_REQUESTS * 2 + 1)
return 0;
return pos;
}
static inline int ring_isempty(struct req_ring* ring)
{
return ring->head == ring->tail;
}
static inline int ring_isfull(struct req_ring* ring)
{
return ring_next(ring, ring->tail) == ring->head;
}
/* functions to create and sumbit treq's */
static void
replicated_write_callback(td_request_t treq, int err)
{
struct tdremus_state *s = (struct tdremus_state *) treq.cb_data;
td_vbd_request_t *vreq;
vreq = (td_vbd_request_t *) treq.private;
/* the write failed for now, lets panic. this is very bad */
if (err) {
RPRINTF("ramdisk write failed, disk image is not consistent\n");
exit(-1);
}
/* The write succeeded. let's pull the vreq off whatever request list
* it is on and free() it */
list_del(&vreq->next);
free(vreq);
s->ramdisk.inflight--;
if (!s->ramdisk.inflight && !s->ramdisk.prev) {
/* TODO: the ramdisk has been flushed */
}
}
static inline int
create_write_request(struct tdremus_state *state, td_sector_t sec, int secs, char *buf)
{
td_request_t treq;
td_vbd_request_t *vreq;
treq.op = TD_OP_WRITE;
treq.buf = buf;
treq.sec = sec;
treq.secs = secs;
treq.image = remus_image;
treq.cb = replicated_write_callback;
treq.cb_data = state;
treq.id = 0;
treq.sidx = 0;
vreq = calloc(1, sizeof(td_vbd_request_t));
treq.private = vreq;
if(!vreq)
return -1;
vreq->submitting = 1;
INIT_LIST_HEAD(&vreq->next);
tapdisk_vbd_move_request(treq.private, &device_vbd->pending_requests);
/* TODO:
* we should probably leave it up to the caller to forward the request */
td_forward_request(treq);
vreq->submitting--;
return 0;
}
/* ramdisk methods */
static int ramdisk_flush(td_driver_t *driver, struct tdremus_state *s);
/* http://www.concentric.net/~Ttwang/tech/inthash.htm */
static unsigned int uint64_hash(void* k)
{
uint64_t key = *(uint64_t*)k;
key = (~key) + (key << 18);
key = key ^ (key >> 31);
key = key * 21;
key = key ^ (key >> 11);
key = key + (key << 6);
key = key ^ (key >> 22);
return (unsigned int)key;
}
static int rd_hash_equal(void* k1, void* k2)
{
uint64_t key1, key2;
key1 = *(uint64_t*)k1;
key2 = *(uint64_t*)k2;
return key1 == key2;
}
static int ramdisk_read(struct ramdisk* ramdisk, uint64_t sector,
int nb_sectors, char* buf)
{
int i;
char* v;
uint64_t key;
for (i = 0; i < nb_sectors; i++) {
key = sector + i;
if (!(v = hashtable_search(ramdisk->h, &key))) {
/* check whether it is queued in a previous flush request */
if (!(ramdisk->prev && (v = hashtable_search(ramdisk->prev, &key))))
return -1;
}
memcpy(buf + i * ramdisk->sector_size, v, ramdisk->sector_size);
}
return 0;
}
static int ramdisk_write_hash(struct hashtable* h, uint64_t sector, char* buf,
size_t len)
{
char* v;
uint64_t* key;
if ((v = hashtable_search(h, §or))) {
memcpy(v, buf, len);
return 0;
}
if (!(v = malloc(len))) {
DPRINTF("ramdisk_write_hash: malloc failed\n");
return -1;
}
memcpy(v, buf, len);
if (!(key = malloc(sizeof(*key)))) {
DPRINTF("ramdisk_write_hash: error allocating key\n");
free(v);
return -1;
}
*key = sector;
if (!hashtable_insert(h, key, v)) {
DPRINTF("ramdisk_write_hash failed on sector %" PRIu64 "\n", sector);
free(key);
free(v);
return -1;
}
return 0;
}
static inline int ramdisk_write(struct ramdisk* ramdisk, uint64_t sector,
int nb_sectors, char* buf)
{
int i, rc;
for (i = 0; i < nb_sectors; i++) {
rc = ramdisk_write_hash(ramdisk->h, sector + i,
buf + i * ramdisk->sector_size,
ramdisk->sector_size);
if (rc)
return rc;
}
return 0;
}
static int ramdisk_write_cb(td_driver_t *driver, int res, uint64_t sector,
int nb_sectors, int id, void* private)
{
struct ramdisk_write_cbdata *cbdata = (struct ramdisk_write_cbdata*)private;
struct tdremus_state *s = cbdata->state;
int rc;
/*
RPRINTF("ramdisk write callback: rc %d, %d sectors @ %" PRIu64 "\n", res, nb_sectors,
sector);
*/
free(cbdata->buf);
free(cbdata);
s->ramdisk.inflight--;
if (!s->ramdisk.inflight && !s->ramdisk.prev) {
/* when this reaches 0 and prev is empty, the disk is flushed. */
/*
RPRINTF("ramdisk flush complete\n");
*/
}
if (s->ramdisk.prev) {
/* resubmit as much as possible in the remaining disk */
/*
RPRINTF("calling ramdisk_flush from write callback\n");
*/
return ramdisk_flush(driver, s);
}
return 0;
}
static int uint64_compare(const void* k1, const void* k2)
{
uint64_t u1 = *(uint64_t*)k1;
uint64_t u2 = *(uint64_t*)k2;
/* u1 - u2 is unsigned */
return u1 < u2 ? -1 : u1 > u2 ? 1 : 0;
}
/* set psectors to an array of the sector numbers in the hash, returning
* the number of entries (or -1 on error) */
static int ramdisk_get_sectors(struct hashtable* h, uint64_t** psectors)
{
struct hashtable_itr* itr;
uint64_t* sectors;
int count;
if (!(count = hashtable_count(h)))
return 0;
if (!(*psectors = malloc(count * sizeof(uint64_t)))) {
DPRINTF("ramdisk_get_sectors: error allocating sector map\n");
return -1;
}
sectors = *psectors;
itr = hashtable_iterator(h);
count = 0;
do {
sectors[count++] = *(uint64_t*)hashtable_iterator_key(itr);
} while (hashtable_iterator_advance(itr));
free(itr);
return count;
}
static char* merge_requests(struct ramdisk* ramdisk, uint64_t start,
size_t count)
{
char* buf;
char* sector;
int i;
if (!(buf = valloc(count * ramdisk->sector_size))) {
DPRINTF("merge_request: allocation failed\n");
return NULL;
}
for (i = 0; i < count; i++) {
if (!(sector = hashtable_search(ramdisk->prev, &start))) {
DPRINTF("merge_request: lookup failed on %"PRIu64"\n", start);
return NULL;
}
memcpy(buf + i * ramdisk->sector_size, sector, ramdisk->sector_size);
free(sector);
start++;
}
return buf;
}
/* The underlying driver may not handle having the whole ramdisk queued at
* once. We queue what we can and let the callbacks attempt to queue more. */
/* NOTE: may be called from callback, while dd->private still belongs to
* the underlying driver */
static int ramdisk_flush(td_driver_t *driver, struct tdremus_state* s)
{
uint64_t* sectors;
char* buf = NULL;
uint64_t base, batchlen;
int i, j, count = 0;
// RPRINTF("ramdisk flush\n");
if ((count = ramdisk_get_sectors(s->ramdisk.prev, §ors)) <= 0)
return count;
/*
RPRINTF("ramdisk: flushing %d sectors\n", count);
*/
/* sort and merge sectors to improve disk performance */
qsort(sectors, count, sizeof(*sectors), uint64_compare);
for (i = 0; i < count;) {
base = sectors[i++];
while (i < count && sectors[i] == sectors[i-1] + 1)
i++;
batchlen = sectors[i-1] - base + 1;
if (!(buf = merge_requests(&s->ramdisk, base, batchlen))) {
RPRINTF("ramdisk_flush: merge_requests failed\n");
free(sectors);
return -1;
}
/* NOTE: create_write_request() creates a treq AND forwards it down
* the driver chain */
// RPRINTF("forwarding write request at %" PRIu64 ", length: %" PRIu64 "\n", base, batchlen);
create_write_request(s, base, batchlen, buf);
//RPRINTF("write request at %" PRIu64 ", length: %" PRIu64 " forwarded\n", base, batchlen);
s->ramdisk.inflight++;
for (j = 0; j < batchlen; j++) {
hashtable_remove(s->ramdisk.prev, &base);
base++;
}
}
if (!hashtable_count(s->ramdisk.prev)) {
/* everything is in flight */
hashtable_destroy(s->ramdisk.prev, 0);
s->ramdisk.prev = NULL;
}
free(sectors);
// RPRINTF("ramdisk flush done\n");
return 0;
}
/* flush ramdisk contents to disk */
static int ramdisk_start_flush(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
uint64_t* key;
char* buf;
int rc = 0;
int i, j, count, batchlen;
uint64_t* sectors;
if (!hashtable_count(s->ramdisk.h)) {
/*
RPRINTF("Nothing to flush\n");
*/
return 0;
}
if (s->ramdisk.prev) {
/* a flush request issued while a previous flush is still in progress
* will merge with the previous request. If you want the previous
* request to be consistent, wait for it to complete. */
if ((count = ramdisk_get_sectors(s->ramdisk.h, §ors)) < 0)
return count;
for (i = 0; i < count; i++) {
buf = hashtable_search(s->ramdisk.h, sectors + i);
ramdisk_write_hash(s->ramdisk.prev, sectors[i], buf,
s->ramdisk.sector_size);
}
free(sectors);
hashtable_destroy (s->ramdisk.h, 0);
} else
s->ramdisk.prev = s->ramdisk.h;
/* We create a new hashtable so that new writes can be performed before
* the old hashtable is completely drained. */
s->ramdisk.h = create_hashtable(RAMDISK_HASHSIZE, uint64_hash,
rd_hash_equal);
return ramdisk_flush(driver, s);
}
static int ramdisk_start(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
if (s->ramdisk.h) {
RPRINTF("ramdisk already allocated\n");
return 0;
}
s->ramdisk.sector_size = driver->info.sector_size;
s->ramdisk.h = create_hashtable(RAMDISK_HASHSIZE, uint64_hash,
rd_hash_equal);
DPRINTF("Ramdisk started, %zu bytes/sector\n", s->ramdisk.sector_size);
return 0;
}
/* common client/server functions */
/* mayberead: Time out after a certain interval. */
static int mread(int fd, void* buf, size_t len)
{
fd_set rfds;
int rc;
size_t cur = 0;
struct timeval tv = {
.tv_sec = HEARTBEAT_MS / 1000,
.tv_usec = (HEARTBEAT_MS % 1000) * 1000
};
if (!len)
return 0;
/* read first. Only select if read is incomplete. */
rc = read(fd, buf, len);
while (rc < 0 || cur + rc < len) {
if (!rc) {
RPRINTF("end-of-file");
return -1;
}
if (rc < 0 && errno != EAGAIN) {
RPRINTF("error during read: %s\n", strerror(errno));
return -1;
}
if (rc > 0)
cur += rc;
FD_ZERO(&rfds);
FD_SET(fd, &rfds);
if (!(rc = select(fd + 1, &rfds, NULL, NULL, &tv))) {
RPRINTF("time out during read\n");
return -1;
} else if (rc < 0) {
RPRINTF("error during select: %d\n", errno);
return -1;
}
rc = read(fd, buf + cur, len - cur);
}
/*
RPRINTF("read %d bytes\n", cur + rc);
*/
return 0;
}
static int mwrite(int fd, void* buf, size_t len)
{
fd_set wfds;
size_t cur = 0;
int rc;
struct timeval tv = {
.tv_sec = HEARTBEAT_MS / 1000,
.tv_usec = (HEARTBEAT_MS % 1000) * 1000
};
if (!len)
return 0;
/* read first. Only select if read is incomplete. */
rc = write(fd, buf, len);
while (rc < 0 || cur + rc < len) {
if (!rc) {
RPRINTF("end-of-file");
return -1;
}
if (rc < 0 && errno != EAGAIN) {
RPRINTF("error during write: %s\n", strerror(errno));
return -1;
}
if (rc > 0)
cur += rc;
FD_ZERO(&wfds);
FD_SET(fd, &wfds);
if (!(rc = select(fd + 1, NULL, &wfds, NULL, &tv))) {
RPRINTF("time out during write\n");
return -1;
} else if (rc < 0) {
RPRINTF("error during select: %d\n", errno);
return -1;
}
rc = write(fd, buf + cur, len - cur);
}
/*
RPRINTF("wrote %d bytes\n", cur + rc);
*/
return 0;
FD_ZERO(&wfds);
FD_SET(fd, &wfds);
select(fd + 1, NULL, &wfds, NULL, &tv);
}
static void inline close_stream_fd(struct tdremus_state *s)
{
/* XXX: -2 is magic. replace with macro perhaps? */
tapdisk_server_unregister_event(s->stream_fd.id);
close(s->stream_fd.fd);
s->stream_fd.fd = -2;
}
/* primary functions */
static void remus_client_event(event_id_t, char mode, void *private);
static void remus_connect_event(event_id_t id, char mode, void *private);
static void remus_retry_connect_event(event_id_t id, char mode, void *private);
static int primary_do_connect(struct tdremus_state *state)
{
event_id_t id;
int fd;
int rc;
int flags;
RPRINTF("client connecting to %s:%d...\n", inet_ntoa(state->sa.sin_addr), ntohs(state->sa.sin_port));
if ((fd = socket(PF_INET, SOCK_STREAM, 0)) < 0) {
RPRINTF("could not create client socket: %d\n", errno);
return -1;
}
/* make socket nonblocking */
if ((flags = fcntl(fd, F_GETFL, 0)) == -1)
flags = 0;
if (fcntl(fd, F_SETFL, flags | O_NONBLOCK) == -1)
return -1;
/* once we have created the socket and populated the address, we can now start
* our non-blocking connect. rather than duplicating code we trigger a timeout
* on the socket fd, which calls out nonblocking connect code
*/
if((id = tapdisk_server_register_event(SCHEDULER_POLL_TIMEOUT, fd, 0, remus_retry_connect_event, state)) < 0) {
RPRINTF("error registering timeout client connection event handler: %s\n", strerror(id));
/* TODO: we leak a fd here */
return -1;
}
state->stream_fd.fd = fd;
state->stream_fd.id = id;
return 0;
}
static int primary_blocking_connect(struct tdremus_state *state)
{
int fd;
int id;
int rc;
int flags;
RPRINTF("client connecting to %s:%d...\n", inet_ntoa(state->sa.sin_addr), ntohs(state->sa.sin_port));
if ((fd = socket(PF_INET, SOCK_STREAM, 0)) < 0) {
RPRINTF("could not create client socket: %d\n", errno);
return -1;
}
do {
if ((rc = connect(fd, (struct sockaddr *)&state->sa,
sizeof(state->sa))) < 0)
{
if (errno == ECONNREFUSED) {
RPRINTF("connection refused -- retrying in 1 second\n");
sleep(1);
} else {
RPRINTF("connection failed: %d\n", errno);
close(fd);
return -1;
}
}
} while (rc < 0);
RPRINTF("client connected\n");
/* make socket nonblocking */
if ((flags = fcntl(fd, F_GETFL, 0)) == -1)
flags = 0;
if (fcntl(fd, F_SETFL, flags | O_NONBLOCK) == -1)
{
RPRINTF("error making socket nonblocking\n");
close(fd);
return -1;
}
if((id = tapdisk_server_register_event(SCHEDULER_POLL_READ_FD, fd, 0, remus_client_event, state)) < 0) {
RPRINTF("error registering client event handler: %s\n", strerror(id));
close(fd);
return -1;
}
state->stream_fd.fd = fd;
state->stream_fd.id = id;
return 0;
}
/* on read, just pass request through */
static void primary_queue_read(td_driver_t *driver, td_request_t treq)
{
/* just pass read through */
td_forward_request(treq);
}
/* TODO:
* The primary uses mwrite() to write the contents of a write request to the
* backup. This effectively blocks until all data has been copied into a system
* buffer or a timeout has occured. We may wish to instead use tapdisk's
* nonblocking i/o interface, tapdisk_server_register_event(), to set timeouts
* and write data in an asynchronous fashion.
*/
static void primary_queue_write(td_driver_t *driver, td_request_t treq)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
char header[sizeof(uint32_t) + sizeof(uint64_t)];
uint32_t *sectors = (uint32_t *)header;
uint64_t *sector = (uint64_t *)(header + sizeof(uint32_t));
// RPRINTF("write: stream_fd.fd: %d\n", s->stream_fd.fd);
/* -1 means we haven't connected yet, -2 means the connection was lost */
if(s->stream_fd.fd == -1) {
RPRINTF("connecting to backup...\n");
primary_blocking_connect(s);
}
*sectors = treq.secs;
*sector = treq.sec;
if (mwrite(s->stream_fd.fd, TDREMUS_WRITE, strlen(TDREMUS_WRITE)) < 0)
goto fail;
if (mwrite(s->stream_fd.fd, header, sizeof(header)) < 0)
goto fail;
if (mwrite(s->stream_fd.fd, treq.buf, treq.secs * driver->info.sector_size) < 0)
goto fail;
td_forward_request(treq);
return;
fail:
/* switch to unprotected mode and tell tapdisk to retry */
RPRINTF("write request replication failed, switching to unprotected mode");
switch_mode(s->tdremus_driver, mode_unprotected);
td_complete_request(treq, -EBUSY);
}
static int client_flush(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
// RPRINTF("committing output\n");
if (s->stream_fd.fd == -1)
/* connection not yet established, nothing to flush */
return 0;
if (mwrite(s->stream_fd.fd, TDREMUS_COMMIT, strlen(TDREMUS_COMMIT)) < 0) {
RPRINTF("error flushing output");
close_stream_fd(s);
return -1;
}
return 0;
}
static int primary_start(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
RPRINTF("activating client mode\n");
tapdisk_remus.td_queue_read = primary_queue_read;
tapdisk_remus.td_queue_write = primary_queue_write;
s->queue_flush = client_flush;
s->stream_fd.fd = -1;
s->stream_fd.id = -1;
return 0;
}
/* timeout callback */
static void remus_retry_connect_event(event_id_t id, char mode, void *private)
{
struct tdremus_state *s = (struct tdremus_state *)private;
/* do a non-blocking connect */
if (connect(s->stream_fd.fd, (struct sockaddr *)&s->sa, sizeof(s->sa))
&& errno != EINPROGRESS)
{
if(errno == ECONNREFUSED || errno == ENETUNREACH || errno == EAGAIN || errno == ECONNABORTED)
{
/* try again in a second */
tapdisk_server_unregister_event(s->stream_fd.id);
if((id = tapdisk_server_register_event(SCHEDULER_POLL_TIMEOUT, s->stream_fd.fd, REMUS_CONNRETRY_TIMEOUT, remus_retry_connect_event, s)) < 0) {
RPRINTF("error registering timeout client connection event handler: %s\n", strerror(id));
return;
}
s->stream_fd.id = id;
}
else
{
/* not recoverable */
RPRINTF("error connection to server %s\n", strerror(errno));
return;
}
}
else
{
/* the connect returned EINPROGRESS (nonblocking connect) we must wait for the fd to be writeable to determine if the connect worked */
tapdisk_server_unregister_event(s->stream_fd.id);
if((id = tapdisk_server_register_event(SCHEDULER_POLL_WRITE_FD, s->stream_fd.fd, 0, remus_connect_event, s)) < 0) {
RPRINTF("error registering client connection event handler: %s\n", strerror(id));
return;
}
s->stream_fd.id = id;
}
}
/* callback when nonblocking connect() is finished */
/* called only by primary in unprotected state */
static void remus_connect_event(event_id_t id, char mode, void *private)
{
int socket_errno;
socklen_t socket_errno_size;
struct tdremus_state *s = (struct tdremus_state *)private;
/* check to se if the connect succeeded */
socket_errno_size = sizeof(socket_errno);
if (getsockopt(s->stream_fd.fd, SOL_SOCKET, SO_ERROR, &socket_errno, &socket_errno_size)) {
RPRINTF("error getting socket errno\n");
return;
}
RPRINTF("socket connect returned %d\n", socket_errno);
if(socket_errno)
{
/* the connect did not succeed */
if(socket_errno == ECONNREFUSED || socket_errno == ENETUNREACH || socket_errno == ETIMEDOUT
|| socket_errno == ECONNABORTED || socket_errno == EAGAIN)
{
/* we can probably assume that the backup is down. just try again later */
tapdisk_server_unregister_event(s->stream_fd.id);
if((id = tapdisk_server_register_event(SCHEDULER_POLL_TIMEOUT, s->stream_fd.fd, REMUS_CONNRETRY_TIMEOUT, remus_retry_connect_event, s)) < 0) {
RPRINTF("error registering timeout client connection event handler: %s\n", strerror(id));
return;
}
s->stream_fd.id = id;
}
else
{
RPRINTF("socket connect returned %d, giving up\n", socket_errno);
}
}
else
{
/* the connect succeeded */
/* unregister this function and register a new event handler */
tapdisk_server_unregister_event(s->stream_fd.id);
if((id = tapdisk_server_register_event(SCHEDULER_POLL_READ_FD, s->stream_fd.fd, 0, remus_client_event, s)) < 0) {
RPRINTF("error registering client event handler: %s\n", strerror(id));
return;
}
s->stream_fd.id = id;
/* switch from unprotected to protected client */
switch_mode(s->tdremus_driver, mode_primary);
}
}
/* we install this event handler on the primary once we have connected to the backup */
/* wait for "done" message to commit checkpoint */
static void remus_client_event(event_id_t id, char mode, void *private)
{
struct tdremus_state *s = (struct tdremus_state *)private;
char req[5];
int rc;
if (mread(s->stream_fd.fd, req, sizeof(req) - 1) < 0) {
/* replication stream closed or otherwise broken (timeout, reset, &c) */
RPRINTF("error reading from backup\n");
close_stream_fd(s);
return;
}
req[4] = '\0';
if (!strcmp(req, TDREMUS_DONE))
/* checkpoint committed, inform msg_fd */
ctl_respond(s, TDREMUS_DONE);
else {
RPRINTF("received unknown message: %s\n", req);
close_stream_fd(s);
}
return;
}
/* backup functions */
static void remus_server_event(event_id_t id, char mode, void *private);
/* returns the socket that receives write requests */
static void remus_server_accept(event_id_t id, char mode, void* private)
{
struct tdremus_state* s = (struct tdremus_state *) private;
int stream_fd;
event_id_t cid;
/* XXX: add address-based black/white list */
if ((stream_fd = accept(s->server_fd.fd, NULL, NULL)) < 0) {
RPRINTF("error accepting connection: %d\n", errno);
return;
}
/* TODO: check to see if we are already replicating. if so just close the
* connection (or do something smarter) */
RPRINTF("server accepted connection\n");
/* add tapdisk event for replication stream */
cid = tapdisk_server_register_event(SCHEDULER_POLL_READ_FD, stream_fd, 0,
remus_server_event, s);
if(cid < 0) {
RPRINTF("error registering connection event handler: %s\n", strerror(errno));
close(stream_fd);
return;
}
/* store replication file descriptor */
s->stream_fd.fd = stream_fd;
s->stream_fd.id = cid;
}
/* returns -2 if EADDRNOTAVAIL */
static int remus_bind(struct tdremus_state* s)
{
// struct sockaddr_in sa;
int opt;
int rc = -1;
if ((s->server_fd.fd = socket(AF_INET, SOCK_STREAM, 0)) < 0) {
RPRINTF("could not create server socket: %d\n", errno);
return rc;
}
opt = 1;
if (setsockopt(s->server_fd.fd, SOL_SOCKET, SO_REUSEADDR, &opt, sizeof(opt)) < 0)
RPRINTF("Error setting REUSEADDR on %d: %d\n", s->server_fd.fd, errno);
if (bind(s->server_fd.fd, (struct sockaddr *)&s->sa, sizeof(s->sa)) < 0) {
RPRINTF("could not bind server socket %d to %s:%d: %d %s\n", s->server_fd.fd,
inet_ntoa(s->sa.sin_addr), ntohs(s->sa.sin_port), errno, strerror(errno));
if (errno != EADDRINUSE)
rc = -2;
goto err_sfd;
}
if (listen(s->server_fd.fd, 10)) {
RPRINTF("could not listen on socket: %d\n", errno);
goto err_sfd;
}
/* The socket s now bound to the address and listening so we may now register
* the fd with tapdisk */
if((s->server_fd.id = tapdisk_server_register_event(SCHEDULER_POLL_READ_FD,
s->server_fd.fd, 0,
remus_server_accept, s)) < 0) {
RPRINTF("error registering server connection event handler: %s",
strerror(s->server_fd.id));
goto err_sfd;
}
return 0;
err_sfd:
close(s->server_fd.fd);
s->server_fd.fd = -1;
return rc;
}
/* wait for latest checkpoint to be applied */
static inline int server_writes_inflight(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
if (!s->ramdisk.inflight && !s->ramdisk.prev)
return 0;
return 1;
}
/* Due to block device prefetching this code may be called on the server side
* during normal replication. In this case we must return EBUSY, otherwise the
* domain may be started with stale data.
*/
void backup_queue_read(td_driver_t *driver, td_request_t treq)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
if(!remus_image)
remus_image = treq.image;
#if 0
/* due to prefetching, we must return EBUSY on server reads. This
* maintains a consistent disk image */
td_complete_request(treq, -EBUSY);
#else
/* what exactly is the race that requires the response above? */
td_forward_request(treq);
#endif
}
/* see above */
void backup_queue_write(td_driver_t *driver, td_request_t treq)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
/* on a server write, we know the domain has failed over. we must change our
* state to unprotected and then have the unprotected queue_write function
* handle the write
*/
switch_mode(driver, mode_unprotected);
/* TODO: call the appropriate write function rather than return EBUSY */
td_complete_request(treq, -EBUSY);
}
static int backup_start(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
int fd;
if (ramdisk_start(driver) < 0)
return -1;
tapdisk_remus.td_queue_read = backup_queue_read;
tapdisk_remus.td_queue_write = backup_queue_write;
/* TODO set flush function */
return 0;
}
static int server_do_wreq(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
static tdremus_wire_t twreq;
char buf[4096];
int len, rc;
char header[sizeof(uint32_t) + sizeof(uint64_t)];
uint32_t *sectors = (uint32_t *) header;
uint64_t *sector = (uint64_t *) &header[sizeof(uint32_t)];
// RPRINTF("received write request\n");
if (mread(s->stream_fd.fd, header, sizeof(header)) < 0)
goto err;
len = *sectors * driver->info.sector_size;
//RPRINTF("writing %d sectors (%d bytes) starting at %" PRIu64 "\n", *sectors, len,
// *sector);
if (len > sizeof(buf)) {
/* freak out! */
RPRINTF("write request too large: %d/%u\n", len, (unsigned)sizeof(buf));
return -1;
}
if (mread(s->stream_fd.fd, buf, len) < 0)
goto err;
if (ramdisk_write(&s->ramdisk, *sector, *sectors, buf) < 0)
goto err;
return 0;
err:
/* should start failover */
RPRINTF("backup write request error\n");
close_stream_fd(s);
return -1;
}
static int server_do_sreq(td_driver_t *driver)
{
/*
RPRINTF("submit request received\n");
*/
return 0;
}
/* at this point, the server can start applying the most recent
* ramdisk. */
static int server_do_creq(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
// RPRINTF("committing buffer\n");
ramdisk_start_flush(driver);
/* XXX this message should not be sent until flush completes! */
if (write(s->stream_fd.fd, TDREMUS_DONE, strlen(TDREMUS_DONE)) != 4)
return -1;
return 0;
}
/* called when data is pending in s->rfd */
static void remus_server_event(event_id_t id, char mode, void *private)
{
struct tdremus_state *s = (struct tdremus_state *)private;
td_driver_t *driver = s->tdremus_driver;
char req[5];
// RPRINTF("replication data waiting\n");
/* TODO: add a get_connection_by_event_id() function.
* for now we can assume that the fd is s->stream_fd */
if (mread(s->stream_fd.fd, req, sizeof(req) - 1) < 0) {
RPRINTF("error reading server event, activating backup\n");
switch_mode(driver, mode_unprotected);
return;
}
req[4] = '\0';
if (!strcmp(req, TDREMUS_WRITE))
server_do_wreq(driver);
else if (!strcmp(req, TDREMUS_SUBMIT))
server_do_sreq(driver);
else if (!strcmp(req, TDREMUS_COMMIT))
server_do_creq(driver);
else
RPRINTF("unknown request received: %s\n", req);
return;
}
/* unprotected */
void unprotected_queue_read(td_driver_t *driver, td_request_t treq)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
/* wait for previous ramdisk to flush before servicing reads */
if (server_writes_inflight(driver)) {
/* for now lets just return EBUSY. if this becomes an issue we can
* do something smarter */
td_complete_request(treq, -EBUSY);
}
else {
/* here we just pass reads through */
td_forward_request(treq);
}
}
/* For a recoverable remus solution we need to log unprotected writes here */
void unprotected_queue_write(td_driver_t *driver, td_request_t treq)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
/* wait for previous ramdisk to flush */
if (server_writes_inflight(driver)) {
RPRINTF("queue_write: waiting for queue to drain");
td_complete_request(treq, -EBUSY);
}
else {
// RPRINTF("servicing write request on backup\n");
td_forward_request(treq);
}
}
static int unprotected_start(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
RPRINTF("failure detected, activating passthrough\n");
/* close the server socket */
close_stream_fd(s);
/* unregister the replication stream */
tapdisk_server_unregister_event(s->server_fd.id);
/* close the replication stream */
close(s->server_fd.fd);
s->server_fd.fd = -1;
/* install the unprotected read/write handlers */
tapdisk_remus.td_queue_read = unprotected_queue_read;
tapdisk_remus.td_queue_write = unprotected_queue_write;
return 0;
}
/* control */
static inline int resolve_address(const char* addr, struct in_addr* ia)
{
struct hostent* he;
uint32_t ip;
if (!(he = gethostbyname(addr))) {
RPRINTF("error resolving %s: %d\n", addr, h_errno);
return -1;
}
if (!he->h_addr_list[0]) {
RPRINTF("no address found for %s\n", addr);
return -1;
}
/* network byte order */
ip = *((uint32_t**)he->h_addr_list)[0];
ia->s_addr = ip;
return 0;
}
static int get_args(td_driver_t *driver, const char* name)
{
struct tdremus_state *state = (struct tdremus_state *)driver->data;
char* host;
char* port;
// char* driver_str;
// char* parent;
// int type;
// char* path;
// unsigned long ulport;
// int i;
// struct sockaddr_in server_addr_in;
int gai_status;
int valid_addr;
struct addrinfo gai_hints;
struct addrinfo *servinfo, *servinfo_itr;
memset(&gai_hints, 0, sizeof gai_hints);
gai_hints.ai_family = AF_UNSPEC;
gai_hints.ai_socktype = SOCK_STREAM;
port = strchr(name, ':');
if (!port) {
RPRINTF("missing host in %s\n", name);
return -ENOENT;
}
if (!(host = strndup(name, port - name))) {
RPRINTF("unable to allocate host\n");
return -ENOMEM;
}
port++;
if ((gai_status = getaddrinfo(host, port, &gai_hints, &servinfo)) != 0) {
RPRINTF("getaddrinfo error: %s\n", gai_strerror(gai_status));
return -ENOENT;
}
/* TODO: do something smarter here */
valid_addr = 0;
for(servinfo_itr = servinfo; servinfo_itr != NULL; servinfo_itr = servinfo_itr->ai_next) {
void *addr;
char *ipver;
if (servinfo_itr->ai_family == AF_INET) {
valid_addr = 1;
memset(&state->sa, 0, sizeof(state->sa));
state->sa = *(struct sockaddr_in *)servinfo_itr->ai_addr;
break;
}
}
freeaddrinfo(servinfo);
if (!valid_addr)
return -ENOENT;
RPRINTF("host: %s, port: %d\n", inet_ntoa(state->sa.sin_addr), ntohs(state->sa.sin_port));
return 0;
}
static int switch_mode(td_driver_t *driver, enum tdremus_mode mode)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
int rc;
if (mode == s->mode)
return 0;
if (s->queue_flush)
if ((rc = s->queue_flush(driver)) < 0) {
// fall back to unprotected mode on error
RPRINTF("switch_mode: error flushing queue (old: %d, new: %d)", s->mode, mode);
mode = mode_unprotected;
}
if (mode == mode_unprotected)
rc = unprotected_start(driver);
else if (mode == mode_primary)
rc = primary_start(driver);
else if (mode == mode_backup)
rc = backup_start(driver);
else {
RPRINTF("unknown mode requested: %d\n", mode);
rc = -1;
}
if (!rc)
s->mode = mode;
return rc;
}
static void ctl_request(event_id_t id, char mode, void *private)
{
struct tdremus_state *s = (struct tdremus_state *)private;
td_driver_t *driver = s->tdremus_driver;
char msg[80];
int rc;
// RPRINTF("data waiting on control fifo\n");
if (!(rc = read(s->ctl_fd.fd, msg, sizeof(msg) - 1 /* append nul */))) {
RPRINTF("0-byte read received, reopening FIFO\n");
/*TODO: we may have to unregister/re-register with tapdisk_server */
close(s->ctl_fd.fd);
RPRINTF("FIFO closed\n");
if ((s->ctl_fd.fd = open(s->ctl_path, O_RDWR)) < 0) {
RPRINTF("error reopening FIFO: %d\n", errno);
}
return;
}
if (rc < 0) {
RPRINTF("error reading from FIFO: %d\n", errno);
return;
}
/* TODO: need to get driver somehow */
msg[rc] = '\0';
if (!strncmp(msg, "flush", 5)) {
if (s->queue_flush)
if ((rc = s->queue_flush(driver))) {
RPRINTF("error passing flush request to backup");
ctl_respond(s, TDREMUS_FAIL);
}
} else {
RPRINTF("unknown command: %s\n", msg);
}
}
static int ctl_respond(struct tdremus_state *s, const char *response)
{
int rc;
if ((rc = write(s->msg_fd.fd, response, strlen(response))) < 0) {
RPRINTF("error writing notification: %d\n", errno);
close(s->msg_fd.fd);
if ((s->msg_fd.fd = open(s->msg_path, O_RDWR)) < 0)
RPRINTF("error reopening FIFO: %d\n", errno);
}
return rc;
}
/* must be called after the underlying driver has been initialized */
static int ctl_open(td_driver_t *driver, const char* name)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
int i, l;
/* first we must ensure that BLKTAP_CTRL_DIR exists */
if (mkdir(BLKTAP_CTRL_DIR, 0755) && errno != EEXIST)
{
DPRINTF("error creating directory %s: %d\n", BLKTAP_CTRL_DIR, errno);
return -1;
}
/* use the device name to create the control fifo path */
if (asprintf(&s->ctl_path, BLKTAP_CTRL_DIR "/remus_%s", name) < 0)
return -1;
/* scrub fifo pathname */
for (i = strlen(BLKTAP_CTRL_DIR) + 1, l = strlen(s->ctl_path); i < l; i++) {
if (strchr(":/", s->ctl_path[i]))
s->ctl_path[i] = '_';
}
if (asprintf(&s->msg_path, "%s.msg", s->ctl_path) < 0)
goto err_ctlfifo;
if (mkfifo(s->ctl_path, S_IRWXU|S_IRWXG|S_IRWXO) && errno != EEXIST) {
RPRINTF("error creating control FIFO %s: %d\n", s->ctl_path, errno);
goto err_msgfifo;
}
if (mkfifo(s->msg_path, S_IRWXU|S_IRWXG|S_IRWXO) && errno != EEXIST) {
RPRINTF("error creating message FIFO %s: %d\n", s->msg_path, errno);
goto err_msgfifo;
}
/* RDWR so that fd doesn't block select when no writer is present */
if ((s->ctl_fd.fd = open(s->ctl_path, O_RDWR)) < 0) {
RPRINTF("error opening control FIFO %s: %d\n", s->ctl_path, errno);
goto err_msgfifo;
}
if ((s->msg_fd.fd = open(s->msg_path, O_RDWR)) < 0) {
RPRINTF("error opening message FIFO %s: %d\n", s->msg_path, errno);
goto err_openctlfifo;
}
RPRINTF("control FIFO %s\n", s->ctl_path);
RPRINTF("message FIFO %s\n", s->msg_path);
return 0;
err_openctlfifo:
close(s->ctl_fd.fd);
err_msgfifo:
free(s->msg_path);
s->msg_path = NULL;
err_ctlfifo:
free(s->ctl_path);
s->ctl_path = NULL;
return -1;
}
static void ctl_close(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
/* TODO: close *all* connections */
if(s->ctl_fd.fd)
close(s->ctl_fd.fd);
if (s->ctl_path) {
unlink(s->ctl_path);
free(s->ctl_path);
s->ctl_path = NULL;
}
if (s->msg_path) {
unlink(s->msg_path);
free(s->msg_path);
s->msg_path = NULL;
}
}
static int ctl_register(struct tdremus_state *s)
{
RPRINTF("registering ctl fifo\n");
/* register ctl fd */
s->ctl_fd.id = tapdisk_server_register_event(SCHEDULER_POLL_READ_FD, s->ctl_fd.fd, 0, ctl_request, s);
if (s->ctl_fd.id < 0) {
RPRINTF("error registering ctrl FIFO %s: %d\n", s->ctl_path, s->ctl_fd.id);
return -1;
}
return 0;
}
/* interface */
static int tdremus_open(td_driver_t *driver, const char *name,
td_flag_t flags)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
int rc;
RPRINTF("opening %s\n", name);
/* first we need to get the underlying vbd for this driver stack. To do so we
* need to know the vbd's id. Fortunately, for tapdisk2 this is hard-coded as
* 0 (see tapdisk2.c)
*/
device_vbd = tapdisk_server_get_vbd(0);
memset(s, 0, sizeof(*s));
s->server_fd.fd = -1;
s->stream_fd.fd = -1;
s->ctl_fd.fd = -1;
s->msg_fd.fd = -1;
/* TODO: this is only needed so that the server can send writes down
* the driver stack from the stream_fd event handler */
s->tdremus_driver = driver;
/* parse name to get info etc */
if ((rc = get_args(driver, name)))
return rc;
if ((rc = ctl_open(driver, name))) {
RPRINTF("error setting up control channel\n");
free(s->driver_data);
return rc;
}
if ((rc = ctl_register(s))) {
RPRINTF("error registering control channel\n");
free(s->driver_data);
return rc;
}
if (!(rc = remus_bind(s)))
rc = switch_mode(driver, mode_backup);
else if (rc == -2)
rc = switch_mode(driver, mode_primary);
if (!rc)
return 0;
tdremus_close(driver);
return -EIO;
}
static int tdremus_close(td_driver_t *driver)
{
struct tdremus_state *s = (struct tdremus_state *)driver->data;
RPRINTF("closing\n");
if (s->driver_data) {
free(s->driver_data);
s->driver_data = NULL;
}
if (s->server_fd.fd >= 0) {
close(s->server_fd.fd);
s->server_fd.fd = -1;
}
if (s->stream_fd.fd >= 0)
close_stream_fd(s);
ctl_close(driver);
return 0;
}
static int tdremus_get_parent_id(td_driver_t *driver, td_disk_id_t *id)
{
/* we shouldn't have a parent... for now */
return -EINVAL;
}
static int tdremus_validate_parent(td_driver_t *driver,
td_driver_t *pdriver, td_flag_t flags)
{
return 0;
}
struct tap_disk tapdisk_remus = {
.disk_type = "tapdisk_remus",
.private_data_size = sizeof(struct tdremus_state),
.td_open = tdremus_open,
.td_queue_read = unprotected_queue_read,
.td_queue_write = unprotected_queue_write,
.td_close = tdremus_close,
.td_get_parent_id = tdremus_get_parent_id,
.td_validate_parent = tdremus_validate_parent,
.td_debug = NULL,
};
|
