qemu-e2k/migration/rdma.c
Padmanabh Ratnakar 80b262e143 rdma: Fix cleanup in error paths
As part of commit e325b49a32,
order in which resources are destroyed was changed for fixing
a seg fault. Due to this change, CQ will never get destroyed as
CQ should be destroyed after QP destruction. Seg fault is caused
improper cleanup when connection fails. Fixing cleanup after
connection failure and order in which resources are destroyed
in qemu_rdma_cleanup() routine.

Signed-off-by: Meghana Cheripady <meghana.cheripady@emulex.com>
Signed-off-by: Padmanabh Ratnakar <padmanabh.ratnakar@emulex.com>
Signed-off-by: Juan Quintela <quintela@redhat.com>
2015-03-26 15:31:46 +01:00

3380 lines
103 KiB
C

/*
* RDMA protocol and interfaces
*
* Copyright IBM, Corp. 2010-2013
*
* Authors:
* Michael R. Hines <mrhines@us.ibm.com>
* Jiuxing Liu <jl@us.ibm.com>
*
* This work is licensed under the terms of the GNU GPL, version 2 or
* later. See the COPYING file in the top-level directory.
*
*/
#include "qemu-common.h"
#include "migration/migration.h"
#include "migration/qemu-file.h"
#include "exec/cpu-common.h"
#include "qemu/main-loop.h"
#include "qemu/sockets.h"
#include "qemu/bitmap.h"
#include "block/coroutine.h"
#include <stdio.h>
#include <sys/types.h>
#include <sys/socket.h>
#include <netdb.h>
#include <arpa/inet.h>
#include <string.h>
#include <rdma/rdma_cma.h>
#include "trace.h"
/*
* Print and error on both the Monitor and the Log file.
*/
#define ERROR(errp, fmt, ...) \
do { \
fprintf(stderr, "RDMA ERROR: " fmt "\n", ## __VA_ARGS__); \
if (errp && (*(errp) == NULL)) { \
error_setg(errp, "RDMA ERROR: " fmt, ## __VA_ARGS__); \
} \
} while (0)
#define RDMA_RESOLVE_TIMEOUT_MS 10000
/* Do not merge data if larger than this. */
#define RDMA_MERGE_MAX (2 * 1024 * 1024)
#define RDMA_SIGNALED_SEND_MAX (RDMA_MERGE_MAX / 4096)
#define RDMA_REG_CHUNK_SHIFT 20 /* 1 MB */
/*
* This is only for non-live state being migrated.
* Instead of RDMA_WRITE messages, we use RDMA_SEND
* messages for that state, which requires a different
* delivery design than main memory.
*/
#define RDMA_SEND_INCREMENT 32768
/*
* Maximum size infiniband SEND message
*/
#define RDMA_CONTROL_MAX_BUFFER (512 * 1024)
#define RDMA_CONTROL_MAX_COMMANDS_PER_MESSAGE 4096
#define RDMA_CONTROL_VERSION_CURRENT 1
/*
* Capabilities for negotiation.
*/
#define RDMA_CAPABILITY_PIN_ALL 0x01
/*
* Add the other flags above to this list of known capabilities
* as they are introduced.
*/
static uint32_t known_capabilities = RDMA_CAPABILITY_PIN_ALL;
#define CHECK_ERROR_STATE() \
do { \
if (rdma->error_state) { \
if (!rdma->error_reported) { \
error_report("RDMA is in an error state waiting migration" \
" to abort!"); \
rdma->error_reported = 1; \
} \
return rdma->error_state; \
} \
} while (0);
/*
* A work request ID is 64-bits and we split up these bits
* into 3 parts:
*
* bits 0-15 : type of control message, 2^16
* bits 16-29: ram block index, 2^14
* bits 30-63: ram block chunk number, 2^34
*
* The last two bit ranges are only used for RDMA writes,
* in order to track their completion and potentially
* also track unregistration status of the message.
*/
#define RDMA_WRID_TYPE_SHIFT 0UL
#define RDMA_WRID_BLOCK_SHIFT 16UL
#define RDMA_WRID_CHUNK_SHIFT 30UL
#define RDMA_WRID_TYPE_MASK \
((1UL << RDMA_WRID_BLOCK_SHIFT) - 1UL)
#define RDMA_WRID_BLOCK_MASK \
(~RDMA_WRID_TYPE_MASK & ((1UL << RDMA_WRID_CHUNK_SHIFT) - 1UL))
#define RDMA_WRID_CHUNK_MASK (~RDMA_WRID_BLOCK_MASK & ~RDMA_WRID_TYPE_MASK)
/*
* RDMA migration protocol:
* 1. RDMA Writes (data messages, i.e. RAM)
* 2. IB Send/Recv (control channel messages)
*/
enum {
RDMA_WRID_NONE = 0,
RDMA_WRID_RDMA_WRITE = 1,
RDMA_WRID_SEND_CONTROL = 2000,
RDMA_WRID_RECV_CONTROL = 4000,
};
static const char *wrid_desc[] = {
[RDMA_WRID_NONE] = "NONE",
[RDMA_WRID_RDMA_WRITE] = "WRITE RDMA",
[RDMA_WRID_SEND_CONTROL] = "CONTROL SEND",
[RDMA_WRID_RECV_CONTROL] = "CONTROL RECV",
};
/*
* Work request IDs for IB SEND messages only (not RDMA writes).
* This is used by the migration protocol to transmit
* control messages (such as device state and registration commands)
*
* We could use more WRs, but we have enough for now.
*/
enum {
RDMA_WRID_READY = 0,
RDMA_WRID_DATA,
RDMA_WRID_CONTROL,
RDMA_WRID_MAX,
};
/*
* SEND/RECV IB Control Messages.
*/
enum {
RDMA_CONTROL_NONE = 0,
RDMA_CONTROL_ERROR,
RDMA_CONTROL_READY, /* ready to receive */
RDMA_CONTROL_QEMU_FILE, /* QEMUFile-transmitted bytes */
RDMA_CONTROL_RAM_BLOCKS_REQUEST, /* RAMBlock synchronization */
RDMA_CONTROL_RAM_BLOCKS_RESULT, /* RAMBlock synchronization */
RDMA_CONTROL_COMPRESS, /* page contains repeat values */
RDMA_CONTROL_REGISTER_REQUEST, /* dynamic page registration */
RDMA_CONTROL_REGISTER_RESULT, /* key to use after registration */
RDMA_CONTROL_REGISTER_FINISHED, /* current iteration finished */
RDMA_CONTROL_UNREGISTER_REQUEST, /* dynamic UN-registration */
RDMA_CONTROL_UNREGISTER_FINISHED, /* unpinning finished */
};
static const char *control_desc[] = {
[RDMA_CONTROL_NONE] = "NONE",
[RDMA_CONTROL_ERROR] = "ERROR",
[RDMA_CONTROL_READY] = "READY",
[RDMA_CONTROL_QEMU_FILE] = "QEMU FILE",
[RDMA_CONTROL_RAM_BLOCKS_REQUEST] = "RAM BLOCKS REQUEST",
[RDMA_CONTROL_RAM_BLOCKS_RESULT] = "RAM BLOCKS RESULT",
[RDMA_CONTROL_COMPRESS] = "COMPRESS",
[RDMA_CONTROL_REGISTER_REQUEST] = "REGISTER REQUEST",
[RDMA_CONTROL_REGISTER_RESULT] = "REGISTER RESULT",
[RDMA_CONTROL_REGISTER_FINISHED] = "REGISTER FINISHED",
[RDMA_CONTROL_UNREGISTER_REQUEST] = "UNREGISTER REQUEST",
[RDMA_CONTROL_UNREGISTER_FINISHED] = "UNREGISTER FINISHED",
};
/*
* Memory and MR structures used to represent an IB Send/Recv work request.
* This is *not* used for RDMA writes, only IB Send/Recv.
*/
typedef struct {
uint8_t control[RDMA_CONTROL_MAX_BUFFER]; /* actual buffer to register */
struct ibv_mr *control_mr; /* registration metadata */
size_t control_len; /* length of the message */
uint8_t *control_curr; /* start of unconsumed bytes */
} RDMAWorkRequestData;
/*
* Negotiate RDMA capabilities during connection-setup time.
*/
typedef struct {
uint32_t version;
uint32_t flags;
} RDMACapabilities;
static void caps_to_network(RDMACapabilities *cap)
{
cap->version = htonl(cap->version);
cap->flags = htonl(cap->flags);
}
static void network_to_caps(RDMACapabilities *cap)
{
cap->version = ntohl(cap->version);
cap->flags = ntohl(cap->flags);
}
/*
* Representation of a RAMBlock from an RDMA perspective.
* This is not transmitted, only local.
* This and subsequent structures cannot be linked lists
* because we're using a single IB message to transmit
* the information. It's small anyway, so a list is overkill.
*/
typedef struct RDMALocalBlock {
uint8_t *local_host_addr; /* local virtual address */
uint64_t remote_host_addr; /* remote virtual address */
uint64_t offset;
uint64_t length;
struct ibv_mr **pmr; /* MRs for chunk-level registration */
struct ibv_mr *mr; /* MR for non-chunk-level registration */
uint32_t *remote_keys; /* rkeys for chunk-level registration */
uint32_t remote_rkey; /* rkeys for non-chunk-level registration */
int index; /* which block are we */
bool is_ram_block;
int nb_chunks;
unsigned long *transit_bitmap;
unsigned long *unregister_bitmap;
} RDMALocalBlock;
/*
* Also represents a RAMblock, but only on the dest.
* This gets transmitted by the dest during connection-time
* to the source VM and then is used to populate the
* corresponding RDMALocalBlock with
* the information needed to perform the actual RDMA.
*/
typedef struct QEMU_PACKED RDMARemoteBlock {
uint64_t remote_host_addr;
uint64_t offset;
uint64_t length;
uint32_t remote_rkey;
uint32_t padding;
} RDMARemoteBlock;
static uint64_t htonll(uint64_t v)
{
union { uint32_t lv[2]; uint64_t llv; } u;
u.lv[0] = htonl(v >> 32);
u.lv[1] = htonl(v & 0xFFFFFFFFULL);
return u.llv;
}
static uint64_t ntohll(uint64_t v) {
union { uint32_t lv[2]; uint64_t llv; } u;
u.llv = v;
return ((uint64_t)ntohl(u.lv[0]) << 32) | (uint64_t) ntohl(u.lv[1]);
}
static void remote_block_to_network(RDMARemoteBlock *rb)
{
rb->remote_host_addr = htonll(rb->remote_host_addr);
rb->offset = htonll(rb->offset);
rb->length = htonll(rb->length);
rb->remote_rkey = htonl(rb->remote_rkey);
}
static void network_to_remote_block(RDMARemoteBlock *rb)
{
rb->remote_host_addr = ntohll(rb->remote_host_addr);
rb->offset = ntohll(rb->offset);
rb->length = ntohll(rb->length);
rb->remote_rkey = ntohl(rb->remote_rkey);
}
/*
* Virtual address of the above structures used for transmitting
* the RAMBlock descriptions at connection-time.
* This structure is *not* transmitted.
*/
typedef struct RDMALocalBlocks {
int nb_blocks;
bool init; /* main memory init complete */
RDMALocalBlock *block;
} RDMALocalBlocks;
/*
* Main data structure for RDMA state.
* While there is only one copy of this structure being allocated right now,
* this is the place where one would start if you wanted to consider
* having more than one RDMA connection open at the same time.
*/
typedef struct RDMAContext {
char *host;
int port;
RDMAWorkRequestData wr_data[RDMA_WRID_MAX];
/*
* This is used by *_exchange_send() to figure out whether or not
* the initial "READY" message has already been received or not.
* This is because other functions may potentially poll() and detect
* the READY message before send() does, in which case we need to
* know if it completed.
*/
int control_ready_expected;
/* number of outstanding writes */
int nb_sent;
/* store info about current buffer so that we can
merge it with future sends */
uint64_t current_addr;
uint64_t current_length;
/* index of ram block the current buffer belongs to */
int current_index;
/* index of the chunk in the current ram block */
int current_chunk;
bool pin_all;
/*
* infiniband-specific variables for opening the device
* and maintaining connection state and so forth.
*
* cm_id also has ibv_context, rdma_event_channel, and ibv_qp in
* cm_id->verbs, cm_id->channel, and cm_id->qp.
*/
struct rdma_cm_id *cm_id; /* connection manager ID */
struct rdma_cm_id *listen_id;
bool connected;
struct ibv_context *verbs;
struct rdma_event_channel *channel;
struct ibv_qp *qp; /* queue pair */
struct ibv_comp_channel *comp_channel; /* completion channel */
struct ibv_pd *pd; /* protection domain */
struct ibv_cq *cq; /* completion queue */
/*
* If a previous write failed (perhaps because of a failed
* memory registration, then do not attempt any future work
* and remember the error state.
*/
int error_state;
int error_reported;
/*
* Description of ram blocks used throughout the code.
*/
RDMALocalBlocks local_ram_blocks;
RDMARemoteBlock *block;
/*
* Migration on *destination* started.
* Then use coroutine yield function.
* Source runs in a thread, so we don't care.
*/
int migration_started_on_destination;
int total_registrations;
int total_writes;
int unregister_current, unregister_next;
uint64_t unregistrations[RDMA_SIGNALED_SEND_MAX];
GHashTable *blockmap;
} RDMAContext;
/*
* Interface to the rest of the migration call stack.
*/
typedef struct QEMUFileRDMA {
RDMAContext *rdma;
size_t len;
void *file;
} QEMUFileRDMA;
/*
* Main structure for IB Send/Recv control messages.
* This gets prepended at the beginning of every Send/Recv.
*/
typedef struct QEMU_PACKED {
uint32_t len; /* Total length of data portion */
uint32_t type; /* which control command to perform */
uint32_t repeat; /* number of commands in data portion of same type */
uint32_t padding;
} RDMAControlHeader;
static void control_to_network(RDMAControlHeader *control)
{
control->type = htonl(control->type);
control->len = htonl(control->len);
control->repeat = htonl(control->repeat);
}
static void network_to_control(RDMAControlHeader *control)
{
control->type = ntohl(control->type);
control->len = ntohl(control->len);
control->repeat = ntohl(control->repeat);
}
/*
* Register a single Chunk.
* Information sent by the source VM to inform the dest
* to register an single chunk of memory before we can perform
* the actual RDMA operation.
*/
typedef struct QEMU_PACKED {
union QEMU_PACKED {
uint64_t current_addr; /* offset into the ramblock of the chunk */
uint64_t chunk; /* chunk to lookup if unregistering */
} key;
uint32_t current_index; /* which ramblock the chunk belongs to */
uint32_t padding;
uint64_t chunks; /* how many sequential chunks to register */
} RDMARegister;
static void register_to_network(RDMARegister *reg)
{
reg->key.current_addr = htonll(reg->key.current_addr);
reg->current_index = htonl(reg->current_index);
reg->chunks = htonll(reg->chunks);
}
static void network_to_register(RDMARegister *reg)
{
reg->key.current_addr = ntohll(reg->key.current_addr);
reg->current_index = ntohl(reg->current_index);
reg->chunks = ntohll(reg->chunks);
}
typedef struct QEMU_PACKED {
uint32_t value; /* if zero, we will madvise() */
uint32_t block_idx; /* which ram block index */
uint64_t offset; /* where in the remote ramblock this chunk */
uint64_t length; /* length of the chunk */
} RDMACompress;
static void compress_to_network(RDMACompress *comp)
{
comp->value = htonl(comp->value);
comp->block_idx = htonl(comp->block_idx);
comp->offset = htonll(comp->offset);
comp->length = htonll(comp->length);
}
static void network_to_compress(RDMACompress *comp)
{
comp->value = ntohl(comp->value);
comp->block_idx = ntohl(comp->block_idx);
comp->offset = ntohll(comp->offset);
comp->length = ntohll(comp->length);
}
/*
* The result of the dest's memory registration produces an "rkey"
* which the source VM must reference in order to perform
* the RDMA operation.
*/
typedef struct QEMU_PACKED {
uint32_t rkey;
uint32_t padding;
uint64_t host_addr;
} RDMARegisterResult;
static void result_to_network(RDMARegisterResult *result)
{
result->rkey = htonl(result->rkey);
result->host_addr = htonll(result->host_addr);
};
static void network_to_result(RDMARegisterResult *result)
{
result->rkey = ntohl(result->rkey);
result->host_addr = ntohll(result->host_addr);
};
const char *print_wrid(int wrid);
static int qemu_rdma_exchange_send(RDMAContext *rdma, RDMAControlHeader *head,
uint8_t *data, RDMAControlHeader *resp,
int *resp_idx,
int (*callback)(RDMAContext *rdma));
static inline uint64_t ram_chunk_index(const uint8_t *start,
const uint8_t *host)
{
return ((uintptr_t) host - (uintptr_t) start) >> RDMA_REG_CHUNK_SHIFT;
}
static inline uint8_t *ram_chunk_start(const RDMALocalBlock *rdma_ram_block,
uint64_t i)
{
return (uint8_t *)(uintptr_t)(rdma_ram_block->local_host_addr +
(i << RDMA_REG_CHUNK_SHIFT));
}
static inline uint8_t *ram_chunk_end(const RDMALocalBlock *rdma_ram_block,
uint64_t i)
{
uint8_t *result = ram_chunk_start(rdma_ram_block, i) +
(1UL << RDMA_REG_CHUNK_SHIFT);
if (result > (rdma_ram_block->local_host_addr + rdma_ram_block->length)) {
result = rdma_ram_block->local_host_addr + rdma_ram_block->length;
}
return result;
}
static int rdma_add_block(RDMAContext *rdma, void *host_addr,
ram_addr_t block_offset, uint64_t length)
{
RDMALocalBlocks *local = &rdma->local_ram_blocks;
RDMALocalBlock *block = g_hash_table_lookup(rdma->blockmap,
(void *)(uintptr_t)block_offset);
RDMALocalBlock *old = local->block;
assert(block == NULL);
local->block = g_malloc0(sizeof(RDMALocalBlock) * (local->nb_blocks + 1));
if (local->nb_blocks) {
int x;
for (x = 0; x < local->nb_blocks; x++) {
g_hash_table_remove(rdma->blockmap,
(void *)(uintptr_t)old[x].offset);
g_hash_table_insert(rdma->blockmap,
(void *)(uintptr_t)old[x].offset,
&local->block[x]);
}
memcpy(local->block, old, sizeof(RDMALocalBlock) * local->nb_blocks);
g_free(old);
}
block = &local->block[local->nb_blocks];
block->local_host_addr = host_addr;
block->offset = block_offset;
block->length = length;
block->index = local->nb_blocks;
block->nb_chunks = ram_chunk_index(host_addr, host_addr + length) + 1UL;
block->transit_bitmap = bitmap_new(block->nb_chunks);
bitmap_clear(block->transit_bitmap, 0, block->nb_chunks);
block->unregister_bitmap = bitmap_new(block->nb_chunks);
bitmap_clear(block->unregister_bitmap, 0, block->nb_chunks);
block->remote_keys = g_malloc0(block->nb_chunks * sizeof(uint32_t));
block->is_ram_block = local->init ? false : true;
g_hash_table_insert(rdma->blockmap, (void *) block_offset, block);
trace_rdma_add_block(local->nb_blocks, (uintptr_t) block->local_host_addr,
block->offset, block->length,
(uintptr_t) (block->local_host_addr + block->length),
BITS_TO_LONGS(block->nb_chunks) *
sizeof(unsigned long) * 8,
block->nb_chunks);
local->nb_blocks++;
return 0;
}
/*
* Memory regions need to be registered with the device and queue pairs setup
* in advanced before the migration starts. This tells us where the RAM blocks
* are so that we can register them individually.
*/
static void qemu_rdma_init_one_block(void *host_addr,
ram_addr_t block_offset, ram_addr_t length, void *opaque)
{
rdma_add_block(opaque, host_addr, block_offset, length);
}
/*
* Identify the RAMBlocks and their quantity. They will be references to
* identify chunk boundaries inside each RAMBlock and also be referenced
* during dynamic page registration.
*/
static int qemu_rdma_init_ram_blocks(RDMAContext *rdma)
{
RDMALocalBlocks *local = &rdma->local_ram_blocks;
assert(rdma->blockmap == NULL);
rdma->blockmap = g_hash_table_new(g_direct_hash, g_direct_equal);
memset(local, 0, sizeof *local);
qemu_ram_foreach_block(qemu_rdma_init_one_block, rdma);
trace_qemu_rdma_init_ram_blocks(local->nb_blocks);
rdma->block = (RDMARemoteBlock *) g_malloc0(sizeof(RDMARemoteBlock) *
rdma->local_ram_blocks.nb_blocks);
local->init = true;
return 0;
}
static int rdma_delete_block(RDMAContext *rdma, ram_addr_t block_offset)
{
RDMALocalBlocks *local = &rdma->local_ram_blocks;
RDMALocalBlock *block = g_hash_table_lookup(rdma->blockmap,
(void *) block_offset);
RDMALocalBlock *old = local->block;
int x;
assert(block);
if (block->pmr) {
int j;
for (j = 0; j < block->nb_chunks; j++) {
if (!block->pmr[j]) {
continue;
}
ibv_dereg_mr(block->pmr[j]);
rdma->total_registrations--;
}
g_free(block->pmr);
block->pmr = NULL;
}
if (block->mr) {
ibv_dereg_mr(block->mr);
rdma->total_registrations--;
block->mr = NULL;
}
g_free(block->transit_bitmap);
block->transit_bitmap = NULL;
g_free(block->unregister_bitmap);
block->unregister_bitmap = NULL;
g_free(block->remote_keys);
block->remote_keys = NULL;
for (x = 0; x < local->nb_blocks; x++) {
g_hash_table_remove(rdma->blockmap, (void *)(uintptr_t)old[x].offset);
}
if (local->nb_blocks > 1) {
local->block = g_malloc0(sizeof(RDMALocalBlock) *
(local->nb_blocks - 1));
if (block->index) {
memcpy(local->block, old, sizeof(RDMALocalBlock) * block->index);
}
if (block->index < (local->nb_blocks - 1)) {
memcpy(local->block + block->index, old + (block->index + 1),
sizeof(RDMALocalBlock) *
(local->nb_blocks - (block->index + 1)));
}
} else {
assert(block == local->block);
local->block = NULL;
}
trace_rdma_delete_block(local->nb_blocks,
(uintptr_t)block->local_host_addr,
block->offset, block->length,
(uintptr_t)(block->local_host_addr + block->length),
BITS_TO_LONGS(block->nb_chunks) *
sizeof(unsigned long) * 8, block->nb_chunks);
g_free(old);
local->nb_blocks--;
if (local->nb_blocks) {
for (x = 0; x < local->nb_blocks; x++) {
g_hash_table_insert(rdma->blockmap,
(void *)(uintptr_t)local->block[x].offset,
&local->block[x]);
}
}
return 0;
}
/*
* Put in the log file which RDMA device was opened and the details
* associated with that device.
*/
static void qemu_rdma_dump_id(const char *who, struct ibv_context *verbs)
{
struct ibv_port_attr port;
if (ibv_query_port(verbs, 1, &port)) {
error_report("Failed to query port information");
return;
}
printf("%s RDMA Device opened: kernel name %s "
"uverbs device name %s, "
"infiniband_verbs class device path %s, "
"infiniband class device path %s, "
"transport: (%d) %s\n",
who,
verbs->device->name,
verbs->device->dev_name,
verbs->device->dev_path,
verbs->device->ibdev_path,
port.link_layer,
(port.link_layer == IBV_LINK_LAYER_INFINIBAND) ? "Infiniband" :
((port.link_layer == IBV_LINK_LAYER_ETHERNET)
? "Ethernet" : "Unknown"));
}
/*
* Put in the log file the RDMA gid addressing information,
* useful for folks who have trouble understanding the
* RDMA device hierarchy in the kernel.
*/
static void qemu_rdma_dump_gid(const char *who, struct rdma_cm_id *id)
{
char sgid[33];
char dgid[33];
inet_ntop(AF_INET6, &id->route.addr.addr.ibaddr.sgid, sgid, sizeof sgid);
inet_ntop(AF_INET6, &id->route.addr.addr.ibaddr.dgid, dgid, sizeof dgid);
trace_qemu_rdma_dump_gid(who, sgid, dgid);
}
/*
* As of now, IPv6 over RoCE / iWARP is not supported by linux.
* We will try the next addrinfo struct, and fail if there are
* no other valid addresses to bind against.
*
* If user is listening on '[::]', then we will not have a opened a device
* yet and have no way of verifying if the device is RoCE or not.
*
* In this case, the source VM will throw an error for ALL types of
* connections (both IPv4 and IPv6) if the destination machine does not have
* a regular infiniband network available for use.
*
* The only way to guarantee that an error is thrown for broken kernels is
* for the management software to choose a *specific* interface at bind time
* and validate what time of hardware it is.
*
* Unfortunately, this puts the user in a fix:
*
* If the source VM connects with an IPv4 address without knowing that the
* destination has bound to '[::]' the migration will unconditionally fail
* unless the management software is explicitly listening on the the IPv4
* address while using a RoCE-based device.
*
* If the source VM connects with an IPv6 address, then we're OK because we can
* throw an error on the source (and similarly on the destination).
*
* But in mixed environments, this will be broken for a while until it is fixed
* inside linux.
*
* We do provide a *tiny* bit of help in this function: We can list all of the
* devices in the system and check to see if all the devices are RoCE or
* Infiniband.
*
* If we detect that we have a *pure* RoCE environment, then we can safely
* thrown an error even if the management software has specified '[::]' as the
* bind address.
*
* However, if there is are multiple hetergeneous devices, then we cannot make
* this assumption and the user just has to be sure they know what they are
* doing.
*
* Patches are being reviewed on linux-rdma.
*/
static int qemu_rdma_broken_ipv6_kernel(Error **errp, struct ibv_context *verbs)
{
struct ibv_port_attr port_attr;
/* This bug only exists in linux, to our knowledge. */
#ifdef CONFIG_LINUX
/*
* Verbs are only NULL if management has bound to '[::]'.
*
* Let's iterate through all the devices and see if there any pure IB
* devices (non-ethernet).
*
* If not, then we can safely proceed with the migration.
* Otherwise, there are no guarantees until the bug is fixed in linux.
*/
if (!verbs) {
int num_devices, x;
struct ibv_device ** dev_list = ibv_get_device_list(&num_devices);
bool roce_found = false;
bool ib_found = false;
for (x = 0; x < num_devices; x++) {
verbs = ibv_open_device(dev_list[x]);
if (ibv_query_port(verbs, 1, &port_attr)) {
ibv_close_device(verbs);
ERROR(errp, "Could not query initial IB port");
return -EINVAL;
}
if (port_attr.link_layer == IBV_LINK_LAYER_INFINIBAND) {
ib_found = true;
} else if (port_attr.link_layer == IBV_LINK_LAYER_ETHERNET) {
roce_found = true;
}
ibv_close_device(verbs);
}
if (roce_found) {
if (ib_found) {
fprintf(stderr, "WARN: migrations may fail:"
" IPv6 over RoCE / iWARP in linux"
" is broken. But since you appear to have a"
" mixed RoCE / IB environment, be sure to only"
" migrate over the IB fabric until the kernel "
" fixes the bug.\n");
} else {
ERROR(errp, "You only have RoCE / iWARP devices in your systems"
" and your management software has specified '[::]'"
", but IPv6 over RoCE / iWARP is not supported in Linux.");
return -ENONET;
}
}
return 0;
}
/*
* If we have a verbs context, that means that some other than '[::]' was
* used by the management software for binding. In which case we can
* actually warn the user about a potentially broken kernel.
*/
/* IB ports start with 1, not 0 */
if (ibv_query_port(verbs, 1, &port_attr)) {
ERROR(errp, "Could not query initial IB port");
return -EINVAL;
}
if (port_attr.link_layer == IBV_LINK_LAYER_ETHERNET) {
ERROR(errp, "Linux kernel's RoCE / iWARP does not support IPv6 "
"(but patches on linux-rdma in progress)");
return -ENONET;
}
#endif
return 0;
}
/*
* Figure out which RDMA device corresponds to the requested IP hostname
* Also create the initial connection manager identifiers for opening
* the connection.
*/
static int qemu_rdma_resolve_host(RDMAContext *rdma, Error **errp)
{
int ret;
struct rdma_addrinfo *res;
char port_str[16];
struct rdma_cm_event *cm_event;
char ip[40] = "unknown";
struct rdma_addrinfo *e;
if (rdma->host == NULL || !strcmp(rdma->host, "")) {
ERROR(errp, "RDMA hostname has not been set");
return -EINVAL;
}
/* create CM channel */
rdma->channel = rdma_create_event_channel();
if (!rdma->channel) {
ERROR(errp, "could not create CM channel");
return -EINVAL;
}
/* create CM id */
ret = rdma_create_id(rdma->channel, &rdma->cm_id, NULL, RDMA_PS_TCP);
if (ret) {
ERROR(errp, "could not create channel id");
goto err_resolve_create_id;
}
snprintf(port_str, 16, "%d", rdma->port);
port_str[15] = '\0';
ret = rdma_getaddrinfo(rdma->host, port_str, NULL, &res);
if (ret < 0) {
ERROR(errp, "could not rdma_getaddrinfo address %s", rdma->host);
goto err_resolve_get_addr;
}
for (e = res; e != NULL; e = e->ai_next) {
inet_ntop(e->ai_family,
&((struct sockaddr_in *) e->ai_dst_addr)->sin_addr, ip, sizeof ip);
trace_qemu_rdma_resolve_host_trying(rdma->host, ip);
ret = rdma_resolve_addr(rdma->cm_id, NULL, e->ai_dst_addr,
RDMA_RESOLVE_TIMEOUT_MS);
if (!ret) {
if (e->ai_family == AF_INET6) {
ret = qemu_rdma_broken_ipv6_kernel(errp, rdma->cm_id->verbs);
if (ret) {
continue;
}
}
goto route;
}
}
ERROR(errp, "could not resolve address %s", rdma->host);
goto err_resolve_get_addr;
route:
qemu_rdma_dump_gid("source_resolve_addr", rdma->cm_id);
ret = rdma_get_cm_event(rdma->channel, &cm_event);
if (ret) {
ERROR(errp, "could not perform event_addr_resolved");
goto err_resolve_get_addr;
}
if (cm_event->event != RDMA_CM_EVENT_ADDR_RESOLVED) {
ERROR(errp, "result not equal to event_addr_resolved %s",
rdma_event_str(cm_event->event));
perror("rdma_resolve_addr");
rdma_ack_cm_event(cm_event);
ret = -EINVAL;
goto err_resolve_get_addr;
}
rdma_ack_cm_event(cm_event);
/* resolve route */
ret = rdma_resolve_route(rdma->cm_id, RDMA_RESOLVE_TIMEOUT_MS);
if (ret) {
ERROR(errp, "could not resolve rdma route");
goto err_resolve_get_addr;
}
ret = rdma_get_cm_event(rdma->channel, &cm_event);
if (ret) {
ERROR(errp, "could not perform event_route_resolved");
goto err_resolve_get_addr;
}
if (cm_event->event != RDMA_CM_EVENT_ROUTE_RESOLVED) {
ERROR(errp, "result not equal to event_route_resolved: %s",
rdma_event_str(cm_event->event));
rdma_ack_cm_event(cm_event);
ret = -EINVAL;
goto err_resolve_get_addr;
}
rdma_ack_cm_event(cm_event);
rdma->verbs = rdma->cm_id->verbs;
qemu_rdma_dump_id("source_resolve_host", rdma->cm_id->verbs);
qemu_rdma_dump_gid("source_resolve_host", rdma->cm_id);
return 0;
err_resolve_get_addr:
rdma_destroy_id(rdma->cm_id);
rdma->cm_id = NULL;
err_resolve_create_id:
rdma_destroy_event_channel(rdma->channel);
rdma->channel = NULL;
return ret;
}
/*
* Create protection domain and completion queues
*/
static int qemu_rdma_alloc_pd_cq(RDMAContext *rdma)
{
/* allocate pd */
rdma->pd = ibv_alloc_pd(rdma->verbs);
if (!rdma->pd) {
error_report("failed to allocate protection domain");
return -1;
}
/* create completion channel */
rdma->comp_channel = ibv_create_comp_channel(rdma->verbs);
if (!rdma->comp_channel) {
error_report("failed to allocate completion channel");
goto err_alloc_pd_cq;
}
/*
* Completion queue can be filled by both read and write work requests,
* so must reflect the sum of both possible queue sizes.
*/
rdma->cq = ibv_create_cq(rdma->verbs, (RDMA_SIGNALED_SEND_MAX * 3),
NULL, rdma->comp_channel, 0);
if (!rdma->cq) {
error_report("failed to allocate completion queue");
goto err_alloc_pd_cq;
}
return 0;
err_alloc_pd_cq:
if (rdma->pd) {
ibv_dealloc_pd(rdma->pd);
}
if (rdma->comp_channel) {
ibv_destroy_comp_channel(rdma->comp_channel);
}
rdma->pd = NULL;
rdma->comp_channel = NULL;
return -1;
}
/*
* Create queue pairs.
*/
static int qemu_rdma_alloc_qp(RDMAContext *rdma)
{
struct ibv_qp_init_attr attr = { 0 };
int ret;
attr.cap.max_send_wr = RDMA_SIGNALED_SEND_MAX;
attr.cap.max_recv_wr = 3;
attr.cap.max_send_sge = 1;
attr.cap.max_recv_sge = 1;
attr.send_cq = rdma->cq;
attr.recv_cq = rdma->cq;
attr.qp_type = IBV_QPT_RC;
ret = rdma_create_qp(rdma->cm_id, rdma->pd, &attr);
if (ret) {
return -1;
}
rdma->qp = rdma->cm_id->qp;
return 0;
}
static int qemu_rdma_reg_whole_ram_blocks(RDMAContext *rdma)
{
int i;
RDMALocalBlocks *local = &rdma->local_ram_blocks;
for (i = 0; i < local->nb_blocks; i++) {
local->block[i].mr =
ibv_reg_mr(rdma->pd,
local->block[i].local_host_addr,
local->block[i].length,
IBV_ACCESS_LOCAL_WRITE |
IBV_ACCESS_REMOTE_WRITE
);
if (!local->block[i].mr) {
perror("Failed to register local dest ram block!\n");
break;
}
rdma->total_registrations++;
}
if (i >= local->nb_blocks) {
return 0;
}
for (i--; i >= 0; i--) {
ibv_dereg_mr(local->block[i].mr);
rdma->total_registrations--;
}
return -1;
}
/*
* Find the ram block that corresponds to the page requested to be
* transmitted by QEMU.
*
* Once the block is found, also identify which 'chunk' within that
* block that the page belongs to.
*
* This search cannot fail or the migration will fail.
*/
static int qemu_rdma_search_ram_block(RDMAContext *rdma,
uintptr_t block_offset,
uint64_t offset,
uint64_t length,
uint64_t *block_index,
uint64_t *chunk_index)
{
uint64_t current_addr = block_offset + offset;
RDMALocalBlock *block = g_hash_table_lookup(rdma->blockmap,
(void *) block_offset);
assert(block);
assert(current_addr >= block->offset);
assert((current_addr + length) <= (block->offset + block->length));
*block_index = block->index;
*chunk_index = ram_chunk_index(block->local_host_addr,
block->local_host_addr + (current_addr - block->offset));
return 0;
}
/*
* Register a chunk with IB. If the chunk was already registered
* previously, then skip.
*
* Also return the keys associated with the registration needed
* to perform the actual RDMA operation.
*/
static int qemu_rdma_register_and_get_keys(RDMAContext *rdma,
RDMALocalBlock *block, uintptr_t host_addr,
uint32_t *lkey, uint32_t *rkey, int chunk,
uint8_t *chunk_start, uint8_t *chunk_end)
{
if (block->mr) {
if (lkey) {
*lkey = block->mr->lkey;
}
if (rkey) {
*rkey = block->mr->rkey;
}
return 0;
}
/* allocate memory to store chunk MRs */
if (!block->pmr) {
block->pmr = g_malloc0(block->nb_chunks * sizeof(struct ibv_mr *));
}
/*
* If 'rkey', then we're the destination, so grant access to the source.
*
* If 'lkey', then we're the source VM, so grant access only to ourselves.
*/
if (!block->pmr[chunk]) {
uint64_t len = chunk_end - chunk_start;
trace_qemu_rdma_register_and_get_keys(len, chunk_start);
block->pmr[chunk] = ibv_reg_mr(rdma->pd,
chunk_start, len,
(rkey ? (IBV_ACCESS_LOCAL_WRITE |
IBV_ACCESS_REMOTE_WRITE) : 0));
if (!block->pmr[chunk]) {
perror("Failed to register chunk!");
fprintf(stderr, "Chunk details: block: %d chunk index %d"
" start %" PRIuPTR " end %" PRIuPTR
" host %" PRIuPTR
" local %" PRIuPTR " registrations: %d\n",
block->index, chunk, (uintptr_t)chunk_start,
(uintptr_t)chunk_end, host_addr,
(uintptr_t)block->local_host_addr,
rdma->total_registrations);
return -1;
}
rdma->total_registrations++;
}
if (lkey) {
*lkey = block->pmr[chunk]->lkey;
}
if (rkey) {
*rkey = block->pmr[chunk]->rkey;
}
return 0;
}
/*
* Register (at connection time) the memory used for control
* channel messages.
*/
static int qemu_rdma_reg_control(RDMAContext *rdma, int idx)
{
rdma->wr_data[idx].control_mr = ibv_reg_mr(rdma->pd,
rdma->wr_data[idx].control, RDMA_CONTROL_MAX_BUFFER,
IBV_ACCESS_LOCAL_WRITE | IBV_ACCESS_REMOTE_WRITE);
if (rdma->wr_data[idx].control_mr) {
rdma->total_registrations++;
return 0;
}
error_report("qemu_rdma_reg_control failed");
return -1;
}
const char *print_wrid(int wrid)
{
if (wrid >= RDMA_WRID_RECV_CONTROL) {
return wrid_desc[RDMA_WRID_RECV_CONTROL];
}
return wrid_desc[wrid];
}
/*
* RDMA requires memory registration (mlock/pinning), but this is not good for
* overcommitment.
*
* In preparation for the future where LRU information or workload-specific
* writable writable working set memory access behavior is available to QEMU
* it would be nice to have in place the ability to UN-register/UN-pin
* particular memory regions from the RDMA hardware when it is determine that
* those regions of memory will likely not be accessed again in the near future.
*
* While we do not yet have such information right now, the following
* compile-time option allows us to perform a non-optimized version of this
* behavior.
*
* By uncommenting this option, you will cause *all* RDMA transfers to be
* unregistered immediately after the transfer completes on both sides of the
* connection. This has no effect in 'rdma-pin-all' mode, only regular mode.
*
* This will have a terrible impact on migration performance, so until future
* workload information or LRU information is available, do not attempt to use
* this feature except for basic testing.
*/
//#define RDMA_UNREGISTRATION_EXAMPLE
/*
* Perform a non-optimized memory unregistration after every transfer
* for demonsration purposes, only if pin-all is not requested.
*
* Potential optimizations:
* 1. Start a new thread to run this function continuously
- for bit clearing
- and for receipt of unregister messages
* 2. Use an LRU.
* 3. Use workload hints.
*/
static int qemu_rdma_unregister_waiting(RDMAContext *rdma)
{
while (rdma->unregistrations[rdma->unregister_current]) {
int ret;
uint64_t wr_id = rdma->unregistrations[rdma->unregister_current];
uint64_t chunk =
(wr_id & RDMA_WRID_CHUNK_MASK) >> RDMA_WRID_CHUNK_SHIFT;
uint64_t index =
(wr_id & RDMA_WRID_BLOCK_MASK) >> RDMA_WRID_BLOCK_SHIFT;
RDMALocalBlock *block =
&(rdma->local_ram_blocks.block[index]);
RDMARegister reg = { .current_index = index };
RDMAControlHeader resp = { .type = RDMA_CONTROL_UNREGISTER_FINISHED,
};
RDMAControlHeader head = { .len = sizeof(RDMARegister),
.type = RDMA_CONTROL_UNREGISTER_REQUEST,
.repeat = 1,
};
trace_qemu_rdma_unregister_waiting_proc(chunk,
rdma->unregister_current);
rdma->unregistrations[rdma->unregister_current] = 0;
rdma->unregister_current++;
if (rdma->unregister_current == RDMA_SIGNALED_SEND_MAX) {
rdma->unregister_current = 0;
}
/*
* Unregistration is speculative (because migration is single-threaded
* and we cannot break the protocol's inifinband message ordering).
* Thus, if the memory is currently being used for transmission,
* then abort the attempt to unregister and try again
* later the next time a completion is received for this memory.
*/
clear_bit(chunk, block->unregister_bitmap);
if (test_bit(chunk, block->transit_bitmap)) {
trace_qemu_rdma_unregister_waiting_inflight(chunk);
continue;
}
trace_qemu_rdma_unregister_waiting_send(chunk);
ret = ibv_dereg_mr(block->pmr[chunk]);
block->pmr[chunk] = NULL;
block->remote_keys[chunk] = 0;
if (ret != 0) {
perror("unregistration chunk failed");
return -ret;
}
rdma->total_registrations--;
reg.key.chunk = chunk;
register_to_network(&reg);
ret = qemu_rdma_exchange_send(rdma, &head, (uint8_t *) &reg,
&resp, NULL, NULL);
if (ret < 0) {
return ret;
}
trace_qemu_rdma_unregister_waiting_complete(chunk);
}
return 0;
}
static uint64_t qemu_rdma_make_wrid(uint64_t wr_id, uint64_t index,
uint64_t chunk)
{
uint64_t result = wr_id & RDMA_WRID_TYPE_MASK;
result |= (index << RDMA_WRID_BLOCK_SHIFT);
result |= (chunk << RDMA_WRID_CHUNK_SHIFT);
return result;
}
/*
* Set bit for unregistration in the next iteration.
* We cannot transmit right here, but will unpin later.
*/
static void qemu_rdma_signal_unregister(RDMAContext *rdma, uint64_t index,
uint64_t chunk, uint64_t wr_id)
{
if (rdma->unregistrations[rdma->unregister_next] != 0) {
error_report("rdma migration: queue is full");
} else {
RDMALocalBlock *block = &(rdma->local_ram_blocks.block[index]);
if (!test_and_set_bit(chunk, block->unregister_bitmap)) {
trace_qemu_rdma_signal_unregister_append(chunk,
rdma->unregister_next);
rdma->unregistrations[rdma->unregister_next++] =
qemu_rdma_make_wrid(wr_id, index, chunk);
if (rdma->unregister_next == RDMA_SIGNALED_SEND_MAX) {
rdma->unregister_next = 0;
}
} else {
trace_qemu_rdma_signal_unregister_already(chunk);
}
}
}
/*
* Consult the connection manager to see a work request
* (of any kind) has completed.
* Return the work request ID that completed.
*/
static uint64_t qemu_rdma_poll(RDMAContext *rdma, uint64_t *wr_id_out,
uint32_t *byte_len)
{
int ret;
struct ibv_wc wc;
uint64_t wr_id;
ret = ibv_poll_cq(rdma->cq, 1, &wc);
if (!ret) {
*wr_id_out = RDMA_WRID_NONE;
return 0;
}
if (ret < 0) {
error_report("ibv_poll_cq return %d", ret);
return ret;
}
wr_id = wc.wr_id & RDMA_WRID_TYPE_MASK;
if (wc.status != IBV_WC_SUCCESS) {
fprintf(stderr, "ibv_poll_cq wc.status=%d %s!\n",
wc.status, ibv_wc_status_str(wc.status));
fprintf(stderr, "ibv_poll_cq wrid=%s!\n", wrid_desc[wr_id]);
return -1;
}
if (rdma->control_ready_expected &&
(wr_id >= RDMA_WRID_RECV_CONTROL)) {
trace_qemu_rdma_poll_recv(wrid_desc[RDMA_WRID_RECV_CONTROL],
wr_id - RDMA_WRID_RECV_CONTROL, wr_id, rdma->nb_sent);
rdma->control_ready_expected = 0;
}
if (wr_id == RDMA_WRID_RDMA_WRITE) {
uint64_t chunk =
(wc.wr_id & RDMA_WRID_CHUNK_MASK) >> RDMA_WRID_CHUNK_SHIFT;
uint64_t index =
(wc.wr_id & RDMA_WRID_BLOCK_MASK) >> RDMA_WRID_BLOCK_SHIFT;
RDMALocalBlock *block = &(rdma->local_ram_blocks.block[index]);
trace_qemu_rdma_poll_write(print_wrid(wr_id), wr_id, rdma->nb_sent,
index, chunk, block->local_host_addr,
(void *)(uintptr_t)block->remote_host_addr);
clear_bit(chunk, block->transit_bitmap);
if (rdma->nb_sent > 0) {
rdma->nb_sent--;
}
if (!rdma->pin_all) {
/*
* FYI: If one wanted to signal a specific chunk to be unregistered
* using LRU or workload-specific information, this is the function
* you would call to do so. That chunk would then get asynchronously
* unregistered later.
*/
#ifdef RDMA_UNREGISTRATION_EXAMPLE
qemu_rdma_signal_unregister(rdma, index, chunk, wc.wr_id);
#endif
}
} else {
trace_qemu_rdma_poll_other(print_wrid(wr_id), wr_id, rdma->nb_sent);
}
*wr_id_out = wc.wr_id;
if (byte_len) {
*byte_len = wc.byte_len;
}
return 0;
}
/*
* Block until the next work request has completed.
*
* First poll to see if a work request has already completed,
* otherwise block.
*
* If we encounter completed work requests for IDs other than
* the one we're interested in, then that's generally an error.
*
* The only exception is actual RDMA Write completions. These
* completions only need to be recorded, but do not actually
* need further processing.
*/
static int qemu_rdma_block_for_wrid(RDMAContext *rdma, int wrid_requested,
uint32_t *byte_len)
{
int num_cq_events = 0, ret = 0;
struct ibv_cq *cq;
void *cq_ctx;
uint64_t wr_id = RDMA_WRID_NONE, wr_id_in;
if (ibv_req_notify_cq(rdma->cq, 0)) {
return -1;
}
/* poll cq first */
while (wr_id != wrid_requested) {
ret = qemu_rdma_poll(rdma, &wr_id_in, byte_len);
if (ret < 0) {
return ret;
}
wr_id = wr_id_in & RDMA_WRID_TYPE_MASK;
if (wr_id == RDMA_WRID_NONE) {
break;
}
if (wr_id != wrid_requested) {
trace_qemu_rdma_block_for_wrid_miss(print_wrid(wrid_requested),
wrid_requested, print_wrid(wr_id), wr_id);
}
}
if (wr_id == wrid_requested) {
return 0;
}
while (1) {
/*
* Coroutine doesn't start until process_incoming_migration()
* so don't yield unless we know we're running inside of a coroutine.
*/
if (rdma->migration_started_on_destination) {
yield_until_fd_readable(rdma->comp_channel->fd);
}
if (ibv_get_cq_event(rdma->comp_channel, &cq, &cq_ctx)) {
perror("ibv_get_cq_event");
goto err_block_for_wrid;
}
num_cq_events++;
if (ibv_req_notify_cq(cq, 0)) {
goto err_block_for_wrid;
}
while (wr_id != wrid_requested) {
ret = qemu_rdma_poll(rdma, &wr_id_in, byte_len);
if (ret < 0) {
goto err_block_for_wrid;
}
wr_id = wr_id_in & RDMA_WRID_TYPE_MASK;
if (wr_id == RDMA_WRID_NONE) {
break;
}
if (wr_id != wrid_requested) {
trace_qemu_rdma_block_for_wrid_miss(print_wrid(wrid_requested),
wrid_requested, print_wrid(wr_id), wr_id);
}
}
if (wr_id == wrid_requested) {
goto success_block_for_wrid;
}
}
success_block_for_wrid:
if (num_cq_events) {
ibv_ack_cq_events(cq, num_cq_events);
}
return 0;
err_block_for_wrid:
if (num_cq_events) {
ibv_ack_cq_events(cq, num_cq_events);
}
return ret;
}
/*
* Post a SEND message work request for the control channel
* containing some data and block until the post completes.
*/
static int qemu_rdma_post_send_control(RDMAContext *rdma, uint8_t *buf,
RDMAControlHeader *head)
{
int ret = 0;
RDMAWorkRequestData *wr = &rdma->wr_data[RDMA_WRID_CONTROL];
struct ibv_send_wr *bad_wr;
struct ibv_sge sge = {
.addr = (uintptr_t)(wr->control),
.length = head->len + sizeof(RDMAControlHeader),
.lkey = wr->control_mr->lkey,
};
struct ibv_send_wr send_wr = {
.wr_id = RDMA_WRID_SEND_CONTROL,
.opcode = IBV_WR_SEND,
.send_flags = IBV_SEND_SIGNALED,
.sg_list = &sge,
.num_sge = 1,
};
trace_qemu_rdma_post_send_control(control_desc[head->type]);
/*
* We don't actually need to do a memcpy() in here if we used
* the "sge" properly, but since we're only sending control messages
* (not RAM in a performance-critical path), then its OK for now.
*
* The copy makes the RDMAControlHeader simpler to manipulate
* for the time being.
*/
assert(head->len <= RDMA_CONTROL_MAX_BUFFER - sizeof(*head));
memcpy(wr->control, head, sizeof(RDMAControlHeader));
control_to_network((void *) wr->control);
if (buf) {
memcpy(wr->control + sizeof(RDMAControlHeader), buf, head->len);
}
ret = ibv_post_send(rdma->qp, &send_wr, &bad_wr);
if (ret > 0) {
error_report("Failed to use post IB SEND for control");
return -ret;
}
ret = qemu_rdma_block_for_wrid(rdma, RDMA_WRID_SEND_CONTROL, NULL);
if (ret < 0) {
error_report("rdma migration: send polling control error");
}
return ret;
}
/*
* Post a RECV work request in anticipation of some future receipt
* of data on the control channel.
*/
static int qemu_rdma_post_recv_control(RDMAContext *rdma, int idx)
{
struct ibv_recv_wr *bad_wr;
struct ibv_sge sge = {
.addr = (uintptr_t)(rdma->wr_data[idx].control),
.length = RDMA_CONTROL_MAX_BUFFER,
.lkey = rdma->wr_data[idx].control_mr->lkey,
};
struct ibv_recv_wr recv_wr = {
.wr_id = RDMA_WRID_RECV_CONTROL + idx,
.sg_list = &sge,
.num_sge = 1,
};
if (ibv_post_recv(rdma->qp, &recv_wr, &bad_wr)) {
return -1;
}
return 0;
}
/*
* Block and wait for a RECV control channel message to arrive.
*/
static int qemu_rdma_exchange_get_response(RDMAContext *rdma,
RDMAControlHeader *head, int expecting, int idx)
{
uint32_t byte_len;
int ret = qemu_rdma_block_for_wrid(rdma, RDMA_WRID_RECV_CONTROL + idx,
&byte_len);
if (ret < 0) {
error_report("rdma migration: recv polling control error!");
return ret;
}
network_to_control((void *) rdma->wr_data[idx].control);
memcpy(head, rdma->wr_data[idx].control, sizeof(RDMAControlHeader));
trace_qemu_rdma_exchange_get_response_start(control_desc[expecting]);
if (expecting == RDMA_CONTROL_NONE) {
trace_qemu_rdma_exchange_get_response_none(control_desc[head->type],
head->type);
} else if (head->type != expecting || head->type == RDMA_CONTROL_ERROR) {
error_report("Was expecting a %s (%d) control message"
", but got: %s (%d), length: %d",
control_desc[expecting], expecting,
control_desc[head->type], head->type, head->len);
return -EIO;
}
if (head->len > RDMA_CONTROL_MAX_BUFFER - sizeof(*head)) {
error_report("too long length: %d", head->len);
return -EINVAL;
}
if (sizeof(*head) + head->len != byte_len) {
error_report("Malformed length: %d byte_len %d", head->len, byte_len);
return -EINVAL;
}
return 0;
}
/*
* When a RECV work request has completed, the work request's
* buffer is pointed at the header.
*
* This will advance the pointer to the data portion
* of the control message of the work request's buffer that
* was populated after the work request finished.
*/
static void qemu_rdma_move_header(RDMAContext *rdma, int idx,
RDMAControlHeader *head)
{
rdma->wr_data[idx].control_len = head->len;
rdma->wr_data[idx].control_curr =
rdma->wr_data[idx].control + sizeof(RDMAControlHeader);
}
/*
* This is an 'atomic' high-level operation to deliver a single, unified
* control-channel message.
*
* Additionally, if the user is expecting some kind of reply to this message,
* they can request a 'resp' response message be filled in by posting an
* additional work request on behalf of the user and waiting for an additional
* completion.
*
* The extra (optional) response is used during registration to us from having
* to perform an *additional* exchange of message just to provide a response by
* instead piggy-backing on the acknowledgement.
*/
static int qemu_rdma_exchange_send(RDMAContext *rdma, RDMAControlHeader *head,
uint8_t *data, RDMAControlHeader *resp,
int *resp_idx,
int (*callback)(RDMAContext *rdma))
{
int ret = 0;
/*
* Wait until the dest is ready before attempting to deliver the message
* by waiting for a READY message.
*/
if (rdma->control_ready_expected) {
RDMAControlHeader resp;
ret = qemu_rdma_exchange_get_response(rdma,
&resp, RDMA_CONTROL_READY, RDMA_WRID_READY);
if (ret < 0) {
return ret;
}
}
/*
* If the user is expecting a response, post a WR in anticipation of it.
*/
if (resp) {
ret = qemu_rdma_post_recv_control(rdma, RDMA_WRID_DATA);
if (ret) {
error_report("rdma migration: error posting"
" extra control recv for anticipated result!");
return ret;
}
}
/*
* Post a WR to replace the one we just consumed for the READY message.
*/
ret = qemu_rdma_post_recv_control(rdma, RDMA_WRID_READY);
if (ret) {
error_report("rdma migration: error posting first control recv!");
return ret;
}
/*
* Deliver the control message that was requested.
*/
ret = qemu_rdma_post_send_control(rdma, data, head);
if (ret < 0) {
error_report("Failed to send control buffer!");
return ret;
}
/*
* If we're expecting a response, block and wait for it.
*/
if (resp) {
if (callback) {
trace_qemu_rdma_exchange_send_issue_callback();
ret = callback(rdma);
if (ret < 0) {
return ret;
}
}
trace_qemu_rdma_exchange_send_waiting(control_desc[resp->type]);
ret = qemu_rdma_exchange_get_response(rdma, resp,
resp->type, RDMA_WRID_DATA);
if (ret < 0) {
return ret;
}
qemu_rdma_move_header(rdma, RDMA_WRID_DATA, resp);
if (resp_idx) {
*resp_idx = RDMA_WRID_DATA;
}
trace_qemu_rdma_exchange_send_received(control_desc[resp->type]);
}
rdma->control_ready_expected = 1;
return 0;
}
/*
* This is an 'atomic' high-level operation to receive a single, unified
* control-channel message.
*/
static int qemu_rdma_exchange_recv(RDMAContext *rdma, RDMAControlHeader *head,
int expecting)
{
RDMAControlHeader ready = {
.len = 0,
.type = RDMA_CONTROL_READY,
.repeat = 1,
};
int ret;
/*
* Inform the source that we're ready to receive a message.
*/
ret = qemu_rdma_post_send_control(rdma, NULL, &ready);
if (ret < 0) {
error_report("Failed to send control buffer!");
return ret;
}
/*
* Block and wait for the message.
*/
ret = qemu_rdma_exchange_get_response(rdma, head,
expecting, RDMA_WRID_READY);
if (ret < 0) {
return ret;
}
qemu_rdma_move_header(rdma, RDMA_WRID_READY, head);
/*
* Post a new RECV work request to replace the one we just consumed.
*/
ret = qemu_rdma_post_recv_control(rdma, RDMA_WRID_READY);
if (ret) {
error_report("rdma migration: error posting second control recv!");
return ret;
}
return 0;
}
/*
* Write an actual chunk of memory using RDMA.
*
* If we're using dynamic registration on the dest-side, we have to
* send a registration command first.
*/
static int qemu_rdma_write_one(QEMUFile *f, RDMAContext *rdma,
int current_index, uint64_t current_addr,
uint64_t length)
{
struct ibv_sge sge;
struct ibv_send_wr send_wr = { 0 };
struct ibv_send_wr *bad_wr;
int reg_result_idx, ret, count = 0;
uint64_t chunk, chunks;
uint8_t *chunk_start, *chunk_end;
RDMALocalBlock *block = &(rdma->local_ram_blocks.block[current_index]);
RDMARegister reg;
RDMARegisterResult *reg_result;
RDMAControlHeader resp = { .type = RDMA_CONTROL_REGISTER_RESULT };
RDMAControlHeader head = { .len = sizeof(RDMARegister),
.type = RDMA_CONTROL_REGISTER_REQUEST,
.repeat = 1,
};
retry:
sge.addr = (uintptr_t)(block->local_host_addr +
(current_addr - block->offset));
sge.length = length;
chunk = ram_chunk_index(block->local_host_addr,
(uint8_t *)(uintptr_t)sge.addr);
chunk_start = ram_chunk_start(block, chunk);
if (block->is_ram_block) {
chunks = length / (1UL << RDMA_REG_CHUNK_SHIFT);
if (chunks && ((length % (1UL << RDMA_REG_CHUNK_SHIFT)) == 0)) {
chunks--;
}
} else {
chunks = block->length / (1UL << RDMA_REG_CHUNK_SHIFT);
if (chunks && ((block->length % (1UL << RDMA_REG_CHUNK_SHIFT)) == 0)) {
chunks--;
}
}
trace_qemu_rdma_write_one_top(chunks + 1,
(chunks + 1) *
(1UL << RDMA_REG_CHUNK_SHIFT) / 1024 / 1024);
chunk_end = ram_chunk_end(block, chunk + chunks);
if (!rdma->pin_all) {
#ifdef RDMA_UNREGISTRATION_EXAMPLE
qemu_rdma_unregister_waiting(rdma);
#endif
}
while (test_bit(chunk, block->transit_bitmap)) {
(void)count;
trace_qemu_rdma_write_one_block(count++, current_index, chunk,
sge.addr, length, rdma->nb_sent, block->nb_chunks);
ret = qemu_rdma_block_for_wrid(rdma, RDMA_WRID_RDMA_WRITE, NULL);
if (ret < 0) {
error_report("Failed to Wait for previous write to complete "
"block %d chunk %" PRIu64
" current %" PRIu64 " len %" PRIu64 " %d",
current_index, chunk, sge.addr, length, rdma->nb_sent);
return ret;
}
}
if (!rdma->pin_all || !block->is_ram_block) {
if (!block->remote_keys[chunk]) {
/*
* This chunk has not yet been registered, so first check to see
* if the entire chunk is zero. If so, tell the other size to
* memset() + madvise() the entire chunk without RDMA.
*/
if (can_use_buffer_find_nonzero_offset((void *)(uintptr_t)sge.addr,
length)
&& buffer_find_nonzero_offset((void *)(uintptr_t)sge.addr,
length) == length) {
RDMACompress comp = {
.offset = current_addr,
.value = 0,
.block_idx = current_index,
.length = length,
};
head.len = sizeof(comp);
head.type = RDMA_CONTROL_COMPRESS;
trace_qemu_rdma_write_one_zero(chunk, sge.length,
current_index, current_addr);
compress_to_network(&comp);
ret = qemu_rdma_exchange_send(rdma, &head,
(uint8_t *) &comp, NULL, NULL, NULL);
if (ret < 0) {
return -EIO;
}
acct_update_position(f, sge.length, true);
return 1;
}
/*
* Otherwise, tell other side to register.
*/
reg.current_index = current_index;
if (block->is_ram_block) {
reg.key.current_addr = current_addr;
} else {
reg.key.chunk = chunk;
}
reg.chunks = chunks;
trace_qemu_rdma_write_one_sendreg(chunk, sge.length, current_index,
current_addr);
register_to_network(&reg);
ret = qemu_rdma_exchange_send(rdma, &head, (uint8_t *) &reg,
&resp, &reg_result_idx, NULL);
if (ret < 0) {
return ret;
}
/* try to overlap this single registration with the one we sent. */
if (qemu_rdma_register_and_get_keys(rdma, block, sge.addr,
&sge.lkey, NULL, chunk,
chunk_start, chunk_end)) {
error_report("cannot get lkey");
return -EINVAL;
}
reg_result = (RDMARegisterResult *)
rdma->wr_data[reg_result_idx].control_curr;
network_to_result(reg_result);
trace_qemu_rdma_write_one_recvregres(block->remote_keys[chunk],
reg_result->rkey, chunk);
block->remote_keys[chunk] = reg_result->rkey;
block->remote_host_addr = reg_result->host_addr;
} else {
/* already registered before */
if (qemu_rdma_register_and_get_keys(rdma, block, sge.addr,
&sge.lkey, NULL, chunk,
chunk_start, chunk_end)) {
error_report("cannot get lkey!");
return -EINVAL;
}
}
send_wr.wr.rdma.rkey = block->remote_keys[chunk];
} else {
send_wr.wr.rdma.rkey = block->remote_rkey;
if (qemu_rdma_register_and_get_keys(rdma, block, sge.addr,
&sge.lkey, NULL, chunk,
chunk_start, chunk_end)) {
error_report("cannot get lkey!");
return -EINVAL;
}
}
/*
* Encode the ram block index and chunk within this wrid.
* We will use this information at the time of completion
* to figure out which bitmap to check against and then which
* chunk in the bitmap to look for.
*/
send_wr.wr_id = qemu_rdma_make_wrid(RDMA_WRID_RDMA_WRITE,
current_index, chunk);
send_wr.opcode = IBV_WR_RDMA_WRITE;
send_wr.send_flags = IBV_SEND_SIGNALED;
send_wr.sg_list = &sge;
send_wr.num_sge = 1;
send_wr.wr.rdma.remote_addr = block->remote_host_addr +
(current_addr - block->offset);
trace_qemu_rdma_write_one_post(chunk, sge.addr, send_wr.wr.rdma.remote_addr,
sge.length);
/*
* ibv_post_send() does not return negative error numbers,
* per the specification they are positive - no idea why.
*/
ret = ibv_post_send(rdma->qp, &send_wr, &bad_wr);
if (ret == ENOMEM) {
trace_qemu_rdma_write_one_queue_full();
ret = qemu_rdma_block_for_wrid(rdma, RDMA_WRID_RDMA_WRITE, NULL);
if (ret < 0) {
error_report("rdma migration: failed to make "
"room in full send queue! %d", ret);
return ret;
}
goto retry;
} else if (ret > 0) {
perror("rdma migration: post rdma write failed");
return -ret;
}
set_bit(chunk, block->transit_bitmap);
acct_update_position(f, sge.length, false);
rdma->total_writes++;
return 0;
}
/*
* Push out any unwritten RDMA operations.
*
* We support sending out multiple chunks at the same time.
* Not all of them need to get signaled in the completion queue.
*/
static int qemu_rdma_write_flush(QEMUFile *f, RDMAContext *rdma)
{
int ret;
if (!rdma->current_length) {
return 0;
}
ret = qemu_rdma_write_one(f, rdma,
rdma->current_index, rdma->current_addr, rdma->current_length);
if (ret < 0) {
return ret;
}
if (ret == 0) {
rdma->nb_sent++;
trace_qemu_rdma_write_flush(rdma->nb_sent);
}
rdma->current_length = 0;
rdma->current_addr = 0;
return 0;
}
static inline int qemu_rdma_buffer_mergable(RDMAContext *rdma,
uint64_t offset, uint64_t len)
{
RDMALocalBlock *block;
uint8_t *host_addr;
uint8_t *chunk_end;
if (rdma->current_index < 0) {
return 0;
}
if (rdma->current_chunk < 0) {
return 0;
}
block = &(rdma->local_ram_blocks.block[rdma->current_index]);
host_addr = block->local_host_addr + (offset - block->offset);
chunk_end = ram_chunk_end(block, rdma->current_chunk);
if (rdma->current_length == 0) {
return 0;
}
/*
* Only merge into chunk sequentially.
*/
if (offset != (rdma->current_addr + rdma->current_length)) {
return 0;
}
if (offset < block->offset) {
return 0;
}
if ((offset + len) > (block->offset + block->length)) {
return 0;
}
if ((host_addr + len) > chunk_end) {
return 0;
}
return 1;
}
/*
* We're not actually writing here, but doing three things:
*
* 1. Identify the chunk the buffer belongs to.
* 2. If the chunk is full or the buffer doesn't belong to the current
* chunk, then start a new chunk and flush() the old chunk.
* 3. To keep the hardware busy, we also group chunks into batches
* and only require that a batch gets acknowledged in the completion
* qeueue instead of each individual chunk.
*/
static int qemu_rdma_write(QEMUFile *f, RDMAContext *rdma,
uint64_t block_offset, uint64_t offset,
uint64_t len)
{
uint64_t current_addr = block_offset + offset;
uint64_t index = rdma->current_index;
uint64_t chunk = rdma->current_chunk;
int ret;
/* If we cannot merge it, we flush the current buffer first. */
if (!qemu_rdma_buffer_mergable(rdma, current_addr, len)) {
ret = qemu_rdma_write_flush(f, rdma);
if (ret) {
return ret;
}
rdma->current_length = 0;
rdma->current_addr = current_addr;
ret = qemu_rdma_search_ram_block(rdma, block_offset,
offset, len, &index, &chunk);
if (ret) {
error_report("ram block search failed");
return ret;
}
rdma->current_index = index;
rdma->current_chunk = chunk;
}
/* merge it */
rdma->current_length += len;
/* flush it if buffer is too large */
if (rdma->current_length >= RDMA_MERGE_MAX) {
return qemu_rdma_write_flush(f, rdma);
}
return 0;
}
static void qemu_rdma_cleanup(RDMAContext *rdma)
{
struct rdma_cm_event *cm_event;
int ret, idx;
if (rdma->cm_id && rdma->connected) {
if (rdma->error_state) {
RDMAControlHeader head = { .len = 0,
.type = RDMA_CONTROL_ERROR,
.repeat = 1,
};
error_report("Early error. Sending error.");
qemu_rdma_post_send_control(rdma, NULL, &head);
}
ret = rdma_disconnect(rdma->cm_id);
if (!ret) {
trace_qemu_rdma_cleanup_waiting_for_disconnect();
ret = rdma_get_cm_event(rdma->channel, &cm_event);
if (!ret) {
rdma_ack_cm_event(cm_event);
}
}
trace_qemu_rdma_cleanup_disconnect();
rdma->connected = false;
}
g_free(rdma->block);
rdma->block = NULL;
for (idx = 0; idx < RDMA_WRID_MAX; idx++) {
if (rdma->wr_data[idx].control_mr) {
rdma->total_registrations--;
ibv_dereg_mr(rdma->wr_data[idx].control_mr);
}
rdma->wr_data[idx].control_mr = NULL;
}
if (rdma->local_ram_blocks.block) {
while (rdma->local_ram_blocks.nb_blocks) {
rdma_delete_block(rdma, rdma->local_ram_blocks.block->offset);
}
}
if (rdma->qp) {
rdma_destroy_qp(rdma->cm_id);
rdma->qp = NULL;
}
if (rdma->cq) {
ibv_destroy_cq(rdma->cq);
rdma->cq = NULL;
}
if (rdma->comp_channel) {
ibv_destroy_comp_channel(rdma->comp_channel);
rdma->comp_channel = NULL;
}
if (rdma->pd) {
ibv_dealloc_pd(rdma->pd);
rdma->pd = NULL;
}
if (rdma->cm_id) {
rdma_destroy_id(rdma->cm_id);
rdma->cm_id = NULL;
}
if (rdma->listen_id) {
rdma_destroy_id(rdma->listen_id);
rdma->listen_id = NULL;
}
if (rdma->channel) {
rdma_destroy_event_channel(rdma->channel);
rdma->channel = NULL;
}
g_free(rdma->host);
rdma->host = NULL;
}
static int qemu_rdma_source_init(RDMAContext *rdma, Error **errp, bool pin_all)
{
int ret, idx;
Error *local_err = NULL, **temp = &local_err;
/*
* Will be validated against destination's actual capabilities
* after the connect() completes.
*/
rdma->pin_all = pin_all;
ret = qemu_rdma_resolve_host(rdma, temp);
if (ret) {
goto err_rdma_source_init;
}
ret = qemu_rdma_alloc_pd_cq(rdma);
if (ret) {
ERROR(temp, "rdma migration: error allocating pd and cq! Your mlock()"
" limits may be too low. Please check $ ulimit -a # and "
"search for 'ulimit -l' in the output");
goto err_rdma_source_init;
}
ret = qemu_rdma_alloc_qp(rdma);
if (ret) {
ERROR(temp, "rdma migration: error allocating qp!");
goto err_rdma_source_init;
}
ret = qemu_rdma_init_ram_blocks(rdma);
if (ret) {
ERROR(temp, "rdma migration: error initializing ram blocks!");
goto err_rdma_source_init;
}
for (idx = 0; idx < RDMA_WRID_MAX; idx++) {
ret = qemu_rdma_reg_control(rdma, idx);
if (ret) {
ERROR(temp, "rdma migration: error registering %d control!",
idx);
goto err_rdma_source_init;
}
}
return 0;
err_rdma_source_init:
error_propagate(errp, local_err);
qemu_rdma_cleanup(rdma);
return -1;
}
static int qemu_rdma_connect(RDMAContext *rdma, Error **errp)
{
RDMACapabilities cap = {
.version = RDMA_CONTROL_VERSION_CURRENT,
.flags = 0,
};
struct rdma_conn_param conn_param = { .initiator_depth = 2,
.retry_count = 5,
.private_data = &cap,
.private_data_len = sizeof(cap),
};
struct rdma_cm_event *cm_event;
int ret;
/*
* Only negotiate the capability with destination if the user
* on the source first requested the capability.
*/
if (rdma->pin_all) {
trace_qemu_rdma_connect_pin_all_requested();
cap.flags |= RDMA_CAPABILITY_PIN_ALL;
}
caps_to_network(&cap);
ret = rdma_connect(rdma->cm_id, &conn_param);
if (ret) {
perror("rdma_connect");
ERROR(errp, "connecting to destination!");
goto err_rdma_source_connect;
}
ret = rdma_get_cm_event(rdma->channel, &cm_event);
if (ret) {
perror("rdma_get_cm_event after rdma_connect");
ERROR(errp, "connecting to destination!");
rdma_ack_cm_event(cm_event);
goto err_rdma_source_connect;
}
if (cm_event->event != RDMA_CM_EVENT_ESTABLISHED) {
perror("rdma_get_cm_event != EVENT_ESTABLISHED after rdma_connect");
ERROR(errp, "connecting to destination!");
rdma_ack_cm_event(cm_event);
goto err_rdma_source_connect;
}
rdma->connected = true;
memcpy(&cap, cm_event->param.conn.private_data, sizeof(cap));
network_to_caps(&cap);
/*
* Verify that the *requested* capabilities are supported by the destination
* and disable them otherwise.
*/
if (rdma->pin_all && !(cap.flags & RDMA_CAPABILITY_PIN_ALL)) {
ERROR(errp, "Server cannot support pinning all memory. "
"Will register memory dynamically.");
rdma->pin_all = false;
}
trace_qemu_rdma_connect_pin_all_outcome(rdma->pin_all);
rdma_ack_cm_event(cm_event);
ret = qemu_rdma_post_recv_control(rdma, RDMA_WRID_READY);
if (ret) {
ERROR(errp, "posting second control recv!");
goto err_rdma_source_connect;
}
rdma->control_ready_expected = 1;
rdma->nb_sent = 0;
return 0;
err_rdma_source_connect:
qemu_rdma_cleanup(rdma);
return -1;
}
static int qemu_rdma_dest_init(RDMAContext *rdma, Error **errp)
{
int ret, idx;
struct rdma_cm_id *listen_id;
char ip[40] = "unknown";
struct rdma_addrinfo *res, *e;
char port_str[16];
for (idx = 0; idx < RDMA_WRID_MAX; idx++) {
rdma->wr_data[idx].control_len = 0;
rdma->wr_data[idx].control_curr = NULL;
}
if (!rdma->host || !rdma->host[0]) {
ERROR(errp, "RDMA host is not set!");
rdma->error_state = -EINVAL;
return -1;
}
/* create CM channel */
rdma->channel = rdma_create_event_channel();
if (!rdma->channel) {
ERROR(errp, "could not create rdma event channel");
rdma->error_state = -EINVAL;
return -1;
}
/* create CM id */
ret = rdma_create_id(rdma->channel, &listen_id, NULL, RDMA_PS_TCP);
if (ret) {
ERROR(errp, "could not create cm_id!");
goto err_dest_init_create_listen_id;
}
snprintf(port_str, 16, "%d", rdma->port);
port_str[15] = '\0';
ret = rdma_getaddrinfo(rdma->host, port_str, NULL, &res);
if (ret < 0) {
ERROR(errp, "could not rdma_getaddrinfo address %s", rdma->host);
goto err_dest_init_bind_addr;
}
for (e = res; e != NULL; e = e->ai_next) {
inet_ntop(e->ai_family,
&((struct sockaddr_in *) e->ai_dst_addr)->sin_addr, ip, sizeof ip);
trace_qemu_rdma_dest_init_trying(rdma->host, ip);
ret = rdma_bind_addr(listen_id, e->ai_dst_addr);
if (ret) {
continue;
}
if (e->ai_family == AF_INET6) {
ret = qemu_rdma_broken_ipv6_kernel(errp, listen_id->verbs);
if (ret) {
continue;
}
}
break;
}
if (!e) {
ERROR(errp, "Error: could not rdma_bind_addr!");
goto err_dest_init_bind_addr;
}
rdma->listen_id = listen_id;
qemu_rdma_dump_gid("dest_init", listen_id);
return 0;
err_dest_init_bind_addr:
rdma_destroy_id(listen_id);
err_dest_init_create_listen_id:
rdma_destroy_event_channel(rdma->channel);
rdma->channel = NULL;
rdma->error_state = ret;
return ret;
}
static void *qemu_rdma_data_init(const char *host_port, Error **errp)
{
RDMAContext *rdma = NULL;
InetSocketAddress *addr;
if (host_port) {
rdma = g_malloc0(sizeof(RDMAContext));
memset(rdma, 0, sizeof(RDMAContext));
rdma->current_index = -1;
rdma->current_chunk = -1;
addr = inet_parse(host_port, NULL);
if (addr != NULL) {
rdma->port = atoi(addr->port);
rdma->host = g_strdup(addr->host);
} else {
ERROR(errp, "bad RDMA migration address '%s'", host_port);
g_free(rdma);
rdma = NULL;
}
qapi_free_InetSocketAddress(addr);
}
return rdma;
}
/*
* QEMUFile interface to the control channel.
* SEND messages for control only.
* VM's ram is handled with regular RDMA messages.
*/
static int qemu_rdma_put_buffer(void *opaque, const uint8_t *buf,
int64_t pos, int size)
{
QEMUFileRDMA *r = opaque;
QEMUFile *f = r->file;
RDMAContext *rdma = r->rdma;
size_t remaining = size;
uint8_t * data = (void *) buf;
int ret;
CHECK_ERROR_STATE();
/*
* Push out any writes that
* we're queued up for VM's ram.
*/
ret = qemu_rdma_write_flush(f, rdma);
if (ret < 0) {
rdma->error_state = ret;
return ret;
}
while (remaining) {
RDMAControlHeader head;
r->len = MIN(remaining, RDMA_SEND_INCREMENT);
remaining -= r->len;
head.len = r->len;
head.type = RDMA_CONTROL_QEMU_FILE;
ret = qemu_rdma_exchange_send(rdma, &head, data, NULL, NULL, NULL);
if (ret < 0) {
rdma->error_state = ret;
return ret;
}
data += r->len;
}
return size;
}
static size_t qemu_rdma_fill(RDMAContext *rdma, uint8_t *buf,
int size, int idx)
{
size_t len = 0;
if (rdma->wr_data[idx].control_len) {
trace_qemu_rdma_fill(rdma->wr_data[idx].control_len, size);
len = MIN(size, rdma->wr_data[idx].control_len);
memcpy(buf, rdma->wr_data[idx].control_curr, len);
rdma->wr_data[idx].control_curr += len;
rdma->wr_data[idx].control_len -= len;
}
return len;
}
/*
* QEMUFile interface to the control channel.
* RDMA links don't use bytestreams, so we have to
* return bytes to QEMUFile opportunistically.
*/
static int qemu_rdma_get_buffer(void *opaque, uint8_t *buf,
int64_t pos, int size)
{
QEMUFileRDMA *r = opaque;
RDMAContext *rdma = r->rdma;
RDMAControlHeader head;
int ret = 0;
CHECK_ERROR_STATE();
/*
* First, we hold on to the last SEND message we
* were given and dish out the bytes until we run
* out of bytes.
*/
r->len = qemu_rdma_fill(r->rdma, buf, size, 0);
if (r->len) {
return r->len;
}
/*
* Once we run out, we block and wait for another
* SEND message to arrive.
*/
ret = qemu_rdma_exchange_recv(rdma, &head, RDMA_CONTROL_QEMU_FILE);
if (ret < 0) {
rdma->error_state = ret;
return ret;
}
/*
* SEND was received with new bytes, now try again.
*/
return qemu_rdma_fill(r->rdma, buf, size, 0);
}
/*
* Block until all the outstanding chunks have been delivered by the hardware.
*/
static int qemu_rdma_drain_cq(QEMUFile *f, RDMAContext *rdma)
{
int ret;
if (qemu_rdma_write_flush(f, rdma) < 0) {
return -EIO;
}
while (rdma->nb_sent) {
ret = qemu_rdma_block_for_wrid(rdma, RDMA_WRID_RDMA_WRITE, NULL);
if (ret < 0) {
error_report("rdma migration: complete polling error!");
return -EIO;
}
}
qemu_rdma_unregister_waiting(rdma);
return 0;
}
static int qemu_rdma_close(void *opaque)
{
trace_qemu_rdma_close();
QEMUFileRDMA *r = opaque;
if (r->rdma) {
qemu_rdma_cleanup(r->rdma);
g_free(r->rdma);
}
g_free(r);
return 0;
}
/*
* Parameters:
* @offset == 0 :
* This means that 'block_offset' is a full virtual address that does not
* belong to a RAMBlock of the virtual machine and instead
* represents a private malloc'd memory area that the caller wishes to
* transfer.
*
* @offset != 0 :
* Offset is an offset to be added to block_offset and used
* to also lookup the corresponding RAMBlock.
*
* @size > 0 :
* Initiate an transfer this size.
*
* @size == 0 :
* A 'hint' or 'advice' that means that we wish to speculatively
* and asynchronously unregister this memory. In this case, there is no
* guarantee that the unregister will actually happen, for example,
* if the memory is being actively transmitted. Additionally, the memory
* may be re-registered at any future time if a write within the same
* chunk was requested again, even if you attempted to unregister it
* here.
*
* @size < 0 : TODO, not yet supported
* Unregister the memory NOW. This means that the caller does not
* expect there to be any future RDMA transfers and we just want to clean
* things up. This is used in case the upper layer owns the memory and
* cannot wait for qemu_fclose() to occur.
*
* @bytes_sent : User-specificed pointer to indicate how many bytes were
* sent. Usually, this will not be more than a few bytes of
* the protocol because most transfers are sent asynchronously.
*/
static size_t qemu_rdma_save_page(QEMUFile *f, void *opaque,
ram_addr_t block_offset, ram_addr_t offset,
size_t size, uint64_t *bytes_sent)
{
QEMUFileRDMA *rfile = opaque;
RDMAContext *rdma = rfile->rdma;
int ret;
CHECK_ERROR_STATE();
qemu_fflush(f);
if (size > 0) {
/*
* Add this page to the current 'chunk'. If the chunk
* is full, or the page doen't belong to the current chunk,
* an actual RDMA write will occur and a new chunk will be formed.
*/
ret = qemu_rdma_write(f, rdma, block_offset, offset, size);
if (ret < 0) {
error_report("rdma migration: write error! %d", ret);
goto err;
}
/*
* We always return 1 bytes because the RDMA
* protocol is completely asynchronous. We do not yet know
* whether an identified chunk is zero or not because we're
* waiting for other pages to potentially be merged with
* the current chunk. So, we have to call qemu_update_position()
* later on when the actual write occurs.
*/
if (bytes_sent) {
*bytes_sent = 1;
}
} else {
uint64_t index, chunk;
/* TODO: Change QEMUFileOps prototype to be signed: size_t => long
if (size < 0) {
ret = qemu_rdma_drain_cq(f, rdma);
if (ret < 0) {
fprintf(stderr, "rdma: failed to synchronously drain"
" completion queue before unregistration.\n");
goto err;
}
}
*/
ret = qemu_rdma_search_ram_block(rdma, block_offset,
offset, size, &index, &chunk);
if (ret) {
error_report("ram block search failed");
goto err;
}
qemu_rdma_signal_unregister(rdma, index, chunk, 0);
/*
* TODO: Synchronous, guaranteed unregistration (should not occur during
* fast-path). Otherwise, unregisters will process on the next call to
* qemu_rdma_drain_cq()
if (size < 0) {
qemu_rdma_unregister_waiting(rdma);
}
*/
}
/*
* Drain the Completion Queue if possible, but do not block,
* just poll.
*
* If nothing to poll, the end of the iteration will do this
* again to make sure we don't overflow the request queue.
*/
while (1) {
uint64_t wr_id, wr_id_in;
int ret = qemu_rdma_poll(rdma, &wr_id_in, NULL);
if (ret < 0) {
error_report("rdma migration: polling error! %d", ret);
goto err;
}
wr_id = wr_id_in & RDMA_WRID_TYPE_MASK;
if (wr_id == RDMA_WRID_NONE) {
break;
}
}
return RAM_SAVE_CONTROL_DELAYED;
err:
rdma->error_state = ret;
return ret;
}
static int qemu_rdma_accept(RDMAContext *rdma)
{
RDMACapabilities cap;
struct rdma_conn_param conn_param = {
.responder_resources = 2,
.private_data = &cap,
.private_data_len = sizeof(cap),
};
struct rdma_cm_event *cm_event;
struct ibv_context *verbs;
int ret = -EINVAL;
int idx;
ret = rdma_get_cm_event(rdma->channel, &cm_event);
if (ret) {
goto err_rdma_dest_wait;
}
if (cm_event->event != RDMA_CM_EVENT_CONNECT_REQUEST) {
rdma_ack_cm_event(cm_event);
goto err_rdma_dest_wait;
}
memcpy(&cap, cm_event->param.conn.private_data, sizeof(cap));
network_to_caps(&cap);
if (cap.version < 1 || cap.version > RDMA_CONTROL_VERSION_CURRENT) {
error_report("Unknown source RDMA version: %d, bailing...",
cap.version);
rdma_ack_cm_event(cm_event);
goto err_rdma_dest_wait;
}
/*
* Respond with only the capabilities this version of QEMU knows about.
*/
cap.flags &= known_capabilities;
/*
* Enable the ones that we do know about.
* Add other checks here as new ones are introduced.
*/
if (cap.flags & RDMA_CAPABILITY_PIN_ALL) {
rdma->pin_all = true;
}
rdma->cm_id = cm_event->id;
verbs = cm_event->id->verbs;
rdma_ack_cm_event(cm_event);
trace_qemu_rdma_accept_pin_state(rdma->pin_all);
caps_to_network(&cap);
trace_qemu_rdma_accept_pin_verbsc(verbs);
if (!rdma->verbs) {
rdma->verbs = verbs;
} else if (rdma->verbs != verbs) {
error_report("ibv context not matching %p, %p!", rdma->verbs,
verbs);
goto err_rdma_dest_wait;
}
qemu_rdma_dump_id("dest_init", verbs);
ret = qemu_rdma_alloc_pd_cq(rdma);
if (ret) {
error_report("rdma migration: error allocating pd and cq!");
goto err_rdma_dest_wait;
}
ret = qemu_rdma_alloc_qp(rdma);
if (ret) {
error_report("rdma migration: error allocating qp!");
goto err_rdma_dest_wait;
}
ret = qemu_rdma_init_ram_blocks(rdma);
if (ret) {
error_report("rdma migration: error initializing ram blocks!");
goto err_rdma_dest_wait;
}
for (idx = 0; idx < RDMA_WRID_MAX; idx++) {
ret = qemu_rdma_reg_control(rdma, idx);
if (ret) {
error_report("rdma: error registering %d control", idx);
goto err_rdma_dest_wait;
}
}
qemu_set_fd_handler2(rdma->channel->fd, NULL, NULL, NULL, NULL);
ret = rdma_accept(rdma->cm_id, &conn_param);
if (ret) {
error_report("rdma_accept returns %d", ret);
goto err_rdma_dest_wait;
}
ret = rdma_get_cm_event(rdma->channel, &cm_event);
if (ret) {
error_report("rdma_accept get_cm_event failed %d", ret);
goto err_rdma_dest_wait;
}
if (cm_event->event != RDMA_CM_EVENT_ESTABLISHED) {
error_report("rdma_accept not event established");
rdma_ack_cm_event(cm_event);
goto err_rdma_dest_wait;
}
rdma_ack_cm_event(cm_event);
rdma->connected = true;
ret = qemu_rdma_post_recv_control(rdma, RDMA_WRID_READY);
if (ret) {
error_report("rdma migration: error posting second control recv");
goto err_rdma_dest_wait;
}
qemu_rdma_dump_gid("dest_connect", rdma->cm_id);
return 0;
err_rdma_dest_wait:
rdma->error_state = ret;
qemu_rdma_cleanup(rdma);
return ret;
}
/*
* During each iteration of the migration, we listen for instructions
* by the source VM to perform dynamic page registrations before they
* can perform RDMA operations.
*
* We respond with the 'rkey'.
*
* Keep doing this until the source tells us to stop.
*/
static int qemu_rdma_registration_handle(QEMUFile *f, void *opaque,
uint64_t flags)
{
RDMAControlHeader reg_resp = { .len = sizeof(RDMARegisterResult),
.type = RDMA_CONTROL_REGISTER_RESULT,
.repeat = 0,
};
RDMAControlHeader unreg_resp = { .len = 0,
.type = RDMA_CONTROL_UNREGISTER_FINISHED,
.repeat = 0,
};
RDMAControlHeader blocks = { .type = RDMA_CONTROL_RAM_BLOCKS_RESULT,
.repeat = 1 };
QEMUFileRDMA *rfile = opaque;
RDMAContext *rdma = rfile->rdma;
RDMALocalBlocks *local = &rdma->local_ram_blocks;
RDMAControlHeader head;
RDMARegister *reg, *registers;
RDMACompress *comp;
RDMARegisterResult *reg_result;
static RDMARegisterResult results[RDMA_CONTROL_MAX_COMMANDS_PER_MESSAGE];
RDMALocalBlock *block;
void *host_addr;
int ret = 0;
int idx = 0;
int count = 0;
int i = 0;
CHECK_ERROR_STATE();
do {
trace_qemu_rdma_registration_handle_wait(flags);
ret = qemu_rdma_exchange_recv(rdma, &head, RDMA_CONTROL_NONE);
if (ret < 0) {
break;
}
if (head.repeat > RDMA_CONTROL_MAX_COMMANDS_PER_MESSAGE) {
error_report("rdma: Too many requests in this message (%d)."
"Bailing.", head.repeat);
ret = -EIO;
break;
}
switch (head.type) {
case RDMA_CONTROL_COMPRESS:
comp = (RDMACompress *) rdma->wr_data[idx].control_curr;
network_to_compress(comp);
trace_qemu_rdma_registration_handle_compress(comp->length,
comp->block_idx,
comp->offset);
block = &(rdma->local_ram_blocks.block[comp->block_idx]);
host_addr = block->local_host_addr +
(comp->offset - block->offset);
ram_handle_compressed(host_addr, comp->value, comp->length);
break;
case RDMA_CONTROL_REGISTER_FINISHED:
trace_qemu_rdma_registration_handle_finished();
goto out;
case RDMA_CONTROL_RAM_BLOCKS_REQUEST:
trace_qemu_rdma_registration_handle_ram_blocks();
if (rdma->pin_all) {
ret = qemu_rdma_reg_whole_ram_blocks(rdma);
if (ret) {
error_report("rdma migration: error dest "
"registering ram blocks");
goto out;
}
}
/*
* Dest uses this to prepare to transmit the RAMBlock descriptions
* to the source VM after connection setup.
* Both sides use the "remote" structure to communicate and update
* their "local" descriptions with what was sent.
*/
for (i = 0; i < local->nb_blocks; i++) {
rdma->block[i].remote_host_addr =
(uintptr_t)(local->block[i].local_host_addr);
if (rdma->pin_all) {
rdma->block[i].remote_rkey = local->block[i].mr->rkey;
}
rdma->block[i].offset = local->block[i].offset;
rdma->block[i].length = local->block[i].length;
remote_block_to_network(&rdma->block[i]);
}
blocks.len = rdma->local_ram_blocks.nb_blocks
* sizeof(RDMARemoteBlock);
ret = qemu_rdma_post_send_control(rdma,
(uint8_t *) rdma->block, &blocks);
if (ret < 0) {
error_report("rdma migration: error sending remote info");
goto out;
}
break;
case RDMA_CONTROL_REGISTER_REQUEST:
trace_qemu_rdma_registration_handle_register(head.repeat);
reg_resp.repeat = head.repeat;
registers = (RDMARegister *) rdma->wr_data[idx].control_curr;
for (count = 0; count < head.repeat; count++) {
uint64_t chunk;
uint8_t *chunk_start, *chunk_end;
reg = &registers[count];
network_to_register(reg);
reg_result = &results[count];
trace_qemu_rdma_registration_handle_register_loop(count,
reg->current_index, reg->key.current_addr, reg->chunks);
block = &(rdma->local_ram_blocks.block[reg->current_index]);
if (block->is_ram_block) {
host_addr = (block->local_host_addr +
(reg->key.current_addr - block->offset));
chunk = ram_chunk_index(block->local_host_addr,
(uint8_t *) host_addr);
} else {
chunk = reg->key.chunk;
host_addr = block->local_host_addr +
(reg->key.chunk * (1UL << RDMA_REG_CHUNK_SHIFT));
}
chunk_start = ram_chunk_start(block, chunk);
chunk_end = ram_chunk_end(block, chunk + reg->chunks);
if (qemu_rdma_register_and_get_keys(rdma, block,
(uintptr_t)host_addr, NULL, &reg_result->rkey,
chunk, chunk_start, chunk_end)) {
error_report("cannot get rkey");
ret = -EINVAL;
goto out;
}
reg_result->host_addr = (uintptr_t)block->local_host_addr;
trace_qemu_rdma_registration_handle_register_rkey(
reg_result->rkey);
result_to_network(reg_result);
}
ret = qemu_rdma_post_send_control(rdma,
(uint8_t *) results, &reg_resp);
if (ret < 0) {
error_report("Failed to send control buffer");
goto out;
}
break;
case RDMA_CONTROL_UNREGISTER_REQUEST:
trace_qemu_rdma_registration_handle_unregister(head.repeat);
unreg_resp.repeat = head.repeat;
registers = (RDMARegister *) rdma->wr_data[idx].control_curr;
for (count = 0; count < head.repeat; count++) {
reg = &registers[count];
network_to_register(reg);
trace_qemu_rdma_registration_handle_unregister_loop(count,
reg->current_index, reg->key.chunk);
block = &(rdma->local_ram_blocks.block[reg->current_index]);
ret = ibv_dereg_mr(block->pmr[reg->key.chunk]);
block->pmr[reg->key.chunk] = NULL;
if (ret != 0) {
perror("rdma unregistration chunk failed");
ret = -ret;
goto out;
}
rdma->total_registrations--;
trace_qemu_rdma_registration_handle_unregister_success(
reg->key.chunk);
}
ret = qemu_rdma_post_send_control(rdma, NULL, &unreg_resp);
if (ret < 0) {
error_report("Failed to send control buffer");
goto out;
}
break;
case RDMA_CONTROL_REGISTER_RESULT:
error_report("Invalid RESULT message at dest.");
ret = -EIO;
goto out;
default:
error_report("Unknown control message %s", control_desc[head.type]);
ret = -EIO;
goto out;
}
} while (1);
out:
if (ret < 0) {
rdma->error_state = ret;
}
return ret;
}
static int qemu_rdma_registration_start(QEMUFile *f, void *opaque,
uint64_t flags)
{
QEMUFileRDMA *rfile = opaque;
RDMAContext *rdma = rfile->rdma;
CHECK_ERROR_STATE();
trace_qemu_rdma_registration_start(flags);
qemu_put_be64(f, RAM_SAVE_FLAG_HOOK);
qemu_fflush(f);
return 0;
}
/*
* Inform dest that dynamic registrations are done for now.
* First, flush writes, if any.
*/
static int qemu_rdma_registration_stop(QEMUFile *f, void *opaque,
uint64_t flags)
{
Error *local_err = NULL, **errp = &local_err;
QEMUFileRDMA *rfile = opaque;
RDMAContext *rdma = rfile->rdma;
RDMAControlHeader head = { .len = 0, .repeat = 1 };
int ret = 0;
CHECK_ERROR_STATE();
qemu_fflush(f);
ret = qemu_rdma_drain_cq(f, rdma);
if (ret < 0) {
goto err;
}
if (flags == RAM_CONTROL_SETUP) {
RDMAControlHeader resp = {.type = RDMA_CONTROL_RAM_BLOCKS_RESULT };
RDMALocalBlocks *local = &rdma->local_ram_blocks;
int reg_result_idx, i, j, nb_remote_blocks;
head.type = RDMA_CONTROL_RAM_BLOCKS_REQUEST;
trace_qemu_rdma_registration_stop_ram();
/*
* Make sure that we parallelize the pinning on both sides.
* For very large guests, doing this serially takes a really
* long time, so we have to 'interleave' the pinning locally
* with the control messages by performing the pinning on this
* side before we receive the control response from the other
* side that the pinning has completed.
*/
ret = qemu_rdma_exchange_send(rdma, &head, NULL, &resp,
&reg_result_idx, rdma->pin_all ?
qemu_rdma_reg_whole_ram_blocks : NULL);
if (ret < 0) {
ERROR(errp, "receiving remote info!");
return ret;
}
nb_remote_blocks = resp.len / sizeof(RDMARemoteBlock);
/*
* The protocol uses two different sets of rkeys (mutually exclusive):
* 1. One key to represent the virtual address of the entire ram block.
* (dynamic chunk registration disabled - pin everything with one rkey.)
* 2. One to represent individual chunks within a ram block.
* (dynamic chunk registration enabled - pin individual chunks.)
*
* Once the capability is successfully negotiated, the destination transmits
* the keys to use (or sends them later) including the virtual addresses
* and then propagates the remote ram block descriptions to his local copy.
*/
if (local->nb_blocks != nb_remote_blocks) {
ERROR(errp, "ram blocks mismatch #1! "
"Your QEMU command line parameters are probably "
"not identical on both the source and destination.");
return -EINVAL;
}
qemu_rdma_move_header(rdma, reg_result_idx, &resp);
memcpy(rdma->block,
rdma->wr_data[reg_result_idx].control_curr, resp.len);
for (i = 0; i < nb_remote_blocks; i++) {
network_to_remote_block(&rdma->block[i]);
/* search local ram blocks */
for (j = 0; j < local->nb_blocks; j++) {
if (rdma->block[i].offset != local->block[j].offset) {
continue;
}
if (rdma->block[i].length != local->block[j].length) {
ERROR(errp, "ram blocks mismatch #2! "
"Your QEMU command line parameters are probably "
"not identical on both the source and destination.");
return -EINVAL;
}
local->block[j].remote_host_addr =
rdma->block[i].remote_host_addr;
local->block[j].remote_rkey = rdma->block[i].remote_rkey;
break;
}
if (j >= local->nb_blocks) {
ERROR(errp, "ram blocks mismatch #3! "
"Your QEMU command line parameters are probably "
"not identical on both the source and destination.");
return -EINVAL;
}
}
}
trace_qemu_rdma_registration_stop(flags);
head.type = RDMA_CONTROL_REGISTER_FINISHED;
ret = qemu_rdma_exchange_send(rdma, &head, NULL, NULL, NULL, NULL);
if (ret < 0) {
goto err;
}
return 0;
err:
rdma->error_state = ret;
return ret;
}
static int qemu_rdma_get_fd(void *opaque)
{
QEMUFileRDMA *rfile = opaque;
RDMAContext *rdma = rfile->rdma;
return rdma->comp_channel->fd;
}
static const QEMUFileOps rdma_read_ops = {
.get_buffer = qemu_rdma_get_buffer,
.get_fd = qemu_rdma_get_fd,
.close = qemu_rdma_close,
.hook_ram_load = qemu_rdma_registration_handle,
};
static const QEMUFileOps rdma_write_ops = {
.put_buffer = qemu_rdma_put_buffer,
.close = qemu_rdma_close,
.before_ram_iterate = qemu_rdma_registration_start,
.after_ram_iterate = qemu_rdma_registration_stop,
.save_page = qemu_rdma_save_page,
};
static void *qemu_fopen_rdma(RDMAContext *rdma, const char *mode)
{
QEMUFileRDMA *r = g_malloc0(sizeof(QEMUFileRDMA));
if (qemu_file_mode_is_not_valid(mode)) {
return NULL;
}
r->rdma = rdma;
if (mode[0] == 'w') {
r->file = qemu_fopen_ops(r, &rdma_write_ops);
} else {
r->file = qemu_fopen_ops(r, &rdma_read_ops);
}
return r->file;
}
static void rdma_accept_incoming_migration(void *opaque)
{
RDMAContext *rdma = opaque;
int ret;
QEMUFile *f;
Error *local_err = NULL, **errp = &local_err;
trace_qemu_dma_accept_incoming_migration();
ret = qemu_rdma_accept(rdma);
if (ret) {
ERROR(errp, "RDMA Migration initialization failed!");
return;
}
trace_qemu_dma_accept_incoming_migration_accepted();
f = qemu_fopen_rdma(rdma, "rb");
if (f == NULL) {
ERROR(errp, "could not qemu_fopen_rdma!");
qemu_rdma_cleanup(rdma);
return;
}
rdma->migration_started_on_destination = 1;
process_incoming_migration(f);
}
void rdma_start_incoming_migration(const char *host_port, Error **errp)
{
int ret;
RDMAContext *rdma;
Error *local_err = NULL;
trace_rdma_start_incoming_migration();
rdma = qemu_rdma_data_init(host_port, &local_err);
if (rdma == NULL) {
goto err;
}
ret = qemu_rdma_dest_init(rdma, &local_err);
if (ret) {
goto err;
}
trace_rdma_start_incoming_migration_after_dest_init();
ret = rdma_listen(rdma->listen_id, 5);
if (ret) {
ERROR(errp, "listening on socket!");
goto err;
}
trace_rdma_start_incoming_migration_after_rdma_listen();
qemu_set_fd_handler2(rdma->channel->fd, NULL,
rdma_accept_incoming_migration, NULL,
(void *)(intptr_t) rdma);
return;
err:
error_propagate(errp, local_err);
g_free(rdma);
}
void rdma_start_outgoing_migration(void *opaque,
const char *host_port, Error **errp)
{
MigrationState *s = opaque;
Error *local_err = NULL, **temp = &local_err;
RDMAContext *rdma = qemu_rdma_data_init(host_port, &local_err);
int ret = 0;
if (rdma == NULL) {
ERROR(temp, "Failed to initialize RDMA data structures! %d", ret);
goto err;
}
ret = qemu_rdma_source_init(rdma, &local_err,
s->enabled_capabilities[MIGRATION_CAPABILITY_RDMA_PIN_ALL]);
if (ret) {
goto err;
}
trace_rdma_start_outgoing_migration_after_rdma_source_init();
ret = qemu_rdma_connect(rdma, &local_err);
if (ret) {
goto err;
}
trace_rdma_start_outgoing_migration_after_rdma_connect();
s->file = qemu_fopen_rdma(rdma, "wb");
migrate_fd_connect(s);
return;
err:
error_propagate(errp, local_err);
g_free(rdma);
migrate_fd_error(s);
}