WSL2-Linux-Kernel/net/ceph/messenger.c

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C
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#include <linux/ceph/ceph_debug.h>
#include <linux/crc32c.h>
#include <linux/ctype.h>
#include <linux/highmem.h>
#include <linux/inet.h>
#include <linux/kthread.h>
#include <linux/net.h>
include cleanup: Update gfp.h and slab.h includes to prepare for breaking implicit slab.h inclusion from percpu.h percpu.h is included by sched.h and module.h and thus ends up being included when building most .c files. percpu.h includes slab.h which in turn includes gfp.h making everything defined by the two files universally available and complicating inclusion dependencies. percpu.h -> slab.h dependency is about to be removed. Prepare for this change by updating users of gfp and slab facilities include those headers directly instead of assuming availability. As this conversion needs to touch large number of source files, the following script is used as the basis of conversion. http://userweb.kernel.org/~tj/misc/slabh-sweep.py The script does the followings. * Scan files for gfp and slab usages and update includes such that only the necessary includes are there. ie. if only gfp is used, gfp.h, if slab is used, slab.h. * When the script inserts a new include, it looks at the include blocks and try to put the new include such that its order conforms to its surrounding. It's put in the include block which contains core kernel includes, in the same order that the rest are ordered - alphabetical, Christmas tree, rev-Xmas-tree or at the end if there doesn't seem to be any matching order. * If the script can't find a place to put a new include (mostly because the file doesn't have fitting include block), it prints out an error message indicating which .h file needs to be added to the file. The conversion was done in the following steps. 1. The initial automatic conversion of all .c files updated slightly over 4000 files, deleting around 700 includes and adding ~480 gfp.h and ~3000 slab.h inclusions. The script emitted errors for ~400 files. 2. Each error was manually checked. Some didn't need the inclusion, some needed manual addition while adding it to implementation .h or embedding .c file was more appropriate for others. This step added inclusions to around 150 files. 3. The script was run again and the output was compared to the edits from #2 to make sure no file was left behind. 4. Several build tests were done and a couple of problems were fixed. e.g. lib/decompress_*.c used malloc/free() wrappers around slab APIs requiring slab.h to be added manually. 5. The script was run on all .h files but without automatically editing them as sprinkling gfp.h and slab.h inclusions around .h files could easily lead to inclusion dependency hell. Most gfp.h inclusion directives were ignored as stuff from gfp.h was usually wildly available and often used in preprocessor macros. Each slab.h inclusion directive was examined and added manually as necessary. 6. percpu.h was updated not to include slab.h. 7. Build test were done on the following configurations and failures were fixed. CONFIG_GCOV_KERNEL was turned off for all tests (as my distributed build env didn't work with gcov compiles) and a few more options had to be turned off depending on archs to make things build (like ipr on powerpc/64 which failed due to missing writeq). * x86 and x86_64 UP and SMP allmodconfig and a custom test config. * powerpc and powerpc64 SMP allmodconfig * sparc and sparc64 SMP allmodconfig * ia64 SMP allmodconfig * s390 SMP allmodconfig * alpha SMP allmodconfig * um on x86_64 SMP allmodconfig 8. percpu.h modifications were reverted so that it could be applied as a separate patch and serve as bisection point. Given the fact that I had only a couple of failures from tests on step 6, I'm fairly confident about the coverage of this conversion patch. If there is a breakage, it's likely to be something in one of the arch headers which should be easily discoverable easily on most builds of the specific arch. Signed-off-by: Tejun Heo <tj@kernel.org> Guess-its-ok-by: Christoph Lameter <cl@linux-foundation.org> Cc: Ingo Molnar <mingo@redhat.com> Cc: Lee Schermerhorn <Lee.Schermerhorn@hp.com>
2010-03-24 11:04:11 +03:00
#include <linux/slab.h>
#include <linux/socket.h>
#include <linux/string.h>
#include <linux/bio.h>
#include <linux/blkdev.h>
#include <linux/dns_resolver.h>
#include <net/tcp.h>
#include <linux/ceph/libceph.h>
#include <linux/ceph/messenger.h>
#include <linux/ceph/decode.h>
#include <linux/ceph/pagelist.h>
#include <linux/export.h>
/*
* Ceph uses the messenger to exchange ceph_msg messages with other
* hosts in the system. The messenger provides ordered and reliable
* delivery. We tolerate TCP disconnects by reconnecting (with
* exponential backoff) in the case of a fault (disconnection, bad
* crc, protocol error). Acks allow sent messages to be discarded by
* the sender.
*/
/* State values for ceph_connection->sock_state; NEW is assumed to be 0 */
#define CON_SOCK_STATE_NEW 0 /* -> CLOSED */
#define CON_SOCK_STATE_CLOSED 1 /* -> CONNECTING */
#define CON_SOCK_STATE_CONNECTING 2 /* -> CONNECTED or -> CLOSING */
#define CON_SOCK_STATE_CONNECTED 3 /* -> CLOSING or -> CLOSED */
#define CON_SOCK_STATE_CLOSING 4 /* -> CLOSED */
/* static tag bytes (protocol control messages) */
static char tag_msg = CEPH_MSGR_TAG_MSG;
static char tag_ack = CEPH_MSGR_TAG_ACK;
static char tag_keepalive = CEPH_MSGR_TAG_KEEPALIVE;
#ifdef CONFIG_LOCKDEP
static struct lock_class_key socket_class;
#endif
/*
* When skipping (ignoring) a block of input we read it into a "skip
* buffer," which is this many bytes in size.
*/
#define SKIP_BUF_SIZE 1024
static void queue_con(struct ceph_connection *con);
static void con_work(struct work_struct *);
static void ceph_fault(struct ceph_connection *con);
/*
* Nicely render a sockaddr as a string. An array of formatted
* strings is used, to approximate reentrancy.
*/
#define ADDR_STR_COUNT_LOG 5 /* log2(# address strings in array) */
#define ADDR_STR_COUNT (1 << ADDR_STR_COUNT_LOG)
#define ADDR_STR_COUNT_MASK (ADDR_STR_COUNT - 1)
#define MAX_ADDR_STR_LEN 64 /* 54 is enough */
static char addr_str[ADDR_STR_COUNT][MAX_ADDR_STR_LEN];
static atomic_t addr_str_seq = ATOMIC_INIT(0);
static struct page *zero_page; /* used in certain error cases */
const char *ceph_pr_addr(const struct sockaddr_storage *ss)
{
int i;
char *s;
struct sockaddr_in *in4 = (struct sockaddr_in *) ss;
struct sockaddr_in6 *in6 = (struct sockaddr_in6 *) ss;
i = atomic_inc_return(&addr_str_seq) & ADDR_STR_COUNT_MASK;
s = addr_str[i];
switch (ss->ss_family) {
case AF_INET:
snprintf(s, MAX_ADDR_STR_LEN, "%pI4:%hu", &in4->sin_addr,
ntohs(in4->sin_port));
break;
case AF_INET6:
snprintf(s, MAX_ADDR_STR_LEN, "[%pI6c]:%hu", &in6->sin6_addr,
ntohs(in6->sin6_port));
break;
default:
snprintf(s, MAX_ADDR_STR_LEN, "(unknown sockaddr family %hu)",
ss->ss_family);
}
return s;
}
EXPORT_SYMBOL(ceph_pr_addr);
static void encode_my_addr(struct ceph_messenger *msgr)
{
memcpy(&msgr->my_enc_addr, &msgr->inst.addr, sizeof(msgr->my_enc_addr));
ceph_encode_addr(&msgr->my_enc_addr);
}
/*
* work queue for all reading and writing to/from the socket.
*/
static struct workqueue_struct *ceph_msgr_wq;
void _ceph_msgr_exit(void)
{
if (ceph_msgr_wq) {
destroy_workqueue(ceph_msgr_wq);
ceph_msgr_wq = NULL;
}
BUG_ON(zero_page == NULL);
kunmap(zero_page);
page_cache_release(zero_page);
zero_page = NULL;
}
int ceph_msgr_init(void)
{
BUG_ON(zero_page != NULL);
zero_page = ZERO_PAGE(0);
page_cache_get(zero_page);
ceph_msgr_wq = alloc_workqueue("ceph-msgr", WQ_NON_REENTRANT, 0);
if (ceph_msgr_wq)
return 0;
pr_err("msgr_init failed to create workqueue\n");
_ceph_msgr_exit();
return -ENOMEM;
}
EXPORT_SYMBOL(ceph_msgr_init);
void ceph_msgr_exit(void)
{
BUG_ON(ceph_msgr_wq == NULL);
_ceph_msgr_exit();
}
EXPORT_SYMBOL(ceph_msgr_exit);
void ceph_msgr_flush(void)
{
flush_workqueue(ceph_msgr_wq);
}
EXPORT_SYMBOL(ceph_msgr_flush);
/* Connection socket state transition functions */
static void con_sock_state_init(struct ceph_connection *con)
{
int old_state;
old_state = atomic_xchg(&con->sock_state, CON_SOCK_STATE_CLOSED);
if (WARN_ON(old_state != CON_SOCK_STATE_NEW))
printk("%s: unexpected old state %d\n", __func__, old_state);
}
static void con_sock_state_connecting(struct ceph_connection *con)
{
int old_state;
old_state = atomic_xchg(&con->sock_state, CON_SOCK_STATE_CONNECTING);
if (WARN_ON(old_state != CON_SOCK_STATE_CLOSED))
printk("%s: unexpected old state %d\n", __func__, old_state);
}
static void con_sock_state_connected(struct ceph_connection *con)
{
int old_state;
old_state = atomic_xchg(&con->sock_state, CON_SOCK_STATE_CONNECTED);
if (WARN_ON(old_state != CON_SOCK_STATE_CONNECTING))
printk("%s: unexpected old state %d\n", __func__, old_state);
}
static void con_sock_state_closing(struct ceph_connection *con)
{
int old_state;
old_state = atomic_xchg(&con->sock_state, CON_SOCK_STATE_CLOSING);
if (WARN_ON(old_state != CON_SOCK_STATE_CONNECTING &&
old_state != CON_SOCK_STATE_CONNECTED &&
old_state != CON_SOCK_STATE_CLOSING))
printk("%s: unexpected old state %d\n", __func__, old_state);
}
static void con_sock_state_closed(struct ceph_connection *con)
{
int old_state;
old_state = atomic_xchg(&con->sock_state, CON_SOCK_STATE_CLOSED);
if (WARN_ON(old_state != CON_SOCK_STATE_CONNECTED &&
old_state != CON_SOCK_STATE_CLOSING))
printk("%s: unexpected old state %d\n", __func__, old_state);
}
/*
* socket callback functions
*/
/* data available on socket, or listen socket received a connect */
static void ceph_sock_data_ready(struct sock *sk, int count_unused)
{
struct ceph_connection *con = sk->sk_user_data;
if (sk->sk_state != TCP_CLOSE_WAIT) {
dout("%s on %p state = %lu, queueing work\n", __func__,
con, con->state);
queue_con(con);
}
}
/* socket has buffer space for writing */
static void ceph_sock_write_space(struct sock *sk)
{
struct ceph_connection *con = sk->sk_user_data;
/* only queue to workqueue if there is data we want to write,
* and there is sufficient space in the socket buffer to accept
* more data. clear SOCK_NOSPACE so that ceph_sock_write_space()
* doesn't get called again until try_write() fills the socket
* buffer. See net/ipv4/tcp_input.c:tcp_check_space()
* and net/core/stream.c:sk_stream_write_space().
*/
if (test_bit(WRITE_PENDING, &con->flags)) {
if (sk_stream_wspace(sk) >= sk_stream_min_wspace(sk)) {
dout("%s %p queueing write work\n", __func__, con);
clear_bit(SOCK_NOSPACE, &sk->sk_socket->flags);
queue_con(con);
}
} else {
dout("%s %p nothing to write\n", __func__, con);
}
}
/* socket's state has changed */
static void ceph_sock_state_change(struct sock *sk)
{
struct ceph_connection *con = sk->sk_user_data;
dout("%s %p state = %lu sk_state = %u\n", __func__,
con, con->state, sk->sk_state);
if (test_bit(CLOSED, &con->state))
return;
switch (sk->sk_state) {
case TCP_CLOSE:
dout("%s TCP_CLOSE\n", __func__);
case TCP_CLOSE_WAIT:
dout("%s TCP_CLOSE_WAIT\n", __func__);
con_sock_state_closing(con);
set_bit(SOCK_CLOSED, &con->flags);
queue_con(con);
break;
case TCP_ESTABLISHED:
dout("%s TCP_ESTABLISHED\n", __func__);
con_sock_state_connected(con);
queue_con(con);
break;
default: /* Everything else is uninteresting */
break;
}
}
/*
* set up socket callbacks
*/
static void set_sock_callbacks(struct socket *sock,
struct ceph_connection *con)
{
struct sock *sk = sock->sk;
sk->sk_user_data = con;
sk->sk_data_ready = ceph_sock_data_ready;
sk->sk_write_space = ceph_sock_write_space;
sk->sk_state_change = ceph_sock_state_change;
}
/*
* socket helpers
*/
/*
* initiate connection to a remote socket.
*/
static int ceph_tcp_connect(struct ceph_connection *con)
{
struct sockaddr_storage *paddr = &con->peer_addr.in_addr;
struct socket *sock;
int ret;
BUG_ON(con->sock);
ret = sock_create_kern(con->peer_addr.in_addr.ss_family, SOCK_STREAM,
IPPROTO_TCP, &sock);
if (ret)
return ret;
sock->sk->sk_allocation = GFP_NOFS;
#ifdef CONFIG_LOCKDEP
lockdep_set_class(&sock->sk->sk_lock, &socket_class);
#endif
set_sock_callbacks(sock, con);
dout("connect %s\n", ceph_pr_addr(&con->peer_addr.in_addr));
con_sock_state_connecting(con);
ret = sock->ops->connect(sock, (struct sockaddr *)paddr, sizeof(*paddr),
O_NONBLOCK);
if (ret == -EINPROGRESS) {
dout("connect %s EINPROGRESS sk_state = %u\n",
ceph_pr_addr(&con->peer_addr.in_addr),
sock->sk->sk_state);
} else if (ret < 0) {
pr_err("connect %s error %d\n",
ceph_pr_addr(&con->peer_addr.in_addr), ret);
sock_release(sock);
con->error_msg = "connect error";
return ret;
}
con->sock = sock;
return 0;
}
static int ceph_tcp_recvmsg(struct socket *sock, void *buf, size_t len)
{
struct kvec iov = {buf, len};
struct msghdr msg = { .msg_flags = MSG_DONTWAIT | MSG_NOSIGNAL };
int r;
r = kernel_recvmsg(sock, &msg, &iov, 1, len, msg.msg_flags);
if (r == -EAGAIN)
r = 0;
return r;
}
/*
* write something. @more is true if caller will be sending more data
* shortly.
*/
static int ceph_tcp_sendmsg(struct socket *sock, struct kvec *iov,
size_t kvlen, size_t len, int more)
{
struct msghdr msg = { .msg_flags = MSG_DONTWAIT | MSG_NOSIGNAL };
int r;
if (more)
msg.msg_flags |= MSG_MORE;
else
msg.msg_flags |= MSG_EOR; /* superfluous, but what the hell */
r = kernel_sendmsg(sock, &msg, iov, kvlen, len);
if (r == -EAGAIN)
r = 0;
return r;
}
static int ceph_tcp_sendpage(struct socket *sock, struct page *page,
int offset, size_t size, int more)
{
int flags = MSG_DONTWAIT | MSG_NOSIGNAL | (more ? MSG_MORE : MSG_EOR);
int ret;
ret = kernel_sendpage(sock, page, offset, size, flags);
if (ret == -EAGAIN)
ret = 0;
return ret;
}
/*
* Shutdown/close the socket for the given connection.
*/
static int con_close_socket(struct ceph_connection *con)
{
int rc;
dout("con_close_socket on %p sock %p\n", con, con->sock);
if (!con->sock)
return 0;
rc = con->sock->ops->shutdown(con->sock, SHUT_RDWR);
sock_release(con->sock);
con->sock = NULL;
/*
* Forcibly clear the SOCK_CLOSE flag. It gets set
* independent of the connection mutex, and we could have
* received a socket close event before we had the chance to
* shut the socket down.
*/
clear_bit(SOCK_CLOSED, &con->flags);
con_sock_state_closed(con);
return rc;
}
/*
* Reset a connection. Discard all incoming and outgoing messages
* and clear *_seq state.
*/
static void ceph_msg_remove(struct ceph_msg *msg)
{
list_del_init(&msg->list_head);
BUG_ON(msg->con == NULL);
msg->con->ops->put(msg->con);
msg->con = NULL;
ceph_msg_put(msg);
}
static void ceph_msg_remove_list(struct list_head *head)
{
while (!list_empty(head)) {
struct ceph_msg *msg = list_first_entry(head, struct ceph_msg,
list_head);
ceph_msg_remove(msg);
}
}
static void reset_connection(struct ceph_connection *con)
{
/* reset connection, out_queue, msg_ and connect_seq */
/* discard existing out_queue and msg_seq */
ceph_msg_remove_list(&con->out_queue);
ceph_msg_remove_list(&con->out_sent);
if (con->in_msg) {
BUG_ON(con->in_msg->con != con);
con->in_msg->con = NULL;
ceph_msg_put(con->in_msg);
con->in_msg = NULL;
con->ops->put(con);
}
con->connect_seq = 0;
con->out_seq = 0;
if (con->out_msg) {
ceph_msg_put(con->out_msg);
con->out_msg = NULL;
}
con->in_seq = 0;
con->in_seq_acked = 0;
}
/*
* mark a peer down. drop any open connections.
*/
void ceph_con_close(struct ceph_connection *con)
{
dout("con_close %p peer %s\n", con,
ceph_pr_addr(&con->peer_addr.in_addr));
clear_bit(NEGOTIATING, &con->state);
clear_bit(CONNECTING, &con->state);
clear_bit(STANDBY, &con->state); /* avoid connect_seq bump */
set_bit(CLOSED, &con->state);
clear_bit(LOSSYTX, &con->flags); /* so we retry next connect */
clear_bit(KEEPALIVE_PENDING, &con->flags);
clear_bit(WRITE_PENDING, &con->flags);
mutex_lock(&con->mutex);
reset_connection(con);
con->peer_global_seq = 0;
cancel_delayed_work(&con->work);
mutex_unlock(&con->mutex);
queue_con(con);
}
EXPORT_SYMBOL(ceph_con_close);
/*
* Reopen a closed connection, with a new peer address.
*/
void ceph_con_open(struct ceph_connection *con, struct ceph_entity_addr *addr)
{
dout("con_open %p %s\n", con, ceph_pr_addr(&addr->in_addr));
set_bit(OPENING, &con->state);
WARN_ON(!test_and_clear_bit(CLOSED, &con->state));
memcpy(&con->peer_addr, addr, sizeof(*addr));
con->delay = 0; /* reset backoff memory */
queue_con(con);
}
EXPORT_SYMBOL(ceph_con_open);
/*
* return true if this connection ever successfully opened
*/
bool ceph_con_opened(struct ceph_connection *con)
{
return con->connect_seq > 0;
}
/*
* initialize a new connection.
*/
void ceph_con_init(struct ceph_connection *con, void *private,
const struct ceph_connection_operations *ops,
struct ceph_messenger *msgr, __u8 entity_type, __u64 entity_num)
{
dout("con_init %p\n", con);
memset(con, 0, sizeof(*con));
con->private = private;
con->ops = ops;
con->msgr = msgr;
con_sock_state_init(con);
con->peer_name.type = (__u8) entity_type;
con->peer_name.num = cpu_to_le64(entity_num);
mutex_init(&con->mutex);
INIT_LIST_HEAD(&con->out_queue);
INIT_LIST_HEAD(&con->out_sent);
INIT_DELAYED_WORK(&con->work, con_work);
set_bit(CLOSED, &con->state);
}
EXPORT_SYMBOL(ceph_con_init);
/*
* We maintain a global counter to order connection attempts. Get
* a unique seq greater than @gt.
*/
static u32 get_global_seq(struct ceph_messenger *msgr, u32 gt)
{
u32 ret;
spin_lock(&msgr->global_seq_lock);
if (msgr->global_seq < gt)
msgr->global_seq = gt;
ret = ++msgr->global_seq;
spin_unlock(&msgr->global_seq_lock);
return ret;
}
static void con_out_kvec_reset(struct ceph_connection *con)
{
con->out_kvec_left = 0;
con->out_kvec_bytes = 0;
con->out_kvec_cur = &con->out_kvec[0];
}
static void con_out_kvec_add(struct ceph_connection *con,
size_t size, void *data)
{
int index;
index = con->out_kvec_left;
BUG_ON(index >= ARRAY_SIZE(con->out_kvec));
con->out_kvec[index].iov_len = size;
con->out_kvec[index].iov_base = data;
con->out_kvec_left++;
con->out_kvec_bytes += size;
}
#ifdef CONFIG_BLOCK
static void init_bio_iter(struct bio *bio, struct bio **iter, int *seg)
{
if (!bio) {
*iter = NULL;
*seg = 0;
return;
}
*iter = bio;
*seg = bio->bi_idx;
}
static void iter_bio_next(struct bio **bio_iter, int *seg)
{
if (*bio_iter == NULL)
return;
BUG_ON(*seg >= (*bio_iter)->bi_vcnt);
(*seg)++;
if (*seg == (*bio_iter)->bi_vcnt)
init_bio_iter((*bio_iter)->bi_next, bio_iter, seg);
}
#endif
static void prepare_write_message_data(struct ceph_connection *con)
{
struct ceph_msg *msg = con->out_msg;
BUG_ON(!msg);
BUG_ON(!msg->hdr.data_len);
/* initialize page iterator */
con->out_msg_pos.page = 0;
if (msg->pages)
con->out_msg_pos.page_pos = msg->page_alignment;
else
con->out_msg_pos.page_pos = 0;
#ifdef CONFIG_BLOCK
if (msg->bio)
init_bio_iter(msg->bio, &msg->bio_iter, &msg->bio_seg);
#endif
con->out_msg_pos.data_pos = 0;
con->out_msg_pos.did_page_crc = false;
con->out_more = 1; /* data + footer will follow */
}
/*
* Prepare footer for currently outgoing message, and finish things
* off. Assumes out_kvec* are already valid.. we just add on to the end.
*/
static void prepare_write_message_footer(struct ceph_connection *con)
{
struct ceph_msg *m = con->out_msg;
int v = con->out_kvec_left;
m->footer.flags |= CEPH_MSG_FOOTER_COMPLETE;
dout("prepare_write_message_footer %p\n", con);
con->out_kvec_is_msg = true;
con->out_kvec[v].iov_base = &m->footer;
con->out_kvec[v].iov_len = sizeof(m->footer);
con->out_kvec_bytes += sizeof(m->footer);
con->out_kvec_left++;
con->out_more = m->more_to_follow;
con->out_msg_done = true;
}
/*
* Prepare headers for the next outgoing message.
*/
static void prepare_write_message(struct ceph_connection *con)
{
struct ceph_msg *m;
u32 crc;
con_out_kvec_reset(con);
con->out_kvec_is_msg = true;
con->out_msg_done = false;
/* Sneak an ack in there first? If we can get it into the same
* TCP packet that's a good thing. */
if (con->in_seq > con->in_seq_acked) {
con->in_seq_acked = con->in_seq;
con_out_kvec_add(con, sizeof (tag_ack), &tag_ack);
con->out_temp_ack = cpu_to_le64(con->in_seq_acked);
con_out_kvec_add(con, sizeof (con->out_temp_ack),
&con->out_temp_ack);
}
BUG_ON(list_empty(&con->out_queue));
m = list_first_entry(&con->out_queue, struct ceph_msg, list_head);
con->out_msg = m;
BUG_ON(m->con != con);
/* put message on sent list */
ceph_msg_get(m);
list_move_tail(&m->list_head, &con->out_sent);
/*
* only assign outgoing seq # if we haven't sent this message
* yet. if it is requeued, resend with it's original seq.
*/
if (m->needs_out_seq) {
m->hdr.seq = cpu_to_le64(++con->out_seq);
m->needs_out_seq = false;
}
dout("prepare_write_message %p seq %lld type %d len %d+%d+%d %d pgs\n",
m, con->out_seq, le16_to_cpu(m->hdr.type),
le32_to_cpu(m->hdr.front_len), le32_to_cpu(m->hdr.middle_len),
le32_to_cpu(m->hdr.data_len),
m->nr_pages);
BUG_ON(le32_to_cpu(m->hdr.front_len) != m->front.iov_len);
/* tag + hdr + front + middle */
con_out_kvec_add(con, sizeof (tag_msg), &tag_msg);
con_out_kvec_add(con, sizeof (m->hdr), &m->hdr);
con_out_kvec_add(con, m->front.iov_len, m->front.iov_base);
if (m->middle)
con_out_kvec_add(con, m->middle->vec.iov_len,
m->middle->vec.iov_base);
/* fill in crc (except data pages), footer */
crc = crc32c(0, &m->hdr, offsetof(struct ceph_msg_header, crc));
con->out_msg->hdr.crc = cpu_to_le32(crc);
con->out_msg->footer.flags = 0;
crc = crc32c(0, m->front.iov_base, m->front.iov_len);
con->out_msg->footer.front_crc = cpu_to_le32(crc);
if (m->middle) {
crc = crc32c(0, m->middle->vec.iov_base,
m->middle->vec.iov_len);
con->out_msg->footer.middle_crc = cpu_to_le32(crc);
} else
con->out_msg->footer.middle_crc = 0;
dout("%s front_crc %u middle_crc %u\n", __func__,
le32_to_cpu(con->out_msg->footer.front_crc),
le32_to_cpu(con->out_msg->footer.middle_crc));
/* is there a data payload? */
con->out_msg->footer.data_crc = 0;
if (m->hdr.data_len)
prepare_write_message_data(con);
else
/* no, queue up footer too and be done */
prepare_write_message_footer(con);
set_bit(WRITE_PENDING, &con->flags);
}
/*
* Prepare an ack.
*/
static void prepare_write_ack(struct ceph_connection *con)
{
dout("prepare_write_ack %p %llu -> %llu\n", con,
con->in_seq_acked, con->in_seq);
con->in_seq_acked = con->in_seq;
con_out_kvec_reset(con);
con_out_kvec_add(con, sizeof (tag_ack), &tag_ack);
con->out_temp_ack = cpu_to_le64(con->in_seq_acked);
con_out_kvec_add(con, sizeof (con->out_temp_ack),
&con->out_temp_ack);
con->out_more = 1; /* more will follow.. eventually.. */
set_bit(WRITE_PENDING, &con->flags);
}
/*
* Prepare to write keepalive byte.
*/
static void prepare_write_keepalive(struct ceph_connection *con)
{
dout("prepare_write_keepalive %p\n", con);
con_out_kvec_reset(con);
con_out_kvec_add(con, sizeof (tag_keepalive), &tag_keepalive);
set_bit(WRITE_PENDING, &con->flags);
}
/*
* Connection negotiation.
*/
static struct ceph_auth_handshake *get_connect_authorizer(struct ceph_connection *con,
int *auth_proto)
{
struct ceph_auth_handshake *auth;
if (!con->ops->get_authorizer) {
con->out_connect.authorizer_protocol = CEPH_AUTH_UNKNOWN;
con->out_connect.authorizer_len = 0;
return NULL;
}
/* Can't hold the mutex while getting authorizer */
mutex_unlock(&con->mutex);
auth = con->ops->get_authorizer(con, auth_proto, con->auth_retry);
mutex_lock(&con->mutex);
if (IS_ERR(auth))
return auth;
if (test_bit(CLOSED, &con->state) || test_bit(OPENING, &con->flags))
return ERR_PTR(-EAGAIN);
con->auth_reply_buf = auth->authorizer_reply_buf;
con->auth_reply_buf_len = auth->authorizer_reply_buf_len;
return auth;
}
/*
* We connected to a peer and are saying hello.
*/
static void prepare_write_banner(struct ceph_connection *con)
{
con_out_kvec_add(con, strlen(CEPH_BANNER), CEPH_BANNER);
con_out_kvec_add(con, sizeof (con->msgr->my_enc_addr),
&con->msgr->my_enc_addr);
con->out_more = 0;
set_bit(WRITE_PENDING, &con->flags);
}
static int prepare_write_connect(struct ceph_connection *con)
{
unsigned int global_seq = get_global_seq(con->msgr, 0);
int proto;
int auth_proto;
struct ceph_auth_handshake *auth;
switch (con->peer_name.type) {
case CEPH_ENTITY_TYPE_MON:
proto = CEPH_MONC_PROTOCOL;
break;
case CEPH_ENTITY_TYPE_OSD:
proto = CEPH_OSDC_PROTOCOL;
break;
case CEPH_ENTITY_TYPE_MDS:
proto = CEPH_MDSC_PROTOCOL;
break;
default:
BUG();
}
dout("prepare_write_connect %p cseq=%d gseq=%d proto=%d\n", con,
con->connect_seq, global_seq, proto);
con->out_connect.features = cpu_to_le64(con->msgr->supported_features);
con->out_connect.host_type = cpu_to_le32(CEPH_ENTITY_TYPE_CLIENT);
con->out_connect.connect_seq = cpu_to_le32(con->connect_seq);
con->out_connect.global_seq = cpu_to_le32(global_seq);
con->out_connect.protocol_version = cpu_to_le32(proto);
con->out_connect.flags = 0;
auth_proto = CEPH_AUTH_UNKNOWN;
auth = get_connect_authorizer(con, &auth_proto);
if (IS_ERR(auth))
return PTR_ERR(auth);
con->out_connect.authorizer_protocol = cpu_to_le32(auth_proto);
con->out_connect.authorizer_len = auth ?
cpu_to_le32(auth->authorizer_buf_len) : 0;
con_out_kvec_add(con, sizeof (con->out_connect),
&con->out_connect);
if (auth && auth->authorizer_buf_len)
con_out_kvec_add(con, auth->authorizer_buf_len,
auth->authorizer_buf);
con->out_more = 0;
set_bit(WRITE_PENDING, &con->flags);
return 0;
}
/*
* write as much of pending kvecs to the socket as we can.
* 1 -> done
* 0 -> socket full, but more to do
* <0 -> error
*/
static int write_partial_kvec(struct ceph_connection *con)
{
int ret;
dout("write_partial_kvec %p %d left\n", con, con->out_kvec_bytes);
while (con->out_kvec_bytes > 0) {
ret = ceph_tcp_sendmsg(con->sock, con->out_kvec_cur,
con->out_kvec_left, con->out_kvec_bytes,
con->out_more);
if (ret <= 0)
goto out;
con->out_kvec_bytes -= ret;
if (con->out_kvec_bytes == 0)
break; /* done */
/* account for full iov entries consumed */
while (ret >= con->out_kvec_cur->iov_len) {
BUG_ON(!con->out_kvec_left);
ret -= con->out_kvec_cur->iov_len;
con->out_kvec_cur++;
con->out_kvec_left--;
}
/* and for a partially-consumed entry */
if (ret) {
con->out_kvec_cur->iov_len -= ret;
con->out_kvec_cur->iov_base += ret;
}
}
con->out_kvec_left = 0;
con->out_kvec_is_msg = false;
ret = 1;
out:
dout("write_partial_kvec %p %d left in %d kvecs ret = %d\n", con,
con->out_kvec_bytes, con->out_kvec_left, ret);
return ret; /* done! */
}
static void out_msg_pos_next(struct ceph_connection *con, struct page *page,
size_t len, size_t sent, bool in_trail)
{
struct ceph_msg *msg = con->out_msg;
BUG_ON(!msg);
BUG_ON(!sent);
con->out_msg_pos.data_pos += sent;
con->out_msg_pos.page_pos += sent;
if (sent == len) {
con->out_msg_pos.page_pos = 0;
con->out_msg_pos.page++;
con->out_msg_pos.did_page_crc = false;
if (in_trail)
list_move_tail(&page->lru,
&msg->trail->head);
else if (msg->pagelist)
list_move_tail(&page->lru,
&msg->pagelist->head);
#ifdef CONFIG_BLOCK
else if (msg->bio)
iter_bio_next(&msg->bio_iter, &msg->bio_seg);
#endif
}
}
/*
* Write as much message data payload as we can. If we finish, queue
* up the footer.
* 1 -> done, footer is now queued in out_kvec[].
* 0 -> socket full, but more to do
* <0 -> error
*/
static int write_partial_msg_pages(struct ceph_connection *con)
{
struct ceph_msg *msg = con->out_msg;
unsigned int data_len = le32_to_cpu(msg->hdr.data_len);
size_t len;
bool do_datacrc = !con->msgr->nocrc;
int ret;
int total_max_write;
bool in_trail = false;
size_t trail_len = (msg->trail ? msg->trail->length : 0);
dout("write_partial_msg_pages %p msg %p page %d/%d offset %d\n",
con, msg, con->out_msg_pos.page, msg->nr_pages,
con->out_msg_pos.page_pos);
while (data_len > con->out_msg_pos.data_pos) {
struct page *page = NULL;
int max_write = PAGE_SIZE;
int bio_offset = 0;
total_max_write = data_len - trail_len -
con->out_msg_pos.data_pos;
/*
* if we are calculating the data crc (the default), we need
* to map the page. if our pages[] has been revoked, use the
* zero page.
*/
/* have we reached the trail part of the data? */
if (con->out_msg_pos.data_pos >= data_len - trail_len) {
in_trail = true;
total_max_write = data_len - con->out_msg_pos.data_pos;
page = list_first_entry(&msg->trail->head,
struct page, lru);
} else if (msg->pages) {
page = msg->pages[con->out_msg_pos.page];
} else if (msg->pagelist) {
page = list_first_entry(&msg->pagelist->head,
struct page, lru);
#ifdef CONFIG_BLOCK
} else if (msg->bio) {
struct bio_vec *bv;
bv = bio_iovec_idx(msg->bio_iter, msg->bio_seg);
page = bv->bv_page;
bio_offset = bv->bv_offset;
max_write = bv->bv_len;
#endif
} else {
page = zero_page;
}
len = min_t(int, max_write - con->out_msg_pos.page_pos,
total_max_write);
if (do_datacrc && !con->out_msg_pos.did_page_crc) {
void *base;
u32 crc;
u32 tmpcrc = le32_to_cpu(msg->footer.data_crc);
char *kaddr;
kaddr = kmap(page);
BUG_ON(kaddr == NULL);
base = kaddr + con->out_msg_pos.page_pos + bio_offset;
crc = crc32c(tmpcrc, base, len);
msg->footer.data_crc = cpu_to_le32(crc);
con->out_msg_pos.did_page_crc = true;
}
ret = ceph_tcp_sendpage(con->sock, page,
con->out_msg_pos.page_pos + bio_offset,
len, 1);
if (do_datacrc)
kunmap(page);
if (ret <= 0)
goto out;
out_msg_pos_next(con, page, len, (size_t) ret, in_trail);
}
dout("write_partial_msg_pages %p msg %p done\n", con, msg);
/* prepare and queue up footer, too */
if (!do_datacrc)
msg->footer.flags |= CEPH_MSG_FOOTER_NOCRC;
con_out_kvec_reset(con);
prepare_write_message_footer(con);
ret = 1;
out:
return ret;
}
/*
* write some zeros
*/
static int write_partial_skip(struct ceph_connection *con)
{
int ret;
while (con->out_skip > 0) {
size_t size = min(con->out_skip, (int) PAGE_CACHE_SIZE);
ret = ceph_tcp_sendpage(con->sock, zero_page, 0, size, 1);
if (ret <= 0)
goto out;
con->out_skip -= ret;
}
ret = 1;
out:
return ret;
}
/*
* Prepare to read connection handshake, or an ack.
*/
static void prepare_read_banner(struct ceph_connection *con)
{
dout("prepare_read_banner %p\n", con);
con->in_base_pos = 0;
}
static void prepare_read_connect(struct ceph_connection *con)
{
dout("prepare_read_connect %p\n", con);
con->in_base_pos = 0;
}
static void prepare_read_ack(struct ceph_connection *con)
{
dout("prepare_read_ack %p\n", con);
con->in_base_pos = 0;
}
static void prepare_read_tag(struct ceph_connection *con)
{
dout("prepare_read_tag %p\n", con);
con->in_base_pos = 0;
con->in_tag = CEPH_MSGR_TAG_READY;
}
/*
* Prepare to read a message.
*/
static int prepare_read_message(struct ceph_connection *con)
{
dout("prepare_read_message %p\n", con);
BUG_ON(con->in_msg != NULL);
con->in_base_pos = 0;
con->in_front_crc = con->in_middle_crc = con->in_data_crc = 0;
return 0;
}
static int read_partial(struct ceph_connection *con,
int end, int size, void *object)
{
while (con->in_base_pos < end) {
int left = end - con->in_base_pos;
int have = size - left;
int ret = ceph_tcp_recvmsg(con->sock, object + have, left);
if (ret <= 0)
return ret;
con->in_base_pos += ret;
}
return 1;
}
/*
* Read all or part of the connect-side handshake on a new connection
*/
static int read_partial_banner(struct ceph_connection *con)
{
int size;
int end;
int ret;
dout("read_partial_banner %p at %d\n", con, con->in_base_pos);
/* peer's banner */
size = strlen(CEPH_BANNER);
end = size;
ret = read_partial(con, end, size, con->in_banner);
if (ret <= 0)
goto out;
size = sizeof (con->actual_peer_addr);
end += size;
ret = read_partial(con, end, size, &con->actual_peer_addr);
if (ret <= 0)
goto out;
size = sizeof (con->peer_addr_for_me);
end += size;
ret = read_partial(con, end, size, &con->peer_addr_for_me);
if (ret <= 0)
goto out;
out:
return ret;
}
static int read_partial_connect(struct ceph_connection *con)
{
int size;
int end;
int ret;
dout("read_partial_connect %p at %d\n", con, con->in_base_pos);
size = sizeof (con->in_reply);
end = size;
ret = read_partial(con, end, size, &con->in_reply);
if (ret <= 0)
goto out;
size = le32_to_cpu(con->in_reply.authorizer_len);
end += size;
ret = read_partial(con, end, size, con->auth_reply_buf);
if (ret <= 0)
goto out;
dout("read_partial_connect %p tag %d, con_seq = %u, g_seq = %u\n",
con, (int)con->in_reply.tag,
le32_to_cpu(con->in_reply.connect_seq),
le32_to_cpu(con->in_reply.global_seq));
out:
return ret;
}
/*
* Verify the hello banner looks okay.
*/
static int verify_hello(struct ceph_connection *con)
{
if (memcmp(con->in_banner, CEPH_BANNER, strlen(CEPH_BANNER))) {
pr_err("connect to %s got bad banner\n",
ceph_pr_addr(&con->peer_addr.in_addr));
con->error_msg = "protocol error, bad banner";
return -1;
}
return 0;
}
static bool addr_is_blank(struct sockaddr_storage *ss)
{
switch (ss->ss_family) {
case AF_INET:
return ((struct sockaddr_in *)ss)->sin_addr.s_addr == 0;
case AF_INET6:
return
((struct sockaddr_in6 *)ss)->sin6_addr.s6_addr32[0] == 0 &&
((struct sockaddr_in6 *)ss)->sin6_addr.s6_addr32[1] == 0 &&
((struct sockaddr_in6 *)ss)->sin6_addr.s6_addr32[2] == 0 &&
((struct sockaddr_in6 *)ss)->sin6_addr.s6_addr32[3] == 0;
}
return false;
}
static int addr_port(struct sockaddr_storage *ss)
{
switch (ss->ss_family) {
case AF_INET:
return ntohs(((struct sockaddr_in *)ss)->sin_port);
case AF_INET6:
return ntohs(((struct sockaddr_in6 *)ss)->sin6_port);
}
return 0;
}
static void addr_set_port(struct sockaddr_storage *ss, int p)
{
switch (ss->ss_family) {
case AF_INET:
((struct sockaddr_in *)ss)->sin_port = htons(p);
break;
case AF_INET6:
((struct sockaddr_in6 *)ss)->sin6_port = htons(p);
break;
}
}
/*
* Unlike other *_pton function semantics, zero indicates success.
*/
static int ceph_pton(const char *str, size_t len, struct sockaddr_storage *ss,
char delim, const char **ipend)
{
struct sockaddr_in *in4 = (struct sockaddr_in *) ss;
struct sockaddr_in6 *in6 = (struct sockaddr_in6 *) ss;
memset(ss, 0, sizeof(*ss));
if (in4_pton(str, len, (u8 *)&in4->sin_addr.s_addr, delim, ipend)) {
ss->ss_family = AF_INET;
return 0;
}
if (in6_pton(str, len, (u8 *)&in6->sin6_addr.s6_addr, delim, ipend)) {
ss->ss_family = AF_INET6;
return 0;
}
return -EINVAL;
}
/*
* Extract hostname string and resolve using kernel DNS facility.
*/
#ifdef CONFIG_CEPH_LIB_USE_DNS_RESOLVER
static int ceph_dns_resolve_name(const char *name, size_t namelen,
struct sockaddr_storage *ss, char delim, const char **ipend)
{
const char *end, *delim_p;
char *colon_p, *ip_addr = NULL;
int ip_len, ret;
/*
* The end of the hostname occurs immediately preceding the delimiter or
* the port marker (':') where the delimiter takes precedence.
*/
delim_p = memchr(name, delim, namelen);
colon_p = memchr(name, ':', namelen);
if (delim_p && colon_p)
end = delim_p < colon_p ? delim_p : colon_p;
else if (!delim_p && colon_p)
end = colon_p;
else {
end = delim_p;
if (!end) /* case: hostname:/ */
end = name + namelen;
}
if (end <= name)
return -EINVAL;
/* do dns_resolve upcall */
ip_len = dns_query(NULL, name, end - name, NULL, &ip_addr, NULL);
if (ip_len > 0)
ret = ceph_pton(ip_addr, ip_len, ss, -1, NULL);
else
ret = -ESRCH;
kfree(ip_addr);
*ipend = end;
pr_info("resolve '%.*s' (ret=%d): %s\n", (int)(end - name), name,
ret, ret ? "failed" : ceph_pr_addr(ss));
return ret;
}
#else
static inline int ceph_dns_resolve_name(const char *name, size_t namelen,
struct sockaddr_storage *ss, char delim, const char **ipend)
{
return -EINVAL;
}
#endif
/*
* Parse a server name (IP or hostname). If a valid IP address is not found
* then try to extract a hostname to resolve using userspace DNS upcall.
*/
static int ceph_parse_server_name(const char *name, size_t namelen,
struct sockaddr_storage *ss, char delim, const char **ipend)
{
int ret;
ret = ceph_pton(name, namelen, ss, delim, ipend);
if (ret)
ret = ceph_dns_resolve_name(name, namelen, ss, delim, ipend);
return ret;
}
/*
* Parse an ip[:port] list into an addr array. Use the default
* monitor port if a port isn't specified.
*/
int ceph_parse_ips(const char *c, const char *end,
struct ceph_entity_addr *addr,
int max_count, int *count)
{
int i, ret = -EINVAL;
const char *p = c;
dout("parse_ips on '%.*s'\n", (int)(end-c), c);
for (i = 0; i < max_count; i++) {
const char *ipend;
struct sockaddr_storage *ss = &addr[i].in_addr;
int port;
char delim = ',';
if (*p == '[') {
delim = ']';
p++;
}
ret = ceph_parse_server_name(p, end - p, ss, delim, &ipend);
if (ret)
goto bad;
ret = -EINVAL;
p = ipend;
if (delim == ']') {
if (*p != ']') {
dout("missing matching ']'\n");
goto bad;
}
p++;
}
/* port? */
if (p < end && *p == ':') {
port = 0;
p++;
while (p < end && *p >= '0' && *p <= '9') {
port = (port * 10) + (*p - '0');
p++;
}
if (port > 65535 || port == 0)
goto bad;
} else {
port = CEPH_MON_PORT;
}
addr_set_port(ss, port);
dout("parse_ips got %s\n", ceph_pr_addr(ss));
if (p == end)
break;
if (*p != ',')
goto bad;
p++;
}
if (p != end)
goto bad;
if (count)
*count = i + 1;
return 0;
bad:
pr_err("parse_ips bad ip '%.*s'\n", (int)(end - c), c);
return ret;
}
EXPORT_SYMBOL(ceph_parse_ips);
static int process_banner(struct ceph_connection *con)
{
dout("process_banner on %p\n", con);
if (verify_hello(con) < 0)
return -1;
ceph_decode_addr(&con->actual_peer_addr);
ceph_decode_addr(&con->peer_addr_for_me);
/*
* Make sure the other end is who we wanted. note that the other
* end may not yet know their ip address, so if it's 0.0.0.0, give
* them the benefit of the doubt.
*/
if (memcmp(&con->peer_addr, &con->actual_peer_addr,
sizeof(con->peer_addr)) != 0 &&
!(addr_is_blank(&con->actual_peer_addr.in_addr) &&
con->actual_peer_addr.nonce == con->peer_addr.nonce)) {
pr_warning("wrong peer, want %s/%d, got %s/%d\n",
ceph_pr_addr(&con->peer_addr.in_addr),
(int)le32_to_cpu(con->peer_addr.nonce),
ceph_pr_addr(&con->actual_peer_addr.in_addr),
(int)le32_to_cpu(con->actual_peer_addr.nonce));
con->error_msg = "wrong peer at address";
return -1;
}
/*
* did we learn our address?
*/
if (addr_is_blank(&con->msgr->inst.addr.in_addr)) {
int port = addr_port(&con->msgr->inst.addr.in_addr);
memcpy(&con->msgr->inst.addr.in_addr,
&con->peer_addr_for_me.in_addr,
sizeof(con->peer_addr_for_me.in_addr));
addr_set_port(&con->msgr->inst.addr.in_addr, port);
encode_my_addr(con->msgr);
dout("process_banner learned my addr is %s\n",
ceph_pr_addr(&con->msgr->inst.addr.in_addr));
}
set_bit(NEGOTIATING, &con->state);
prepare_read_connect(con);
return 0;
}
static void fail_protocol(struct ceph_connection *con)
{
reset_connection(con);
set_bit(CLOSED, &con->state); /* in case there's queued work */
}
static int process_connect(struct ceph_connection *con)
{
u64 sup_feat = con->msgr->supported_features;
u64 req_feat = con->msgr->required_features;
u64 server_feat = le64_to_cpu(con->in_reply.features);
int ret;
dout("process_connect on %p tag %d\n", con, (int)con->in_tag);
switch (con->in_reply.tag) {
case CEPH_MSGR_TAG_FEATURES:
pr_err("%s%lld %s feature set mismatch,"
" my %llx < server's %llx, missing %llx\n",
ENTITY_NAME(con->peer_name),
ceph_pr_addr(&con->peer_addr.in_addr),
sup_feat, server_feat, server_feat & ~sup_feat);
con->error_msg = "missing required protocol features";
fail_protocol(con);
return -1;
case CEPH_MSGR_TAG_BADPROTOVER:
pr_err("%s%lld %s protocol version mismatch,"
" my %d != server's %d\n",
ENTITY_NAME(con->peer_name),
ceph_pr_addr(&con->peer_addr.in_addr),
le32_to_cpu(con->out_connect.protocol_version),
le32_to_cpu(con->in_reply.protocol_version));
con->error_msg = "protocol version mismatch";
fail_protocol(con);
return -1;
case CEPH_MSGR_TAG_BADAUTHORIZER:
con->auth_retry++;
dout("process_connect %p got BADAUTHORIZER attempt %d\n", con,
con->auth_retry);
if (con->auth_retry == 2) {
con->error_msg = "connect authorization failure";
return -1;
}
con->auth_retry = 1;
con_out_kvec_reset(con);
ret = prepare_write_connect(con);
if (ret < 0)
return ret;
prepare_read_connect(con);
break;
case CEPH_MSGR_TAG_RESETSESSION:
/*
* If we connected with a large connect_seq but the peer
* has no record of a session with us (no connection, or
* connect_seq == 0), they will send RESETSESION to indicate
* that they must have reset their session, and may have
* dropped messages.
*/
dout("process_connect got RESET peer seq %u\n",
le32_to_cpu(con->in_connect.connect_seq));
pr_err("%s%lld %s connection reset\n",
ENTITY_NAME(con->peer_name),
ceph_pr_addr(&con->peer_addr.in_addr));
reset_connection(con);
con_out_kvec_reset(con);
ret = prepare_write_connect(con);
if (ret < 0)
return ret;
prepare_read_connect(con);
/* Tell ceph about it. */
mutex_unlock(&con->mutex);
pr_info("reset on %s%lld\n", ENTITY_NAME(con->peer_name));
if (con->ops->peer_reset)
con->ops->peer_reset(con);
mutex_lock(&con->mutex);
if (test_bit(CLOSED, &con->state) ||
test_bit(OPENING, &con->state))
return -EAGAIN;
break;
case CEPH_MSGR_TAG_RETRY_SESSION:
/*
* If we sent a smaller connect_seq than the peer has, try
* again with a larger value.
*/
dout("process_connect got RETRY my seq = %u, peer_seq = %u\n",
le32_to_cpu(con->out_connect.connect_seq),
le32_to_cpu(con->in_connect.connect_seq));
con->connect_seq = le32_to_cpu(con->in_connect.connect_seq);
con_out_kvec_reset(con);
ret = prepare_write_connect(con);
if (ret < 0)
return ret;
prepare_read_connect(con);
break;
case CEPH_MSGR_TAG_RETRY_GLOBAL:
/*
* If we sent a smaller global_seq than the peer has, try
* again with a larger value.
*/
dout("process_connect got RETRY_GLOBAL my %u peer_gseq %u\n",
con->peer_global_seq,
le32_to_cpu(con->in_connect.global_seq));
get_global_seq(con->msgr,
le32_to_cpu(con->in_connect.global_seq));
con_out_kvec_reset(con);
ret = prepare_write_connect(con);
if (ret < 0)
return ret;
prepare_read_connect(con);
break;
case CEPH_MSGR_TAG_READY:
if (req_feat & ~server_feat) {
pr_err("%s%lld %s protocol feature mismatch,"
" my required %llx > server's %llx, need %llx\n",
ENTITY_NAME(con->peer_name),
ceph_pr_addr(&con->peer_addr.in_addr),
req_feat, server_feat, req_feat & ~server_feat);
con->error_msg = "missing required protocol features";
fail_protocol(con);
return -1;
}
clear_bit(NEGOTIATING, &con->state);
clear_bit(CONNECTING, &con->state);
con->peer_global_seq = le32_to_cpu(con->in_reply.global_seq);
con->connect_seq++;
con->peer_features = server_feat;
dout("process_connect got READY gseq %d cseq %d (%d)\n",
con->peer_global_seq,
le32_to_cpu(con->in_reply.connect_seq),
con->connect_seq);
WARN_ON(con->connect_seq !=
le32_to_cpu(con->in_reply.connect_seq));
if (con->in_reply.flags & CEPH_MSG_CONNECT_LOSSY)
set_bit(LOSSYTX, &con->flags);
prepare_read_tag(con);
break;
case CEPH_MSGR_TAG_WAIT:
/*
* If there is a connection race (we are opening
* connections to each other), one of us may just have
* to WAIT. This shouldn't happen if we are the
* client.
*/
pr_err("process_connect got WAIT as client\n");
con->error_msg = "protocol error, got WAIT as client";
return -1;
default:
pr_err("connect protocol error, will retry\n");
con->error_msg = "protocol error, garbage tag during connect";
return -1;
}
return 0;
}
/*
* read (part of) an ack
*/
static int read_partial_ack(struct ceph_connection *con)
{
int size = sizeof (con->in_temp_ack);
int end = size;
return read_partial(con, end, size, &con->in_temp_ack);
}
/*
* We can finally discard anything that's been acked.
*/
static void process_ack(struct ceph_connection *con)
{
struct ceph_msg *m;
u64 ack = le64_to_cpu(con->in_temp_ack);
u64 seq;
while (!list_empty(&con->out_sent)) {
m = list_first_entry(&con->out_sent, struct ceph_msg,
list_head);
seq = le64_to_cpu(m->hdr.seq);
if (seq > ack)
break;
dout("got ack for seq %llu type %d at %p\n", seq,
le16_to_cpu(m->hdr.type), m);
m->ack_stamp = jiffies;
ceph_msg_remove(m);
}
prepare_read_tag(con);
}
static int read_partial_message_section(struct ceph_connection *con,
struct kvec *section,
unsigned int sec_len, u32 *crc)
{
int ret, left;
BUG_ON(!section);
while (section->iov_len < sec_len) {
BUG_ON(section->iov_base == NULL);
left = sec_len - section->iov_len;
ret = ceph_tcp_recvmsg(con->sock, (char *)section->iov_base +
section->iov_len, left);
if (ret <= 0)
return ret;
section->iov_len += ret;
}
if (section->iov_len == sec_len)
*crc = crc32c(0, section->iov_base, section->iov_len);
return 1;
}
static bool ceph_con_in_msg_alloc(struct ceph_connection *con,
struct ceph_msg_header *hdr);
static int read_partial_message_pages(struct ceph_connection *con,
struct page **pages,
unsigned int data_len, bool do_datacrc)
{
void *p;
int ret;
int left;
left = min((int)(data_len - con->in_msg_pos.data_pos),
(int)(PAGE_SIZE - con->in_msg_pos.page_pos));
/* (page) data */
BUG_ON(pages == NULL);
p = kmap(pages[con->in_msg_pos.page]);
ret = ceph_tcp_recvmsg(con->sock, p + con->in_msg_pos.page_pos,
left);
if (ret > 0 && do_datacrc)
con->in_data_crc =
crc32c(con->in_data_crc,
p + con->in_msg_pos.page_pos, ret);
kunmap(pages[con->in_msg_pos.page]);
if (ret <= 0)
return ret;
con->in_msg_pos.data_pos += ret;
con->in_msg_pos.page_pos += ret;
if (con->in_msg_pos.page_pos == PAGE_SIZE) {
con->in_msg_pos.page_pos = 0;
con->in_msg_pos.page++;
}
return ret;
}
#ifdef CONFIG_BLOCK
static int read_partial_message_bio(struct ceph_connection *con,
struct bio **bio_iter, int *bio_seg,
unsigned int data_len, bool do_datacrc)
{
struct bio_vec *bv = bio_iovec_idx(*bio_iter, *bio_seg);
void *p;
int ret, left;
if (IS_ERR(bv))
return PTR_ERR(bv);
left = min((int)(data_len - con->in_msg_pos.data_pos),
(int)(bv->bv_len - con->in_msg_pos.page_pos));
p = kmap(bv->bv_page) + bv->bv_offset;
ret = ceph_tcp_recvmsg(con->sock, p + con->in_msg_pos.page_pos,
left);
if (ret > 0 && do_datacrc)
con->in_data_crc =
crc32c(con->in_data_crc,
p + con->in_msg_pos.page_pos, ret);
kunmap(bv->bv_page);
if (ret <= 0)
return ret;
con->in_msg_pos.data_pos += ret;
con->in_msg_pos.page_pos += ret;
if (con->in_msg_pos.page_pos == bv->bv_len) {
con->in_msg_pos.page_pos = 0;
iter_bio_next(bio_iter, bio_seg);
}
return ret;
}
#endif
/*
* read (part of) a message.
*/
static int read_partial_message(struct ceph_connection *con)
{
struct ceph_msg *m = con->in_msg;
int size;
int end;
int ret;
unsigned int front_len, middle_len, data_len;
bool do_datacrc = !con->msgr->nocrc;
u64 seq;
u32 crc;
dout("read_partial_message con %p msg %p\n", con, m);
/* header */
size = sizeof (con->in_hdr);
end = size;
ret = read_partial(con, end, size, &con->in_hdr);
if (ret <= 0)
return ret;
crc = crc32c(0, &con->in_hdr, offsetof(struct ceph_msg_header, crc));
if (cpu_to_le32(crc) != con->in_hdr.crc) {
pr_err("read_partial_message bad hdr "
" crc %u != expected %u\n",
crc, con->in_hdr.crc);
return -EBADMSG;
}
front_len = le32_to_cpu(con->in_hdr.front_len);
if (front_len > CEPH_MSG_MAX_FRONT_LEN)
return -EIO;
middle_len = le32_to_cpu(con->in_hdr.middle_len);
if (middle_len > CEPH_MSG_MAX_DATA_LEN)
return -EIO;
data_len = le32_to_cpu(con->in_hdr.data_len);
if (data_len > CEPH_MSG_MAX_DATA_LEN)
return -EIO;
/* verify seq# */
seq = le64_to_cpu(con->in_hdr.seq);
if ((s64)seq - (s64)con->in_seq < 1) {
pr_info("skipping %s%lld %s seq %lld expected %lld\n",
ENTITY_NAME(con->peer_name),
ceph_pr_addr(&con->peer_addr.in_addr),
seq, con->in_seq + 1);
con->in_base_pos = -front_len - middle_len - data_len -
sizeof(m->footer);
con->in_tag = CEPH_MSGR_TAG_READY;
return 0;
} else if ((s64)seq - (s64)con->in_seq > 1) {
pr_err("read_partial_message bad seq %lld expected %lld\n",
seq, con->in_seq + 1);
con->error_msg = "bad message sequence # for incoming message";
return -EBADMSG;
}
/* allocate message? */
if (!con->in_msg) {
dout("got hdr type %d front %d data %d\n", con->in_hdr.type,
con->in_hdr.front_len, con->in_hdr.data_len);
if (ceph_con_in_msg_alloc(con, &con->in_hdr)) {
/* skip this message */
dout("alloc_msg said skip message\n");
BUG_ON(con->in_msg);
con->in_base_pos = -front_len - middle_len - data_len -
sizeof(m->footer);
con->in_tag = CEPH_MSGR_TAG_READY;
con->in_seq++;
return 0;
}
if (!con->in_msg) {
con->error_msg =
"error allocating memory for incoming message";
return -ENOMEM;
}
BUG_ON(con->in_msg->con != con);
m = con->in_msg;
m->front.iov_len = 0; /* haven't read it yet */
if (m->middle)
m->middle->vec.iov_len = 0;
con->in_msg_pos.page = 0;
if (m->pages)
con->in_msg_pos.page_pos = m->page_alignment;
else
con->in_msg_pos.page_pos = 0;
con->in_msg_pos.data_pos = 0;
}
/* front */
ret = read_partial_message_section(con, &m->front, front_len,
&con->in_front_crc);
if (ret <= 0)
return ret;
/* middle */
if (m->middle) {
ret = read_partial_message_section(con, &m->middle->vec,
middle_len,
&con->in_middle_crc);
if (ret <= 0)
return ret;
}
#ifdef CONFIG_BLOCK
if (m->bio && !m->bio_iter)
init_bio_iter(m->bio, &m->bio_iter, &m->bio_seg);
#endif
/* (page) data */
while (con->in_msg_pos.data_pos < data_len) {
if (m->pages) {
ret = read_partial_message_pages(con, m->pages,
data_len, do_datacrc);
if (ret <= 0)
return ret;
#ifdef CONFIG_BLOCK
} else if (m->bio) {
ret = read_partial_message_bio(con,
&m->bio_iter, &m->bio_seg,
data_len, do_datacrc);
if (ret <= 0)
return ret;
#endif
} else {
BUG_ON(1);
}
}
/* footer */
size = sizeof (m->footer);
end += size;
ret = read_partial(con, end, size, &m->footer);
if (ret <= 0)
return ret;
dout("read_partial_message got msg %p %d (%u) + %d (%u) + %d (%u)\n",
m, front_len, m->footer.front_crc, middle_len,
m->footer.middle_crc, data_len, m->footer.data_crc);
/* crc ok? */
if (con->in_front_crc != le32_to_cpu(m->footer.front_crc)) {
pr_err("read_partial_message %p front crc %u != exp. %u\n",
m, con->in_front_crc, m->footer.front_crc);
return -EBADMSG;
}
if (con->in_middle_crc != le32_to_cpu(m->footer.middle_crc)) {
pr_err("read_partial_message %p middle crc %u != exp %u\n",
m, con->in_middle_crc, m->footer.middle_crc);
return -EBADMSG;
}
if (do_datacrc &&
(m->footer.flags & CEPH_MSG_FOOTER_NOCRC) == 0 &&
con->in_data_crc != le32_to_cpu(m->footer.data_crc)) {
pr_err("read_partial_message %p data crc %u != exp. %u\n", m,
con->in_data_crc, le32_to_cpu(m->footer.data_crc));
return -EBADMSG;
}
return 1; /* done! */
}
/*
* Process message. This happens in the worker thread. The callback should
* be careful not to do anything that waits on other incoming messages or it
* may deadlock.
*/
static void process_message(struct ceph_connection *con)
{
struct ceph_msg *msg;
BUG_ON(con->in_msg->con != con);
con->in_msg->con = NULL;
msg = con->in_msg;
con->in_msg = NULL;
con->ops->put(con);
/* if first message, set peer_name */
if (con->peer_name.type == 0)
con->peer_name = msg->hdr.src;
con->in_seq++;
mutex_unlock(&con->mutex);
dout("===== %p %llu from %s%lld %d=%s len %d+%d (%u %u %u) =====\n",
msg, le64_to_cpu(msg->hdr.seq),
ENTITY_NAME(msg->hdr.src),
le16_to_cpu(msg->hdr.type),
ceph_msg_type_name(le16_to_cpu(msg->hdr.type)),
le32_to_cpu(msg->hdr.front_len),
le32_to_cpu(msg->hdr.data_len),
con->in_front_crc, con->in_middle_crc, con->in_data_crc);
con->ops->dispatch(con, msg);
mutex_lock(&con->mutex);
prepare_read_tag(con);
}
/*
* Write something to the socket. Called in a worker thread when the
* socket appears to be writeable and we have something ready to send.
*/
static int try_write(struct ceph_connection *con)
{
int ret = 1;
dout("try_write start %p state %lu\n", con, con->state);
more:
dout("try_write out_kvec_bytes %d\n", con->out_kvec_bytes);
/* open the socket first? */
if (con->sock == NULL) {
set_bit(CONNECTING, &con->state);
con_out_kvec_reset(con);
prepare_write_banner(con);
ret = prepare_write_connect(con);
if (ret < 0)
goto out;
prepare_read_banner(con);
BUG_ON(con->in_msg);
con->in_tag = CEPH_MSGR_TAG_READY;
dout("try_write initiating connect on %p new state %lu\n",
con, con->state);
ret = ceph_tcp_connect(con);
if (ret < 0) {
con->error_msg = "connect error";
goto out;
}
}
more_kvec:
/* kvec data queued? */
if (con->out_skip) {
ret = write_partial_skip(con);
if (ret <= 0)
goto out;
}
if (con->out_kvec_left) {
ret = write_partial_kvec(con);
if (ret <= 0)
goto out;
}
/* msg pages? */
if (con->out_msg) {
if (con->out_msg_done) {
ceph_msg_put(con->out_msg);
con->out_msg = NULL; /* we're done with this one */
goto do_next;
}
ret = write_partial_msg_pages(con);
if (ret == 1)
goto more_kvec; /* we need to send the footer, too! */
if (ret == 0)
goto out;
if (ret < 0) {
dout("try_write write_partial_msg_pages err %d\n",
ret);
goto out;
}
}
do_next:
if (!test_bit(CONNECTING, &con->state)) {
/* is anything else pending? */
if (!list_empty(&con->out_queue)) {
prepare_write_message(con);
goto more;
}
if (con->in_seq > con->in_seq_acked) {
prepare_write_ack(con);
goto more;
}
if (test_and_clear_bit(KEEPALIVE_PENDING, &con->flags)) {
prepare_write_keepalive(con);
goto more;
}
}
/* Nothing to do! */
clear_bit(WRITE_PENDING, &con->flags);
dout("try_write nothing else to write.\n");
ret = 0;
out:
dout("try_write done on %p ret %d\n", con, ret);
return ret;
}
/*
* Read what we can from the socket.
*/
static int try_read(struct ceph_connection *con)
{
int ret = -1;
if (!con->sock)
return 0;
if (test_bit(STANDBY, &con->state))
return 0;
dout("try_read start on %p\n", con);
more:
dout("try_read tag %d in_base_pos %d\n", (int)con->in_tag,
con->in_base_pos);
/*
* process_connect and process_message drop and re-take
* con->mutex. make sure we handle a racing close or reopen.
*/
if (test_bit(CLOSED, &con->state) ||
test_bit(OPENING, &con->state)) {
ret = -EAGAIN;
goto out;
}
if (test_bit(CONNECTING, &con->state)) {
if (!test_bit(NEGOTIATING, &con->state)) {
dout("try_read connecting\n");
ret = read_partial_banner(con);
if (ret <= 0)
goto out;
ret = process_banner(con);
if (ret < 0)
goto out;
}
ret = read_partial_connect(con);
if (ret <= 0)
goto out;
ret = process_connect(con);
if (ret < 0)
goto out;
goto more;
}
if (con->in_base_pos < 0) {
/*
* skipping + discarding content.
*
* FIXME: there must be a better way to do this!
*/
static char buf[SKIP_BUF_SIZE];
int skip = min((int) sizeof (buf), -con->in_base_pos);
dout("skipping %d / %d bytes\n", skip, -con->in_base_pos);
ret = ceph_tcp_recvmsg(con->sock, buf, skip);
if (ret <= 0)
goto out;
con->in_base_pos += ret;
if (con->in_base_pos)
goto more;
}
if (con->in_tag == CEPH_MSGR_TAG_READY) {
/*
* what's next?
*/
ret = ceph_tcp_recvmsg(con->sock, &con->in_tag, 1);
if (ret <= 0)
goto out;
dout("try_read got tag %d\n", (int)con->in_tag);
switch (con->in_tag) {
case CEPH_MSGR_TAG_MSG:
prepare_read_message(con);
break;
case CEPH_MSGR_TAG_ACK:
prepare_read_ack(con);
break;
case CEPH_MSGR_TAG_CLOSE:
set_bit(CLOSED, &con->state); /* fixme */
goto out;
default:
goto bad_tag;
}
}
if (con->in_tag == CEPH_MSGR_TAG_MSG) {
ret = read_partial_message(con);
if (ret <= 0) {
switch (ret) {
case -EBADMSG:
con->error_msg = "bad crc";
ret = -EIO;
break;
case -EIO:
con->error_msg = "io error";
break;
}
goto out;
}
if (con->in_tag == CEPH_MSGR_TAG_READY)
goto more;
process_message(con);
goto more;
}
if (con->in_tag == CEPH_MSGR_TAG_ACK) {
ret = read_partial_ack(con);
if (ret <= 0)
goto out;
process_ack(con);
goto more;
}
out:
dout("try_read done on %p ret %d\n", con, ret);
return ret;
bad_tag:
pr_err("try_read bad con->in_tag = %d\n", (int)con->in_tag);
con->error_msg = "protocol error, garbage tag";
ret = -1;
goto out;
}
/*
* Atomically queue work on a connection. Bump @con reference to
* avoid races with connection teardown.
*/
static void queue_con(struct ceph_connection *con)
{
if (!con->ops->get(con)) {
dout("queue_con %p ref count 0\n", con);
return;
}
if (!queue_delayed_work(ceph_msgr_wq, &con->work, 0)) {
dout("queue_con %p - already queued\n", con);
con->ops->put(con);
} else {
dout("queue_con %p\n", con);
}
}
/*
* Do some work on a connection. Drop a connection ref when we're done.
*/
static void con_work(struct work_struct *work)
{
struct ceph_connection *con = container_of(work, struct ceph_connection,
work.work);
int ret;
mutex_lock(&con->mutex);
restart:
if (test_and_clear_bit(SOCK_CLOSED, &con->flags)) {
if (test_and_clear_bit(CONNECTING, &con->state)) {
clear_bit(NEGOTIATING, &con->state);
con->error_msg = "connection failed";
} else {
con->error_msg = "socket closed";
}
goto fault;
}
if (test_and_clear_bit(BACKOFF, &con->flags)) {
dout("con_work %p backing off\n", con);
if (queue_delayed_work(ceph_msgr_wq, &con->work,
round_jiffies_relative(con->delay))) {
dout("con_work %p backoff %lu\n", con, con->delay);
mutex_unlock(&con->mutex);
return;
} else {
con->ops->put(con);
dout("con_work %p FAILED to back off %lu\n", con,
con->delay);
}
}
if (test_bit(STANDBY, &con->state)) {
dout("con_work %p STANDBY\n", con);
goto done;
}
if (test_bit(CLOSED, &con->state)) { /* e.g. if we are replaced */
dout("con_work CLOSED\n");
con_close_socket(con);
goto done;
}
if (test_and_clear_bit(OPENING, &con->state)) {
/* reopen w/ new peer */
dout("con_work OPENING\n");
con_close_socket(con);
}
ret = try_read(con);
if (ret == -EAGAIN)
goto restart;
if (ret < 0)
goto fault;
ret = try_write(con);
if (ret == -EAGAIN)
goto restart;
if (ret < 0)
goto fault;
done:
mutex_unlock(&con->mutex);
done_unlocked:
con->ops->put(con);
return;
fault:
mutex_unlock(&con->mutex);
ceph_fault(con); /* error/fault path */
goto done_unlocked;
}
/*
* Generic error/fault handler. A retry mechanism is used with
* exponential backoff
*/
static void ceph_fault(struct ceph_connection *con)
{
pr_err("%s%lld %s %s\n", ENTITY_NAME(con->peer_name),
ceph_pr_addr(&con->peer_addr.in_addr), con->error_msg);
dout("fault %p state %lu to peer %s\n",
con, con->state, ceph_pr_addr(&con->peer_addr.in_addr));
if (test_bit(LOSSYTX, &con->flags)) {
dout("fault on LOSSYTX channel\n");
goto out;
}
mutex_lock(&con->mutex);
if (test_bit(CLOSED, &con->state))
goto out_unlock;
con_close_socket(con);
if (con->in_msg) {
BUG_ON(con->in_msg->con != con);
con->in_msg->con = NULL;
ceph_msg_put(con->in_msg);
con->in_msg = NULL;
con->ops->put(con);
}
/* Requeue anything that hasn't been acked */
list_splice_init(&con->out_sent, &con->out_queue);
/* If there are no messages queued or keepalive pending, place
* the connection in a STANDBY state */
if (list_empty(&con->out_queue) &&
!test_bit(KEEPALIVE_PENDING, &con->flags)) {
dout("fault %p setting STANDBY clearing WRITE_PENDING\n", con);
clear_bit(WRITE_PENDING, &con->flags);
set_bit(STANDBY, &con->state);
} else {
/* retry after a delay. */
if (con->delay == 0)
con->delay = BASE_DELAY_INTERVAL;
else if (con->delay < MAX_DELAY_INTERVAL)
con->delay *= 2;
con->ops->get(con);
if (queue_delayed_work(ceph_msgr_wq, &con->work,
round_jiffies_relative(con->delay))) {
dout("fault queued %p delay %lu\n", con, con->delay);
} else {
con->ops->put(con);
dout("fault failed to queue %p delay %lu, backoff\n",
con, con->delay);
/*
* In many cases we see a socket state change
* while con_work is running and end up
* queuing (non-delayed) work, such that we
* can't backoff with a delay. Set a flag so
* that when con_work restarts we schedule the
* delay then.
*/
set_bit(BACKOFF, &con->flags);
}
}
out_unlock:
mutex_unlock(&con->mutex);
out:
/*
* in case we faulted due to authentication, invalidate our
* current tickets so that we can get new ones.
*/
if (con->auth_retry && con->ops->invalidate_authorizer) {
dout("calling invalidate_authorizer()\n");
con->ops->invalidate_authorizer(con);
}
if (con->ops->fault)
con->ops->fault(con);
}
/*
* initialize a new messenger instance
*/
void ceph_messenger_init(struct ceph_messenger *msgr,
struct ceph_entity_addr *myaddr,
u32 supported_features,
u32 required_features,
bool nocrc)
{
msgr->supported_features = supported_features;
msgr->required_features = required_features;
spin_lock_init(&msgr->global_seq_lock);
if (myaddr)
msgr->inst.addr = *myaddr;
/* select a random nonce */
msgr->inst.addr.type = 0;
get_random_bytes(&msgr->inst.addr.nonce, sizeof(msgr->inst.addr.nonce));
encode_my_addr(msgr);
msgr->nocrc = nocrc;
dout("%s %p\n", __func__, msgr);
}
EXPORT_SYMBOL(ceph_messenger_init);
static void clear_standby(struct ceph_connection *con)
{
/* come back from STANDBY? */
if (test_and_clear_bit(STANDBY, &con->state)) {
mutex_lock(&con->mutex);
dout("clear_standby %p and ++connect_seq\n", con);
con->connect_seq++;
WARN_ON(test_bit(WRITE_PENDING, &con->flags));
WARN_ON(test_bit(KEEPALIVE_PENDING, &con->flags));
mutex_unlock(&con->mutex);
}
}
/*
* Queue up an outgoing message on the given connection.
*/
void ceph_con_send(struct ceph_connection *con, struct ceph_msg *msg)
{
if (test_bit(CLOSED, &con->state)) {
dout("con_send %p closed, dropping %p\n", con, msg);
ceph_msg_put(msg);
return;
}
/* set src+dst */
msg->hdr.src = con->msgr->inst.name;
BUG_ON(msg->front.iov_len != le32_to_cpu(msg->hdr.front_len));
msg->needs_out_seq = true;
/* queue */
mutex_lock(&con->mutex);
libceph: have messages take a connection reference There are essentially two types of ceph messages: incoming and outgoing. Outgoing messages are always allocated via ceph_msg_new(), and at the time of their allocation they are not associated with any particular connection. Incoming messages are always allocated via ceph_con_in_msg_alloc(), and they are initially associated with the connection from which incoming data will be placed into the message. When an outgoing message gets sent, it becomes associated with a connection and remains that way until the message is successfully sent. The association of an incoming message goes away at the point it is sent to an upper layer via a con->ops->dispatch method. This patch implements reference counting for all ceph messages, such that every message holds a reference (and a pointer) to a connection if and only if it is associated with that connection (as described above). For background, here is an explanation of the ceph message lifecycle, emphasizing when an association exists between a message and a connection. Outgoing Messages An outgoing message is "owned" by its allocator, from the time it is allocated in ceph_msg_new() up to the point it gets queued for sending in ceph_con_send(). Prior to that point the message's msg->con pointer is null; at the point it is queued for sending its message pointer is assigned to refer to the connection. At that time the message is inserted into a connection's out_queue list. When a message on the out_queue list has been sent to the socket layer to be put on the wire, it is transferred out of that list and into the connection's out_sent list. At that point it is still owned by the connection, and will remain so until an acknowledgement is received from the recipient that indicates the message was successfully transferred. When such an acknowledgement is received (in process_ack()), the message is removed from its list (in ceph_msg_remove()), at which point it is no longer associated with the connection. So basically, any time a message is on one of a connection's lists, it is associated with that connection. Reference counting outgoing messages can thus be done at the points a message is added to the out_queue (in ceph_con_send()) and the point it is removed from either its two lists (in ceph_msg_remove())--at which point its connection pointer becomes null. Incoming Messages When an incoming message on a connection is getting read (in read_partial_message()) and there is no message in con->in_msg, a new one is allocated using ceph_con_in_msg_alloc(). At that point the message is associated with the connection. Once that message has been completely and successfully read, it is passed to upper layer code using the connection's con->ops->dispatch method. At that point the association between the message and the connection no longer exists. Reference counting of connections for incoming messages can be done by taking a reference to the connection when the message gets allocated, and releasing that reference when it gets handed off using the dispatch method. We should never fail to get a connection reference for a message--the since the caller should already hold one. Signed-off-by: Alex Elder <elder@inktank.com> Reviewed-by: Sage Weil <sage@inktank.com>
2012-06-04 23:43:33 +04:00
BUG_ON(msg->con != NULL);
msg->con = con->ops->get(con);
libceph: have messages take a connection reference There are essentially two types of ceph messages: incoming and outgoing. Outgoing messages are always allocated via ceph_msg_new(), and at the time of their allocation they are not associated with any particular connection. Incoming messages are always allocated via ceph_con_in_msg_alloc(), and they are initially associated with the connection from which incoming data will be placed into the message. When an outgoing message gets sent, it becomes associated with a connection and remains that way until the message is successfully sent. The association of an incoming message goes away at the point it is sent to an upper layer via a con->ops->dispatch method. This patch implements reference counting for all ceph messages, such that every message holds a reference (and a pointer) to a connection if and only if it is associated with that connection (as described above). For background, here is an explanation of the ceph message lifecycle, emphasizing when an association exists between a message and a connection. Outgoing Messages An outgoing message is "owned" by its allocator, from the time it is allocated in ceph_msg_new() up to the point it gets queued for sending in ceph_con_send(). Prior to that point the message's msg->con pointer is null; at the point it is queued for sending its message pointer is assigned to refer to the connection. At that time the message is inserted into a connection's out_queue list. When a message on the out_queue list has been sent to the socket layer to be put on the wire, it is transferred out of that list and into the connection's out_sent list. At that point it is still owned by the connection, and will remain so until an acknowledgement is received from the recipient that indicates the message was successfully transferred. When such an acknowledgement is received (in process_ack()), the message is removed from its list (in ceph_msg_remove()), at which point it is no longer associated with the connection. So basically, any time a message is on one of a connection's lists, it is associated with that connection. Reference counting outgoing messages can thus be done at the points a message is added to the out_queue (in ceph_con_send()) and the point it is removed from either its two lists (in ceph_msg_remove())--at which point its connection pointer becomes null. Incoming Messages When an incoming message on a connection is getting read (in read_partial_message()) and there is no message in con->in_msg, a new one is allocated using ceph_con_in_msg_alloc(). At that point the message is associated with the connection. Once that message has been completely and successfully read, it is passed to upper layer code using the connection's con->ops->dispatch method. At that point the association between the message and the connection no longer exists. Reference counting of connections for incoming messages can be done by taking a reference to the connection when the message gets allocated, and releasing that reference when it gets handed off using the dispatch method. We should never fail to get a connection reference for a message--the since the caller should already hold one. Signed-off-by: Alex Elder <elder@inktank.com> Reviewed-by: Sage Weil <sage@inktank.com>
2012-06-04 23:43:33 +04:00
BUG_ON(msg->con == NULL);
BUG_ON(!list_empty(&msg->list_head));
list_add_tail(&msg->list_head, &con->out_queue);
dout("----- %p to %s%lld %d=%s len %d+%d+%d -----\n", msg,
ENTITY_NAME(con->peer_name), le16_to_cpu(msg->hdr.type),
ceph_msg_type_name(le16_to_cpu(msg->hdr.type)),
le32_to_cpu(msg->hdr.front_len),
le32_to_cpu(msg->hdr.middle_len),
le32_to_cpu(msg->hdr.data_len));
mutex_unlock(&con->mutex);
/* if there wasn't anything waiting to send before, queue
* new work */
clear_standby(con);
if (test_and_set_bit(WRITE_PENDING, &con->flags) == 0)
queue_con(con);
}
EXPORT_SYMBOL(ceph_con_send);
/*
* Revoke a message that was previously queued for send
*/
void ceph_msg_revoke(struct ceph_msg *msg)
{
struct ceph_connection *con = msg->con;
if (!con)
return; /* Message not in our possession */
mutex_lock(&con->mutex);
if (!list_empty(&msg->list_head)) {
dout("%s %p msg %p - was on queue\n", __func__, con, msg);
list_del_init(&msg->list_head);
BUG_ON(msg->con == NULL);
msg->con->ops->put(msg->con);
msg->con = NULL;
libceph: have messages take a connection reference There are essentially two types of ceph messages: incoming and outgoing. Outgoing messages are always allocated via ceph_msg_new(), and at the time of their allocation they are not associated with any particular connection. Incoming messages are always allocated via ceph_con_in_msg_alloc(), and they are initially associated with the connection from which incoming data will be placed into the message. When an outgoing message gets sent, it becomes associated with a connection and remains that way until the message is successfully sent. The association of an incoming message goes away at the point it is sent to an upper layer via a con->ops->dispatch method. This patch implements reference counting for all ceph messages, such that every message holds a reference (and a pointer) to a connection if and only if it is associated with that connection (as described above). For background, here is an explanation of the ceph message lifecycle, emphasizing when an association exists between a message and a connection. Outgoing Messages An outgoing message is "owned" by its allocator, from the time it is allocated in ceph_msg_new() up to the point it gets queued for sending in ceph_con_send(). Prior to that point the message's msg->con pointer is null; at the point it is queued for sending its message pointer is assigned to refer to the connection. At that time the message is inserted into a connection's out_queue list. When a message on the out_queue list has been sent to the socket layer to be put on the wire, it is transferred out of that list and into the connection's out_sent list. At that point it is still owned by the connection, and will remain so until an acknowledgement is received from the recipient that indicates the message was successfully transferred. When such an acknowledgement is received (in process_ack()), the message is removed from its list (in ceph_msg_remove()), at which point it is no longer associated with the connection. So basically, any time a message is on one of a connection's lists, it is associated with that connection. Reference counting outgoing messages can thus be done at the points a message is added to the out_queue (in ceph_con_send()) and the point it is removed from either its two lists (in ceph_msg_remove())--at which point its connection pointer becomes null. Incoming Messages When an incoming message on a connection is getting read (in read_partial_message()) and there is no message in con->in_msg, a new one is allocated using ceph_con_in_msg_alloc(). At that point the message is associated with the connection. Once that message has been completely and successfully read, it is passed to upper layer code using the connection's con->ops->dispatch method. At that point the association between the message and the connection no longer exists. Reference counting of connections for incoming messages can be done by taking a reference to the connection when the message gets allocated, and releasing that reference when it gets handed off using the dispatch method. We should never fail to get a connection reference for a message--the since the caller should already hold one. Signed-off-by: Alex Elder <elder@inktank.com> Reviewed-by: Sage Weil <sage@inktank.com>
2012-06-04 23:43:33 +04:00
msg->hdr.seq = 0;
ceph_msg_put(msg);
}
if (con->out_msg == msg) {
dout("%s %p msg %p - was sending\n", __func__, con, msg);
con->out_msg = NULL;
if (con->out_kvec_is_msg) {
con->out_skip = con->out_kvec_bytes;
con->out_kvec_is_msg = false;
}
msg->hdr.seq = 0;
libceph: have messages take a connection reference There are essentially two types of ceph messages: incoming and outgoing. Outgoing messages are always allocated via ceph_msg_new(), and at the time of their allocation they are not associated with any particular connection. Incoming messages are always allocated via ceph_con_in_msg_alloc(), and they are initially associated with the connection from which incoming data will be placed into the message. When an outgoing message gets sent, it becomes associated with a connection and remains that way until the message is successfully sent. The association of an incoming message goes away at the point it is sent to an upper layer via a con->ops->dispatch method. This patch implements reference counting for all ceph messages, such that every message holds a reference (and a pointer) to a connection if and only if it is associated with that connection (as described above). For background, here is an explanation of the ceph message lifecycle, emphasizing when an association exists between a message and a connection. Outgoing Messages An outgoing message is "owned" by its allocator, from the time it is allocated in ceph_msg_new() up to the point it gets queued for sending in ceph_con_send(). Prior to that point the message's msg->con pointer is null; at the point it is queued for sending its message pointer is assigned to refer to the connection. At that time the message is inserted into a connection's out_queue list. When a message on the out_queue list has been sent to the socket layer to be put on the wire, it is transferred out of that list and into the connection's out_sent list. At that point it is still owned by the connection, and will remain so until an acknowledgement is received from the recipient that indicates the message was successfully transferred. When such an acknowledgement is received (in process_ack()), the message is removed from its list (in ceph_msg_remove()), at which point it is no longer associated with the connection. So basically, any time a message is on one of a connection's lists, it is associated with that connection. Reference counting outgoing messages can thus be done at the points a message is added to the out_queue (in ceph_con_send()) and the point it is removed from either its two lists (in ceph_msg_remove())--at which point its connection pointer becomes null. Incoming Messages When an incoming message on a connection is getting read (in read_partial_message()) and there is no message in con->in_msg, a new one is allocated using ceph_con_in_msg_alloc(). At that point the message is associated with the connection. Once that message has been completely and successfully read, it is passed to upper layer code using the connection's con->ops->dispatch method. At that point the association between the message and the connection no longer exists. Reference counting of connections for incoming messages can be done by taking a reference to the connection when the message gets allocated, and releasing that reference when it gets handed off using the dispatch method. We should never fail to get a connection reference for a message--the since the caller should already hold one. Signed-off-by: Alex Elder <elder@inktank.com> Reviewed-by: Sage Weil <sage@inktank.com>
2012-06-04 23:43:33 +04:00
ceph_msg_put(msg);
}
mutex_unlock(&con->mutex);
}
/*
* Revoke a message that we may be reading data into
*/
void ceph_msg_revoke_incoming(struct ceph_msg *msg)
{
struct ceph_connection *con;
BUG_ON(msg == NULL);
if (!msg->con) {
dout("%s msg %p null con\n", __func__, msg);
return; /* Message not in our possession */
}
con = msg->con;
mutex_lock(&con->mutex);
if (con->in_msg == msg) {
unsigned int front_len = le32_to_cpu(con->in_hdr.front_len);
unsigned int middle_len = le32_to_cpu(con->in_hdr.middle_len);
unsigned int data_len = le32_to_cpu(con->in_hdr.data_len);
/* skip rest of message */
dout("%s %p msg %p revoked\n", __func__, con, msg);
con->in_base_pos = con->in_base_pos -
sizeof(struct ceph_msg_header) -
front_len -
middle_len -
data_len -
sizeof(struct ceph_msg_footer);
ceph_msg_put(con->in_msg);
con->in_msg = NULL;
con->in_tag = CEPH_MSGR_TAG_READY;
con->in_seq++;
} else {
dout("%s %p in_msg %p msg %p no-op\n",
__func__, con, con->in_msg, msg);
}
mutex_unlock(&con->mutex);
}
/*
* Queue a keepalive byte to ensure the tcp connection is alive.
*/
void ceph_con_keepalive(struct ceph_connection *con)
{
dout("con_keepalive %p\n", con);
clear_standby(con);
if (test_and_set_bit(KEEPALIVE_PENDING, &con->flags) == 0 &&
test_and_set_bit(WRITE_PENDING, &con->flags) == 0)
queue_con(con);
}
EXPORT_SYMBOL(ceph_con_keepalive);
/*
* construct a new message with given type, size
* the new msg has a ref count of 1.
*/
struct ceph_msg *ceph_msg_new(int type, int front_len, gfp_t flags,
bool can_fail)
{
struct ceph_msg *m;
m = kmalloc(sizeof(*m), flags);
if (m == NULL)
goto out;
kref_init(&m->kref);
m->con = NULL;
INIT_LIST_HEAD(&m->list_head);
m->hdr.tid = 0;
m->hdr.type = cpu_to_le16(type);
m->hdr.priority = cpu_to_le16(CEPH_MSG_PRIO_DEFAULT);
m->hdr.version = 0;
m->hdr.front_len = cpu_to_le32(front_len);
m->hdr.middle_len = 0;
m->hdr.data_len = 0;
m->hdr.data_off = 0;
m->hdr.reserved = 0;
m->footer.front_crc = 0;
m->footer.middle_crc = 0;
m->footer.data_crc = 0;
m->footer.flags = 0;
m->front_max = front_len;
m->front_is_vmalloc = false;
m->more_to_follow = false;
m->ack_stamp = 0;
m->pool = NULL;
/* middle */
m->middle = NULL;
/* data */
m->nr_pages = 0;
m->page_alignment = 0;
m->pages = NULL;
m->pagelist = NULL;
m->bio = NULL;
m->bio_iter = NULL;
m->bio_seg = 0;
m->trail = NULL;
/* front */
if (front_len) {
if (front_len > PAGE_CACHE_SIZE) {
m->front.iov_base = __vmalloc(front_len, flags,
PAGE_KERNEL);
m->front_is_vmalloc = true;
} else {
m->front.iov_base = kmalloc(front_len, flags);
}
if (m->front.iov_base == NULL) {
dout("ceph_msg_new can't allocate %d bytes\n",
front_len);
goto out2;
}
} else {
m->front.iov_base = NULL;
}
m->front.iov_len = front_len;
dout("ceph_msg_new %p front %d\n", m, front_len);
return m;
out2:
ceph_msg_put(m);
out:
if (!can_fail) {
pr_err("msg_new can't create type %d front %d\n", type,
front_len);
WARN_ON(1);
} else {
dout("msg_new can't create type %d front %d\n", type,
front_len);
}
return NULL;
}
EXPORT_SYMBOL(ceph_msg_new);
/*
* Allocate "middle" portion of a message, if it is needed and wasn't
* allocated by alloc_msg. This allows us to read a small fixed-size
* per-type header in the front and then gracefully fail (i.e.,
* propagate the error to the caller based on info in the front) when
* the middle is too large.
*/
static int ceph_alloc_middle(struct ceph_connection *con, struct ceph_msg *msg)
{
int type = le16_to_cpu(msg->hdr.type);
int middle_len = le32_to_cpu(msg->hdr.middle_len);
dout("alloc_middle %p type %d %s middle_len %d\n", msg, type,
ceph_msg_type_name(type), middle_len);
BUG_ON(!middle_len);
BUG_ON(msg->middle);
msg->middle = ceph_buffer_new(middle_len, GFP_NOFS);
if (!msg->middle)
return -ENOMEM;
return 0;
}
/*
* Allocate a message for receiving an incoming message on a
* connection, and save the result in con->in_msg. Uses the
* connection's private alloc_msg op if available.
*
* Returns true if the message should be skipped, false otherwise.
* If true is returned (skip message), con->in_msg will be NULL.
* If false is returned, con->in_msg will contain a pointer to the
* newly-allocated message, or NULL in case of memory exhaustion.
*/
static bool ceph_con_in_msg_alloc(struct ceph_connection *con,
struct ceph_msg_header *hdr)
{
int type = le16_to_cpu(hdr->type);
int front_len = le32_to_cpu(hdr->front_len);
int middle_len = le32_to_cpu(hdr->middle_len);
int ret;
BUG_ON(con->in_msg != NULL);
if (con->ops->alloc_msg) {
int skip = 0;
mutex_unlock(&con->mutex);
con->in_msg = con->ops->alloc_msg(con, hdr, &skip);
mutex_lock(&con->mutex);
libceph: have messages take a connection reference There are essentially two types of ceph messages: incoming and outgoing. Outgoing messages are always allocated via ceph_msg_new(), and at the time of their allocation they are not associated with any particular connection. Incoming messages are always allocated via ceph_con_in_msg_alloc(), and they are initially associated with the connection from which incoming data will be placed into the message. When an outgoing message gets sent, it becomes associated with a connection and remains that way until the message is successfully sent. The association of an incoming message goes away at the point it is sent to an upper layer via a con->ops->dispatch method. This patch implements reference counting for all ceph messages, such that every message holds a reference (and a pointer) to a connection if and only if it is associated with that connection (as described above). For background, here is an explanation of the ceph message lifecycle, emphasizing when an association exists between a message and a connection. Outgoing Messages An outgoing message is "owned" by its allocator, from the time it is allocated in ceph_msg_new() up to the point it gets queued for sending in ceph_con_send(). Prior to that point the message's msg->con pointer is null; at the point it is queued for sending its message pointer is assigned to refer to the connection. At that time the message is inserted into a connection's out_queue list. When a message on the out_queue list has been sent to the socket layer to be put on the wire, it is transferred out of that list and into the connection's out_sent list. At that point it is still owned by the connection, and will remain so until an acknowledgement is received from the recipient that indicates the message was successfully transferred. When such an acknowledgement is received (in process_ack()), the message is removed from its list (in ceph_msg_remove()), at which point it is no longer associated with the connection. So basically, any time a message is on one of a connection's lists, it is associated with that connection. Reference counting outgoing messages can thus be done at the points a message is added to the out_queue (in ceph_con_send()) and the point it is removed from either its two lists (in ceph_msg_remove())--at which point its connection pointer becomes null. Incoming Messages When an incoming message on a connection is getting read (in read_partial_message()) and there is no message in con->in_msg, a new one is allocated using ceph_con_in_msg_alloc(). At that point the message is associated with the connection. Once that message has been completely and successfully read, it is passed to upper layer code using the connection's con->ops->dispatch method. At that point the association between the message and the connection no longer exists. Reference counting of connections for incoming messages can be done by taking a reference to the connection when the message gets allocated, and releasing that reference when it gets handed off using the dispatch method. We should never fail to get a connection reference for a message--the since the caller should already hold one. Signed-off-by: Alex Elder <elder@inktank.com> Reviewed-by: Sage Weil <sage@inktank.com>
2012-06-04 23:43:33 +04:00
if (con->in_msg) {
con->in_msg->con = con->ops->get(con);
libceph: have messages take a connection reference There are essentially two types of ceph messages: incoming and outgoing. Outgoing messages are always allocated via ceph_msg_new(), and at the time of their allocation they are not associated with any particular connection. Incoming messages are always allocated via ceph_con_in_msg_alloc(), and they are initially associated with the connection from which incoming data will be placed into the message. When an outgoing message gets sent, it becomes associated with a connection and remains that way until the message is successfully sent. The association of an incoming message goes away at the point it is sent to an upper layer via a con->ops->dispatch method. This patch implements reference counting for all ceph messages, such that every message holds a reference (and a pointer) to a connection if and only if it is associated with that connection (as described above). For background, here is an explanation of the ceph message lifecycle, emphasizing when an association exists between a message and a connection. Outgoing Messages An outgoing message is "owned" by its allocator, from the time it is allocated in ceph_msg_new() up to the point it gets queued for sending in ceph_con_send(). Prior to that point the message's msg->con pointer is null; at the point it is queued for sending its message pointer is assigned to refer to the connection. At that time the message is inserted into a connection's out_queue list. When a message on the out_queue list has been sent to the socket layer to be put on the wire, it is transferred out of that list and into the connection's out_sent list. At that point it is still owned by the connection, and will remain so until an acknowledgement is received from the recipient that indicates the message was successfully transferred. When such an acknowledgement is received (in process_ack()), the message is removed from its list (in ceph_msg_remove()), at which point it is no longer associated with the connection. So basically, any time a message is on one of a connection's lists, it is associated with that connection. Reference counting outgoing messages can thus be done at the points a message is added to the out_queue (in ceph_con_send()) and the point it is removed from either its two lists (in ceph_msg_remove())--at which point its connection pointer becomes null. Incoming Messages When an incoming message on a connection is getting read (in read_partial_message()) and there is no message in con->in_msg, a new one is allocated using ceph_con_in_msg_alloc(). At that point the message is associated with the connection. Once that message has been completely and successfully read, it is passed to upper layer code using the connection's con->ops->dispatch method. At that point the association between the message and the connection no longer exists. Reference counting of connections for incoming messages can be done by taking a reference to the connection when the message gets allocated, and releasing that reference when it gets handed off using the dispatch method. We should never fail to get a connection reference for a message--the since the caller should already hold one. Signed-off-by: Alex Elder <elder@inktank.com> Reviewed-by: Sage Weil <sage@inktank.com>
2012-06-04 23:43:33 +04:00
BUG_ON(con->in_msg->con == NULL);
}
if (skip)
con->in_msg = NULL;
if (!con->in_msg)
return skip != 0;
}
if (!con->in_msg) {
con->in_msg = ceph_msg_new(type, front_len, GFP_NOFS, false);
if (!con->in_msg) {
pr_err("unable to allocate msg type %d len %d\n",
type, front_len);
return false;
}
con->in_msg->con = con->ops->get(con);
libceph: have messages take a connection reference There are essentially two types of ceph messages: incoming and outgoing. Outgoing messages are always allocated via ceph_msg_new(), and at the time of their allocation they are not associated with any particular connection. Incoming messages are always allocated via ceph_con_in_msg_alloc(), and they are initially associated with the connection from which incoming data will be placed into the message. When an outgoing message gets sent, it becomes associated with a connection and remains that way until the message is successfully sent. The association of an incoming message goes away at the point it is sent to an upper layer via a con->ops->dispatch method. This patch implements reference counting for all ceph messages, such that every message holds a reference (and a pointer) to a connection if and only if it is associated with that connection (as described above). For background, here is an explanation of the ceph message lifecycle, emphasizing when an association exists between a message and a connection. Outgoing Messages An outgoing message is "owned" by its allocator, from the time it is allocated in ceph_msg_new() up to the point it gets queued for sending in ceph_con_send(). Prior to that point the message's msg->con pointer is null; at the point it is queued for sending its message pointer is assigned to refer to the connection. At that time the message is inserted into a connection's out_queue list. When a message on the out_queue list has been sent to the socket layer to be put on the wire, it is transferred out of that list and into the connection's out_sent list. At that point it is still owned by the connection, and will remain so until an acknowledgement is received from the recipient that indicates the message was successfully transferred. When such an acknowledgement is received (in process_ack()), the message is removed from its list (in ceph_msg_remove()), at which point it is no longer associated with the connection. So basically, any time a message is on one of a connection's lists, it is associated with that connection. Reference counting outgoing messages can thus be done at the points a message is added to the out_queue (in ceph_con_send()) and the point it is removed from either its two lists (in ceph_msg_remove())--at which point its connection pointer becomes null. Incoming Messages When an incoming message on a connection is getting read (in read_partial_message()) and there is no message in con->in_msg, a new one is allocated using ceph_con_in_msg_alloc(). At that point the message is associated with the connection. Once that message has been completely and successfully read, it is passed to upper layer code using the connection's con->ops->dispatch method. At that point the association between the message and the connection no longer exists. Reference counting of connections for incoming messages can be done by taking a reference to the connection when the message gets allocated, and releasing that reference when it gets handed off using the dispatch method. We should never fail to get a connection reference for a message--the since the caller should already hold one. Signed-off-by: Alex Elder <elder@inktank.com> Reviewed-by: Sage Weil <sage@inktank.com>
2012-06-04 23:43:33 +04:00
BUG_ON(con->in_msg->con == NULL);
con->in_msg->page_alignment = le16_to_cpu(hdr->data_off);
}
memcpy(&con->in_msg->hdr, &con->in_hdr, sizeof(con->in_hdr));
if (middle_len && !con->in_msg->middle) {
ret = ceph_alloc_middle(con, con->in_msg);
if (ret < 0) {
ceph_msg_put(con->in_msg);
con->in_msg = NULL;
}
}
return false;
}
/*
* Free a generically kmalloc'd message.
*/
void ceph_msg_kfree(struct ceph_msg *m)
{
dout("msg_kfree %p\n", m);
if (m->front_is_vmalloc)
vfree(m->front.iov_base);
else
kfree(m->front.iov_base);
kfree(m);
}
/*
* Drop a msg ref. Destroy as needed.
*/
void ceph_msg_last_put(struct kref *kref)
{
struct ceph_msg *m = container_of(kref, struct ceph_msg, kref);
dout("ceph_msg_put last one on %p\n", m);
WARN_ON(!list_empty(&m->list_head));
/* drop middle, data, if any */
if (m->middle) {
ceph_buffer_put(m->middle);
m->middle = NULL;
}
m->nr_pages = 0;
m->pages = NULL;
if (m->pagelist) {
ceph_pagelist_release(m->pagelist);
kfree(m->pagelist);
m->pagelist = NULL;
}
m->trail = NULL;
if (m->pool)
ceph_msgpool_put(m->pool, m);
else
ceph_msg_kfree(m);
}
EXPORT_SYMBOL(ceph_msg_last_put);
void ceph_msg_dump(struct ceph_msg *msg)
{
pr_debug("msg_dump %p (front_max %d nr_pages %d)\n", msg,
msg->front_max, msg->nr_pages);
print_hex_dump(KERN_DEBUG, "header: ",
DUMP_PREFIX_OFFSET, 16, 1,
&msg->hdr, sizeof(msg->hdr), true);
print_hex_dump(KERN_DEBUG, " front: ",
DUMP_PREFIX_OFFSET, 16, 1,
msg->front.iov_base, msg->front.iov_len, true);
if (msg->middle)
print_hex_dump(KERN_DEBUG, "middle: ",
DUMP_PREFIX_OFFSET, 16, 1,
msg->middle->vec.iov_base,
msg->middle->vec.iov_len, true);
print_hex_dump(KERN_DEBUG, "footer: ",
DUMP_PREFIX_OFFSET, 16, 1,
&msg->footer, sizeof(msg->footer), true);
}
EXPORT_SYMBOL(ceph_msg_dump);