qemu/migration/migration.h
Avihai Horon b0cf3bfc69 migration: Remove errp parameter in migration_fd_process_incoming()
Errp parameter in migration_fd_process_incoming() is unused.
Remove it.

Signed-off-by: Avihai Horon <avihaih@nvidia.com>
Reviewed-by: Fabiano Rosas <farosas@suse.de>
Link: https://lore.kernel.org/r/20231231093016.14204-5-avihaih@nvidia.com
Signed-off-by: Peter Xu <peterx@redhat.com>
2024-01-04 09:52:42 +08:00

552 lines
19 KiB
C

/*
* QEMU live migration
*
* Copyright IBM, Corp. 2008
*
* Authors:
* Anthony Liguori <aliguori@us.ibm.com>
*
* This work is licensed under the terms of the GNU GPL, version 2. See
* the COPYING file in the top-level directory.
*
*/
#ifndef QEMU_MIGRATION_H
#define QEMU_MIGRATION_H
#include "exec/cpu-common.h"
#include "hw/qdev-core.h"
#include "qapi/qapi-types-migration.h"
#include "qapi/qmp/json-writer.h"
#include "qemu/thread.h"
#include "qemu/coroutine_int.h"
#include "io/channel.h"
#include "io/channel-buffer.h"
#include "net/announce.h"
#include "qom/object.h"
#include "postcopy-ram.h"
#include "sysemu/runstate.h"
struct PostcopyBlocktimeContext;
#define MIGRATION_RESUME_ACK_VALUE (1)
/*
* 1<<6=64 pages -> 256K chunk when page size is 4K. This gives us
* the benefit that all the chunks are 64 pages aligned then the
* bitmaps are always aligned to LONG.
*/
#define CLEAR_BITMAP_SHIFT_MIN 6
/*
* 1<<18=256K pages -> 1G chunk when page size is 4K. This is the
* default value to use if no one specified.
*/
#define CLEAR_BITMAP_SHIFT_DEFAULT 18
/*
* 1<<31=2G pages -> 8T chunk when page size is 4K. This should be
* big enough and make sure we won't overflow easily.
*/
#define CLEAR_BITMAP_SHIFT_MAX 31
/* This is an abstraction of a "temp huge page" for postcopy's purpose */
typedef struct {
/*
* This points to a temporary huge page as a buffer for UFFDIO_COPY. It's
* mmap()ed and needs to be freed when cleanup.
*/
void *tmp_huge_page;
/*
* This points to the host page we're going to install for this temp page.
* It tells us after we've received the whole page, where we should put it.
*/
void *host_addr;
/* Number of small pages copied (in size of TARGET_PAGE_SIZE) */
unsigned int target_pages;
/* Whether this page contains all zeros */
bool all_zero;
} PostcopyTmpPage;
typedef enum {
PREEMPT_THREAD_NONE = 0,
PREEMPT_THREAD_CREATED,
PREEMPT_THREAD_QUIT,
} PreemptThreadStatus;
/* State for the incoming migration */
struct MigrationIncomingState {
QEMUFile *from_src_file;
/* Previously received RAM's RAMBlock pointer */
RAMBlock *last_recv_block[RAM_CHANNEL_MAX];
/* A hook to allow cleanup at the end of incoming migration */
void *transport_data;
void (*transport_cleanup)(void *data);
/*
* Used to sync thread creations. Note that we can't create threads in
* parallel with this sem.
*/
QemuSemaphore thread_sync_sem;
/*
* Free at the start of the main state load, set as the main thread finishes
* loading state.
*/
QemuEvent main_thread_load_event;
/* For network announces */
AnnounceTimer announce_timer;
size_t largest_page_size;
bool have_fault_thread;
QemuThread fault_thread;
/* Set this when we want the fault thread to quit */
bool fault_thread_quit;
bool have_listen_thread;
QemuThread listen_thread;
/* For the kernel to send us notifications */
int userfault_fd;
/* To notify the fault_thread to wake, e.g., when need to quit */
int userfault_event_fd;
QEMUFile *to_src_file;
QemuMutex rp_mutex; /* We send replies from multiple threads */
/* RAMBlock of last request sent to source */
RAMBlock *last_rb;
/*
* Number of postcopy channels including the default precopy channel, so
* vanilla postcopy will only contain one channel which contain both
* precopy and postcopy streams.
*
* This is calculated when the src requests to enable postcopy but before
* it starts. Its value can depend on e.g. whether postcopy preemption is
* enabled.
*/
unsigned int postcopy_channels;
/* QEMUFile for postcopy only; it'll be handled by a separate thread */
QEMUFile *postcopy_qemufile_dst;
/*
* When postcopy_qemufile_dst is properly setup, this sem is posted.
* One can wait on this semaphore to wait until the preempt channel is
* properly setup.
*/
QemuSemaphore postcopy_qemufile_dst_done;
/* Postcopy priority thread is used to receive postcopy requested pages */
QemuThread postcopy_prio_thread;
/*
* Always set by the main vm load thread only, but can be read by the
* postcopy preempt thread. "volatile" makes sure all reads will be
* up-to-date across cores.
*/
volatile PreemptThreadStatus preempt_thread_status;
/*
* Used to sync between the ram load main thread and the fast ram load
* thread. It protects postcopy_qemufile_dst, which is the postcopy
* fast channel.
*
* The ram fast load thread will take it mostly for the whole lifecycle
* because it needs to continuously read data from the channel, and
* it'll only release this mutex if postcopy is interrupted, so that
* the ram load main thread will take this mutex over and properly
* release the broken channel.
*/
QemuMutex postcopy_prio_thread_mutex;
/*
* An array of temp host huge pages to be used, one for each postcopy
* channel.
*/
PostcopyTmpPage *postcopy_tmp_pages;
/* This is shared for all postcopy channels */
void *postcopy_tmp_zero_page;
/* PostCopyFD's for external userfaultfds & handlers of shared memory */
GArray *postcopy_remote_fds;
QEMUBH *bh;
int state;
/*
* The incoming migration coroutine, non-NULL during qemu_loadvm_state().
* Used to wake the migration incoming coroutine from rdma code. How much is
* it safe - it's a question.
*/
Coroutine *loadvm_co;
/* The coroutine we should enter (back) after failover */
Coroutine *colo_incoming_co;
QemuSemaphore colo_incoming_sem;
/*
* PostcopyBlocktimeContext to keep information for postcopy
* live migration, to calculate vCPU block time
* */
struct PostcopyBlocktimeContext *blocktime_ctx;
/* notify PAUSED postcopy incoming migrations to try to continue */
QemuSemaphore postcopy_pause_sem_dst;
QemuSemaphore postcopy_pause_sem_fault;
/*
* This semaphore is used to allow the ram fast load thread (only when
* postcopy preempt is enabled) fall into sleep when there's network
* interruption detected. When the recovery is done, the main load
* thread will kick the fast ram load thread using this semaphore.
*/
QemuSemaphore postcopy_pause_sem_fast_load;
/* List of listening socket addresses */
SocketAddressList *socket_address_list;
/* A tree of pages that we requested to the source VM */
GTree *page_requested;
/*
* For postcopy only, count the number of requested page faults that
* still haven't been resolved.
*/
int page_requested_count;
/*
* The mutex helps to maintain the requested pages that we sent to the
* source, IOW, to guarantee coherent between the page_requests tree and
* the per-ramblock receivedmap. Note! This does not guarantee consistency
* of the real page copy procedures (using UFFDIO_[ZERO]COPY). E.g., even
* if one bit in receivedmap is cleared, UFFDIO_COPY could have happened
* for that page already. This is intended so that the mutex won't
* serialize and blocked by slow operations like UFFDIO_* ioctls. However
* this should be enough to make sure the page_requested tree always
* contains valid information.
*/
QemuMutex page_request_mutex;
/*
* If postcopy preempt is enabled, there is a chance that the main
* thread finished loading its data before the preempt channel has
* finished loading the urgent pages. If that happens, the two threads
* will use this condvar to synchronize, so the main thread will always
* wait until all pages received.
*/
QemuCond page_request_cond;
/*
* Number of devices that have yet to approve switchover. When this reaches
* zero an ACK that it's OK to do switchover is sent to the source. No lock
* is needed as this field is updated serially.
*/
unsigned int switchover_ack_pending_num;
};
MigrationIncomingState *migration_incoming_get_current(void);
void migration_incoming_state_destroy(void);
void migration_incoming_transport_cleanup(MigrationIncomingState *mis);
/*
* Functions to work with blocktime context
*/
void fill_destination_postcopy_migration_info(MigrationInfo *info);
#define TYPE_MIGRATION "migration"
typedef struct MigrationClass MigrationClass;
DECLARE_OBJ_CHECKERS(MigrationState, MigrationClass,
MIGRATION_OBJ, TYPE_MIGRATION)
struct MigrationClass {
/*< private >*/
DeviceClass parent_class;
};
struct MigrationState {
/*< private >*/
DeviceState parent_obj;
/*< public >*/
QemuThread thread;
QEMUBH *vm_start_bh;
QEMUBH *cleanup_bh;
/* Protected by qemu_file_lock */
QEMUFile *to_dst_file;
/* Postcopy specific transfer channel */
QEMUFile *postcopy_qemufile_src;
/*
* It is posted when the preempt channel is established. Note: this is
* used for both the start or recover of a postcopy migration. We'll
* post to this sem every time a new preempt channel is created in the
* main thread, and we keep post() and wait() in pair.
*/
QemuSemaphore postcopy_qemufile_src_sem;
QIOChannelBuffer *bioc;
/*
* Protects to_dst_file/from_dst_file pointers. We need to make sure we
* won't yield or hang during the critical section, since this lock will be
* used in OOB command handler.
*/
QemuMutex qemu_file_lock;
/*
* Used to allow urgent requests to override rate limiting.
*/
QemuSemaphore rate_limit_sem;
/* pages already send at the beginning of current iteration */
uint64_t iteration_initial_pages;
/* pages transferred per second */
double pages_per_second;
/* bytes already send at the beginning of current iteration */
uint64_t iteration_initial_bytes;
/* time at the start of current iteration */
int64_t iteration_start_time;
/*
* The final stage happens when the remaining data is smaller than
* this threshold; it's calculated from the requested downtime and
* measured bandwidth, or avail-switchover-bandwidth if specified.
*/
int64_t threshold_size;
/* params from 'migrate-set-parameters' */
MigrationParameters parameters;
int state;
/* State related to return path */
struct {
/* Protected by qemu_file_lock */
QEMUFile *from_dst_file;
QemuThread rp_thread;
/*
* We can also check non-zero of rp_thread, but there's no "official"
* way to do this, so this bool makes it slightly more elegant.
* Checking from_dst_file for this is racy because from_dst_file will
* be cleared in the rp_thread!
*/
bool rp_thread_created;
/*
* Used to synchronize between migration main thread and return
* path thread. The migration thread can wait() on this sem, while
* other threads (e.g., return path thread) can kick it using a
* post().
*/
QemuSemaphore rp_sem;
/*
* We post to this when we got one PONG from dest. So far it's an
* easy way to know the main channel has successfully established
* on dest QEMU.
*/
QemuSemaphore rp_pong_acks;
} rp_state;
double mbps;
/* Timestamp when recent migration starts (ms) */
int64_t start_time;
/* Total time used by latest migration (ms) */
int64_t total_time;
/* Timestamp when VM is down (ms) to migrate the last stuff */
int64_t downtime_start;
int64_t downtime;
int64_t expected_downtime;
bool capabilities[MIGRATION_CAPABILITY__MAX];
int64_t setup_time;
/*
* State before stopping the vm by vm_stop_force_state().
* If migration is interrupted by any reason, we need to continue
* running the guest on source if it was running or restore its stopped
* state.
*/
RunState vm_old_state;
/* Flag set once the migration has been asked to enter postcopy */
bool start_postcopy;
/* Flag set after postcopy has sent the device state */
bool postcopy_after_devices;
/* Flag set once the migration thread is running (and needs joining) */
bool migration_thread_running;
/* Flag set once the migration thread called bdrv_inactivate_all */
bool block_inactive;
/* Migration is waiting for guest to unplug device */
QemuSemaphore wait_unplug_sem;
/* Migration is paused due to pause-before-switchover */
QemuSemaphore pause_sem;
/* The semaphore is used to notify COLO thread that failover is finished */
QemuSemaphore colo_exit_sem;
/* The event is used to notify COLO thread to do checkpoint */
QemuEvent colo_checkpoint_event;
int64_t colo_checkpoint_time;
QEMUTimer *colo_delay_timer;
/* The first error that has occurred.
We used the mutex to be able to return the 1st error message */
Error *error;
/* mutex to protect errp */
QemuMutex error_mutex;
/* Do we have to clean up -b/-i from old migrate parameters */
/* This feature is deprecated and will be removed */
bool must_remove_block_options;
/*
* Global switch on whether we need to store the global state
* during migration.
*/
bool store_global_state;
/* Whether we send QEMU_VM_CONFIGURATION during migration */
bool send_configuration;
/* Whether we send section footer during migration */
bool send_section_footer;
/* Needed by postcopy-pause state */
QemuSemaphore postcopy_pause_sem;
/*
* Whether we abort the migration if decompression errors are
* detected at the destination. It is left at false for qemu
* older than 3.0, since only newer qemu sends streams that
* do not trigger spurious decompression errors.
*/
bool decompress_error_check;
/*
* This variable only affects behavior when postcopy preempt mode is
* enabled.
*
* When set:
*
* - postcopy preempt src QEMU instance will generate an EOS message at
* the end of migration to shut the preempt channel on dest side.
*
* - postcopy preempt channel will be created at the setup phase on src
QEMU.
*
* When clear:
*
* - postcopy preempt src QEMU instance will _not_ generate an EOS
* message at the end of migration, the dest qemu will shutdown the
* channel itself.
*
* - postcopy preempt channel will be created at the switching phase
* from precopy -> postcopy (to avoid race condition of misordered
* creation of channels).
*
* NOTE: See message-id <ZBoShWArKDPpX/D7@work-vm> on qemu-devel
* mailing list for more information on the possible race. Everyone
* should probably just keep this value untouched after set by the
* machine type (or the default).
*/
bool preempt_pre_7_2;
/*
* flush every channel after each section sent.
*
* This assures that we can't mix pages from one iteration through
* ram pages with pages for the following iteration. We really
* only need to do this flush after we have go through all the
* dirty pages. For historical reasons, we do that after each
* section. This is suboptimal (we flush too many times).
* Default value is false. (since 8.1)
*/
bool multifd_flush_after_each_section;
/*
* This decides the size of guest memory chunk that will be used
* to track dirty bitmap clearing. The size of memory chunk will
* be GUEST_PAGE_SIZE << N. Say, N=0 means we will clear dirty
* bitmap for each page to send (1<<0=1); N=10 means we will clear
* dirty bitmap only once for 1<<10=1K continuous guest pages
* (which is in 4M chunk).
*/
uint8_t clear_bitmap_shift;
/*
* This save hostname when out-going migration starts
*/
char *hostname;
/* QEMU_VM_VMDESCRIPTION content filled for all non-iterable devices. */
JSONWriter *vmdesc;
/*
* Indicates whether an ACK from the destination that it's OK to do
* switchover has been received.
*/
bool switchover_acked;
/* Is this a rdma migration */
bool rdma_migration;
};
void migrate_set_state(int *state, int old_state, int new_state);
void migration_fd_process_incoming(QEMUFile *f);
void migration_ioc_process_incoming(QIOChannel *ioc, Error **errp);
void migration_incoming_process(void);
bool migration_has_all_channels(void);
void migrate_set_error(MigrationState *s, const Error *error);
bool migrate_has_error(MigrationState *s);
void migrate_fd_connect(MigrationState *s, Error *error_in);
bool migration_is_setup_or_active(int state);
bool migration_is_running(int state);
int migrate_init(MigrationState *s, Error **errp);
bool migration_is_blocked(Error **errp);
/* True if outgoing migration has entered postcopy phase */
bool migration_in_postcopy(void);
bool migration_postcopy_is_alive(int state);
MigrationState *migrate_get_current(void);
uint64_t ram_get_total_transferred_pages(void);
/* Sending on the return path - generic and then for each message type */
void migrate_send_rp_shut(MigrationIncomingState *mis,
uint32_t value);
void migrate_send_rp_pong(MigrationIncomingState *mis,
uint32_t value);
int migrate_send_rp_req_pages(MigrationIncomingState *mis, RAMBlock *rb,
ram_addr_t start, uint64_t haddr);
int migrate_send_rp_message_req_pages(MigrationIncomingState *mis,
RAMBlock *rb, ram_addr_t start);
void migrate_send_rp_recv_bitmap(MigrationIncomingState *mis,
char *block_name);
void migrate_send_rp_resume_ack(MigrationIncomingState *mis, uint32_t value);
int migrate_send_rp_switchover_ack(MigrationIncomingState *mis);
void dirty_bitmap_mig_before_vm_start(void);
void dirty_bitmap_mig_cancel_outgoing(void);
void dirty_bitmap_mig_cancel_incoming(void);
bool check_dirty_bitmap_mig_alias_map(const BitmapMigrationNodeAliasList *bbm,
Error **errp);
void migrate_add_address(SocketAddress *address);
bool migrate_uri_parse(const char *uri, MigrationChannel **channel,
Error **errp);
int foreach_not_ignored_block(RAMBlockIterFunc func, void *opaque);
#define qemu_ram_foreach_block \
#warning "Use foreach_not_ignored_block in migration code"
void migration_make_urgent_request(void);
void migration_consume_urgent_request(void);
bool migration_rate_limit(void);
void migration_cancel(const Error *error);
void migration_populate_vfio_info(MigrationInfo *info);
void migration_reset_vfio_bytes_transferred(void);
void postcopy_temp_page_reset(PostcopyTmpPage *tmp_page);
/*
* Migration thread waiting for return path thread. Return non-zero if an
* error is detected.
*/
int migration_rp_wait(MigrationState *s);
/*
* Kick the migration thread waiting for return path messages. NOTE: the
* name can be slightly confusing (when read as "kick the rp thread"), just
* to remember the target is always the migration thread.
*/
void migration_rp_kick(MigrationState *s);
int migration_stop_vm(RunState state);
#endif