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compare: ivdok:trace-sync
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ivdok:openonload
ivdok:sync-io-test
ivdok:trace-sync
ivdok:trace-sqes
ivdok:test-submit-and-wait
ivdok:test-sq-poll
ivdok:blocking-uring-test
vitalif:nfs-rdma
vitalif:master
vitalif:bindiff
vitalif:hugo-docs
vitalif:node-mutex-and-postpone
vitalif:check-writeback
vitalif:msgr-iothreads-v2
vitalif:antietcd
vitalif:rel-1.4
vitalif:test-fix-ec-unknown-state-51
vitalif:kv-update
vitalif:kv-debug
vitalif:hotfix-1.2.0
vitalif:rdma-simple-nodp
vitalif:zerocopy-tcp-send
vitalif:csi-staging
vitalif:hotfix-1.1.0
vitalif:hotfix-1.0.0
vitalif:fsync-feedback
vitalif:cached-reads
vitalif:qemu-send-loop
vitalif:openssl
vitalif:test-double-alloc
vitalif:hier-failure-domains
vitalif:mon-self-restart
vitalif:epoch-deletions
vitalif:rdma-flow-control
vitalif:csi-use-vitastor-cli
vitalif:rdma-v2
vitalif:etcd-hide-base64
vitalif:lrc-matrix
vitalif:rm-left-on-dead
vitalif:nfs-proxy-old
vitalif:non-odp-rdma
vitalif:test-zctr
vitalif:separate-data-connections
vitalif:sec_osd_msgr
vitalif:test-assert
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vitalif:allow-etcd-address-option
vitalif:rdma-zerocopy
vitalif:rel-0.5
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vitalif:trace-sqes
vitalif:test-submit-and-wait
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vitalif:blocking-uring-test
ivdok:v0.6.3
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vitalif:v0.5.13
vitalif:v0.5.2
vitalif:v0.5.3
vitalif:v0.5.4
vitalif:v0.5.5
vitalif:v0.5.6
vitalif:v0.5.7
vitalif:v0.5.8
vitalif:v0.5.9
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vitalif:v0.8.1
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vitalif:v0.8.3
vitalif:v0.8.4
vitalif:v0.8.5
vitalif:v0.8.6
vitalif:v0.8.7
vitalif:v0.8.8
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vitalif:v0.9.3
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vitalif:v0.9.5
vitalif:v0.9.6
vitalif:v1.0.0
vitalif:v1.1.0
vitalif:v1.2.0
vitalif:v1.3.0
vitalif:v1.3.1
vitalif:v1.4.0
vitalif:v1.4.1
vitalif:v1.4.2
vitalif:v1.4.3
vitalif:v1.4.4
vitalif:v1.4.5
vitalif:v1.4.6
vitalif:v1.4.7
vitalif:v1.4.8
vitalif:v1.5.0
vitalif:v1.6.0
vitalif:v1.6.1
vitalif:v1.7.0
vitalif:v1.7.1
vitalif:v1.8.0
vitalif:v1.9.0
vitalif:v1.9.1
vitalif:v1.9.2
vitalif:v1.9.3

2 Commits
master ... trace-sync

Author SHA1 Message Date
Vitaliy Filippov 735b97fe33 Trace I/O operations (SQEs, recvmsg/sendmsg, uring_submit) 2020-06-09 00:52:29 +03:00
Vitaliy Filippov d56633843f Replace io_uring sendmsg/recvmsg with synchronous sendmsg/recvmsg 2020-06-09 00:52:29 +03:00
101 changed files with 2303 additions and 7386 deletions
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6
.gitmodules vendored
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@ -1,6 +0,0 @@
[submodule "cpp-btree"]
path = cpp-btree
url = ../cpp-btree.git
[submodule "json11"]
path = json11
url = ../json11.git

339
GPL-2.0.txt
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@ -1,339 +0,0 @@
GNU GENERAL PUBLIC LICENSE
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Copyright (C) 1989, 1991 Free Software Foundation, Inc.,
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Also add information on how to contact you by electronic and paper mail.
If the program is interactive, make it output a short notice like this
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Yoyodyne, Inc., hereby disclaims all copyright interest in the program
`Gnomovision' (which makes passes at compilers) written by James Hacker.
<signature of Ty Coon>, 1 April 1989
Ty Coon, President of Vice
This General Public License does not permit incorporating your program into
proprietary programs. If your program is a subroutine library, you may
consider it more useful to permit linking proprietary applications with the
library. If this is what you want to do, use the GNU Lesser General
Public License instead of this License.

88
Makefile
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@ -2,7 +2,7 @@ BLOCKSTORE_OBJS := allocator.o blockstore.o blockstore_impl.o blockstore_init.o
blockstore_write.o blockstore_sync.o blockstore_stable.o blockstore_rollback.o blockstore_flush.o crc32c.o ringloop.o
# -fsanitize=address
CXXFLAGS := -g -O3 -Wall -Wno-sign-compare -Wno-comment -Wno-parentheses -Wno-pointer-arith -fPIC -fdiagnostics-color=always
all: libfio_blockstore.so osd libfio_sec_osd.so libfio_cluster.so stub_osd stub_uring_osd stub_bench osd_test dump_journal qemu_driver.so nbd_proxy
all: libfio_blockstore.so osd libfio_sec_osd.so libfio_cluster.so stub_osd stub_uring_osd stub_bench osd_test dump_journal
clean:
rm -f *.o
@ -15,8 +15,8 @@ libfio_blockstore.so: ./libblockstore.so fio_engine.o json11.o
g++ $(CXXFLAGS) -shared -o $@ fio_engine.o json11.o ./libblockstore.so -ltcmalloc_minimal -luring
OSD_OBJS := osd.o osd_secondary.o msgr_receive.o msgr_send.o osd_peering.o osd_flush.o osd_peering_pg.o \
osd_primary.o osd_primary_subops.o etcd_state_client.o messenger.o osd_cluster.o http_client.o osd_ops.o pg_states.o \
osd_rmw.o json11.o base64.o timerfd_manager.o epoll_manager.o
osd_primary.o osd_primary_subops.o etcd_state_client.o messenger.o osd_cluster.o http_client.o pg_states.o \
osd_rmw.o json11.o base64.o timerfd_manager.o
osd: ./libblockstore.so osd_main.cpp osd.h osd_ops.h $(OSD_OBJS)
g++ $(CXXFLAGS) -o $@ osd_main.cpp $(OSD_OBJS) ./libblockstore.so -ltcmalloc_minimal -luring
@ -36,20 +36,10 @@ osd_peering_pg_test: osd_peering_pg_test.cpp osd_peering_pg.o
libfio_sec_osd.so: fio_sec_osd.o rw_blocking.o
g++ $(CXXFLAGS) -ltcmalloc_minimal -shared -o $@ fio_sec_osd.o rw_blocking.o
FIO_CLUSTER_OBJS := cluster_client.o epoll_manager.o etcd_state_client.o \
messenger.o msgr_send.o msgr_receive.o ringloop.o json11.o http_client.o osd_ops.o pg_states.o timerfd_manager.o base64.o
libfio_cluster.so: fio_cluster.o $(FIO_CLUSTER_OBJS)
g++ $(CXXFLAGS) -ltcmalloc_minimal -shared -o $@ $< $(FIO_CLUSTER_OBJS) -luring
nbd_proxy: nbd_proxy.o $(FIO_CLUSTER_OBJS)
g++ $(CXXFLAGS) -ltcmalloc_minimal -o $@ $< $(FIO_CLUSTER_OBJS) -luring
qemu_driver.o: qemu_driver.c qemu_proxy.h
gcc -I qemu/b/qemu `pkg-config glib-2.0 --cflags` \
-I qemu/include $(CXXFLAGS) -c -o $@ $<
qemu_driver.so: qemu_driver.o qemu_proxy.o $(FIO_CLUSTER_OBJS)
g++ $(CXXFLAGS) -ltcmalloc_minimal -shared -o $@ $< $(FIO_CLUSTER_OBJS) qemu_driver.o qemu_proxy.o -luring
FIO_CLUSTER_OBJS := fio_cluster.o cluster_client.o epoll_manager.o etcd_state_client.o \
messenger.o msgr_send.o msgr_receive.o ringloop.o json11.o http_client.o pg_states.o timerfd_manager.o base64.o
libfio_cluster.so: $(FIO_CLUSTER_OBJS)
g++ $(CXXFLAGS) -ltcmalloc_minimal -shared -o $@ $(FIO_CLUSTER_OBJS) -luring
test_blockstore: ./libblockstore.so test_blockstore.cpp timerfd_interval.o
g++ $(CXXFLAGS) -o test_blockstore test_blockstore.cpp timerfd_interval.o ./libblockstore.so -ltcmalloc_minimal -luring
@ -69,37 +59,37 @@ allocator.o: allocator.cpp allocator.h
g++ $(CXXFLAGS) -c -o $@ $<
base64.o: base64.cpp base64.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore.o: blockstore.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore.o: blockstore.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_flush.o: blockstore_flush.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_flush.o: blockstore_flush.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_impl.o: blockstore_impl.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_impl.o: blockstore_impl.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_init.o: blockstore_init.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_init.o: blockstore_init.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_journal.o: blockstore_journal.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_journal.o: blockstore_journal.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_open.o: blockstore_open.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_open.o: blockstore_open.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_read.o: blockstore_read.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_read.o: blockstore_read.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_rollback.o: blockstore_rollback.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_rollback.o: blockstore_rollback.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_stable.o: blockstore_stable.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_stable.o: blockstore_stable.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_sync.o: blockstore_sync.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_sync.o: blockstore_sync.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
blockstore_write.o: blockstore_write.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
blockstore_write.o: blockstore_write.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
cluster_client.o: cluster_client.cpp cluster_client.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
cluster_client.o: cluster_client.cpp cluster_client.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
dump_journal.o: dump_journal.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h ringloop.h
dump_journal.o: dump_journal.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
epoll_manager.o: epoll_manager.cpp epoll_manager.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
etcd_state_client.o: etcd_state_client.cpp base64.h etcd_state_client.h http_client.h json11/json11.hpp object_id.h osd_id.h osd_ops.h pg_states.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
fio_cluster.o: fio_cluster.cpp cluster_client.h epoll_manager.h etcd_state_client.h fio/fio.h fio/optgroup.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
fio_cluster.o: fio_cluster.cpp cluster_client.h epoll_manager.h etcd_state_client.h fio/fio.h fio/optgroup.h http_client.h json11/json11.hpp messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
fio_engine.o: fio_engine.cpp blockstore.h fio/fio.h fio/optgroup.h json11/json11.hpp object_id.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
@ -107,46 +97,40 @@ fio_sec_osd.o: fio_sec_osd.cpp fio/fio.h fio/optgroup.h object_id.h osd_id.h osd
g++ $(CXXFLAGS) -c -o $@ $<
http_client.o: http_client.cpp http_client.h json11/json11.hpp timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
messenger.o: messenger.cpp json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
messenger.o: messenger.cpp json11/json11.hpp messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
msgr_receive.o: msgr_receive.cpp json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
msgr_receive.o: msgr_receive.cpp json11/json11.hpp messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
msgr_send.o: msgr_send.cpp json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
msgr_send.o: msgr_send.cpp json11/json11.hpp messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
nbd_proxy.o: nbd_proxy.cpp cluster_client.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
osd.o: osd.cpp blockstore.h cpp-btree/btree_map.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd.o: osd.cpp blockstore.h cpp-btree/btree_map.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
osd_cluster.o: osd_cluster.cpp base64.h blockstore.h cpp-btree/btree_map.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_cluster.o: osd_cluster.cpp base64.h blockstore.h cpp-btree/btree_map.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
osd_flush.o: osd_flush.cpp blockstore.h cpp-btree/btree_map.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_flush.o: osd_flush.cpp blockstore.h cpp-btree/btree_map.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
osd_main.o: osd_main.cpp blockstore.h cpp-btree/btree_map.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_main.o: osd_main.cpp blockstore.h cpp-btree/btree_map.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_ops.o: osd_ops.cpp object_id.h osd_id.h osd_ops.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_peering.o: osd_peering.cpp base64.h blockstore.h cpp-btree/btree_map.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
osd_peering.o: osd_peering.cpp base64.h blockstore.h cpp-btree/btree_map.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_peering_pg.o: osd_peering_pg.cpp cpp-btree/btree_map.h object_id.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_peering_pg_test.o: osd_peering_pg_test.cpp cpp-btree/btree_map.h object_id.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_primary.o: osd_primary.cpp blockstore.h cpp-btree/btree_map.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h osd_primary.h osd_rmw.h pg_states.h ringloop.h timerfd_manager.h
osd_primary.o: osd_primary.cpp blockstore.h cpp-btree/btree_map.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h osd_primary.h osd_rmw.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_primary_subops.o: osd_primary_subops.cpp blockstore.h cpp-btree/btree_map.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h osd_primary.h osd_rmw.h pg_states.h ringloop.h timerfd_manager.h
osd_primary_subops.o: osd_primary_subops.cpp blockstore.h cpp-btree/btree_map.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h osd_primary.h osd_rmw.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_rmw.o: osd_rmw.cpp malloc_or_die.h object_id.h osd_id.h osd_rmw.h xor.h
osd_rmw.o: osd_rmw.cpp object_id.h osd_id.h osd_rmw.h xor.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_rmw_test.o: osd_rmw_test.cpp malloc_or_die.h object_id.h osd_id.h osd_rmw.cpp osd_rmw.h test_pattern.h xor.h
osd_rmw_test.o: osd_rmw_test.cpp object_id.h osd_id.h osd_rmw.cpp osd_rmw.h test_pattern.h xor.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_secondary.o: osd_secondary.cpp blockstore.h cpp-btree/btree_map.h epoll_manager.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
osd_secondary.o: osd_secondary.cpp blockstore.h cpp-btree/btree_map.h etcd_state_client.h http_client.h json11/json11.hpp messenger.h object_id.h osd.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
osd_test.o: osd_test.cpp object_id.h osd_id.h osd_ops.h rw_blocking.h test_pattern.h
g++ $(CXXFLAGS) -c -o $@ $<
pg_states.o: pg_states.cpp pg_states.h
g++ $(CXXFLAGS) -c -o $@ $<
qemu_proxy.o: qemu_proxy.cpp cluster_client.h etcd_state_client.h http_client.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd_id.h osd_ops.h qemu_proxy.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
ringloop.o: ringloop.cpp ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
rw_blocking.o: rw_blocking.cpp rw_blocking.h
@ -155,9 +139,9 @@ stub_bench.o: stub_bench.cpp object_id.h osd_id.h osd_ops.h rw_blocking.h
g++ $(CXXFLAGS) -c -o $@ $<
stub_osd.o: stub_osd.cpp object_id.h osd_id.h osd_ops.h rw_blocking.h
g++ $(CXXFLAGS) -c -o $@ $<
stub_uring_osd.o: stub_uring_osd.cpp epoll_manager.h json11/json11.hpp malloc_or_die.h messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
stub_uring_osd.o: stub_uring_osd.cpp epoll_manager.h json11/json11.hpp messenger.h object_id.h osd_id.h osd_ops.h ringloop.h timerfd_manager.h
g++ $(CXXFLAGS) -c -o $@ $<
test.o: test.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h malloc_or_die.h object_id.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h
test.o: test.cpp allocator.h blockstore.h blockstore_flush.h blockstore_impl.h blockstore_init.h blockstore_journal.h cpp-btree/btree_map.h crc32c.h object_id.h osd_id.h osd_ops.h osd_peering_pg.h pg_states.h ringloop.h
g++ $(CXXFLAGS) -c -o $@ $<
test_allocator.o: test_allocator.cpp allocator.h
g++ $(CXXFLAGS) -c -o $@ $<

387
README.md
View File

@ -1,387 +0,0 @@
## Vitastor
## The Idea
Make Software-Defined Block Storage Great Again.
Vitastor is a small, simple and fast clustered block storage (storage for VM drives),
architecturally similar to Ceph which means strong consistency, primary-replication, symmetric
clustering and automatic data distribution over any number of drives of any size
with configurable redundancy (replication or erasure codes/XOR).
## Features
Vitastor is currently a pre-release, a lot of features are missing and you can still expect
breaking changes in the future. However, the following is implemented:
- Basic part: highly-available block storage with symmetric clustering and no SPOF
- Performance ;-D
- Two redundancy schemes: Replication and XOR n+1 (simplest case of EC)
- Configuration via simple JSON data structures in etcd
- Automatic data distribution over OSDs, with support for:
- Mathematical optimization for better uniformity and less data movement
- Multiple pools
- Placement tree
- Configurable failure domains
- Recovery of degraded blocks
- Rebalancing (data movement between OSDs)
- Lazy fsync support
- I/O statistics reporting to etcd
- Generic user-space client library
- QEMU driver (built out-of-tree)
- Loadable fio engine for benchmarks (also built out-of-tree)
- NBD proxy for kernel mounts
## Roadmap
- Packaging for Debian and, probably, CentOS too
- OSD creation tool (OSDs currently have to be created by hand)
- Inode deletion tool (currently you can't delete anything :))
- Other administrative tools
- Per-inode I/O and space usage statistics
- jerasure EC support with any number of data and parity drives in a group
- Parallel usage of multiple network interfaces
- Proxmox and OpenNebula plugins
- iSCSI proxy
- Inode metadata storage in etcd
- Snapshots and copy-on-write image clones
- Operation timeouts and better failure detection
- Checksums
- SSD+HDD optimizations, possibly including tiered storage and soft journal flushes
- RDMA and NVDIMM support
- Compression (possibly)
- Read caching using system page cache (possibly)
## Architecture
Similarities:
- Just like Ceph, Vitastor has Pools, PGs, OSDs, Monitors, Failure Domains, Placement Tree.
- Just like Ceph, Vitastor is transactional (even though there's a "lazy fsync mode" which
doesn't implicitly flush every operation to disks).
- OSDs also have journal and metadata and they can also be put on separate drives.
- Just like in Ceph, client library attempts to recover from any cluster failure so
you can basically reboot the whole cluster and only pause, but not crash, your clients
(I consider this a bug if the client crashes in that case).
Some basic terms for people not familiar with Ceph:
- OSD (Object Storage Daemon) is a process that stores data and serves read/write requests.
- PG (Placement Group) is a container for data that (normally) shares the same replicas.
- Pool is a container for data that has the same redundancy scheme and placement rules.
- Monitor is a separate daemon that watches cluster state and handles failures.
- Failure Domain is a group of OSDs that you allow to fail. It's "host" by default.
- Placement Tree groups OSDs in a hierarchy to later split them into Failure Domains.
Architectural differences from Ceph:
- Vitastor's primary focus is on SSDs. Proper SSD+HDD optimizations may be added in the future, though.
- Vitastor OSD is (and will always be) single-threaded. If you want to dedicate more than 1 core
per drive you should run multiple OSDs each on a different partition of the drive.
Vitastor isn't CPU-hungry though (as opposed to Ceph), so 1 core is sufficient in a lot of cases.
- Metadata and journal are always kept in memory. Metadata size depends linearly on drive capacity
and data store block size which is 128 KB by default. With 128 KB blocks, metadata should occupy
around 512 MB per 1 TB (which is still less than Ceph wants). Journal doesn't have to be big,
the example test below was conducted with only 16 MB journal. A big journal is probably even
harmful as dirty write metadata also take some memory.
- Vitastor storage layer doesn't have internal copy-on-write or redirect-write. I know that maybe
it's possible to create a good copy-on-write storage, but it's much harder and makes performance
less deterministic, so CoW isn't used in Vitastor.
- The basic layer of Vitastor is block storage with fixed-size blocks, not object storage with
rich semantics like in Ceph (RADOS).
- There's a "lazy fsync" mode which allows to batch writes before flushing them to the disk.
This allows to use Vitastor with desktop SSDs, but still lowers performance due to additional
network roundtrips, so use server SSDs with capacitor-based power loss protection
("Advanced Power Loss Protection") for best performance.
- PGs are ephemeral. This means that they aren't stored on data disks and only exist in memory
while OSDs are running.
- Recovery process is per-object (per-block), not per-PG. Also there are no PGLOGs.
- Monitors don't store data. Cluster configuration and state is stored in etcd in simple human-readable
JSON structures. Monitors only watch cluster state and handle data movement.
Thus Vitastor's Monitor isn't a critical component of the system and is more similar to Ceph's Manager.
Vitastor's Monitor is implemented in node.js.
- PG distribution isn't based on consistent hashes. All PG mappings are stored in etcd.
Rebalancing PGs between OSDs is done by mathematical optimization - data distribution problem
is reduced to a linear programming problem and solved by lp_solve. This allows for almost
perfect (96-99% uniformity compared to Ceph's 80-90%) data distribution in most cases, ability
to map PGs by hand without breaking rebalancing logic, reduced OSD peer-to-peer communication
(on average, OSDs have fewer peers) and less data movement. It also probably has a drawback -
this method may fail in very large clusters, but up to several hundreds of OSDs it's perfectly fine.
It's also easy to add consistent hashes in the future if something proves their necessity.
- There's no separate CRUSH layer. You select pool redundancy scheme, placement root, failure domain
and so on directly in pool configuration.
## Understanding Storage Performance
The most important thing for fast storage is latency, not parallel iops.
The best possible latency is achieved with one thread and queue depth of 1 which basically means
"client load as low as possible". In this case IOPS = 1/latency, and this number doesn't
scale with number of servers, drives, server processes or threads and so on.
Single-threaded IOPS and latency numbers only depend on *how fast a single daemon is*.
Why is it important? It's important because some of the applications *can't* use
queue depth greater than 1 because their task isn't parallelizable. A notable example
is any ACID DBMS because all of them write their WALs sequentially with fsync()s.
fsync, by the way, is another important thing often missing in benchmarks. The point is
that drives have cache buffers and don't guarantee that your data is actually persisted
until you call fsync() which is translated to a FLUSH CACHE command by the OS.
Desktop SSDs are very fast without fsync - NVMes, for example, can process ~80000 write
operations per second with queue depth of 1 without fsync - but they're really slow with
fsync because they have to actually write data to flash chips when you call fsync. Typical
number is around 1000-2000 iops with fsync.
Server SSDs often have supercapacitors that act as a built-in UPS and allow the drive
to flush its DRAM cache to the persistent flash storage when a power loss occurs.
This makes them perform equally well with and without fsync. This feature is called
"Advanced Power Loss Protection" by Intel; other vendors either call it similarly
or directly as "Full Capacitor-Based Power Loss Protection".
All software-defined storages that I currently know are slow in terms of latency.
Notable examples are Ceph and internal SDSes used by cloud providers like Amazon, Google,
Yandex and so on. They're all slow and can only reach ~0.3ms read and ~0.6ms 4 KB write latency
with best-in-slot hardware.
And that's in the SSD era when you can buy an SSD that has ~0.04ms latency for 100 $.
I use the following 6 commands with small variations to benchmark any storage:
- Linear write:
`fio -ioengine=libaio -direct=1 -invalidate=1 -name=test -bs=4M -iodepth=32 -rw=write -runtime=60 -filename=/dev/sdX`
- Linear read:
`fio -ioengine=libaio -direct=1 -invalidate=1 -name=test -bs=4M -iodepth=32 -rw=read -runtime=60 -filename=/dev/sdX`
- Random write latency (this hurts storages the most):
`fio -ioengine=libaio -direct=1 -invalidate=1 -name=test -bs=4k -iodepth=1 -fsync=1 -rw=randwrite -runtime=60 -filename=/dev/sdX`
- Random read latency:
`fio -ioengine=libaio -direct=1 -invalidate=1 -name=test -bs=4k -iodepth=1 -rw=randread -runtime=60 -filename=/dev/sdX`
- Parallel write iops (use numjobs if a single CPU core is insufficient to saturate the load):
`fio -ioengine=libaio -direct=1 -invalidate=1 -name=test -bs=4k -iodepth=128 [-numjobs=4 -group_reporting] -rw=randwrite -runtime=60 -filename=/dev/sdX`
- Parallel read iops (use numjobs if a single CPU core is insufficient to saturate the load):
`fio -ioengine=libaio -direct=1 -invalidate=1 -name=test -bs=4k -iodepth=128 [-numjobs=4 -group_reporting] -rw=randread -runtime=60 -filename=/dev/sdX`
## Vitastor's Theoretical Maximum Random Access Performance
Replicated setups:
- Single-threaded (T1Q1) read latency: 1 network roundtrip + 1 disk read.
- Single-threaded write+fsync latency:
- With immediate commit: 2 network roundtrips + 1 disk write.
- With lazy commit: 4 network roundtrips + 1 disk write + 1 disk flush.
- Saturated parallel read iops: min(network bandwidth, sum(disk read iops)).
- Saturated parallel write iops: min(network bandwidth, sum(disk write iops / number of replicas / write amplification)).
EC/XOR setups:
- Single-threaded (T1Q1) read latency: 1.5 network roundtrips + 1 disk read.
- Single-threaded write+fsync latency:
- With immediate commit: 3.5 network roundtrips + 1 disk read + 2 disk writes.
- With lazy commit: 5.5 network roundtrips + 1 disk read + 2 disk writes + 2 disk fsyncs.
- 0.5 in actually (k-1)/k which means that an additional roundtrip doesn't happen when
the read sub-operation can be served locally.
- Saturated parallel read iops: min(network bandwidth, sum(disk read iops)).
- Saturated parallel write iops: min(network bandwidth, sum(disk write iops * number of data drives / (number of data + parity drives) / write amplification)).
In fact, you should put disk write iops under the condition of ~10% reads / ~90% writes in this formula.
Write amplification for 4 KB blocks is usually 3-5 in Vitastor:
1. Journal block write
2. Journal data write
3. Metadata block write
4. Another journal block write for EC/XOR setups
5. Data block write
If you manage to get an SSD which handles 512 byte blocks well (Optane?) you may
lower 1, 3 and 4 to 512 bytes (1/8 of data size) and get WA as low as 2.375.
Lazy fsync also reduces WA for parallel workloads because journal blocks are only
written when they fill up or fsync is requested.
## Example Comparison with Ceph
Hardware configuration: 4 nodes, each with:
- 6x SATA SSD Intel D3-4510 3.84 TB
- 2x Xeon Gold 6242 (16 cores @ 2.8 GHz)
- 384 GB RAM
- 1x 25 GbE network interface (Mellanox ConnectX-4 LX), connected to a Juniper QFX5200 switch
CPU powersaving was disabled. Both Vitastor and Ceph were configured with 2 OSDs per 1 SSD.
All of the results below apply to 4 KB blocks.
Raw drive performance:
- T1Q1 write ~27000 iops (~0.037ms latency)
- T1Q1 read ~9800 iops (~0.101ms latency)
- T1Q32 write ~60000 iops
- T1Q32 read ~81700 iops
Ceph 15.2.4 (Bluestore):
- T1Q1 write ~1000 iops (~1ms latency)
- T1Q1 read ~1750 iops (~0.57ms latency)
- T8Q64 write ~100000 iops, total CPU usage by OSDs about 40 virtual cores on each node
- T8Q64 read ~480000 iops, total CPU usage by OSDs about 40 virtual cores on each node
T8Q64 tests were conducted over 8 400GB RBD images from all hosts (every host was running 2 instances of fio).
This is because Ceph has performance penalties related to running multiple clients over a single RBD image.
cephx_sign_messages was set to false during tests, RocksDB and Bluestore settings were left at defaults.
In fact, not that bad for Ceph. These servers are an example of well-balanced Ceph nodes.
However, CPU usage and I/O latency were through the roof, as usual.
Vitastor:
- T1Q1 write: 7087 iops (0.14ms latency)
- T1Q1 read: 6838 iops (0.145ms latency)
- T2Q64 write: 162000 iops, total CPU usage by OSDs about 3 virtual cores on each node
- T8Q64 read: 895000 iops, total CPU usage by OSDs about 4 virtual cores on each node
T8Q64 read test was conducted over 1 larger inode (3.2T) from all hosts (every host was running 2 instances of fio).
Vitastor has no performance penalties related to running multiple clients over a single inode.
If conducted from one node with all primary OSDs moved to other nodes the result was slightly lower (689000 iops),
this is because all operations resulted in network roundtrips between the client and the primary OSD.
When fio was colocated with OSDs (like in Ceph benchmarks above), 1/4 of the read workload actually
used the loopback network.
Vitastor was configured with: `--disable_data_fsync true --immediate_commit all --flusher_count 8
--disk_alignment 4096 --journal_block_size 4096 --meta_block_size 4096
--journal_no_same_sector_overwrites true --journal_sector_buffer_count 1024
--journal_size 16777216`.
### NBD
NBD is currently required to mount Vitastor via kernel, but it imposes additional overhead
due to additional copying between the kernel and userspace. This mostly hurts linear
bandwidth, not iops.
Vitastor with single-thread NBD on the same hardware:
- T1Q1 write: 6000 iops (0.166ms latency)
- T1Q1 read: 5518 iops (0.18ms latency)
- T1Q128 write: 94400 iops
- T1Q128 read: 103000 iops
- Linear write (4M T1Q128): 1266 MB/s (compared to 2600 MB/s via fio)
- Linear read (4M T1Q128): 975 MB/s (compared to 1400 MB/s via fio)
## Building
- Install Linux kernel 5.4 or newer for io_uring support.
- Install liburing 0.4 or newer and its headers.
- Install lp_solve.
- Install etcd.
- Install node.js 12 or newer.
- Install gcc and g++ 9.x.
- Clone https://yourcmc.ru/git/vitalif/vitastor/ with submodules.
- Install QEMU 4.x or 5.x, get its source, begin to build it, stop the build and copy headers:
- `<qemu>/include` &rarr; `<vitastor>/qemu/include`
- Debian:
* Use qemu packages from the main repository
* `<qemu>/b/qemu/config-host.h` &rarr; `<vitastor>/qemu/b/qemu/config-host.h`
* `<qemu>/b/qemu/qapi` &rarr; `<vitastor>/qemu/b/qemu/qapi`
- CentOS 8:
* Use qemu packages from the Advanced-Virtualization repository. To enable it, run
`yum install centos-release-advanced-virtualization.noarch` and then `yum install qemu`
* `<qemu>/config-host.h` &rarr; `<vitastor>/qemu/b/qemu/config-host.h`
* `<qemu>/qapi` &rarr; `<vitastor>/qemu/b/qemu/qapi`
- `config-host.h` and `qapi` are required because they contain generated headers
- Install fio 3.16, get its source and symlink it into `<vitastor>/fio`. It doesn't currently
build with fio 3.20 or newer due to the conflicts between g++ and gcc's atomics. This will
be fixed in the future.
- Build Vitastor with `make -j8`.
- Copy binaries somewhere.
## Running
Please note that startup procedure isn't currently simple - you specify configuration
and calculate disk offsets almost by hand. This will be fixed in near future.
- Get some SATA or NVMe SSDs with capacitors (server-grade drives). You can use desktop SSDs
with lazy fsync, but prepare for inferior single-thread latency.
- Get a fast network (at least 10 Gbit/s).
- Disable CPU powersaving: `cpupower idle-set -D 0 && cpupower frequency-set -g performance`.
- Install etcd with `--max-txn-ops=100000 --auto-compaction-retention=10 --auto-compaction-mode=revision` options.
- Create global configuration in etcd: `etcdctl put /vitastor/config/global '{"immediate_commit":"all"}'`
(if all your drives have capacitors).
- Create pool configuration in etcd: `etcdctl put /vitastor/config/pools '{"1":{"name":"testpool","scheme":"replicated","pg_size":2,"pg_minsize":1,"pg_count":256,"failure_domain":"host"}}'`.
- Calculate offsets for your drives with `node ./mon/simple-offsets.js /dev/sdX`.
- Make systemd units for your OSDs. Look at `./mon/make-units.sh` for example.
Notable configuration variables from the example:
- `disable_data_fsync 1` - only safe with server-grade drives with capacitors.
- `immediate_commit all` - use this if all your drives are server-grade.
- `disable_device_lock 1` - only required if you run multiple OSDs on one block device.
- `flusher_count 16` - flusher is a micro-thread that removes old data from the journal.
More flushers mean more aggressive journal flushing which allows for more throughput
but slightly hurts latency under less load. Flushing will probably be improved in the future
because currently high queue depths sometimes lead to performance degradation.
- `disk_alignment`, `journal_block_size`, `meta_block_size` should be set to the internal
block size of your SSDs which is 4096 on most drives.
- `journal_no_same_sector_overwrites true` prevents multiple overwrites of the same journal sector.
Some SSDs (like Intel D3-4510) don't like such overwrites so they benefit from this setting.
When this setting is set, it is also required to raise `journal_sector_buffer_count` setting,
which is the number of dirty journal sectors that may be written to at the same time.
- `systemctl start vitastor.target` everywhere.
- Start any number of monitors: `cd mon; node mon-main.js --etcd_url 'http://10.115.0.10:2379,http://10.115.0.11:2379,http://10.115.0.12:2379,http://10.115.0.13:2379' --etcd_prefix '/vitastor' --etcd_start_timeout 5`.
- At this point, one of the monitors will configure PGs and OSDs will start them.
- You can check PG states with `etcdctl get --prefix /vitastor/pg/state`. All PGs should become 'active'.
- Run tests with (for example): `fio -thread -ioengine=./libfio_cluster.so -name=test -bs=4M -direct=1 -iodepth=16 -rw=write -etcd=10.115.0.10:2379/v3 -pool=1 -inode=1 -size=400G`.
- Upload VM disk image with qemu-img (for example):
```
LD_PRELOAD=./qemu_driver.so qemu-img convert -f qcow2 debian10.qcow2 -p
-O raw 'vitastor:etcd_host=10.115.0.10\:2379/v3:pool=1:inode=1:size=2147483648'
```
- Run QEMU with (for example):
```
LD_PRELOAD=./qemu_driver.so qemu-system-x86_64 -enable-kvm -m 1024
-drive 'file=vitastor:etcd_host=10.115.0.10\:2379/v3:pool=1:inode=1:size=2147483648',format=raw,if=none,id=drive-virtio-disk0,cache=none
-device virtio-blk-pci,scsi=off,bus=pci.0,addr=0x5,drive=drive-virtio-disk0,id=virtio-disk0,bootindex=1,write-cache=off,physical_block_size=4096,logical_block_size=512
-vnc 0.0.0.0:0
```
## Known Problems
- OSDs may currently crash with "can't get SQE, will fall out of sync with EPOLLET"
if you try to load them with very long iodepths because io_uring queue (ring) is limited
and OSDs don't check if it fills up.
- Object deletion requests may currently lead to unfound objects on crashes because
proper handling of deletions in a cluster requires a "three-phase cleanup process"
and it's currently not implemented. In fact, even though deletion requests are
implemented, there's no user tool to delete anything from the cluster yet :).
Of course I'll create such tool, but its first implementation will be vulnerable to this issue.
It's not a big deal though, because you'll be able to just repeat the deletion request
in this case.
## Implementation Principles
- I like simple and stupid solutions, so expect Vitastor to stay simple.
- I also like reinventing the wheel to some extent, like writing my own HTTP client
for etcd interaction instead of using prebuilt libraries, because in this case
I'm confident about what my code does and what it doesn't do.
- I don't care about C++ "best practices" like RAII or proper inheritance or usage of
smart pointers or whatever and I don't intend to change my mind, so if you're here
looking for ideal reference C++ code, this probably isn't the right place.
- I like node.js better than any other dynamically-typed language interpreter
because it's faster than any other interpreter in the world, has neutral C-like
syntax and built-in event loop. That's why Monitor is implemented in node.js.
## Author and License
Copyright (c) Vitaliy Filippov (vitalif [at] yourcmc.ru), 2019+
You can also find me in the Russian Telegram Ceph chat: https://t.me/ceph_ru
All server-side code (OSD, Monitor and so on) is licensed under the terms of
Vitastor Network Public License 1.0 (VNPL 1.0), a copyleft license based on
GNU GPLv3.0 with the additional "Network Interaction" clause which requires
opensourcing all programs directly or indirectly interacting with Vitastor
through a computer network ("Proxy Programs"). Proxy Programs may be made public
not only under the terms of the same license, but also under the terms of any
GPL-Compatible Free Software License, as listed by the Free Software Foundation.
This is a stricter copyleft license than the Affero GPL.
Basically, you can't use the software in a proprietary environment to provide
its functionality to users without opensourcing all intermediary components
standing between the user and Vitastor or purchasing a commercial license
from the author 😀.
Client libraries (cluster_client and so on) are dual-licensed under the same
VNPL 1.0 and also GNU GPL 2.0 or later to allow for compatibility with GPLed
software like QEMU and fio.
You can find the full text of VNPL-1.0 in the file [VNPL-1.0.txt](VNPL-1.0.txt).
GPL 2.0 is also included in this repository as [GPL-2.0.txt](GPL-2.0.txt).

645
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@ -1,645 +0,0 @@
VITASTOR NETWORK PUBLIC LICENSE
Version 1, 17 September 2020
Copyright (C) 2020 Vitaliy Filippov <vitalif@yourcmc.ru>
Everyone is permitted to copy and distribute verbatim copies
of this license document, but changing it is not allowed.
Preamble
The Vitastor Network Public License is a free, copyleft license for
software and other kinds of works, specifically designed to ensure
cooperation with the community in the case of network server software.
The licenses for most software and other practical works are designed
to take away your freedom to share and change the works. By contrast,
GNU General Public Licenses and Vitastor Network Public License are
intended to guarantee your freedom to share and change all versions
of a program--to make sure it remains free software for all its users.
When we speak of free software, we are referring to freedom, not
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are designed to make sure that you have the freedom to distribute copies
of free software (and charge for them if you wish), that you receive
source code or can get it if you want it, that you can change the software
or use pieces of it in new free programs, and that you know you can do these
things.
Developers that use GNU General Public Licenses and Vitastor
Network Public License protect your rights with two steps:
(1) assert copyright on the software, and (2) offer
you this License which gives you legal permission to copy, distribute
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A secondary benefit of defending all users' freedom is that
improvements made in alternate versions of the program, if they
receive widespread use, become available for other developers to
incorporate. Many developers of free software are heartened and
encouraged by the resulting cooperation. However, in the case of
software used on network servers, this result may fail to come about.
The GNU General Public License permits making a modified version and
letting the public access it on a server without ever releasing its
source code to the public. Even the GNU Affero General Public License
permits running a modified version in a closed environment where
public users only interact with it through a closed-source proxy, again,
without making the program and the proxy available to the public
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The Vitastor Network Public License is designed specifically to
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available to the community. It requires the operator of a network server to
provide the source code of the original program and all other programs
communicating with it running there to the users of that server.
Therefore, public use of a modified version, on a server accessible
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any implied license or other defenses to infringement that may
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12. No Surrender of Others' Freedom.
If conditions are imposed on you (whether by court order, agreement or
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to collect a royalty for further conveying from those to whom you convey
the Program, the only way you could satisfy both those terms and this
License would be to refrain entirely from conveying the Program.
13. Remote Network Interaction.
Notwithstanding any other provision of this License, if you provide
any user an opportunity to interact with the covered work directly
or indirectly through a computer network, an imitation of such network,
or an additional program (hereinafter referred to as a "Proxy Program")
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Free Software License, as described by the Free Software Foundation
in their "GPL-Compatible License List".
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will be similar in spirit to the present version, but may differ in detail to
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THERE IS NO WARRANTY FOR THE PROGRAM, TO THE EXTENT PERMITTED BY
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IN NO EVENT UNLESS REQUIRED BY APPLICABLE LAW OR AGREED TO IN WRITING
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17. Interpretation of Sections 15 and 16.
If the disclaimer of warranty and limitation of liability provided
above cannot be given local legal effect according to their terms,
reviewing courts shall apply local law that most closely approximates
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Program, unless a warranty or assumption of liability accompanies a
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END OF TERMS AND CONDITIONS
How to Apply These Terms to Your New Programs
If you develop a new program, and you want it to be of the greatest
possible use to the public, the best way to achieve this is to make it
free software which everyone can redistribute and change under these terms.
To do so, attach the following notices to the program. It is safest
to attach them to the start of each source file to most effectively
state the exclusion of warranty; and each file should have at least
the "copyright" line and a pointer to where the full notice is found.
<one line to give the program's name and a brief idea of what it does.>
Copyright (C) <year> <name of author>
This program is free software: you can redistribute it and/or modify
it under the terms of the Vitastor Network Public License as published by
the Vitastor Author, either version 1 of the License, or
(at your option) any later version.
This program is distributed in the hope that it will be useful,
but WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
Vitastor Network Public License for more details.
Also add information on how to contact you by electronic and paper mail.
If your software can interact with users remotely through a computer
network, you should also make sure that it provides a way for users to
get its source. For example, if your program is a web application, its
interface could display a "Source" link that leads users to an archive
of the code. There are many ways you could offer source, and different
solutions will be better for different programs; see section 13 for the
specific requirements.

3
allocator.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <stdexcept>
#include "allocator.h"

3
allocator.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#include <stdint.h>

3
base64.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "base64.h"
std::string base64_encode(const std::string &in)

3
base64.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#include <string>

3
blockstore.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
blockstore_t::blockstore_t(blockstore_config_t & config, ring_loop_t *ringloop)

24
blockstore.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#ifndef _LARGEFILE64_SOURCE
@ -30,14 +27,13 @@
#define BS_OP_MIN 1
#define BS_OP_READ 1
#define BS_OP_WRITE 2
#define BS_OP_WRITE_STABLE 3
#define BS_OP_SYNC 4
#define BS_OP_STABLE 5
#define BS_OP_DELETE 6
#define BS_OP_LIST 7
#define BS_OP_ROLLBACK 8
#define BS_OP_SYNC_STAB_ALL 9
#define BS_OP_MAX 9
#define BS_OP_SYNC 3
#define BS_OP_STABLE 4
#define BS_OP_DELETE 5
#define BS_OP_LIST 6
#define BS_OP_ROLLBACK 7
#define BS_OP_SYNC_STAB_ALL 8
#define BS_OP_MAX 8
#define BS_OP_PRIVATE_DATA_SIZE 256
@ -45,9 +41,9 @@
Blockstore opcode documentation:
## BS_OP_READ / BS_OP_WRITE / BS_OP_WRITE_STABLE
## BS_OP_READ / BS_OP_WRITE
Read or write object data. WRITE_STABLE writes a version that doesn't require marking as stable.
Read or write object data.
Input:
- oid = requested object
@ -117,8 +113,6 @@ Input:
- oid.stripe = PG alignment
- len = PG count or 0 to list all objects
- offset = PG number
- oid.inode = min inode number or 0 to list all inodes
- version = max inode number or 0 to list all inodes
Output:
- retval = total obj_ver_id count

107
blockstore_flush.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
journal_flusher_t::journal_flusher_t(int flusher_count, blockstore_impl_t *bs)
@ -13,7 +10,7 @@ journal_flusher_t::journal_flusher_t(int flusher_count, blockstore_impl_t *bs)
flusher_start_threshold = bs->journal_block_size / sizeof(journal_entry_stable);
journal_trim_interval = flusher_start_threshold;
journal_trim_counter = 0;
journal_superblock = bs->journal.inmemory ? bs->journal.buffer : memalign_or_die(MEM_ALIGNMENT, bs->journal_block_size);
journal_superblock = bs->journal.inmemory ? bs->journal.buffer : memalign(MEM_ALIGNMENT, bs->journal_block_size);
co = new journal_flusher_co[flusher_count];
for (int i = 0; i < flusher_count; i++)
{
@ -36,6 +33,12 @@ journal_flusher_co::journal_flusher_co()
);
}
wait_count--;
if (!wait_count)
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("finished %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
};
simple_callback_w = [this](ring_data_t* data)
{
@ -48,6 +51,12 @@ journal_flusher_co::journal_flusher_co()
);
}
wait_count--;
if (!wait_count)
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("finished %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
};
}
@ -125,6 +134,11 @@ void journal_flusher_t::release_trim()
#define await_sqe(label) \
resume_##label:\
{\
timespec now;\
clock_gettime(CLOCK_REALTIME, &now);\
printf("get_sqe %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);\
}\
sqe = bs->get_sqe();\
if (!sqe)\
{\
@ -186,23 +200,6 @@ resume_0:
dirty_end = bs->dirty_db.find(cur);
if (dirty_end != bs->dirty_db.end())
{
repeat_it = flusher->sync_to_repeat.find(cur.oid);
if (repeat_it != flusher->sync_to_repeat.end())
{
#ifdef BLOCKSTORE_DEBUG
printf("Postpone %lx:%lx v%lu\n", cur.oid.inode, cur.oid.stripe, cur.version);
#endif
// We don't flush different parts of history of the same object in parallel
// So we check if someone is already flushing this object
// In that case we set sync_to_repeat and pick another object
// Another coroutine will see it and re-queue the object after it finishes
if (repeat_it->second < cur.version)
repeat_it->second = cur.version;
wait_state = 0;
goto resume_0;
}
else
flusher->sync_to_repeat[cur.oid] = 0;
if (dirty_end->second.journal_sector >= bs->journal.dirty_start &&
(bs->journal.dirty_start >= bs->journal.used_start ||
dirty_end->second.journal_sector < bs->journal.used_start))
@ -233,7 +230,6 @@ resume_0:
if (!found)
{
// Try other objects
flusher->sync_to_repeat.erase(cur.oid);
int search_left = flusher->flush_queue.size() - 1;
#ifdef BLOCKSTORE_DEBUG
printf("Flusher overran writers (dirty_start=%08lx) - searching for older flushes (%d left)\n", bs->journal.dirty_start, search_left);
@ -252,18 +248,13 @@ resume_0:
dirty_end->second.journal_sector < bs->journal.used_start))
{
#ifdef BLOCKSTORE_DEBUG
printf("Write %lx:%lx v%lu is too new: offset=%08lx\n", cur.oid.inode, cur.oid.stripe, cur.version, dirty_end->second.journal_sector);
printf("Write %lu:%lu v%lu is too new: offset=%08lx\n", cur.oid.inode, cur.oid.stripe, cur.version, dirty_end->second.journal_sector);
#endif
flusher->enqueue_flush(cur);
}
else
{
repeat_it = flusher->sync_to_repeat.find(cur.oid);
if (repeat_it == flusher->sync_to_repeat.end())
{
flusher->sync_to_repeat[cur.oid] = 0;
break;
}
break;
}
}
search_left--;
@ -279,8 +270,25 @@ resume_0:
}
}
}
repeat_it = flusher->sync_to_repeat.find(cur.oid);
if (repeat_it != flusher->sync_to_repeat.end())
{
#ifdef BLOCKSTORE_DEBUG
printf("Flushing %lx:%lx v%lu\n", cur.oid.inode, cur.oid.stripe, cur.version);
printf("Postpone %lu:%lu v%lu\n", cur.oid.inode, cur.oid.stripe, cur.version);
#endif
// We don't flush different parts of history of the same object in parallel
// So we check if someone is already flushing this object
// In that case we set sync_to_repeat and pick another object
// Another coroutine will see it and re-queue the object after it finishes
if (repeat_it->second < cur.version)
repeat_it->second = cur.version;
wait_state = 0;
goto resume_0;
}
else
flusher->sync_to_repeat[cur.oid] = 0;
#ifdef BLOCKSTORE_DEBUG
printf("Flushing %lu:%lu v%lu\n", cur.oid.inode, cur.oid.stripe, cur.version);
#endif
flusher->active_flushers++;
resume_1:
@ -308,7 +316,7 @@ resume_1:
// Object not allocated. This is a bug.
char err[1024];
snprintf(
err, 1024, "BUG: Object %lx:%lx v%lu that we are trying to flush is not allocated on the data device",
err, 1024, "BUG: Object %lu:%lu v%lu that we are trying to flush is not allocated on the data device",
cur.oid.inode, cur.oid.stripe, cur.version
);
throw std::runtime_error(err);
@ -506,8 +514,7 @@ resume_1:
}
// All done
#ifdef BLOCKSTORE_DEBUG
printf("Flushed %lx:%lx v%lu (%d copies, wr:%d, del:%d), %ld left\n", cur.oid.inode, cur.oid.stripe, cur.version,
copy_count, has_writes, has_delete, flusher->flush_queue.size());
printf("Flushed %lu:%lu v%lu (%ld left)\n", cur.oid.inode, cur.oid.stripe, cur.version, flusher->flush_queue.size());
#endif
flusher->active_flushers--;
repeat_it = flusher->sync_to_repeat.find(cur.oid);
@ -540,16 +547,7 @@ bool journal_flusher_co::scan_dirty(int wait_base)
clean_init_bitmap = false;
while (1)
{
if (!IS_STABLE(dirty_it->second.state))
{
char err[1024];
snprintf(
err, 1024, "BUG: Unexpected dirty_entry %lx:%lx v%lu state during flush: %d",
dirty_it->first.oid.inode, dirty_it->first.oid.stripe, dirty_it->first.version, dirty_it->second.state
);
throw std::runtime_error(err);
}
else if (IS_JOURNAL(dirty_it->second.state) && !skip_copy)
if (dirty_it->second.state == ST_J_STABLE && !skip_copy)
{
// First we submit all reads
has_writes = true;
@ -567,18 +565,18 @@ bool journal_flusher_co::scan_dirty(int wait_base)
{
submit_offset = dirty_it->second.location + offset - dirty_it->second.offset;
submit_len = it == v.end() || it->offset >= end_offset ? end_offset-offset : it->offset-offset;
it = v.insert(it, (copy_buffer_t){ .offset = offset, .len = submit_len, .buf = memalign_or_die(MEM_ALIGNMENT, submit_len) });
it = v.insert(it, (copy_buffer_t){ .offset = offset, .len = submit_len, .buf = memalign(MEM_ALIGNMENT, submit_len) });
copy_count++;
if (bs->journal.inmemory)
{
// Take it from memory
memcpy(it->buf, bs->journal.buffer + submit_offset, submit_len);
memcpy(v.back().buf, bs->journal.buffer + submit_offset, submit_len);
}
else
{
// Read it from disk
await_sqe(0);
data->iov = (struct iovec){ it->buf, (size_t)submit_len };
data->iov = (struct iovec){ v.back().buf, (size_t)submit_len };
data->callback = simple_callback_r;
my_uring_prep_readv(
sqe, bs->journal.fd, &data->iov, 1, bs->journal.offset + submit_offset
@ -592,7 +590,7 @@ bool journal_flusher_co::scan_dirty(int wait_base)
}
}
}
else if (IS_BIG_WRITE(dirty_it->second.state) && !skip_copy)
else if (dirty_it->second.state == ST_D_STABLE && !skip_copy)
{
// There is an unflushed big write. Copy small writes in its position
has_writes = true;
@ -602,12 +600,21 @@ bool journal_flusher_co::scan_dirty(int wait_base)
clean_bitmap_len = dirty_it->second.len;
skip_copy = true;
}
else if (IS_DELETE(dirty_it->second.state) && !skip_copy)
else if (dirty_it->second.state == ST_DEL_STABLE && !skip_copy)
{
// There is an unflushed delete
has_delete = true;
skip_copy = true;
}
else if (!IS_STABLE(dirty_it->second.state))
{
char err[1024];
snprintf(
err, 1024, "BUG: Unexpected dirty_entry %lu:%lu v%lu state during flush: %d",
dirty_it->first.oid.inode, dirty_it->first.oid.stripe, dirty_it->first.version, dirty_it->second.state
);
throw std::runtime_error(err);
}
dirty_start = dirty_it;
if (dirty_it == bs->dirty_db.begin())
{
@ -643,7 +650,7 @@ bool journal_flusher_co::modify_meta_read(uint64_t meta_loc, flusher_meta_write_
if (wr.it == flusher->meta_sectors.end())
{
// Not in memory yet, read it
wr.buf = memalign_or_die(MEM_ALIGNMENT, bs->meta_block_size);
wr.buf = memalign(MEM_ALIGNMENT, bs->meta_block_size);
wr.it = flusher->meta_sectors.emplace(wr.sector, (meta_sector_t){
.offset = wr.sector,
.len = bs->meta_block_size,
@ -673,7 +680,7 @@ void journal_flusher_co::update_clean_db()
if (old_clean_loc != UINT64_MAX && old_clean_loc != clean_loc)
{
#ifdef BLOCKSTORE_DEBUG
printf("Free block %lu (new location is %lu)\n", old_clean_loc >> bs->block_order, clean_loc >> bs->block_order);
printf("Free block %lu\n", old_clean_loc >> bs->block_order);
#endif
bs->data_alloc->set(old_clean_loc >> bs->block_order, false);
}

3
blockstore_flush.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
struct copy_buffer_t
{
uint64_t offset, len;

159
blockstore_impl.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
blockstore_impl_t::blockstore_impl_t(blockstore_config_t & config, ring_loop_t *ringloop)
@ -10,7 +7,7 @@ blockstore_impl_t::blockstore_impl_t(blockstore_config_t & config, ring_loop_t *
ring_consumer.loop = [this]() { loop(); };
ringloop->register_consumer(&ring_consumer);
initialized = 0;
zero_object = (uint8_t*)memalign_or_die(MEM_ALIGNMENT, block_size);
zero_object = (uint8_t*)memalign(MEM_ALIGNMENT, block_size);
data_fd = meta_fd = journal.fd = -1;
parse_config(config);
try
@ -133,7 +130,7 @@ void blockstore_impl_t::loop()
}
else if (PRIV(op)->wait_for)
{
if (op->opcode == BS_OP_WRITE || op->opcode == BS_OP_WRITE_STABLE || op->opcode == BS_OP_DELETE)
if (op->opcode == BS_OP_WRITE || op->opcode == BS_OP_DELETE)
{
has_writes = 2;
}
@ -147,7 +144,7 @@ void blockstore_impl_t::loop()
{
dequeue_op = dequeue_read(op);
}
else if (op->opcode == BS_OP_WRITE || op->opcode == BS_OP_WRITE_STABLE)
else if (op->opcode == BS_OP_WRITE)
{
if (has_writes == 2)
{
@ -332,13 +329,13 @@ void blockstore_impl_t::check_wait(blockstore_op_t *op)
void blockstore_impl_t::enqueue_op(blockstore_op_t *op, bool first)
{
if (op->opcode < BS_OP_MIN || op->opcode > BS_OP_MAX ||
((op->opcode == BS_OP_READ || op->opcode == BS_OP_WRITE || op->opcode == BS_OP_WRITE_STABLE) && (
((op->opcode == BS_OP_READ || op->opcode == BS_OP_WRITE) && (
op->offset >= block_size ||
op->len > block_size-op->offset ||
(op->len % disk_alignment)
)) ||
readonly && op->opcode != BS_OP_READ && op->opcode != BS_OP_LIST ||
first && (op->opcode == BS_OP_WRITE || op->opcode == BS_OP_WRITE_STABLE))
first && op->opcode == BS_OP_WRITE)
{
// Basic verification not passed
op->retval = -EINVAL;
@ -383,7 +380,7 @@ void blockstore_impl_t::enqueue_op(blockstore_op_t *op, bool first)
}
};
}
if ((op->opcode == BS_OP_WRITE || op->opcode == BS_OP_WRITE_STABLE || op->opcode == BS_OP_DELETE) && !enqueue_write(op))
if ((op->opcode == BS_OP_WRITE || op->opcode == BS_OP_DELETE) && !enqueue_write(op))
{
std::function<void (blockstore_op_t*)>(op->callback)(op);
return;
@ -434,12 +431,10 @@ static bool replace_stable(object_id oid, uint64_t version, int search_start, in
void blockstore_impl_t::process_list(blockstore_op_t *op)
{
// Check PG
uint32_t list_pg = op->offset;
uint32_t pg_count = op->len;
uint64_t pg_stripe_size = op->oid.stripe;
uint64_t min_inode = op->oid.inode;
uint64_t max_inode = op->version;
// Check PG
if (pg_count != 0 && (pg_stripe_size < MIN_BLOCK_SIZE || list_pg >= pg_count))
{
op->retval = -EINVAL;
@ -455,122 +450,88 @@ void blockstore_impl_t::process_list(blockstore_op_t *op)
FINISH_OP(op);
return;
}
for (auto it = clean_db.begin(); it != clean_db.end(); it++)
{
auto clean_it = clean_db.begin(), clean_end = clean_db.end();
if ((min_inode != 0 || max_inode != 0) && min_inode <= max_inode)
if (!pg_count || ((it->first.inode + it->first.stripe / pg_stripe_size) % pg_count) == list_pg)
{
clean_it = clean_db.lower_bound({
.inode = min_inode,
.stripe = 0,
});
clean_end = clean_db.upper_bound({
.inode = max_inode,
.stripe = UINT64_MAX,
});
}
for (; clean_it != clean_end; clean_it++)
{
if (!pg_count || ((clean_it->first.inode + clean_it->first.stripe / pg_stripe_size) % pg_count) == list_pg)
if (stable_count >= stable_alloc)
{
if (stable_count >= stable_alloc)
stable_alloc += 32768;
stable = (obj_ver_id*)realloc(stable, sizeof(obj_ver_id) * stable_alloc);
if (!stable)
{
stable_alloc += 32768;
stable = (obj_ver_id*)realloc(stable, sizeof(obj_ver_id) * stable_alloc);
if (!stable)
{
op->retval = -ENOMEM;
FINISH_OP(op);
return;
}
op->retval = -ENOMEM;
FINISH_OP(op);
return;
}
stable[stable_count++] = {
.oid = clean_it->first,
.version = clean_it->second.version,
};
}
stable[stable_count++] = {
.oid = it->first,
.version = it->second.version,
};
}
}
int clean_stable_count = stable_count;
// Copy dirty_db entries (sorted, too)
int unstable_count = 0, unstable_alloc = 0;
obj_ver_id *unstable = NULL;
for (auto it = dirty_db.begin(); it != dirty_db.end(); it++)
{
auto dirty_it = dirty_db.begin(), dirty_end = dirty_db.end();
if ((min_inode != 0 || max_inode != 0) && min_inode <= max_inode)
if (!pg_count || ((it->first.oid.inode + it->first.oid.stripe / pg_stripe_size) % pg_count) == list_pg)
{
dirty_it = dirty_db.lower_bound({
.oid = {
.inode = min_inode,
.stripe = 0,
},
.version = 0,
});
dirty_end = dirty_db.upper_bound({
.oid = {
.inode = max_inode,
.stripe = UINT64_MAX,
},
.version = UINT64_MAX,
});
}
for (; dirty_it != dirty_end; dirty_it++)
{
if (!pg_count || ((dirty_it->first.oid.inode + dirty_it->first.oid.stripe / pg_stripe_size) % pg_count) == list_pg)
if (IS_DELETE(it->second.state))
{
if (IS_DELETE(dirty_it->second.state))
// Deletions are always stable, so try to zero out two possible entries
if (!replace_stable(it->first.oid, 0, 0, clean_stable_count, stable))
{
// Deletions are always stable, so try to zero out two possible entries
if (!replace_stable(dirty_it->first.oid, 0, 0, clean_stable_count, stable))
{
replace_stable(dirty_it->first.oid, 0, clean_stable_count, stable_count, stable);
}
replace_stable(it->first.oid, 0, clean_stable_count, stable_count, stable);
}
else if (IS_STABLE(dirty_it->second.state))
}
else if (IS_STABLE(it->second.state))
{
// First try to replace a clean stable version in the first part of the list
if (!replace_stable(it->first.oid, it->first.version, 0, clean_stable_count, stable))
{
// First try to replace a clean stable version in the first part of the list
if (!replace_stable(dirty_it->first.oid, dirty_it->first.version, 0, clean_stable_count, stable))
// Then try to replace the last dirty stable version in the second part of the list
if (stable[stable_count-1].oid == it->first.oid)
{
// Then try to replace the last dirty stable version in the second part of the list
if (stable[stable_count-1].oid == dirty_it->first.oid)
stable[stable_count-1].version = it->first.version;
}
else
{
if (stable_count >= stable_alloc)
{
stable[stable_count-1].version = dirty_it->first.version;
}
else
{
if (stable_count >= stable_alloc)
stable_alloc += 32768;
stable = (obj_ver_id*)realloc(stable, sizeof(obj_ver_id) * stable_alloc);
if (!stable)
{
stable_alloc += 32768;
stable = (obj_ver_id*)realloc(stable, sizeof(obj_ver_id) * stable_alloc);
if (!stable)
{
if (unstable)
free(unstable);
op->retval = -ENOMEM;
FINISH_OP(op);
return;
}
if (unstable)
free(unstable);
op->retval = -ENOMEM;
FINISH_OP(op);
return;
}
stable[stable_count++] = dirty_it->first;
}
stable[stable_count++] = it->first;
}
}
else
}
else
{
if (unstable_count >= unstable_alloc)
{
if (unstable_count >= unstable_alloc)
unstable_alloc += 32768;
unstable = (obj_ver_id*)realloc(unstable, sizeof(obj_ver_id) * unstable_alloc);
if (!unstable)
{
unstable_alloc += 32768;
unstable = (obj_ver_id*)realloc(unstable, sizeof(obj_ver_id) * unstable_alloc);
if (!unstable)
{
if (stable)
free(stable);
op->retval = -ENOMEM;
FINISH_OP(op);
return;
}
if (stable)
free(stable);
op->retval = -ENOMEM;
FINISH_OP(op);
return;
}
unstable[unstable_count++] = dirty_it->first;
}
unstable[unstable_count++] = it->first;
}
}
}

59
blockstore_impl.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#include "blockstore.h"
@ -10,6 +7,7 @@
#include <sys/stat.h>
#include <fcntl.h>
#include <unistd.h>
#include <malloc.h>
#include <linux/fs.h>
#include <vector>
@ -19,44 +17,56 @@
#include "cpp-btree/btree_map.h"
#include "malloc_or_die.h"
#include "allocator.h"
//#define BLOCKSTORE_DEBUG
// States are not stored on disk. Instead, they're deduced from the journal
// FIXME: Rename to BS_ST_*
#define BS_ST_SMALL_WRITE 0x01
#define BS_ST_BIG_WRITE 0x02
#define BS_ST_DELETE 0x03
#define ST_J_WAIT_BIG 1
#define ST_J_IN_FLIGHT 2
#define ST_J_SUBMITTED 3
#define ST_J_WRITTEN 4
#define ST_J_SYNCED 5
#define ST_J_STABLE 6
#define BS_ST_WAIT_BIG 0x10
#define BS_ST_IN_FLIGHT 0x20
#define BS_ST_SUBMITTED 0x30
#define BS_ST_WRITTEN 0x40
#define BS_ST_SYNCED 0x50
#define BS_ST_STABLE 0x60
#define ST_D_IN_FLIGHT 15
#define ST_D_SUBMITTED 16
#define ST_D_WRITTEN 17
#define ST_D_SYNCED 20
#define ST_D_STABLE 21
#define BS_ST_INSTANT 0x100
#define ST_DEL_IN_FLIGHT 31
#define ST_DEL_SUBMITTED 32
#define ST_DEL_WRITTEN 33
#define ST_DEL_SYNCED 34
#define ST_DEL_STABLE 35
#define ST_CURRENT 48
#define IMMEDIATE_NONE 0
#define IMMEDIATE_SMALL 1
#define IMMEDIATE_ALL 2
#define BS_ST_TYPE_MASK 0x0F
#define BS_ST_WORKFLOW_MASK 0xF0
#define IS_IN_FLIGHT(st) (((st) & 0xF0) <= BS_ST_SUBMITTED)
#define IS_STABLE(st) (((st) & 0xF0) == BS_ST_STABLE)
#define IS_SYNCED(st) (((st) & 0xF0) >= BS_ST_SYNCED)
#define IS_JOURNAL(st) (((st) & 0x0F) == BS_ST_SMALL_WRITE)
#define IS_BIG_WRITE(st) (((st) & 0x0F) == BS_ST_BIG_WRITE)
#define IS_DELETE(st) (((st) & 0x0F) == BS_ST_DELETE)
#define IS_IN_FLIGHT(st) (st == ST_J_WAIT_BIG || st == ST_J_IN_FLIGHT || st == ST_D_IN_FLIGHT || st == ST_DEL_IN_FLIGHT || st == ST_J_SUBMITTED || st == ST_D_SUBMITTED || st == ST_DEL_SUBMITTED)
#define IS_STABLE(st) (st == ST_J_STABLE || st == ST_D_STABLE || st == ST_DEL_STABLE || st == ST_CURRENT)
#define IS_SYNCED(st) (IS_STABLE(st) || st == ST_J_SYNCED || st == ST_D_SYNCED || st == ST_DEL_SYNCED)
#define IS_JOURNAL(st) (st >= ST_J_WAIT_BIG && st <= ST_J_STABLE)
#define IS_BIG_WRITE(st) (st >= ST_D_IN_FLIGHT && st <= ST_D_STABLE)
#define IS_DELETE(st) (st >= ST_DEL_IN_FLIGHT && st <= ST_DEL_STABLE)
#define IS_UNSYNCED(st) (st >= ST_J_WAIT_BIG && st <= ST_J_WRITTEN || st >= ST_D_IN_FLIGHT && st <= ST_D_WRITTEN|| st >= ST_DEL_IN_FLIGHT && st <= ST_DEL_WRITTEN)
#define BS_SUBMIT_GET_SQE(sqe, data) \
BS_SUBMIT_GET_ONLY_SQE(sqe); \
struct ring_data_t *data = ((ring_data_t*)sqe->user_data)
#define BS_SUBMIT_GET_ONLY_SQE(sqe) \
{\
timespec now;\
clock_gettime(CLOCK_REALTIME, &now);\
printf("get_sqe %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);\
}\
struct io_uring_sqe *sqe = get_sqe();\
if (!sqe)\
{\
@ -66,6 +76,11 @@
}
#define BS_SUBMIT_GET_SQE_DECL(sqe) \
{\
timespec now;\
clock_gettime(CLOCK_REALTIME, &now);\
printf("get_sqe %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);\
}\
sqe = get_sqe();\
if (!sqe)\
{\

56
blockstore_init.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
blockstore_init_meta::blockstore_init_meta(blockstore_impl_t *bs)
@ -111,13 +108,13 @@ void blockstore_init_meta::handle_entries(void* entries, unsigned count, int blo
{
// free the previous block
#ifdef BLOCKSTORE_DEBUG
printf("Free block %lu (new location is %lu)\n", clean_it->second.location >> block_order, done_cnt+i >> block_order);
printf("Free block %lu\n", clean_it->second.location >> bs->block_order);
#endif
bs->data_alloc->set(clean_it->second.location >> block_order, false);
}
entries_loaded++;
#ifdef BLOCKSTORE_DEBUG
printf("Allocate block (clean entry) %lu: %lx:%lx v%lu\n", done_cnt+i, entry->oid.inode, entry->oid.stripe, entry->version);
printf("Allocate block (clean entry) %lu: %lu:%lu v%lu\n", done_cnt+i, entry->oid.inode, entry->oid.stripe, entry->version);
#endif
bs->data_alloc->set(done_cnt+i, true);
bs->clean_db[entry->oid] = (struct clean_entry){
@ -128,7 +125,7 @@ void blockstore_init_meta::handle_entries(void* entries, unsigned count, int blo
else
{
#ifdef BLOCKSTORE_DEBUG
printf("Old clean entry %lu: %lx:%lx v%lu\n", done_cnt+i, entry->oid.inode, entry->oid.stripe, entry->version);
printf("Old clean entry %lu: %lu:%lu v%lu\n", done_cnt+i, entry->oid.inode, entry->oid.stripe, entry->version);
#endif
}
}
@ -205,7 +202,11 @@ int blockstore_init_journal::loop()
goto resume_7;
printf("Reading blockstore journal\n");
if (!bs->journal.inmemory)
submitted_buf = memalign_or_die(MEM_ALIGNMENT, 2*bs->journal.block_size);
{
submitted_buf = memalign(MEM_ALIGNMENT, 2*bs->journal.block_size);
if (!submitted_buf)
throw std::bad_alloc();
}
else
submitted_buf = bs->journal.buffer;
// Read first block of the journal
@ -316,7 +317,7 @@ resume_1:
if (journal_pos < bs->journal.used_start)
end = bs->journal.used_start;
if (!bs->journal.inmemory)
submitted_buf = memalign_or_die(MEM_ALIGNMENT, JOURNAL_BUFFER_SIZE);
submitted_buf = memalign(MEM_ALIGNMENT, JOURNAL_BUFFER_SIZE);
else
submitted_buf = bs->journal.buffer + journal_pos;
data->iov = {
@ -453,15 +454,10 @@ int blockstore_init_journal::handle_journal_part(void *buf, uint64_t done_pos, u
break;
}
}
if (je->type == JE_SMALL_WRITE || je->type == JE_SMALL_WRITE_INSTANT)
if (je->type == JE_SMALL_WRITE)
{
#ifdef BLOCKSTORE_DEBUG
printf(
"je_small_write%s oid=%lx:%lx ver=%lu offset=%u len=%u\n",
je->type == JE_SMALL_WRITE_INSTANT ? "_instant" : "",
je->small_write.oid.inode, je->small_write.oid.stripe, je->small_write.version,
je->small_write.offset, je->small_write.len
);
printf("je_small_write oid=%lu:%lu ver=%lu offset=%u len=%u\n", je->small_write.oid.inode, je->small_write.oid.stripe, je->small_write.version, je->small_write.offset, je->small_write.len);
#endif
// oid, version, offset, len
uint64_t prev_free = next_free;
@ -532,7 +528,7 @@ int blockstore_init_journal::handle_journal_part(void *buf, uint64_t done_pos, u
.version = je->small_write.version,
};
bs->dirty_db.emplace(ov, (dirty_entry){
.state = (BS_ST_SMALL_WRITE | BS_ST_SYNCED),
.state = ST_J_SYNCED,
.flags = 0,
.location = location,
.offset = je->small_write.offset,
@ -542,26 +538,18 @@ int blockstore_init_journal::handle_journal_part(void *buf, uint64_t done_pos, u
bs->journal.used_sectors[proc_pos]++;
#ifdef BLOCKSTORE_DEBUG
printf(
"journal offset %08lx is used by %lx:%lx v%lu (%lu refs)\n",
"journal offset %08lx is used by %lu:%lu v%lu (%lu refs)\n",
proc_pos, ov.oid.inode, ov.oid.stripe, ov.version, bs->journal.used_sectors[proc_pos]
);
#endif
auto & unstab = bs->unstable_writes[ov.oid];
unstab = unstab < ov.version ? ov.version : unstab;
if (je->type == JE_SMALL_WRITE_INSTANT)
{
bs->mark_stable(ov);
}
}
}
else if (je->type == JE_BIG_WRITE || je->type == JE_BIG_WRITE_INSTANT)
else if (je->type == JE_BIG_WRITE)
{
#ifdef BLOCKSTORE_DEBUG
printf(
"je_big_write%s oid=%lx:%lx ver=%lu loc=%lu\n",
je->type == JE_BIG_WRITE_INSTANT ? "_instant" : "",
je->big_write.oid.inode, je->big_write.oid.stripe, je->big_write.version, je->big_write.location
);
printf("je_big_write oid=%lu:%lu ver=%lu loc=%lu\n", je->big_write.oid.inode, je->big_write.oid.stripe, je->big_write.version, je->big_write.location);
#endif
auto clean_it = bs->clean_db.find(je->big_write.oid);
if (clean_it == bs->clean_db.end() ||
@ -573,7 +561,7 @@ int blockstore_init_journal::handle_journal_part(void *buf, uint64_t done_pos, u
.version = je->big_write.version,
};
bs->dirty_db.emplace(ov, (dirty_entry){
.state = (BS_ST_BIG_WRITE | BS_ST_SYNCED),
.state = ST_D_SYNCED,
.flags = 0,
.location = je->big_write.location,
.offset = je->big_write.offset,
@ -587,16 +575,12 @@ int blockstore_init_journal::handle_journal_part(void *buf, uint64_t done_pos, u
bs->journal.used_sectors[proc_pos]++;
auto & unstab = bs->unstable_writes[ov.oid];
unstab = unstab < ov.version ? ov.version : unstab;
if (je->type == JE_BIG_WRITE_INSTANT)
{
bs->mark_stable(ov);
}
}
}
else if (je->type == JE_STABLE)
{
#ifdef BLOCKSTORE_DEBUG
printf("je_stable oid=%lx:%lx ver=%lu\n", je->stable.oid.inode, je->stable.oid.stripe, je->stable.version);
printf("je_stable oid=%lu:%lu ver=%lu\n", je->stable.oid.inode, je->stable.oid.stripe, je->stable.version);
#endif
// oid, version
obj_ver_id ov = {
@ -608,7 +592,7 @@ int blockstore_init_journal::handle_journal_part(void *buf, uint64_t done_pos, u
else if (je->type == JE_ROLLBACK)
{
#ifdef BLOCKSTORE_DEBUG
printf("je_rollback oid=%lx:%lx ver=%lu\n", je->rollback.oid.inode, je->rollback.oid.stripe, je->rollback.version);
printf("je_rollback oid=%lu:%lu ver=%lu\n", je->rollback.oid.inode, je->rollback.oid.stripe, je->rollback.version);
#endif
// rollback dirty writes of <oid> up to <version>
obj_ver_id ov = {
@ -620,7 +604,7 @@ int blockstore_init_journal::handle_journal_part(void *buf, uint64_t done_pos, u
else if (je->type == JE_DELETE)
{
#ifdef BLOCKSTORE_DEBUG
printf("je_delete oid=%lx:%lx ver=%lu\n", je->del.oid.inode, je->del.oid.stripe, je->del.version);
printf("je_delete oid=%lu:%lu ver=%lu\n", je->del.oid.inode, je->del.oid.stripe, je->del.version);
#endif
auto clean_it = bs->clean_db.find(je->del.oid);
if (clean_it == bs->clean_db.end() ||
@ -632,7 +616,7 @@ int blockstore_init_journal::handle_journal_part(void *buf, uint64_t done_pos, u
.version = je->del.version,
};
bs->dirty_db.emplace(ov, (dirty_entry){
.state = (BS_ST_DELETE | BS_ST_SYNCED),
.state = ST_DEL_SYNCED,
.flags = 0,
.location = 0,
.offset = 0,

3
blockstore_init.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
class blockstore_init_meta

12
blockstore_journal.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
blockstore_journal_check_t::blockstore_journal_check_t(blockstore_impl_t *bs)
@ -20,9 +17,7 @@ int blockstore_journal_check_t::check_available(blockstore_op_t *op, int entries
int required = entries_required;
while (1)
{
int fits = bs->journal.no_same_sector_overwrites && bs->journal.sector_info[next_sector].written
? 0
: (bs->journal.block_size - next_in_pos) / size;
int fits = (bs->journal.block_size - next_in_pos) / size;
if (fits > 0)
{
if (first_sector == -1)
@ -115,12 +110,10 @@ int blockstore_journal_check_t::check_available(blockstore_op_t *op, int entries
journal_entry* prefill_single_journal_entry(journal_t & journal, uint16_t type, uint32_t size)
{
if (journal.block_size - journal.in_sector_pos < size ||
journal.no_same_sector_overwrites && journal.sector_info[journal.cur_sector].written)
if (journal.block_size - journal.in_sector_pos < size)
{
assert(!journal.sector_info[journal.cur_sector].dirty);
// Move to the next journal sector
journal.sector_info[journal.cur_sector].written = false;
if (journal.sector_info[journal.cur_sector].usage_count > 0)
{
// Also select next sector buffer in memory
@ -155,7 +148,6 @@ journal_entry* prefill_single_journal_entry(journal_t & journal, uint16_t type,
void prepare_journal_sector_write(journal_t & journal, int cur_sector, io_uring_sqe *sqe, std::function<void(ring_data_t*)> cb)
{
journal.sector_info[cur_sector].dirty = false;
journal.sector_info[cur_sector].written = true;
journal.sector_info[cur_sector].usage_count++;
ring_data_t *data = ((ring_data_t*)sqe->user_data);
data->iov = (struct iovec){

9
blockstore_journal.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#include "crc32c.h"
@ -22,9 +19,7 @@
#define JE_STABLE 0x04
#define JE_DELETE 0x05
#define JE_ROLLBACK 0x06
#define JE_SMALL_WRITE_INSTANT 0x07
#define JE_BIG_WRITE_INSTANT 0x08
#define JE_MAX 0x08
#define JE_MAX 0x06
// crc32c comes first to ease calculation and is equal to crc32()
struct __attribute__((__packed__)) journal_entry_start
@ -132,7 +127,6 @@ struct journal_sector_info_t
{
uint64_t offset;
uint64_t usage_count;
bool written;
bool dirty;
};
@ -157,7 +151,6 @@ struct journal_t
void *sector_buf = NULL;
journal_sector_info_t *sector_info = NULL;
uint64_t sector_count;
bool no_same_sector_overwrites = false;
int cur_sector = 0;
int in_sector_pos = 0;

5
blockstore_open.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <sys/file.h>
#include "blockstore_impl.h"
@ -62,8 +59,6 @@ void blockstore_impl_t::parse_config(blockstore_config_t & config)
journal_device = config["journal_device"];
journal.offset = strtoull(config["journal_offset"].c_str(), NULL, 10);
journal.sector_count = strtoull(config["journal_sector_buffer_count"].c_str(), NULL, 10);
journal.no_same_sector_overwrites = config["journal_no_same_sector_overwrites"] == "true" ||
config["journal_no_same_sector_overwrites"] == "1" || config["journal_no_same_sector_overwrites"] == "yes";
journal.inmemory = config["inmemory_journal"] != "false";
disk_alignment = strtoull(config["disk_alignment"].c_str(), NULL, 10);
journal_block_size = strtoull(config["journal_block_size"].c_str(), NULL, 10);

28
blockstore_read.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
int blockstore_impl_t::fulfill_read_push(blockstore_op_t *op, void *buf, uint64_t offset, uint64_t len,
@ -40,7 +37,6 @@ int blockstore_impl_t::fulfill_read_push(blockstore_op_t *op, void *buf, uint64_
return 1;
}
// FIXME I've seen a bug here so I want some tests
int blockstore_impl_t::fulfill_read(blockstore_op_t *read_op, uint64_t &fulfilled, uint32_t item_start, uint32_t item_end,
uint32_t item_state, uint64_t item_version, uint64_t item_location)
{
@ -53,20 +49,8 @@ int blockstore_impl_t::fulfill_read(blockstore_op_t *read_op, uint64_t &fulfille
while (1)
{
for (; it != PRIV(read_op)->read_vec.end(); it++)
{
if (it->offset >= cur_start)
{
break;
}
else if (it->offset + it->len > cur_start)
{
cur_start = it->offset + it->len;
if (cur_start >= item_end)
{
goto endwhile;
}
}
}
if (it == PRIV(read_op)->read_vec.end() || it->offset > cur_start)
{
fulfill_read_t el = {
@ -85,12 +69,9 @@ int blockstore_impl_t::fulfill_read(blockstore_op_t *read_op, uint64_t &fulfille
}
cur_start = it->offset + it->len;
if (it == PRIV(read_op)->read_vec.end() || cur_start >= item_end)
{
break;
}
}
}
endwhile:
return 1;
}
@ -160,7 +141,7 @@ int blockstore_impl_t::dequeue_read(blockstore_op_t *read_op)
{
if (!clean_entry_bitmap_size)
{
if (!fulfill_read(read_op, fulfilled, 0, block_size, (BS_ST_BIG_WRITE | BS_ST_STABLE), 0, clean_it->second.location))
if (!fulfill_read(read_op, fulfilled, 0, block_size, ST_CURRENT, 0, clean_it->second.location))
{
// need to wait. undo added requests, don't dequeue op
PRIV(read_op)->read_vec.clear();
@ -192,7 +173,7 @@ int blockstore_impl_t::dequeue_read(blockstore_op_t *read_op)
{
// fill with zeroes
fulfill_read(read_op, fulfilled, bmp_start * bitmap_granularity,
bmp_end * bitmap_granularity, (BS_ST_DELETE | BS_ST_STABLE), 0, 0);
bmp_end * bitmap_granularity, ST_DEL_STABLE, 0, 0);
}
bmp_start = bmp_end;
while (clean_entry_bitmap[bmp_end >> 3] & (1 << (bmp_end & 0x7)) && bmp_end < bmp_size)
@ -202,8 +183,7 @@ int blockstore_impl_t::dequeue_read(blockstore_op_t *read_op)
if (bmp_end > bmp_start)
{
if (!fulfill_read(read_op, fulfilled, bmp_start * bitmap_granularity,
bmp_end * bitmap_granularity, (BS_ST_BIG_WRITE | BS_ST_STABLE), 0,
clean_it->second.location + bmp_start * bitmap_granularity))
bmp_end * bitmap_granularity, ST_CURRENT, 0, clean_it->second.location + bmp_start * bitmap_granularity))
{
// need to wait. undo added requests, don't dequeue op
PRIV(read_op)->read_vec.clear();
@ -218,7 +198,7 @@ int blockstore_impl_t::dequeue_read(blockstore_op_t *read_op)
else if (fulfilled < read_op->len)
{
// fill remaining parts with zeroes
fulfill_read(read_op, fulfilled, 0, block_size, (BS_ST_DELETE | BS_ST_STABLE), 0, 0);
fulfill_read(read_op, fulfilled, 0, block_size, ST_DEL_STABLE, 0, 0);
}
assert(fulfilled == read_op->len);
read_op->version = result_version;

5
blockstore_rollback.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
int blockstore_impl_t::dequeue_rollback(blockstore_op_t *op)
@ -233,7 +230,7 @@ void blockstore_impl_t::erase_dirty(blockstore_dirty_db_t::iterator dirty_start,
int used = --journal.used_sectors[dirty_it->second.journal_sector];
#ifdef BLOCKSTORE_DEBUG
printf(
"remove usage of journal offset %08lx by %lx:%lx v%lu (%d refs)\n", dirty_it->second.journal_sector,
"remove usage of journal offset %08lx by %lu:%lu v%lu (%d refs)\n", dirty_it->second.journal_sector,
dirty_it->first.oid.inode, dirty_it->first.oid.stripe, dirty_it->first.version, used
);
#endif

29
blockstore_stable.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
// Stabilize small write:
@ -67,7 +64,7 @@ int blockstore_impl_t::dequeue_stable(blockstore_op_t *op)
// Already stable
}
}
else if (!IS_SYNCED(dirty_it->second.state))
else if (IS_UNSYNCED(dirty_it->second.state))
{
// Object not synced yet. Caller must sync it first
op->retval = -EBUSY;
@ -150,6 +147,11 @@ resume_2:
resume_3:
if (!disable_journal_fsync)
{
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("get_sqe %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
io_uring_sqe *sqe = get_sqe();
if (!sqe)
{
@ -187,9 +189,17 @@ void blockstore_impl_t::mark_stable(const obj_ver_id & v)
{
while (1)
{
if ((dirty_it->second.state & BS_ST_WORKFLOW_MASK) == BS_ST_SYNCED)
if (dirty_it->second.state == ST_J_SYNCED)
{
dirty_it->second.state = (dirty_it->second.state & ~BS_ST_WORKFLOW_MASK) | BS_ST_STABLE;
dirty_it->second.state = ST_J_STABLE;
}
else if (dirty_it->second.state == ST_D_SYNCED)
{
dirty_it->second.state = ST_D_STABLE;
}
else if (dirty_it->second.state == ST_DEL_SYNCED)
{
dirty_it->second.state = ST_DEL_STABLE;
}
else if (IS_STABLE(dirty_it->second.state))
{
@ -206,7 +216,7 @@ void blockstore_impl_t::mark_stable(const obj_ver_id & v)
}
}
#ifdef BLOCKSTORE_DEBUG
printf("enqueue_flush %lx:%lx v%lu\n", v.oid.inode, v.oid.stripe, v.version);
printf("enqueue_flush %lu:%lu v%lu\n", v.oid.inode, v.oid.stripe, v.version);
#endif
flusher->enqueue_flush(v);
}
@ -232,6 +242,11 @@ void blockstore_impl_t::handle_stable_event(ring_data_t *data, blockstore_op_t *
PRIV(op)->pending_ops--;
if (PRIV(op)->pending_ops == 0)
{
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("finished %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
PRIV(op)->op_state++;
if (!continue_stable(op))
{

37
blockstore_sync.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
#define SYNC_HAS_SMALL 1
@ -130,16 +127,14 @@ int blockstore_impl_t::continue_sync(blockstore_op_t *op)
}
while (it != PRIV(op)->sync_big_writes.end())
{
journal_entry_big_write *je = (journal_entry_big_write*)prefill_single_journal_entry(
journal, (dirty_db[*it].state & BS_ST_INSTANT) ? JE_BIG_WRITE_INSTANT : JE_BIG_WRITE,
sizeof(journal_entry_big_write)
);
journal_entry_big_write *je = (journal_entry_big_write*)
prefill_single_journal_entry(journal, JE_BIG_WRITE, sizeof(journal_entry_big_write));
dirty_db[*it].journal_sector = journal.sector_info[journal.cur_sector].offset;
journal.sector_info[journal.cur_sector].dirty = false;
journal.used_sectors[journal.sector_info[journal.cur_sector].offset]++;
#ifdef BLOCKSTORE_DEBUG
printf(
"journal offset %08lx is used by %lx:%lx v%lu (%lu refs)\n",
"journal offset %08lx is used by %lu:%lu v%lu (%lu refs)\n",
dirty_db[*it].journal_sector, it->oid.inode, it->oid.stripe, it->version,
journal.used_sectors[journal.sector_info[journal.cur_sector].offset]
);
@ -257,22 +252,18 @@ void blockstore_impl_t::ack_one_sync(blockstore_op_t *op)
for (auto it = PRIV(op)->sync_big_writes.begin(); it != PRIV(op)->sync_big_writes.end(); it++)
{
#ifdef BLOCKSTORE_DEBUG
printf("Ack sync big %lx:%lx v%lu\n", it->oid.inode, it->oid.stripe, it->version);
printf("Ack sync big %lu:%lu v%lu\n", it->oid.inode, it->oid.stripe, it->version);
#endif
auto & unstab = unstable_writes[it->oid];
unstab = unstab < it->version ? it->version : unstab;
auto dirty_it = dirty_db.find(*it);
dirty_it->second.state = ((dirty_it->second.state & ~BS_ST_WORKFLOW_MASK) | BS_ST_SYNCED);
if (dirty_it->second.state & BS_ST_INSTANT)
{
mark_stable(dirty_it->first);
}
dirty_it->second.state = ST_D_SYNCED;
dirty_it++;
while (dirty_it != dirty_db.end() && dirty_it->first.oid == it->oid)
{
if ((dirty_it->second.state & BS_ST_WORKFLOW_MASK) == BS_ST_WAIT_BIG)
if (dirty_it->second.state == ST_J_WAIT_BIG)
{
dirty_it->second.state = (dirty_it->second.state & ~BS_ST_WORKFLOW_MASK) | BS_ST_IN_FLIGHT;
dirty_it->second.state = ST_J_IN_FLIGHT;
}
dirty_it++;
}
@ -280,23 +271,19 @@ void blockstore_impl_t::ack_one_sync(blockstore_op_t *op)
for (auto it = PRIV(op)->sync_small_writes.begin(); it != PRIV(op)->sync_small_writes.end(); it++)
{
#ifdef BLOCKSTORE_DEBUG
printf("Ack sync small %lx:%lx v%lu\n", it->oid.inode, it->oid.stripe, it->version);
printf("Ack sync small %lu:%lu v%lu\n", it->oid.inode, it->oid.stripe, it->version);
#endif
auto & unstab = unstable_writes[it->oid];
unstab = unstab < it->version ? it->version : unstab;
if (dirty_db[*it].state == (BS_ST_DELETE | BS_ST_WRITTEN))
if (dirty_db[*it].state == ST_DEL_WRITTEN)
{
dirty_db[*it].state = (BS_ST_DELETE | BS_ST_SYNCED);
dirty_db[*it].state = ST_DEL_SYNCED;
// Deletions are treated as immediately stable
mark_stable(*it);
}
else /* (BS_ST_INSTANT?) | BS_ST_SMALL_WRITE | BS_ST_WRITTEN */
else /* == ST_J_WRITTEN */
{
dirty_db[*it].state = (dirty_db[*it].state & ~BS_ST_WORKFLOW_MASK) | BS_ST_SYNCED;
if (dirty_db[*it].state & BS_ST_INSTANT)
{
mark_stable(*it);
}
dirty_db[*it].state = ST_J_SYNCED;
}
}
in_progress_syncs.erase(PRIV(op)->in_progress_ptr);

92
blockstore_write.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "blockstore_impl.h"
bool blockstore_impl_t::enqueue_write(blockstore_op_t *op)
@ -21,9 +18,9 @@ bool blockstore_impl_t::enqueue_write(blockstore_op_t *op)
found = true;
version = dirty_it->first.version + 1;
deleted = IS_DELETE(dirty_it->second.state);
is_inflight_big = (dirty_it->second.state & BS_ST_TYPE_MASK) == BS_ST_BIG_WRITE
? !IS_SYNCED(dirty_it->second.state)
: ((dirty_it->second.state & BS_ST_WORKFLOW_MASK) == BS_ST_WAIT_BIG);
is_inflight_big = dirty_it->second.state >= ST_D_IN_FLIGHT &&
dirty_it->second.state < ST_D_SYNCED ||
dirty_it->second.state == ST_J_WAIT_BIG;
}
}
if (!found)
@ -68,9 +65,9 @@ bool blockstore_impl_t::enqueue_write(blockstore_op_t *op)
}
#ifdef BLOCKSTORE_DEBUG
if (is_del)
printf("Delete %lx:%lx v%lu\n", op->oid.inode, op->oid.stripe, op->version);
printf("Delete %lu:%lu v%lu\n", op->oid.inode, op->oid.stripe, op->version);
else
printf("Write %lx:%lx v%lu offset=%u len=%u\n", op->oid.inode, op->oid.stripe, op->version, op->offset, op->len);
printf("Write %lu:%lu v%lu offset=%u len=%u\n", op->oid.inode, op->oid.stripe, op->version, op->offset, op->len);
#endif
// No strict need to add it into dirty_db here, it's just left
// from the previous implementation where reads waited for writes
@ -80,10 +77,8 @@ bool blockstore_impl_t::enqueue_write(blockstore_op_t *op)
}, (dirty_entry){
.state = (uint32_t)(
is_del
? (BS_ST_DELETE | BS_ST_IN_FLIGHT)
: (op->opcode == BS_OP_WRITE_STABLE ? BS_ST_INSTANT : 0) | (op->len == block_size || deleted
? (BS_ST_BIG_WRITE | BS_ST_IN_FLIGHT)
: (is_inflight_big ? (BS_ST_SMALL_WRITE | BS_ST_WAIT_BIG) : (BS_ST_SMALL_WRITE | BS_ST_IN_FLIGHT)))
? ST_DEL_IN_FLIGHT
: (op->len == block_size || deleted ? ST_D_IN_FLIGHT : (is_inflight_big ? ST_J_WAIT_BIG : ST_J_IN_FLIGHT))
),
.flags = 0,
.location = 0,
@ -106,12 +101,11 @@ int blockstore_impl_t::dequeue_write(blockstore_op_t *op)
.version = op->version,
});
assert(dirty_it != dirty_db.end());
if ((dirty_it->second.state & BS_ST_WORKFLOW_MASK) == BS_ST_WAIT_BIG)
if (dirty_it->second.state == ST_J_WAIT_BIG)
{
// Don't dequeue
return 0;
}
else if ((dirty_it->second.state & BS_ST_TYPE_MASK) == BS_ST_BIG_WRITE)
else if (dirty_it->second.state == ST_D_IN_FLIGHT)
{
blockstore_journal_check_t space_check(this);
if (!space_check.check_available(op, unsynced_big_writes.size() + 1, sizeof(journal_entry_big_write), JOURNAL_STABILIZE_RESERVATION))
@ -135,7 +129,7 @@ int blockstore_impl_t::dequeue_write(blockstore_op_t *op)
}
BS_SUBMIT_GET_SQE(sqe, data);
dirty_it->second.location = loc << block_order;
dirty_it->second.state = (dirty_it->second.state & ~BS_ST_WORKFLOW_MASK) | BS_ST_SUBMITTED;
dirty_it->second.state = ST_D_SUBMITTED;
#ifdef BLOCKSTORE_DEBUG
printf("Allocate block %lu\n", loc);
#endif
@ -175,7 +169,7 @@ int blockstore_impl_t::dequeue_write(blockstore_op_t *op)
PRIV(op)->op_state = 1;
}
}
else /* if ((dirty_it->second.state & BS_ST_TYPE_MASK) == BS_ST_SMALL_WRITE) */
else
{
// Small (journaled) write
// First check if the journal has sufficient space
@ -215,15 +209,13 @@ int blockstore_impl_t::dequeue_write(blockstore_op_t *op)
}
}
// Then pre-fill journal entry
journal_entry_small_write *je = (journal_entry_small_write*)prefill_single_journal_entry(
journal, op->opcode == BS_OP_WRITE_STABLE ? JE_SMALL_WRITE_INSTANT : JE_SMALL_WRITE,
sizeof(journal_entry_small_write)
);
journal_entry_small_write *je = (journal_entry_small_write*)
prefill_single_journal_entry(journal, JE_SMALL_WRITE, sizeof(journal_entry_small_write));
dirty_it->second.journal_sector = journal.sector_info[journal.cur_sector].offset;
journal.used_sectors[journal.sector_info[journal.cur_sector].offset]++;
#ifdef BLOCKSTORE_DEBUG
printf(
"journal offset %08lx is used by %lx:%lx v%lu (%lu refs)\n",
"journal offset %08lx is used by %lu:%lu v%lu (%lu refs)\n",
dirty_it->second.journal_sector, dirty_it->first.oid.inode, dirty_it->first.oid.stripe, dirty_it->first.version,
journal.used_sectors[journal.sector_info[journal.cur_sector].offset]
);
@ -265,7 +257,7 @@ int blockstore_impl_t::dequeue_write(blockstore_op_t *op)
// Zero-length overwrite. Allowed to bump object version in EC placement groups without actually writing data
}
dirty_it->second.location = journal.next_free;
dirty_it->second.state = (dirty_it->second.state & ~BS_ST_WORKFLOW_MASK) | BS_ST_SUBMITTED;
dirty_it->second.state = ST_J_SUBMITTED;
journal.next_free += op->len;
if (journal.next_free >= journal.len)
{
@ -310,21 +302,23 @@ int blockstore_impl_t::continue_write(blockstore_op_t *op)
return 1;
resume_2:
// Only for the immediate_commit mode: prepare and submit big_write journal entry
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("get_sqe %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
sqe = get_sqe();
if (!sqe)
{
return 0;
}
je = (journal_entry_big_write*)prefill_single_journal_entry(
journal, op->opcode == BS_OP_WRITE_STABLE ? JE_BIG_WRITE_INSTANT : JE_BIG_WRITE,
sizeof(journal_entry_big_write)
);
je = (journal_entry_big_write*)prefill_single_journal_entry(journal, JE_BIG_WRITE, sizeof(journal_entry_big_write));
dirty_it->second.journal_sector = journal.sector_info[journal.cur_sector].offset;
journal.sector_info[journal.cur_sector].dirty = false;
journal.used_sectors[journal.sector_info[journal.cur_sector].offset]++;
#ifdef BLOCKSTORE_DEBUG
printf(
"journal offset %08lx is used by %lx:%lx v%lu (%lu refs)\n",
"journal offset %08lx is used by %lu:%lu v%lu (%lu refs)\n",
journal.sector_info[journal.cur_sector].offset, op->oid.inode, op->oid.stripe, op->version,
journal.used_sectors[journal.sector_info[journal.cur_sector].offset]
);
@ -344,10 +338,15 @@ resume_2:
return 1;
resume_4:
// Switch object state
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("write_done %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
#ifdef BLOCKSTORE_DEBUG
printf("Ack write %lx:%lx v%lu = %d\n", op->oid.inode, op->oid.stripe, op->version, dirty_it->second.state);
printf("Ack write %lu:%lu v%lu = %d\n", op->oid.inode, op->oid.stripe, op->version, dirty_it->second.state);
#endif
bool imm = (dirty_it->second.state & BS_ST_TYPE_MASK) == BS_ST_BIG_WRITE
bool imm = dirty_it->second.state == ST_D_SUBMITTED
? (immediate_commit == IMMEDIATE_ALL)
: (immediate_commit != IMMEDIATE_NONE);
if (imm)
@ -355,21 +354,31 @@ resume_4:
auto & unstab = unstable_writes[op->oid];
unstab = unstab < op->version ? op->version : unstab;
}
dirty_it->second.state = (dirty_it->second.state & ~BS_ST_WORKFLOW_MASK)
| (imm ? BS_ST_SYNCED : BS_ST_WRITTEN);
if (imm && ((dirty_it->second.state & BS_ST_TYPE_MASK) == BS_ST_DELETE || (dirty_it->second.state & BS_ST_INSTANT)))
if (dirty_it->second.state == ST_J_SUBMITTED)
{
// Deletions are treated as immediately stable
mark_stable(dirty_it->first);
dirty_it->second.state = imm ? ST_J_SYNCED : ST_J_WRITTEN;
}
else if (dirty_it->second.state == ST_D_SUBMITTED)
{
dirty_it->second.state = imm ? ST_D_SYNCED : ST_D_WRITTEN;
}
else if (dirty_it->second.state == ST_DEL_SUBMITTED)
{
dirty_it->second.state = imm ? ST_DEL_SYNCED : ST_DEL_WRITTEN;
if (imm)
{
// Deletions are treated as immediately stable
mark_stable(dirty_it->first);
}
}
if (immediate_commit == IMMEDIATE_ALL)
{
dirty_it++;
while (dirty_it != dirty_db.end() && dirty_it->first.oid == op->oid)
{
if ((dirty_it->second.state & BS_ST_WORKFLOW_MASK) == BS_ST_WAIT_BIG)
if (dirty_it->second.state == ST_J_WAIT_BIG)
{
dirty_it->second.state = (dirty_it->second.state & ~BS_ST_WORKFLOW_MASK) | BS_ST_IN_FLIGHT;
dirty_it->second.state = ST_J_IN_FLIGHT;
}
dirty_it++;
}
@ -473,14 +482,13 @@ int blockstore_impl_t::dequeue_del(blockstore_op_t *op)
}
}
// Pre-fill journal entry
journal_entry_del *je = (journal_entry_del*)prefill_single_journal_entry(
journal, JE_DELETE, sizeof(struct journal_entry_del)
);
journal_entry_del *je = (journal_entry_del*)
prefill_single_journal_entry(journal, JE_DELETE, sizeof(struct journal_entry_del));
dirty_it->second.journal_sector = journal.sector_info[journal.cur_sector].offset;
journal.used_sectors[journal.sector_info[journal.cur_sector].offset]++;
#ifdef BLOCKSTORE_DEBUG
printf(
"journal offset %08lx is used by %lx:%lx v%lu (%lu refs)\n",
"journal offset %08lx is used by %lu:%lu v%lu (%lu refs)\n",
dirty_it->second.journal_sector, dirty_it->first.oid.inode, dirty_it->first.oid.stripe, dirty_it->first.version,
journal.used_sectors[journal.sector_info[journal.cur_sector].offset]
);
@ -489,7 +497,7 @@ int blockstore_impl_t::dequeue_del(blockstore_op_t *op)
je->version = op->version;
je->crc32 = je_crc32((journal_entry*)je);
journal.crc32_last = je->crc32;
dirty_it->second.state = BS_ST_DELETE | BS_ST_SUBMITTED;
dirty_it->second.state = ST_DEL_SUBMITTED;
if (immediate_commit != IMMEDIATE_NONE)
{
prepare_journal_sector_write(journal, journal.cur_sector, sqe, cb);

676
cluster_client.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include "cluster_client.h"
cluster_client_t::cluster_client_t(ring_loop_t *ringloop, timerfd_manager_t *tfd, json11::Json & config)
@ -8,63 +5,17 @@ cluster_client_t::cluster_client_t(ring_loop_t *ringloop, timerfd_manager_t *tfd
this->ringloop = ringloop;
this->tfd = tfd;
msgr.osd_num = 0;
msgr.tfd = tfd;
msgr.ringloop = ringloop;
msgr.repeer_pgs = [this](osd_num_t peer_osd)
{
// peer_osd just connected or dropped connection
if (msgr.osd_peer_fds.find(peer_osd) != msgr.osd_peer_fds.end())
{
// peer_osd just connected
continue_ops();
}
else if (unsynced_writes.size())
{
// peer_osd just dropped connection
for (auto op: syncing_writes)
{
for (auto & part: op->parts)
{
if (part.osd_num == peer_osd && part.done)
{
// repeat this operation
part.osd_num = 0;
part.done = false;
assert(!part.sent);
op->done_count--;
}
}
}
for (auto op: unsynced_writes)
{
for (auto & part: op->parts)
{
if (part.osd_num == peer_osd && part.done)
{
// repeat this operation
part.osd_num = 0;
part.done = false;
assert(!part.sent);
op->done_count--;
}
}
if (op->done_count < op->parts.size())
{
cur_ops.insert(op);
}
}
// really connected :)
continue_ops();
}
};
msgr.exec_op = [this](osd_op_t *op)
{
// Garbage in
printf("Incoming garbage from peer %d\n", op->peer_fd);
msgr.stop_client(op->peer_fd);
delete op;
};
msgr.use_sync_send_recv = config["use_sync_send_recv"].bool_value() ||
config["use_sync_send_recv"].uint64_value();
st_cli.tfd = tfd;
st_cli.on_load_config_hook = [this](json11::Json::object & cfg) { on_load_config_hook(cfg); };
@ -75,51 +26,44 @@ cluster_client_t::cluster_client_t(ring_loop_t *ringloop, timerfd_manager_t *tfd
log_level = config["log_level"].int64_value();
st_cli.parse_config(config);
st_cli.load_global_config();
}
if (ringloop)
void cluster_client_t::continue_ops()
{
for (auto op_it = unsent_ops.begin(); op_it != unsent_ops.end(); )
{
consumer.loop = [this]()
cluster_op_t *op = *op_it;
if (op->needs_reslice && !op->sent_count)
{
msgr.read_requests();
msgr.send_replies();
this->ringloop->submit();
};
ringloop->register_consumer(&consumer);
}
}
cluster_client_t::~cluster_client_t()
{
if (ringloop)
{
ringloop->unregister_consumer(&consumer);
}
}
void cluster_client_t::stop()
{
while (msgr.clients.size() > 0)
{
msgr.stop_client(msgr.clients.begin()->first);
}
}
void cluster_client_t::continue_ops(bool up_retry)
{
for (auto op_it = cur_ops.begin(); op_it != cur_ops.end(); )
{
if ((*op_it)->up_wait)
op->parts.clear();
op->done_count = 0;
op->needs_reslice = false;
}
if (!op->parts.size())
{
if (up_retry)
unsent_ops.erase(op_it++);
execute(op);
continue;
}
if (!op->needs_reslice)
{
for (auto & op_part: op->parts)
{
(*op_it)->up_wait = false;
continue_rw(*op_it++);
if (!op_part.sent && !op_part.done)
{
try_send(op, &op_part);
}
}
if (op->sent_count == op->parts.size() - op->done_count)
{
unsent_ops.erase(op_it++);
sent_ops.insert(op);
}
else
op_it++;
}
else
continue_rw(*op_it++);
op_it++;
}
}
@ -144,103 +88,59 @@ void cluster_client_t::on_load_config_hook(json11::Json::object & config)
bs_disk_alignment = config["disk_alignment"].uint64_value();
bs_bitmap_granularity = config["bitmap_granularity"].uint64_value();
if (!bs_block_size)
{
bs_block_size = DEFAULT_BLOCK_SIZE;
}
if (!bs_disk_alignment)
{
bs_disk_alignment = DEFAULT_DISK_ALIGNMENT;
}
if (!bs_bitmap_granularity)
{
bs_bitmap_granularity = DEFAULT_BITMAP_GRANULARITY;
}
uint32_t block_order;
if ((block_order = is_power_of_two(bs_block_size)) >= 64 || bs_block_size < MIN_BLOCK_SIZE || bs_block_size >= MAX_BLOCK_SIZE)
{
throw std::runtime_error("Bad block size");
uint32_t block_order;
if ((block_order = is_power_of_two(bs_block_size)) >= 64 || bs_block_size < MIN_BLOCK_SIZE || bs_block_size >= MAX_BLOCK_SIZE)
throw std::runtime_error("Bad block size");
}
if (config.find("pg_stripe_size") != config.end())
{
pg_stripe_size = config["pg_stripe_size"].uint64_value();
if (!pg_stripe_size)
pg_stripe_size = DEFAULT_PG_STRIPE_SIZE;
}
if (config["immediate_commit"] == "all")
{
// Cluster-wide immediate_commit mode
immediate_commit = true;
}
else if (config.find("client_dirty_limit") != config.end())
{
client_dirty_limit = config["client_dirty_limit"].uint64_value();
}
if (!client_dirty_limit)
{
client_dirty_limit = DEFAULT_CLIENT_DIRTY_LIMIT;
}
up_wait_retry_interval = config["up_wait_retry_interval"].uint64_value();
if (!up_wait_retry_interval)
{
up_wait_retry_interval = 500;
}
else if (up_wait_retry_interval < 50)
{
up_wait_retry_interval = 50;
}
msgr.peer_connect_interval = config["peer_connect_interval"].uint64_value();
if (!msgr.peer_connect_interval)
{
msgr.peer_connect_interval = DEFAULT_PEER_CONNECT_INTERVAL;
}
msgr.peer_connect_timeout = config["peer_connect_timeout"].uint64_value();
if (!msgr.peer_connect_timeout)
{
msgr.peer_connect_timeout = DEFAULT_PEER_CONNECT_TIMEOUT;
}
st_cli.start_etcd_watcher();
st_cli.load_pgs();
}
void cluster_client_t::on_load_pgs_hook(bool success)
{
for (auto pool_item: st_cli.pool_config)
if (success)
{
pg_counts[pool_item.first] = pool_item.second.real_pg_count;
pg_count = st_cli.pg_config.size();
continue_ops();
}
for (auto op: offline_ops)
{
execute(op);
}
offline_ops.clear();
continue_ops();
}
void cluster_client_t::on_change_hook(json11::Json::object & changes)
{
for (auto pool_item: st_cli.pool_config)
if (pg_count != st_cli.pg_config.size())
{
if (pg_counts[pool_item.first] != pool_item.second.real_pg_count)
// At this point, all operations should be suspended
// And they need to be resliced!
for (auto op: unsent_ops)
{
// At this point, all pool operations should have been suspended
// And now they have to be resliced!
for (auto op: cur_ops)
{
if (INODE_POOL(op->inode) == pool_item.first)
{
op->needs_reslice = true;
}
}
for (auto op: unsynced_writes)
{
if (INODE_POOL(op->inode) == pool_item.first)
{
op->needs_reslice = true;
}
}
for (auto op: syncing_writes)
{
if (INODE_POOL(op->inode) == pool_item.first)
{
op->needs_reslice = true;
}
}
pg_counts[pool_item.first] = pool_item.second.real_pg_count;
op->needs_reslice = true;
}
for (auto op: sent_ops)
{
op->needs_reslice = true;
}
pg_count = st_cli.pg_config.size();
}
continue_ops();
}
@ -253,256 +153,106 @@ void cluster_client_t::on_change_osd_state_hook(uint64_t peer_osd)
}
}
/**
* How writes are synced when immediate_commit is false
*
* 1) accept up to <client_dirty_limit> write operations for execution,
* queue all subsequent writes into <next_writes>
* 2) accept exactly one SYNC, queue all subsequent SYNCs into <next_writes>, too
* 3) "continue" all accepted writes
*
* "Continue" WRITE:
* 1) if the operation is not a copy yet - copy it (required for replay)
* 2) if the operation is not sliced yet - slice it
* 3) if the operation doesn't require reslice - try to connect & send all remaining parts
* 4) if any of them fail due to disconnected peers or PGs not up, repeat after reconnecting or small timeout
* 5) if any of them fail due to other errors, fail the operation and forget it from the current "unsynced batch"
* 6) if PG count changes before all parts are done, wait for all in-progress parts to finish,
* throw all results away, reslice and resubmit op
* 7) when all parts are done, try to "continue" the current SYNC
* 8) if the operation succeeds, but then some OSDs drop their connections, repeat
* parts from the current "unsynced batch" previously sent to those OSDs in any order
*
* "Continue" current SYNC:
* 1) take all unsynced operations from the current batch
* 2) check if all affected OSDs are still alive
* 3) if yes, send all SYNCs. otherwise, leave current SYNC as is.
* 4) if any of them fail due to disconnected peers, repeat SYNC after repeating all writes
* 5) if any of them fail due to other errors, fail the SYNC operation
*/
// FIXME: Implement OSD_OP_SYNC for immediate_commit == false
void cluster_client_t::execute(cluster_op_t *op)
{
if (!bs_disk_alignment)
if (op->opcode == OSD_OP_SYNC && immediate_commit)
{
// We're offline
offline_ops.push_back(op);
// Syncs are not required in the immediate_commit mode
op->retval = 0;
std::function<void(cluster_op_t*)>(op->callback)(op);
return;
}
op->retval = 0;
if (op->opcode != OSD_OP_SYNC && op->opcode != OSD_OP_READ && op->opcode != OSD_OP_WRITE ||
(op->opcode == OSD_OP_READ || op->opcode == OSD_OP_WRITE) && (!op->inode || !op->len ||
op->offset % bs_disk_alignment || op->len % bs_disk_alignment))
if (op->opcode != OSD_OP_READ && op->opcode != OSD_OP_OUT || !op->inode || !op->len ||
op->offset % bs_disk_alignment || op->len % bs_disk_alignment)
{
op->retval = -EINVAL;
std::function<void(cluster_op_t*)>(op->callback)(op);
return;
}
if (op->opcode == OSD_OP_SYNC)
if (!pg_stripe_size)
{
execute_sync(op);
// Config is not loaded yet
unsent_ops.insert(op);
return;
}
if (op->opcode == OSD_OP_WRITE && !immediate_commit)
{
if (next_writes.size() > 0)
{
assert(cur_sync);
next_writes.push_back(op);
return;
}
if (queued_bytes >= client_dirty_limit)
{
// Push an extra SYNC operation to flush previous writes
next_writes.push_back(op);
cluster_op_t *sync_op = new cluster_op_t;
sync_op->is_internal = true;
sync_op->opcode = OSD_OP_SYNC;
sync_op->callback = [](cluster_op_t* sync_op) {};
execute_sync(sync_op);
return;
}
queued_bytes += op->len;
}
cur_ops.insert(op);
continue_rw(op);
}
void cluster_client_t::continue_rw(cluster_op_t *op)
{
pool_id_t pool_id = INODE_POOL(op->inode);
if (!pool_id)
{
op->retval = -EINVAL;
std::function<void(cluster_op_t*)>(op->callback)(op);
return;
}
if (st_cli.pool_config.find(pool_id) == st_cli.pool_config.end() ||
st_cli.pool_config[pool_id].real_pg_count == 0)
{
// Postpone operations to unknown pools
return;
}
if (op->opcode == OSD_OP_WRITE && !immediate_commit && !op->is_internal)
{
// Save operation for replay when PG goes out of sync
// (primary OSD drops our connection in this case)
// Copy operation
cluster_op_t *op_copy = new cluster_op_t();
op_copy->is_internal = true;
op_copy->orig_op = op;
op_copy->opcode = op->opcode;
op_copy->inode = op->inode;
op_copy->offset = op->offset;
op_copy->len = op->len;
op_copy->buf = malloc_or_die(op->len);
op_copy->iov.push_back(op_copy->buf, op->len);
op_copy->callback = [](cluster_op_t* op_copy)
op_copy->buf = malloc(op->len);
memcpy(op_copy->buf, op->buf, op->len);
unsynced_ops.push_back(op_copy);
unsynced_bytes += op->len;
if (inmemory_commit)
{
if (op_copy->orig_op)
{
// Acknowledge write and forget the original pointer
op_copy->orig_op->retval = op_copy->retval;
std::function<void(cluster_op_t*)>(op_copy->orig_op->callback)(op_copy->orig_op);
op_copy->orig_op = NULL;
}
};
void *cur_buf = op_copy->buf;
for (int i = 0; i < op->iov.count; i++)
{
memcpy(cur_buf, op->iov.buf[i].iov_base, op->iov.buf[i].iov_len);
cur_buf += op->iov.buf[i].iov_len;
}
unsynced_writes.push_back(op_copy);
cur_ops.erase(op);
cur_ops.insert(op_copy);
op = op_copy;
}
if (!op->parts.size())
{
// Slice the operation into parts
slice_rw(op);
}
if (!op->needs_reslice)
{
// Send unsent parts, if they're not subject to change
for (auto & op_part: op->parts)
{
if (!op_part.sent && !op_part.done)
{
try_send(op, &op_part);
}
}
}
if (!op->sent_count)
{
if (op->done_count >= op->parts.size())
{
// Finished successfully
// Even if the PG count has changed in meanwhile we treat it as success
// because if some operations were invalid for the new PG count we'd get errors
cur_ops.erase(op);
// Immediately acknowledge write and continue with the copy
op->retval = op->len;
std::function<void(cluster_op_t*)>(op->callback)(op);
continue_sync();
return;
op = op_copy;
}
else if (op->retval != 0 && op->retval != -EPIPE)
if (unsynced_bytes >= inmemory_dirty_limit)
{
// Fatal error (not -EPIPE)
cur_ops.erase(op);
if (!immediate_commit && op->opcode == OSD_OP_WRITE)
{
for (int i = 0; i < unsynced_writes.size(); i++)
{
if (unsynced_writes[i] == op)
{
unsynced_writes.erase(unsynced_writes.begin()+i, unsynced_writes.begin()+i+1);
break;
}
}
}
bool del = op->is_internal;
std::function<void(cluster_op_t*)>(op->callback)(op);
if (del)
{
if (op->buf)
free(op->buf);
delete op;
}
continue_sync();
return;
}
else
{
// -EPIPE or no error - clear the error
op->retval = 0;
if (op->needs_reslice)
{
op->parts.clear();
op->done_count = 0;
op->needs_reslice = false;
continue_rw(op);
}
// Push an extra SYNC operation
}
}
}
void cluster_client_t::slice_rw(cluster_op_t *op)
{
// Slice the request into individual object stripe requests
// Primary OSDs still operate individual stripes, but their size is multiplied by PG minsize in case of EC
auto & pool_cfg = st_cli.pool_config[INODE_POOL(op->inode)];
uint64_t pg_block_size = bs_block_size * (
pool_cfg.scheme == POOL_SCHEME_REPLICATED ? 1 : pool_cfg.pg_minsize
);
uint64_t pg_block_size = bs_block_size * pg_part_count;
uint64_t first_stripe = (op->offset / pg_block_size) * pg_block_size;
uint64_t last_stripe = ((op->offset + op->len + pg_block_size - 1) / pg_block_size - 1) * pg_block_size;
op->retval = 0;
op->parts.resize((last_stripe - first_stripe) / pg_block_size + 1);
int iov_idx = 0;
size_t iov_pos = 0;
int part_count = 0;
for (uint64_t stripe = first_stripe; stripe <= last_stripe; stripe += pg_block_size)
{
if (op->offset < (stripe+pg_block_size) && (op->offset+op->len) > stripe)
{
part_count++;
}
}
op->parts.resize(part_count);
bool resend = false;
int i = 0;
for (uint64_t stripe = first_stripe; stripe <= last_stripe; stripe += pg_block_size)
{
pg_num_t pg_num = (op->inode + stripe/pool_cfg.pg_stripe_size) % pool_cfg.real_pg_count + 1;
uint64_t begin = (op->offset < stripe ? stripe : op->offset);
uint64_t end = (op->offset + op->len) > (stripe + pg_block_size)
? (stripe + pg_block_size) : (op->offset + op->len);
op->parts[i] = {
.parent = op,
.offset = begin,
.len = (uint32_t)(end - begin),
.pg_num = pg_num,
.sent = false,
.done = false,
};
int left = end-begin;
while (left > 0 && iov_idx < op->iov.count)
uint64_t stripe_end = stripe + pg_block_size;
if (op->offset < stripe_end && (op->offset+op->len) > stripe)
{
if (op->iov.buf[iov_idx].iov_len - iov_pos < left)
pg_num_t pg_num = (op->inode + stripe/pg_stripe_size) % pg_count + 1;
op->parts[i] = {
.parent = op,
.offset = op->offset < stripe ? stripe : op->offset,
.len = (uint32_t)((op->offset+op->len) > stripe_end ? pg_block_size : op->offset+op->len-stripe),
.pg_num = pg_num,
.buf = op->buf + (op->offset < stripe ? stripe-op->offset : 0),
.sent = false,
.done = false,
};
if (!try_send(op, &op->parts[i]))
{
op->parts[i].iov.push_back(op->iov.buf[iov_idx].iov_base + iov_pos, op->iov.buf[iov_idx].iov_len - iov_pos);
left -= (op->iov.buf[iov_idx].iov_len - iov_pos);
iov_pos = 0;
iov_idx++;
}
else
{
op->parts[i].iov.push_back(op->iov.buf[iov_idx].iov_base + iov_pos, left);
iov_pos += left;
left = 0;
// Part needs to be sent later
resend = true;
}
i++;
}
assert(left == 0);
i++;
}
if (resend)
{
unsent_ops.insert(op);
}
else
{
sent_ops.insert(op);
}
}
bool cluster_client_t::try_send(cluster_op_t *op, cluster_op_part_t *part)
{
auto & pool_cfg = st_cli.pool_config[INODE_POOL(op->inode)];
auto pg_it = pool_cfg.pg_config.find(part->pg_num);
if (pg_it != pool_cfg.pg_config.end() &&
auto pg_it = st_cli.pg_config.find(part->pg_num);
if (pg_it != st_cli.pg_config.end() &&
!pg_it->second.pause && pg_it->second.cur_primary)
{
osd_num_t primary_osd = pg_it->second.cur_primary;
@ -531,7 +281,15 @@ bool cluster_client_t::try_send(cluster_op_t *op, cluster_op_part_t *part)
handle_op_part(part);
},
};
part->op.iov = part->iov;
part->op.send_list.push_back(part->op.req.buf, OSD_PACKET_SIZE);
if (op->opcode == OSD_OP_WRITE)
{
part->op.send_list.push_back(part->buf, part->len);
}
else
{
part->op.buf = part->buf;
}
msgr.outbox_push(&part->op);
return true;
}
@ -543,185 +301,36 @@ bool cluster_client_t::try_send(cluster_op_t *op, cluster_op_part_t *part)
return false;
}
void cluster_client_t::execute_sync(cluster_op_t *op)
{
if (immediate_commit)
{
// Syncs are not required in the immediate_commit mode
op->retval = 0;
std::function<void(cluster_op_t*)>(op->callback)(op);
}
else if (cur_sync != NULL)
{
next_writes.push_back(op);
}
else
{
cur_sync = op;
continue_sync();
}
}
void cluster_client_t::continue_sync()
{
if (!cur_sync || cur_sync->parts.size() > 0)
{
// Already submitted
return;
}
cur_sync->retval = 0;
std::set<osd_num_t> sync_osds;
for (auto prev_op: unsynced_writes)
{
if (prev_op->done_count < prev_op->parts.size())
{
// Writes not finished yet
return;
}
for (auto & part: prev_op->parts)
{
if (part.osd_num)
{
sync_osds.insert(part.osd_num);
}
}
}
if (!sync_osds.size())
{
// No dirty writes
finish_sync();
return;
}
// Check that all OSD connections are still alive
for (auto sync_osd: sync_osds)
{
auto peer_it = msgr.osd_peer_fds.find(sync_osd);
if (peer_it == msgr.osd_peer_fds.end())
{
// SYNC is pointless to send to a non connected OSD
return;
}
}
syncing_writes.swap(unsynced_writes);
// Post sync to affected OSDs
cur_sync->parts.resize(sync_osds.size());
int i = 0;
for (auto sync_osd: sync_osds)
{
cur_sync->parts[i] = {
.parent = cur_sync,
.osd_num = sync_osd,
.sent = false,
.done = false,
};
send_sync(cur_sync, &cur_sync->parts[i]);
i++;
}
}
void cluster_client_t::finish_sync()
{
int retval = cur_sync->retval;
if (retval != 0)
{
for (auto op: syncing_writes)
{
if (op->done_count < op->parts.size())
{
cur_ops.insert(op);
}
}
unsynced_writes.insert(unsynced_writes.begin(), syncing_writes.begin(), syncing_writes.end());
syncing_writes.clear();
}
if (retval == -EPIPE)
{
// Retry later
cur_sync->parts.clear();
cur_sync->retval = 0;
cur_sync->sent_count = 0;
cur_sync->done_count = 0;
return;
}
std::function<void(cluster_op_t*)>(cur_sync->callback)(cur_sync);
if (!retval)
{
for (auto op: syncing_writes)
{
assert(op->sent_count == 0);
if (op->is_internal)
{
if (op->buf)
free(op->buf);
delete op;
}
}
syncing_writes.clear();
}
cur_sync = NULL;
queued_bytes = 0;
std::vector<cluster_op_t*> next_wr_copy;
next_wr_copy.swap(next_writes);
for (auto next_op: next_wr_copy)
{
execute(next_op);
}
}
void cluster_client_t::send_sync(cluster_op_t *op, cluster_op_part_t *part)
{
auto peer_it = msgr.osd_peer_fds.find(part->osd_num);
assert(peer_it != msgr.osd_peer_fds.end());
part->sent = true;
op->sent_count++;
part->op = {
.op_type = OSD_OP_OUT,
.peer_fd = peer_it->second,
.req = {
.hdr = {
.magic = SECONDARY_OSD_OP_MAGIC,
.id = op_id++,
.opcode = OSD_OP_SYNC,
},
},
.callback = [this, part](osd_op_t *op_part)
{
handle_op_part(part);
},
};
msgr.outbox_push(&part->op);
}
void cluster_client_t::handle_op_part(cluster_op_part_t *part)
{
cluster_op_t *op = part->parent;
part->sent = false;
op->sent_count--;
int expected = part->op.req.hdr.opcode == OSD_OP_SYNC ? 0 : part->op.req.rw.len;
if (part->op.reply.hdr.retval != expected)
part->op.buf = NULL;
if (part->op.reply.hdr.retval != part->op.req.rw.len)
{
// Operation failed, retry
printf(
"Operation failed on OSD %lu: retval=%ld (expected %d), dropping connection\n",
part->osd_num, part->op.reply.hdr.retval, expected
"Operation part failed on OSD %lu: retval=%ld (expected %u), reconnecting\n",
part->osd_num, part->op.reply.hdr.retval, part->op.req.rw.len
);
msgr.stop_client(part->op.peer_fd);
if (part->op.reply.hdr.retval == -EPIPE)
if (op->sent_count == op->parts.size() - op->done_count - 1)
{
op->up_wait = true;
if (!retry_timeout_id)
{
retry_timeout_id = tfd->set_timer(up_wait_retry_interval, false, [this](int)
{
retry_timeout_id = 0;
continue_ops(true);
});
}
// Resend later when OSDs come up
// FIXME: Check for different types of errors
// FIXME: Repeat operations after a small timeout, for the case when OSD is coming up
sent_ops.erase(op);
unsent_ops.insert(op);
}
if (!op->retval || op->retval == -EPIPE)
if (op->sent_count == 0 && op->needs_reslice)
{
// Don't overwrite other errors with -EPIPE
op->retval = part->op.reply.hdr.retval;
// PG count has changed, reslice the operation
unsent_ops.erase(op);
op->parts.clear();
op->done_count = 0;
op->needs_reslice = false;
execute(op);
}
}
else
@ -729,17 +338,12 @@ void cluster_client_t::handle_op_part(cluster_op_part_t *part)
// OK
part->done = true;
op->done_count++;
}
if (op->sent_count == 0)
{
if (op->opcode == OSD_OP_SYNC)
if (op->done_count >= op->parts.size())
{
assert(op == cur_sync);
finish_sync();
}
else
{
continue_rw(op);
// Finished!
sent_ops.erase(op);
op->retval = op->len;
std::function<void(cluster_op_t*)>(op->callback)(op);
}
}
}

48
cluster_client.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include "messenger.h"
@ -9,9 +6,9 @@
#define MIN_BLOCK_SIZE 4*1024
#define MAX_BLOCK_SIZE 128*1024*1024
#define DEFAULT_BLOCK_SIZE 128*1024
#define DEFAULT_PG_STRIPE_SIZE 4*1024*1024
#define DEFAULT_DISK_ALIGNMENT 4096
#define DEFAULT_BITMAP_GRANULARITY 4096
#define DEFAULT_CLIENT_DIRTY_LIMIT 32*1024*1024
struct cluster_op_t;
@ -22,7 +19,7 @@ struct cluster_op_part_t
uint32_t len;
pg_num_t pg_num;
osd_num_t osd_num;
osd_op_buf_list_t iov;
void *buf;
bool sent;
bool done;
osd_op_t op;
@ -35,14 +32,10 @@ struct cluster_op_t
uint64_t offset;
uint64_t len;
int retval;
osd_op_buf_list_t iov;
void *buf;
std::function<void(cluster_op_t*)> callback;
protected:
void *buf = NULL;
cluster_op_t *orig_op = NULL;
bool is_internal = false;
bool needs_reslice = false;
bool up_wait = false;
int sent_count = 0, done_count = 0;
std::vector<cluster_op_part_t> parts;
friend class cluster_client_t;
@ -53,50 +46,35 @@ class cluster_client_t
timerfd_manager_t *tfd;
ring_loop_t *ringloop;
uint64_t pg_part_count = 2;
uint64_t pg_stripe_size = 0;
uint64_t bs_block_size = 0;
uint64_t bs_disk_alignment = 0;
uint64_t bs_bitmap_granularity = 0;
std::map<pool_id_t, uint64_t> pg_counts;
uint64_t pg_count = 0;
bool immediate_commit = false;
// FIXME: Implement inmemory_commit mode. Note that it requires to return overlapping reads from memory.
uint64_t client_dirty_limit = 0;
bool inmemory_commit = false;
uint64_t inmemory_dirty_limit = 32*1024*1024;
int log_level;
int up_wait_retry_interval = 500; // ms
uint64_t op_id = 1;
etcd_state_client_t st_cli;
osd_messenger_t msgr;
ring_consumer_t consumer;
// operations currently in progress
std::set<cluster_op_t*> cur_ops;
int retry_timeout_id = 0;
std::set<cluster_op_t*> sent_ops, unsent_ops;
// unsynced operations are copied in memory to allow replay when cluster isn't in the immediate_commit mode
// unsynced_writes are replayed in any order (because only the SYNC operation guarantees ordering)
std::vector<cluster_op_t*> unsynced_writes;
std::vector<cluster_op_t*> syncing_writes;
cluster_op_t* cur_sync = NULL;
std::vector<cluster_op_t*> next_writes;
std::vector<cluster_op_t*> offline_ops;
uint64_t queued_bytes = 0;
std::vector<cluster_op_t*> unsynced_ops;
uint64_t unsynced_bytes = 0;
public:
cluster_client_t(ring_loop_t *ringloop, timerfd_manager_t *tfd, json11::Json & config);
~cluster_client_t();
void execute(cluster_op_t *op);
void stop();
protected:
void continue_ops(bool up_retry = false);
void on_load_config_hook(json11::Json::object & config);
void continue_ops();
void on_load_config_hook(json11::Json::object & cfg);
void on_load_pgs_hook(bool success);
void on_change_hook(json11::Json::object & changes);
void on_change_osd_state_hook(uint64_t peer_osd);
void continue_rw(cluster_op_t *op);
void slice_rw(cluster_op_t *op);
bool try_send(cluster_op_t *op, cluster_op_part_t *part);
void execute_sync(cluster_op_t *op);
void continue_sync();
void finish_sync();
void send_sync(cluster_op_t *op, cluster_op_part_t *part);
void handle_op_part(cluster_op_part_t *part);
};

1
cpp-btree

@ -1 +0,0 @@
Subproject commit 5dc108754ad40d3b1d024f9bd7cca0595ef1a1db

24
dump_journal.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#define _LARGEFILE64_SOURCE
#include <sys/types.h>
#include <sys/ioctl.h>
@ -97,7 +94,7 @@ void journal_dump_t::dump_block(void *buf)
while (pos < journal_block)
{
journal_entry *je = (journal_entry*)(buf + pos);
if (je->magic != JOURNAL_MAGIC || je->type < JE_MIN || je->type > JE_MAX)
if (je->magic != JOURNAL_MAGIC || je->type < JE_START || je->type > JE_DELETE)
{
break;
}
@ -107,11 +104,10 @@ void journal_dump_t::dump_block(void *buf)
{
printf("je_start start=%08lx\n", je->start.journal_start);
}
else if (je->type == JE_SMALL_WRITE || je->type == JE_SMALL_WRITE_INSTANT)
else if (je->type == JE_SMALL_WRITE)
{
printf(
"je_small_write%s oid=%lx:%lx ver=%lu offset=%u len=%u loc=%08lx",
je->type == JE_SMALL_WRITE_INSTANT ? "_instant" : "",
"je_small_write oid=%lu:%lu ver=%lu offset=%u len=%u loc=%08lx",
je->small_write.oid.inode, je->small_write.oid.stripe,
je->small_write.version, je->small_write.offset, je->small_write.len,
je->small_write.data_offset
@ -143,25 +139,21 @@ void journal_dump_t::dump_block(void *buf)
);
printf("\n");
}
else if (je->type == JE_BIG_WRITE || je->type == JE_BIG_WRITE_INSTANT)
else if (je->type == JE_BIG_WRITE)
{
printf(
"je_big_write%s oid=%lx:%lx ver=%lu loc=%08lx\n",
je->type == JE_BIG_WRITE_INSTANT ? "_instant" : "",
je->big_write.oid.inode, je->big_write.oid.stripe, je->big_write.version, je->big_write.location
);
printf("je_big_write oid=%lu:%lu ver=%lu loc=%08lx\n", je->big_write.oid.inode, je->big_write.oid.stripe, je->big_write.version, je->big_write.location);
}
else if (je->type == JE_STABLE)
{
printf("je_stable oid=%lx:%lx ver=%lu\n", je->stable.oid.inode, je->stable.oid.stripe, je->stable.version);
printf("je_stable oid=%lu:%lu ver=%lu\n", je->stable.oid.inode, je->stable.oid.stripe, je->stable.version);
}
else if (je->type == JE_ROLLBACK)
{
printf("je_rollback oid=%lx:%lx ver=%lu\n", je->rollback.oid.inode, je->rollback.oid.stripe, je->rollback.version);
printf("je_rollback oid=%lu:%lu ver=%lu\n", je->rollback.oid.inode, je->rollback.oid.stripe, je->rollback.version);
}
else if (je->type == JE_DELETE)
{
printf("je_delete oid=%lx:%lx ver=%lu\n", je->del.oid.inode, je->del.oid.stripe, je->del.version);
printf("je_delete oid=%lu:%lu ver=%lu\n", je->del.oid.inode, je->del.oid.stripe, je->del.version);
}
pos += je->size;
entry++;

14
epoll_manager.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include <sys/epoll.h>
#include <sys/poll.h>
#include <unistd.h>
@ -19,7 +16,7 @@ epoll_manager_t::epoll_manager_t(ring_loop_t *ringloop)
throw std::runtime_error(std::string("epoll_create: ") + strerror(errno));
}
tfd = new timerfd_manager_t([this](int fd, bool wr, std::function<void(int, int)> handler) { set_fd_handler(fd, wr, handler); });
tfd = new timerfd_manager_t([this](int fd, std::function<void(int, int)> handler) { set_fd_handler(fd, handler); });
handle_epoll_events();
}
@ -34,14 +31,14 @@ epoll_manager_t::~epoll_manager_t()
close(epoll_fd);
}
void epoll_manager_t::set_fd_handler(int fd, bool wr, std::function<void(int, int)> handler)
void epoll_manager_t::set_fd_handler(int fd, std::function<void(int, int)> handler)
{
if (handler != NULL)
{
bool exists = epoll_handlers.find(fd) != epoll_handlers.end();
epoll_event ev;
ev.data.fd = fd;
ev.events = (wr ? EPOLLOUT : 0) | EPOLLIN | EPOLLRDHUP | EPOLLET;
ev.events = EPOLLOUT | EPOLLIN | EPOLLRDHUP | EPOLLET;
if (epoll_ctl(epoll_fd, exists ? EPOLL_CTL_MOD : EPOLL_CTL_ADD, fd, &ev) < 0)
{
throw std::runtime_error(std::string("epoll_ctl: ") + strerror(errno));
@ -60,6 +57,11 @@ void epoll_manager_t::set_fd_handler(int fd, bool wr, std::function<void(int, in
void epoll_manager_t::handle_epoll_events()
{
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("epoll %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
io_uring_sqe *sqe = ringloop->get_sqe();
if (!sqe)
{

5
epoll_manager.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include <map>
@ -16,7 +13,7 @@ class epoll_manager_t
public:
epoll_manager_t(ring_loop_t *ringloop);
~epoll_manager_t();
void set_fd_handler(int fd, bool wr, std::function<void(int, int)> handler);
void set_fd_handler(int fd, std::function<void(int, int)> handler);
void handle_epoll_events();
timerfd_manager_t *tfd;

194
etcd_state_client.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include "osd_ops.h"
#include "pg_states.h"
#include "etcd_state_client.h"
@ -84,7 +81,7 @@ void etcd_state_client_t::parse_config(json11::Json & config)
this->etcd_prefix = config["etcd_prefix"].string_value();
if (this->etcd_prefix == "")
{
this->etcd_prefix = "/vitastor";
this->etcd_prefix = "/microceph";
}
else if (this->etcd_prefix[0] != '/')
{
@ -236,11 +233,6 @@ void etcd_state_client_t::load_global_config()
void etcd_state_client_t::load_pgs()
{
json11::Json::array txn = {
json11::Json::object {
{ "request_range", json11::Json::object {
{ "key", base64_encode(etcd_prefix+"/config/pools") },
} }
},
json11::Json::object {
{ "request_range", json11::Json::object {
{ "key", base64_encode(etcd_prefix+"/config/pgs") },
@ -301,162 +293,47 @@ void etcd_state_client_t::load_pgs()
void etcd_state_client_t::parse_state(const std::string & key, const json11::Json & value)
{
if (key == etcd_prefix+"/config/pools")
if (key == etcd_prefix+"/config/pgs")
{
for (auto & pool_item: this->pool_config)
for (auto & pg_item: this->pg_config)
{
pool_item.second.exists = false;
pg_item.second.exists = false;
}
for (auto & pool_item: value.object_items())
for (auto & pg_item: value["items"].object_items())
{
pool_id_t pool_id = stoull_full(pool_item.first);
if (!pool_id || pool_id >= POOL_ID_MAX)
pg_num_t pg_num = stoull_full(pg_item.first);
if (!pg_num)
{
printf("Pool ID %s is invalid (must be a number less than 0x%x), skipping pool\n", pool_item.first.c_str(), POOL_ID_MAX);
printf("Bad key in PG configuration: %s (must be a number), skipped\n", pg_item.first.c_str());
continue;
}
if (pool_item.second["pg_size"].uint64_value() < 1 ||
pool_item.second["scheme"] == "xor" && pool_item.second["pg_size"].uint64_value() < 3)
this->pg_config[pg_num].exists = true;
this->pg_config[pg_num].pause = pg_item.second["pause"].bool_value();
this->pg_config[pg_num].primary = pg_item.second["primary"].uint64_value();
this->pg_config[pg_num].target_set.clear();
for (auto pg_osd: pg_item.second["osd_set"].array_items())
{
printf("Pool %u has invalid pg_size, skipping pool\n", pool_id);
continue;
this->pg_config[pg_num].target_set.push_back(pg_osd.uint64_value());
}
if (pool_item.second["pg_minsize"].uint64_value() < 1 ||
pool_item.second["pg_minsize"].uint64_value() > pool_item.second["pg_size"].uint64_value() ||
pool_item.second["pg_minsize"].uint64_value() < (pool_item.second["pg_size"].uint64_value() - 1))
if (this->pg_config[pg_num].target_set.size() != 3)
{
printf("Pool %u has invalid pg_minsize, skipping pool\n", pool_id);
continue;
printf("Bad PG %u config format: incorrect osd_set = %s\n", pg_num, pg_item.second["osd_set"].dump().c_str());
this->pg_config[pg_num].target_set.resize(3);
this->pg_config[pg_num].pause = true;
}
if (pool_item.second["pg_count"].uint64_value() < 1)
{
printf("Pool %u has invalid pg_count, skipping pool\n", pool_id);
continue;
}
if (pool_item.second["name"].string_value() == "")
{
printf("Pool %u has empty name, skipping pool\n", pool_id);
continue;
}
if (pool_item.second["scheme"] != "replicated" && pool_item.second["scheme"] != "xor")
{
printf("Pool %u has invalid coding scheme (only \"xor\" and \"replicated\" are allowed), skipping pool\n", pool_id);
continue;
}
if (pool_item.second["max_osd_combinations"].uint64_value() > 0 &&
pool_item.second["max_osd_combinations"].uint64_value() < 100)
{
printf("Pool %u has invalid max_osd_combinations (must be at least 100), skipping pool\n", pool_id);
continue;
}
auto & parsed_cfg = this->pool_config[pool_id];
parsed_cfg.exists = true;
parsed_cfg.id = pool_id;
parsed_cfg.name = pool_item.second["name"].string_value();
parsed_cfg.scheme = pool_item.second["scheme"] == "replicated" ? POOL_SCHEME_REPLICATED : POOL_SCHEME_XOR;
parsed_cfg.pg_size = pool_item.second["pg_size"].uint64_value();
parsed_cfg.pg_minsize = pool_item.second["pg_minsize"].uint64_value();
parsed_cfg.pg_count = pool_item.second["pg_count"].uint64_value();
parsed_cfg.failure_domain = pool_item.second["failure_domain"].string_value();
parsed_cfg.pg_stripe_size = pool_item.second["pg_stripe_size"].uint64_value();
if (!parsed_cfg.pg_stripe_size)
{
parsed_cfg.pg_stripe_size = DEFAULT_PG_STRIPE_SIZE;
}
parsed_cfg.max_osd_combinations = pool_item.second["max_osd_combinations"].uint64_value();
if (!parsed_cfg.max_osd_combinations)
{
parsed_cfg.max_osd_combinations = 10000;
}
for (auto & pg_item: parsed_cfg.pg_config)
{
if (pg_item.second.target_set.size() != parsed_cfg.pg_size)
{
printf("Pool %u PG %u configuration is invalid: osd_set size %lu != pool pg_size %lu\n",
pool_id, pg_item.first, pg_item.second.target_set.size(), parsed_cfg.pg_size);
pg_item.second.pause = true;
}
}
}
}
else if (key == etcd_prefix+"/config/pgs")
{
for (auto & pool_item: this->pool_config)
{
for (auto & pg_item: pool_item.second.pg_config)
{
pg_item.second.exists = false;
}
}
for (auto & pool_item: value["items"].object_items())
{
pool_id_t pool_id = stoull_full(pool_item.first);
if (!pool_id || pool_id >= POOL_ID_MAX)
{
printf("Pool ID %s is invalid in PG configuration (must be a number less than 0x%x), skipping pool\n", pool_item.first.c_str(), POOL_ID_MAX);
continue;
}
for (auto & pg_item: pool_item.second.object_items())
{
pg_num_t pg_num = stoull_full(pg_item.first);
if (!pg_num)
{
printf("Bad key in pool %u PG configuration: %s (must be a number), skipped\n", pool_id, pg_item.first.c_str());
continue;
}
auto & parsed_cfg = this->pool_config[pool_id].pg_config[pg_num];
parsed_cfg.exists = true;
parsed_cfg.pause = pg_item.second["pause"].bool_value();
parsed_cfg.primary = pg_item.second["primary"].uint64_value();
parsed_cfg.target_set.clear();
for (auto & pg_osd: pg_item.second["osd_set"].array_items())
{
parsed_cfg.target_set.push_back(pg_osd.uint64_value());
}
if (parsed_cfg.target_set.size() != pool_config[pool_id].pg_size)
{
printf("Pool %u PG %u configuration is invalid: osd_set size %lu != pool pg_size %lu\n",
pool_id, pg_num, parsed_cfg.target_set.size(), pool_config[pool_id].pg_size);
parsed_cfg.pause = true;
}
}
}
for (auto & pool_item: this->pool_config)
{
int n = 0;
for (auto pg_it = pool_item.second.pg_config.begin(); pg_it != pool_item.second.pg_config.end(); pg_it++)
{
if (pg_it->second.exists && pg_it->first != ++n)
{
printf(
"Invalid pool %u PG configuration: PG numbers don't cover whole 1..%lu range\n",
pool_item.second.id, pool_item.second.pg_config.size()
);
for (pg_it = pool_item.second.pg_config.begin(); pg_it != pool_item.second.pg_config.end(); pg_it++)
{
pg_it->second.exists = false;
}
n = 0;
break;
}
}
pool_item.second.real_pg_count = n;
}
}
else if (key.substr(0, etcd_prefix.length()+12) == etcd_prefix+"/pg/history/")
{
// <etcd_prefix>/pg/history/%d/%d
pool_id_t pool_id = 0;
pg_num_t pg_num = 0;
char null_byte = 0;
sscanf(key.c_str() + etcd_prefix.length()+12, "%u/%u%c", &pool_id, &pg_num, &null_byte);
if (!pool_id || pool_id >= POOL_ID_MAX || !pg_num || null_byte != 0)
// <etcd_prefix>/pg/history/%d
pg_num_t pg_num = stoull_full(key.substr(etcd_prefix.length()+12));
if (!pg_num)
{
printf("Bad etcd key %s, ignoring\n", key.c_str());
}
else
{
auto & pg_cfg = this->pool_config[pool_id].pg_config[pg_num];
auto & pg_cfg = this->pg_config[pg_num];
pg_cfg.target_history.clear();
pg_cfg.all_peers.clear();
// Refuse to start PG if any set of the <osd_sets> has no live OSDs
@ -474,29 +351,20 @@ void etcd_state_client_t::parse_state(const std::string & key, const json11::Jso
{
pg_cfg.all_peers.push_back(pg_osd.uint64_value());
}
// Read epoch
pg_cfg.epoch = value["epoch"].uint64_value();
if (on_change_pg_history_hook != NULL)
{
on_change_pg_history_hook(pool_id, pg_num);
}
}
}
else if (key.substr(0, etcd_prefix.length()+10) == etcd_prefix+"/pg/state/")
{
// <etcd_prefix>/pg/state/%d/%d
pool_id_t pool_id = 0;
pg_num_t pg_num = 0;
char null_byte = 0;
sscanf(key.c_str() + etcd_prefix.length()+10, "%u/%u%c", &pool_id, &pg_num, &null_byte);
if (!pool_id || pool_id >= POOL_ID_MAX || !pg_num || null_byte != 0)
// <etcd_prefix>/pg/state/%d
pg_num_t pg_num = stoull_full(key.substr(etcd_prefix.length()+10));
if (!pg_num)
{
printf("Bad etcd key %s, ignoring\n", key.c_str());
}
else if (value.is_null())
{
this->pool_config[pool_id].pg_config[pg_num].cur_primary = 0;
this->pool_config[pool_id].pg_config[pg_num].cur_state = 0;
this->pg_config[pg_num].cur_primary = 0;
this->pg_config[pg_num].cur_state = 0;
}
else
{
@ -515,7 +383,7 @@ void etcd_state_client_t::parse_state(const std::string & key, const json11::Jso
}
if (i >= pg_state_bit_count)
{
printf("Unexpected pool %u PG %u state keyword in etcd: %s\n", pool_id, pg_num, e.dump().c_str());
printf("Unexpected PG %u state keyword in etcd: %s\n", pg_num, e.dump().c_str());
return;
}
}
@ -524,11 +392,11 @@ void etcd_state_client_t::parse_state(const std::string & key, const json11::Jso
(state & PG_PEERING) && state != PG_PEERING ||
(state & PG_INCOMPLETE) && state != PG_INCOMPLETE)
{
printf("Unexpected pool %u PG %u state in etcd: primary=%lu, state=%s\n", pool_id, pg_num, cur_primary, value["state"].dump().c_str());
printf("Unexpected PG %u state in etcd: primary=%lu, state=%s\n", pg_num, cur_primary, value["state"].dump().c_str());
return;
}
this->pool_config[pool_id].pg_config[pg_num].cur_primary = cur_primary;
this->pool_config[pool_id].pg_config[pg_num].cur_state = state;
this->pg_config[pg_num].cur_primary = cur_primary;
this->pg_config[pg_num].cur_state = state;
}
}
else if (key.substr(0, etcd_prefix.length()+11) == etcd_prefix+"/osd/state/")

32
etcd_state_client.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include "osd_id.h"
@ -16,14 +13,6 @@
#define ETCD_SLOW_TIMEOUT 5000
#define ETCD_QUICK_TIMEOUT 1000
#define DEFAULT_PG_STRIPE_SIZE 4*1024*1024
struct json_kv_t
{
std::string key;
json11::Json value;
};
struct pg_config_t
{
bool exists;
@ -34,22 +23,12 @@ struct pg_config_t
bool pause;
osd_num_t cur_primary;
int cur_state;
uint64_t epoch;
};
struct pool_config_t
struct json_kv_t
{
bool exists;
pool_id_t id;
std::string name;
uint64_t scheme;
uint64_t pg_size, pg_minsize;
uint64_t pg_count;
uint64_t real_pg_count;
std::string failure_domain;
uint64_t max_osd_combinations;
uint64_t pg_stripe_size;
std::map<pg_num_t, pg_config_t> pg_config;
std::string key;
json11::Json value;
};
struct etcd_state_client_t
@ -62,15 +41,14 @@ struct etcd_state_client_t
int etcd_watches_initialised = 0;
uint64_t etcd_watch_revision = 0;
websocket_t *etcd_watch_ws = NULL;
std::map<pool_id_t, pool_config_t> pool_config;
std::map<pg_num_t, pg_config_t> pg_config;
std::map<osd_num_t, json11::Json> peer_states;
std::function<void(json11::Json::object &)> on_change_hook;
std::function<void(json11::Json::object &)> on_load_config_hook;
std::function<json11::Json()> load_pgs_checks_hook;
std::function<void(bool)> on_load_pgs_hook;
std::function<void(pool_id_t, pg_num_t)> on_change_pg_history_hook;
std::function<void(osd_num_t)> on_change_osd_state_hook;
std::function<void(uint64_t)> on_change_osd_state_hook;
json_kv_t parse_etcd_kv(const json11::Json & kv_json);
void etcd_call(std::string api, json11::Json payload, int timeout, std::function<void(std::string, json11::Json)> callback);

62
fio_cluster.cpp
View File

@ -1,22 +1,19 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
// FIO engine to test cluster I/O
//
// Random write:
//
// fio -thread -ioengine=./libfio_cluster.so -name=test -bs=4k -direct=1 -fsync=16 -iodepth=16 -rw=randwrite \
// -etcd=127.0.0.1:2379 [-etcd_prefix=/vitastor] -pool=1 -inode=1 -size=1000M
// -etcd=127.0.0.1:2379 [-etcd_prefix=/microceph] -size=1000M
//
// Linear write:
//
// fio -thread -ioengine=./libfio_cluster.so -name=test -bs=128k -direct=1 -fsync=32 -iodepth=32 -rw=write \
// -etcd=127.0.0.1:2379 [-etcd_prefix=/vitastor] -pool=1 -inode=1 -size=1000M
// -etcd=127.0.0.1:2379 [-etcd_prefix=/microceph] -size=1000M
//
// Random read (run with -iodepth=32 or -iodepth=1):
//
// fio -thread -ioengine=./libfio_cluster.so -name=test -bs=4k -direct=1 -iodepth=32 -rw=randread \
// -etcd=127.0.0.1:2379 [-etcd_prefix=/vitastor] -pool=1 -inode=1 -size=1000M
// -etcd=127.0.0.1:2379 [-etcd_prefix=/microceph] -size=1000M
#include <sys/types.h>
#include <sys/socket.h>
@ -52,9 +49,7 @@ struct sec_options
int __pad;
char *etcd_host = NULL;
char *etcd_prefix = NULL;
uint64_t pool = 0;
uint64_t inode = 0;
int cluster_log = 0;
int inode = 0;
int trace = 0;
};
@ -73,16 +68,7 @@ static struct fio_option options[] = {
.lname = "etcd key prefix",
.type = FIO_OPT_STR_STORE,
.off1 = offsetof(struct sec_options, etcd_prefix),
.help = "etcd key prefix, by default /vitastor",
.category = FIO_OPT_C_ENGINE,
.group = FIO_OPT_G_FILENAME,
},
{
.name = "pool",
.lname = "pool number for the inode",
.type = FIO_OPT_INT,
.off1 = offsetof(struct sec_options, pool),
.help = "pool number for the inode to run tests on",
.help = "etcd key prefix, by default /microceph",
.category = FIO_OPT_C_ENGINE,
.group = FIO_OPT_G_FILENAME,
},
@ -95,16 +81,6 @@ static struct fio_option options[] = {
.category = FIO_OPT_C_ENGINE,
.group = FIO_OPT_G_FILENAME,
},
{
.name = "cluster_log_level",
.lname = "cluster log level",
.type = FIO_OPT_BOOL,
.off1 = offsetof(struct sec_options, cluster_log),
.help = "Set log level for the Vitastor client",
.def = "0",
.category = FIO_OPT_C_ENGINE,
.group = FIO_OPT_G_FILENAME,
},
{
.name = "osd_trace",
.lname = "OSD trace",
@ -164,17 +140,9 @@ static int sec_init(struct thread_data *td)
json11::Json cfg = json11::Json::object {
{ "etcd_address", std::string(o->etcd_host) },
{ "etcd_prefix", std::string(o->etcd_prefix ? o->etcd_prefix : "/vitastor") },
{ "log_level", o->cluster_log },
{ "etcd_prefix", std::string(o->etcd_prefix ? o->etcd_prefix : "/microceph") },
};
if (o->pool)
o->inode = (o->inode & ((1l << (64-POOL_ID_BITS)) - 1)) | (o->pool << (64-POOL_ID_BITS));
if (!(o->inode >> (64-POOL_ID_BITS)))
{
td_verror(td, EINVAL, "pool is missing");
return 1;
}
bsd->ringloop = new ring_loop_t(512);
bsd->epmgr = new epoll_manager_t(bsd->ringloop);
bsd->cli = new cluster_client_t(bsd->ringloop, bsd->epmgr->tfd, cfg);
@ -207,7 +175,7 @@ static enum fio_q_status sec_queue(struct thread_data *td, struct io_u *io)
op->inode = opt->inode;
op->offset = io->offset;
op->len = io->xfer_buflen;
op->iov.push_back(io->xfer_buf, io->xfer_buflen);
op->buf = io->xfer_buf;
bsd->last_sync = false;
break;
case DDIR_WRITE:
@ -215,7 +183,7 @@ static enum fio_q_status sec_queue(struct thread_data *td, struct io_u *io)
op->inode = opt->inode;
op->offset = io->offset;
op->len = io->xfer_buflen;
op->iov.push_back(io->xfer_buf, io->xfer_buflen);
op->buf = io->xfer_buf;
bsd->last_sync = false;
break;
case DDIR_SYNC:
@ -243,16 +211,8 @@ static enum fio_q_status sec_queue(struct thread_data *td, struct io_u *io)
if (opt->trace)
{
if (io->ddir == DDIR_SYNC)
{
printf("+++ SYNC # %d\n", n);
}
else
{
printf("+++ %s # %d 0x%llx+%llx\n",
io->ddir == DDIR_READ ? "READ" : "WRITE",
n, io->offset, io->xfer_buflen);
}
printf("+++ %s # %d\n", io->ddir == DDIR_READ ? "READ" :
(io->ddir == DDIR_WRITE ? "WRITE" : "SYNC"), n);
}
io->error = 0;
@ -310,7 +270,7 @@ static int sec_invalidate(struct thread_data *td, struct fio_file *f)
}
struct ioengine_ops ioengine = {
.name = "vitastor_cluster",
.name = "microceph_cluster",
.version = FIO_IOOPS_VERSION,
.flags = FIO_MEMALIGN | FIO_DISKLESSIO | FIO_NOEXTEND,
.setup = sec_setup,

5
fio_engine.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
// FIO engine to test Blockstore
//
// Initialize storage for tests:
@ -293,7 +290,7 @@ static int bs_invalidate(struct thread_data *td, struct fio_file *f)
}
struct ioengine_ops ioengine = {
.name = "vitastor_blockstore",
.name = "microceph_blockstore",
.version = FIO_IOOPS_VERSION,
.flags = FIO_MEMALIGN | FIO_DISKLESSIO | FIO_NOEXTEND,
.setup = bs_setup,

9
fio_sec_osd.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
// FIO engine to test Blockstore through Secondary OSD interface
//
// Prepare storage like in fio_engine.cpp, then start OSD with ./osd, then test it
@ -208,7 +205,7 @@ static enum fio_q_status sec_queue(struct thread_data *td, struct io_u *io)
case DDIR_READ:
if (!opt->single_primary)
{
op.hdr.opcode = OSD_OP_SEC_READ;
op.hdr.opcode = OSD_OP_SECONDARY_READ;
op.sec_rw.oid = {
.inode = 1,
.stripe = io->offset >> bsd->block_order,
@ -229,7 +226,7 @@ static enum fio_q_status sec_queue(struct thread_data *td, struct io_u *io)
case DDIR_WRITE:
if (!opt->single_primary)
{
op.hdr.opcode = OSD_OP_SEC_WRITE;
op.hdr.opcode = OSD_OP_SECONDARY_WRITE;
op.sec_rw.oid = {
.inode = 1,
.stripe = io->offset >> bsd->block_order,
@ -384,7 +381,7 @@ static int sec_invalidate(struct thread_data *td, struct fio_file *f)
}
struct ioengine_ops ioengine = {
.name = "vitastor_secondary_osd",
.name = "microceph_secondary_osd",
.version = FIO_IOOPS_VERSION,
.flags = FIO_MEMALIGN | FIO_DISKLESSIO | FIO_NOEXTEND,
.setup = sec_setup,

21
http_client.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include <netinet/tcp.h>
#include <sys/epoll.h>
@ -159,7 +156,7 @@ http_co_t::~http_co_t()
}
if (peer_fd >= 0)
{
tfd->set_fd_handler(peer_fd, false, NULL);
tfd->set_fd_handler(peer_fd, NULL);
close(peer_fd);
peer_fd = -1;
}
@ -226,7 +223,7 @@ void http_co_t::start_connection()
end();
return;
}
tfd->set_fd_handler(peer_fd, true, [this](int peer_fd, int epoll_events)
tfd->set_fd_handler(peer_fd, [this](int peer_fd, int epoll_events)
{
this->epoll_events |= epoll_events;
handle_events();
@ -279,11 +276,6 @@ void http_co_t::handle_connect_result()
}
int one = 1;
setsockopt(peer_fd, SOL_TCP, TCP_NODELAY, &one, sizeof(one));
tfd->set_fd_handler(peer_fd, false, [this](int peer_fd, int epoll_events)
{
this->epoll_events |= epoll_events;
handle_events();
});
state = HTTP_CO_SENDING_REQUEST;
submit_send();
stackout();
@ -305,18 +297,15 @@ void http_co_t::submit_read()
{
res = -errno;
}
if (res == -EAGAIN)
if (res == -EAGAIN || res == 0)
{
epoll_events = epoll_events & ~EPOLLIN;
}
else if (res <= 0)
else if (res < 0)
{
// < 0 means error, 0 means EOF
if (!res)
epoll_events = epoll_events & ~EPOLLIN;
end();
}
else
else if (res > 0)
{
response += std::string(rbuf.data(), res);
handle_read();

3
http_client.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include <string>
#include <vector>

1
json11

@ -1 +0,0 @@
Subproject commit 97f06cb20c1e136fd37d58fb40f57dd8f8a3a4a7

3
lambda_size.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <iostream>
#include <functional>
#include <array>

369
mon/lp-optimizer.js → lp/lp-optimizer.js
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
// Data distribution optimizer using linear programming (lp_solve)
const child_process = require('child_process');
@ -28,7 +25,7 @@ async function lp_solve(text)
let vars = {};
for (const line of stdout.split(/\n/))
{
let m = /^(^Value of objective function: (-?[\d\.]+)|Actual values of the variables:)\s*$/.exec(line);
let m = /^(^Value of objective function: ([\d\.]+)|Actual values of the variables:)\s*$/.exec(line);
if (m)
{
if (m[2])
@ -50,34 +47,34 @@ async function lp_solve(text)
return { score, vars };
}
async function optimize_initial({ osd_tree, pg_count, pg_size = 3, pg_minsize = 2, max_combinations = 10000, parity_space = 1 })
async function optimize_initial(osd_tree, pg_count, max_combinations)
{
if (!pg_count || !osd_tree)
{
return null;
}
max_combinations = max_combinations || 10000;
const all_weights = Object.assign({}, ...Object.values(osd_tree));
const total_weight = Object.values(all_weights).reduce((a, c) => Number(a) + Number(c), 0);
const all_pgs = Object.values(random_combinations(osd_tree, pg_size, max_combinations));
let all_pgs = all_combinations(osd_tree, null, true);
if (all_pgs.length > max_combinations)
{
const prob = max_combinations/all_pgs.length;
all_pgs = all_pgs.filter(pg => Math.random() < prob);
}
const pg_per_osd = {};
for (const pg of all_pgs)
{
for (let i = 0; i < pg.length; i++)
for (const osd of pg)
{
const osd = pg[i];
pg_per_osd[osd] = pg_per_osd[osd] || [];
pg_per_osd[osd].push((i >= pg_minsize ? parity_space+'*' : '')+"pg_"+pg.join("_"));
pg_per_osd[osd].push("pg_"+pg.join("_"));
}
}
const pg_effsize = Math.min(pg_minsize, Object.keys(osd_tree).length)
+ Math.max(0, Math.min(pg_size, Object.keys(osd_tree).length) - pg_minsize) * parity_space;
const pg_size = Math.min(Object.keys(osd_tree).length, 3);
let lp = '';
lp += "max: "+all_pgs.map(pg => 'pg_'+pg.join('_')).join(' + ')+";\n";
for (const osd in pg_per_osd)
{
if (osd !== NO_OSD)
{
let osd_pg_count = all_weights[osd]/total_weight*pg_effsize*pg_count;
let osd_pg_count = all_weights[osd]/total_weight*pg_size*pg_count;
lp += pg_per_osd[osd].join(' + ')+' <= '+osd_pg_count+';\n';
}
}
@ -89,19 +86,11 @@ async function optimize_initial({ osd_tree, pg_count, pg_size = 3, pg_minsize =
const lp_result = await lp_solve(lp);
if (!lp_result)
{
console.log(lp);
throw new Error('Problem is infeasible or unbounded - is it a bug?');
}
const int_pgs = make_int_pgs(lp_result.vars, pg_count);
const eff = pg_list_space_efficiency(int_pgs, all_weights, pg_minsize, parity_space);
const res = {
score: lp_result.score,
weights: lp_result.vars,
int_pgs,
space: eff * pg_effsize,
total_space: total_weight,
};
return res;
const eff = pg_list_space_efficiency(int_pgs, all_weights);
return { score: lp_result.score, weights: lp_result.vars, int_pgs, space: eff*pg_size, total_space: total_weight };
}
function make_int_pgs(weights, pg_count)
@ -123,117 +112,11 @@ function make_int_pgs(weights, pg_count)
return int_pgs;
}
function calc_intersect_weights(pg_size, pg_count, prev_weights, all_pgs)
{
const move_weights = {};
if ((1 << pg_size) < pg_count)
{
const intersect = {};
for (const pg_name in prev_weights)
{
const pg = pg_name.substr(3).split(/_/);
for (let omit = 1; omit < (1 << pg_size); omit++)
{
let pg_omit = [ ...pg ];
let intersect_count = pg_size;
for (let i = 0; i < pg_size; i++)
{
if (omit & (1 << i))
{
pg_omit[i] = '';
intersect_count--;
}
}
pg_omit = pg_omit.join(':');
intersect[pg_omit] = Math.max(intersect[pg_omit] || 0, intersect_count);
}
}
for (const pg of all_pgs)
{
let max_int = 0;
for (let omit = 1; omit < (1 << pg_size); omit++)
{
let pg_omit = [ ...pg ];
for (let i = 0; i < pg_size; i++)
{
if (omit & (1 << i))
{
pg_omit[i] = '';
}
}
pg_omit = pg_omit.join(':');
max_int = Math.max(max_int, intersect[pg_omit] || 0);
}
move_weights['pg_'+pg.join('_')] = pg_size-max_int;
}
}
else
{
const prev_pg_hashed = Object.keys(prev_weights).map(pg_name => pg_name.substr(3).split(/_/).reduce((a, c) => { a[c] = 1; return a; }, {}));
for (const pg of all_pgs)
{
if (!prev_weights['pg_'+pg.join('_')])
{
let max_int = 0;
for (const prev_hash in prev_pg_hashed)
{
const intersect_count = pg.reduce((a, osd) => a + (prev_hash[osd] ? 1 : 0), 0);
if (max_int < intersect_count)
{
max_int = intersect_count;
if (max_int >= pg_size)
{
break;
}
}
}
move_weights['pg_'+pg.join('_')] = pg_size-max_int;
}
}
}
return move_weights;
}
function add_valid_previous(osd_tree, prev_weights, all_pgs)
{
// Add previous combinations that are still valid
const hosts = Object.keys(osd_tree).sort();
const host_per_osd = {};
for (const host in osd_tree)
{
for (const osd in osd_tree[host])
{
host_per_osd[osd] = host;
}
}
skip_pg: for (const pg_name in prev_weights)
{
const seen_hosts = {};
const pg = pg_name.substr(3).split(/_/);
for (const osd of pg)
{
if (!host_per_osd[osd] || seen_hosts[host_per_osd[osd]])
{
continue skip_pg;
}
seen_hosts[host_per_osd[osd]] = true;
}
if (!all_pgs[pg_name])
{
all_pgs[pg_name] = pg;
}
}
}
// Try to minimize data movement
async function optimize_change({ prev_pgs: prev_int_pgs, osd_tree, pg_size = 3, pg_minsize = 2, max_combinations = 10000, parity_space = 1 })
async function optimize_change(prev_int_pgs, osd_tree, max_combinations)
{
if (!osd_tree)
{
return null;
}
const pg_effsize = Math.min(pg_minsize, Object.keys(osd_tree).length)
+ Math.max(0, Math.min(pg_size, Object.keys(osd_tree).length) - pg_minsize) * parity_space;
max_combinations = max_combinations || 10000;
const pg_size = Math.min(Object.keys(osd_tree).length, 3);
const pg_count = prev_int_pgs.length;
const prev_weights = {};
const prev_pg_per_osd = {};
@ -241,50 +124,70 @@ async function optimize_change({ prev_pgs: prev_int_pgs, osd_tree, pg_size = 3,
{
const pg_name = 'pg_'+pg.join('_');
prev_weights[pg_name] = (prev_weights[pg_name]||0) + 1;
for (let i = 0; i < pg.length; i++)
for (const osd of pg)
{
const osd = pg[i];
prev_pg_per_osd[osd] = prev_pg_per_osd[osd] || [];
prev_pg_per_osd[osd].push([ pg_name, (i >= pg_minsize ? parity_space : 1) ]);
prev_pg_per_osd[osd].push(pg_name);
}
}
// Get all combinations
let all_pgs = random_combinations(osd_tree, pg_size, max_combinations);
add_valid_previous(osd_tree, prev_weights, all_pgs);
all_pgs = Object.values(all_pgs);
let all_pgs = all_combinations(osd_tree, null, true);
if (all_pgs.length > max_combinations)
{
const intersecting = all_pgs.filter(pg => prev_weights['pg_'+pg.join('_')]);
if (intersecting.length > max_combinations)
{
const prob = max_combinations/intersecting.length;
all_pgs = intersecting.filter(pg => Math.random() < prob);
}
else
{
const prob = (max_combinations-intersecting.length)/all_pgs.length;
all_pgs = all_pgs.filter(pg => Math.random() < prob || prev_weights['pg_'+pg.join('_')]);
}
}
const pg_per_osd = {};
for (const pg of all_pgs)
{
const pg_name = 'pg_'+pg.join('_');
for (let i = 0; i < pg.length; i++)
for (const osd of pg)
{
const osd = pg[i];
pg_per_osd[osd] = pg_per_osd[osd] || [];
pg_per_osd[osd].push([ pg_name, (i >= pg_minsize ? parity_space : 1) ]);
pg_per_osd[osd].push(pg_name);
}
}
// Penalize PGs based on their similarity to old PGs
const move_weights = calc_intersect_weights(pg_size, pg_count, prev_weights, all_pgs);
const intersect = {};
for (const pg_name in prev_weights)
{
const pg = pg_name.substr(3).split(/_/);
intersect[pg[0]+'::'] = intersect[':'+pg[1]+':'] = intersect['::'+pg[2]] = 2;
intersect[pg[0]+'::'+pg[2]] = intersect[':'+pg[1]+':'+pg[2]] = intersect[pg[0]+':'+pg[1]+':'] = 1;
}
const move_weights = {};
for (const pg of all_pgs)
{
move_weights['pg_'+pg.join('_')] =
intersect[pg[0]+'::'+pg[2]] || intersect[':'+pg[1]+':'+pg[2]] || intersect[pg[0]+':'+pg[1]+':'] ||
intersect[pg[0]+'::'] || intersect[':'+pg[1]+':'] || intersect['::'+pg[2]] ||
3;
}
// Calculate total weight - old PG weights
const all_pg_names = all_pgs.map(pg => 'pg_'+pg.join('_'));
const all_pgs_hash = all_pg_names.reduce((a, c) => { a[c] = true; return a; }, {});
const all_weights = Object.assign({}, ...Object.values(osd_tree));
const total_weight = Object.values(all_weights).reduce((a, c) => Number(a) + Number(c), 0);
// Generate the LP problem
let lp = '';
lp += 'max: '+all_pg_names.map(pg_name => (
prev_weights[pg_name] ? `${pg_size+1}*add_${pg_name} - ${pg_size+1}*del_${pg_name}` : `${pg_size+1-move_weights[pg_name]}*${pg_name}`
prev_weights[pg_name] ? `${4-move_weights[pg_name]}*add_${pg_name} - 4*del_${pg_name}` : `${4-move_weights[pg_name]}*${pg_name}`
)).join(' + ')+';\n';
for (const osd in pg_per_osd)
{
if (osd !== NO_OSD)
{
const osd_sum = (pg_per_osd[osd]||[]).map(([ pg_name, space ]) => (
prev_weights[pg_name] ? `${space} * add_${pg_name} - ${space} * del_${pg_name}` : `${space} * ${pg_name}`
)).join(' + ');
const rm_osd_pg_count = (prev_pg_per_osd[osd]||[])
.reduce((a, [ old_pg_name, space ]) => (a + (all_pgs_hash[old_pg_name] ? space : 0)), 0);
const osd_pg_count = all_weights[osd]*pg_effsize/total_weight*pg_count - rm_osd_pg_count;
const osd_sum = (pg_per_osd[osd]||[]).map(pg_name => prev_weights[pg_name] ? `add_${pg_name} - del_${pg_name}` : pg_name).join(' + ');
const rm_osd_pg_count = (prev_pg_per_osd[osd]||[]).filter(old_pg_name => move_weights[old_pg_name]).length;
let osd_pg_count = all_weights[osd]*3/total_weight*pg_count - rm_osd_pg_count;
lp += osd_sum + ' <= ' + osd_pg_count + ';\n';
}
}
@ -318,7 +221,7 @@ async function optimize_change({ prev_pgs: prev_int_pgs, osd_tree, pg_size = 3,
const weights = { ...prev_weights };
for (const k in prev_weights)
{
if (!all_pgs_hash[k])
if (!move_weights[k])
{
delete weights[k];
}
@ -333,7 +236,7 @@ async function optimize_change({ prev_pgs: prev_int_pgs, osd_tree, pg_size = 3,
{
weights[k.substr(4)] = (weights[k.substr(4)] || 0) - Number(lp_result.vars[k]);
}
else if (k.substr(0, 3) === 'pg_')
else
{
weights[k] = Number(lp_result.vars[k]);
}
@ -355,7 +258,7 @@ async function optimize_change({ prev_pgs: prev_int_pgs, osd_tree, pg_size = 3,
{
differs++;
}
for (let j = 0; j < pg_size; j++)
for (let j = 0; j < 3; j++)
{
if (new_pgs[i][j] != prev_int_pgs[i][j])
{
@ -370,7 +273,7 @@ async function optimize_change({ prev_pgs: prev_int_pgs, osd_tree, pg_size = 3,
int_pgs: new_pgs,
differs,
osd_differs,
space: pg_effsize * pg_list_space_efficiency(new_pgs, all_weights, pg_minsize, parity_space),
space: pg_size * pg_list_space_efficiency(new_pgs, all_weights),
total_space: total_weight,
};
}
@ -488,132 +391,64 @@ function extract_osds(osd_tree, levels, osd_level, osds = {})
return osds;
}
function random_combinations(osd_tree, pg_size, count)
{
let seed = 0x5f020e43;
let rng = () =>
{
seed ^= seed << 13;
seed ^= seed >> 17;
seed ^= seed << 5;
return seed + 2147483648;
};
const hosts = Object.keys(osd_tree).sort();
const osds = Object.keys(osd_tree).reduce((a, c) => { a[c] = Object.keys(osd_tree[c]).sort(); return a; }, {});
const r = {};
// Generate random combinations including each OSD at least once
for (let h = 0; h < hosts.length; h++)
{
for (let o = 0; o < osds[hosts[h]].length; o++)
{
const pg = [ osds[hosts[h]][o] ];
const cur_hosts = [ ...hosts ];
cur_hosts.splice(h, 1);
for (let i = 1; i < pg_size && i < hosts.length; i++)
{
const next_host = rng() % cur_hosts.length;
const next_osd = rng() % osds[cur_hosts[next_host]].length;
pg.push(osds[cur_hosts[next_host]][next_osd]);
cur_hosts.splice(next_host, 1);
}
while (pg.length < pg_size)
{
pg.push(NO_OSD);
}
r['pg_'+pg.join('_')] = pg;
}
}
// Generate purely random combinations
restart: while (count > 0)
{
let host_idx = [];
for (let i = 0; i < pg_size && i < hosts.length; i++)
{
let start = i > 0 ? host_idx[i-1]+1 : 0;
if (start >= hosts.length)
{
continue restart;
}
host_idx[i] = start + rng() % (hosts.length-start);
}
let pg = host_idx.map(h => osds[hosts[h]][rng() % osds[hosts[h]].length]);
while (pg.length < pg_size)
{
pg.push(NO_OSD);
}
r['pg_'+pg.join('_')] = pg;
count--;
}
return r;
}
// Super-stupid algorithm. Given the current OSD tree, generate all possible OSD combinations
// FIXME: support different pg_sizes, not just 3
// osd_tree = { failure_domain1: { osd1: size1, ... }, ... }
// ordered = return combinations without duplicates having different order
function all_combinations(osd_tree, pg_size, ordered, count)
function all_combinations(osd_tree, count, ordered)
{
const hosts = Object.keys(osd_tree).sort();
const osds = Object.keys(osd_tree).reduce((a, c) => { a[c] = Object.keys(osd_tree[c]).sort(); return a; }, {});
while (hosts.length < pg_size)
while (hosts.length < 3)
{
osds[NO_OSD] = [ NO_OSD ];
hosts.push(NO_OSD);
}
let host_idx = [];
let osd_idx = [];
for (let i = 0; i < pg_size; i++)
{
host_idx.push(i);
osd_idx.push(0);
}
let host_idx = [ 0, 1, 2 ];
let osd_idx = [ 0, 0, 0 ];
const r = [];
while (!count || count < 0 || r.length < count)
{
r.push(host_idx.map((hi, i) => osds[hosts[hi]][osd_idx[i]]));
let inc = pg_size-1;
while (inc >= 0)
let inc;
if (host_idx[2] != host_idx[1] && host_idx[2] != host_idx[0] && host_idx[1] != host_idx[0])
{
osd_idx[inc]++;
if (osd_idx[inc] >= osds[hosts[host_idx[inc]]].length)
r.push(host_idx.map((hi, i) => osds[hosts[hi]][osd_idx[i]]));
inc = 2;
while (inc >= 0)
{
osd_idx[inc] = 0;
inc--;
}
else
{
break;
}
}
if (inc < 0)
{
// no osds left in the current host combination, select the next one
inc = pg_size-1;
same_again: while (inc >= 0)
{
host_idx[inc]++;
for (let prev_host = 0; prev_host < inc; prev_host++)
osd_idx[inc]++;
if (osd_idx[inc] >= osds[hosts[host_idx[inc]]].length)
{
if (host_idx[prev_host] == host_idx[inc])
{
continue same_again;
}
}
if (host_idx[inc] < (ordered ? hosts.length-(pg_size-1-inc) : hosts.length))
{
while ((++inc) < pg_size)
{
host_idx[inc] = (ordered ? host_idx[inc-1]+1 : 0);
}
break;
osd_idx[inc] = 0;
inc--;
}
else
{
inc--;
break;
}
}
if (inc < 0)
}
else
{
inc = -1;
}
if (inc < 0)
{
// no osds left in current host combination, select the next one
osd_idx = [ 0, 0, 0 ];
host_idx[2]++;
if (host_idx[2] >= hosts.length)
{
break;
host_idx[1]++;
host_idx[2] = ordered ? host_idx[1]+1 : 0;
if ((ordered ? host_idx[2] : host_idx[1]) >= hosts.length)
{
host_idx[0]++;
host_idx[1] = ordered ? host_idx[0]+1 : 0;
host_idx[2] = ordered ? host_idx[1]+1 : 0;
if ((ordered ? host_idx[2] : host_idx[0]) >= hosts.length)
{
break;
}
}
}
}
}
@ -633,15 +468,14 @@ function pg_weights_space_efficiency(weights, pg_count, osd_sizes)
return pg_per_osd_space_efficiency(per_osd, pg_count, osd_sizes);
}
function pg_list_space_efficiency(pgs, osd_sizes, pg_minsize, parity_space)
function pg_list_space_efficiency(pgs, osd_sizes)
{
const per_osd = {};
for (const pg of pgs)
{
for (let i = 0; i < pg.length; i++)
for (const osd of pg)
{
const osd = pg[i];
per_osd[osd] = (per_osd[osd]||0) + (i >= pg_minsize ? (parity_space||1) : 1);
per_osd[osd] = (per_osd[osd]||0) + 1;
}
}
return pg_per_osd_space_efficiency(per_osd, pgs.length, osd_sizes);
@ -683,6 +517,5 @@ module.exports = {
lp_solve,
make_int_pgs,
align_pgs,
random_combinations,
all_combinations,
};

7
mon/mon-main.js → lp/mon-main.js
View File

@ -1,8 +1,5 @@
#!/usr/bin/node
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
const Mon = require('./mon.js');
const options = {};
@ -18,8 +15,8 @@ for (let i = 2; i < process.argv.length; i++)
if (!options.etcd_url)
{
console.error('USAGE: '+process.argv[0]+' '+process.argv[1]+' --etcd_url "http://127.0.0.1:2379,..." --etcd_prefix "/vitastor" --etcd_start_timeout 5 [--verbose 1]');
console.error('USAGE: '+process.argv[0]+' '+process.argv[1]+' --etcd_url "http://127.0.0.1:2379,..." --etcd_prefix "/rage" --etcd_start_timeout 5');
process.exit();
}
new Mon(options).start().catch(e => { console.error(e); process.exit(); });
new Mon(options).start();

858
lp/mon.js Normal file
View File

@ -0,0 +1,858 @@
const http = require('http');
const os = require('os');
const WebSocket = require('ws');
const LPOptimizer = require('./lp-optimizer.js');
const stableStringify = require('./stable-stringify.js');
class Mon
{
static etcd_tree = {
config: {
global: null,
/* placement_tree = {
levels: { datacenter: 1, rack: 2, host: 3, osd: 4, ... },
nodes: { host1: { level: 'host', parent: 'rack1' }, ... },
failure_domain: 'host',
} */
placement_tree: null,
osd: {},
pgs: {},
},
osd: {
state: {},
stats: {},
},
mon: {
master: null,
},
pg: {
change_stamp: null,
state: {},
stats: {},
history: {},
},
}
constructor(config)
{
// FIXME: Maybe prefer local etcd
this.etcd_urls = [];
for (let url of config.etcd_url.split(/,/))
{
let scheme = 'http';
url = url.trim().replace(/^(https?):\/\//, (m, m1) => { scheme = m1; return ''; });
if (!/\/[^\/]/.exec(url))
url += '/v3';
this.etcd_urls.push(scheme+'://'+url);
}
this.etcd_prefix = config.etcd_prefix || '/rage';
this.etcd_prefix = this.etcd_prefix.replace(/\/\/+/g, '/').replace(/^\/?(.*[^\/])\/?$/, '/$1');
this.etcd_start_timeout = (config.etcd_start_timeout || 5) * 1000;
this.state = JSON.parse(JSON.stringify(Mon.etcd_tree));
}
async start()
{
await this.load_config();
await this.get_lease();
await this.become_master();
await this.load_cluster_state();
await this.start_watcher();
await this.recheck_pgs();
}
async load_config()
{
const res = await this.etcd_call('/txn', { success: [
{ requestRange: { key: b64(this.etcd_prefix+'/config/global') } }
] }, this.etcd_start_timeout, -1);
this.parse_kv(res.responses[0].response_range.kvs[0]);
this.check_config();
}
check_config()
{
this.config.etcd_mon_timeout = Number(this.config.etcd_mon_timeout) || 0;
if (this.config.etcd_mon_timeout <= 0)
{
this.config.etcd_mon_timeout = 1000;
}
this.config.etcd_mon_retries = Number(this.config.etcd_mon_retries) || 5;
if (this.config.etcd_mon_retries < 0)
{
this.config.etcd_mon_retries = 0;
}
this.config.mon_change_timeout = Number(this.config.mon_change_timeout) || 1000;
if (this.config.mon_change_timeout < 100)
{
this.config.mon_change_timeout = 100;
}
this.config.mon_stats_timeout = Number(this.config.mon_stats_timeout) || 1000;
if (this.config.mon_stats_timeout < 100)
{
this.config.mon_stats_timeout = 100;
}
// After this number of seconds, a dead OSD will be removed from PG distribution
this.config.osd_out_time = Number(this.config.osd_out_time) || 0;
if (!this.config.osd_out_time)
{
this.config.osd_out_time = 30*60; // 30 minutes by default
}
this.config.max_osd_combinations = Number(this.config.max_osd_combinations) || 10000;
if (this.config.max_osd_combinations < 100)
{
this.config.max_osd_combinations = 100;
}
}
async start_watcher(retries)
{
let retry = 0;
if (retries >= 0 && retries < 1)
{
retries = 1;
}
while (retries < 0 || retry < retries)
{
const base = 'ws'+this.etcd_urls[Math.floor(Math.random()*this.etcd_urls.length)].substr(4);
const ok = await new Promise((ok, no) =>
{
const timer_id = setTimeout(() =>
{
this.ws.close();
ok(false);
}, timeout);
this.ws = new WebSocket(base+'/watch');
this.ws.on('open', () =>
{
if (timer_id)
clearTimeout(timer_id);
ok(true);
});
});
if (!ok)
{
this.ws = null;
}
retry++;
}
if (!this.ws)
{
this.die('Failed to open etcd watch websocket');
}
this.ws.send(JSON.stringify({
create_request: {
key: b64(this.etcd_prefix+'/'),
range_end: b64(this.etcd_prefix+'0'),
start_revision: ''+this.etcd_watch_revision,
watch_id: 1,
},
}));
this.ws.on('message', (msg) =>
{
let data;
try
{
data = JSON.parse(msg);
}
catch (e)
{
}
if (!data || !data.result || !data.result.events)
{
console.error('Garbage received from watch websocket: '+msg);
}
else
{
let stats_changed = false, changed = false;
console.log('Revision '+data.result.header.revision+' events: ');
for (const e of data.result.events)
{
this.parse_kv(e.kv);
const key = e.kv.key.substr(this.etcd_prefix.length);
if (key.substr(0, 11) == '/osd/stats/' || key.substr(0, 10) == '/pg/stats/')
{
stats_changed = true;
}
else if (key != '/stats')
{
changed = true;
}
console.log(e);
}
if (stats_changed)
{
this.schedule_update_stats();
}
if (changed)
{
this.schedule_recheck();
}
}
});
}
async get_lease()
{
const max_ttl = this.config.etcd_mon_ttl + this.config.etcd_mon_timeout/1000*this.config.etcd_mon_retries;
const res = await this.etcd_call('/lease/grant', { TTL: max_ttl }, this.config.etcd_mon_timeout, this.config.etcd_mon_retries);
this.etcd_lease_id = res.ID;
setInterval(async () =>
{
const res = await this.etcd_call('/lease/keepalive', { ID: this.etcd_lease_id }, this.config.etcd_mon_timeout, this.config.etcd_mon_retries);
if (!res.result.TTL)
{
this.die('Lease expired');
}
}, config.etcd_mon_timeout);
}
async become_master()
{
const state = { ip: this.local_ips() };
while (1)
{
const res = await this.etcd_call('/txn', {
compare: [ { target: 'CREATE', create_revision: 0, key: b64(this.etcd_prefix+'/mon/master') } ],
success: [ { key: b64(this.etcd_prefix+'/mon/master'), value: b64(JSON.stringify(state)), lease: ''+this.etcd_lease_id } ],
}, this.etcd_start_timeout, 0);
if (!res.succeeded)
{
await new Promise(ok => setTimeout(ok, this.etcd_start_timeout));
}
}
}
async load_cluster_state()
{
const res = await this.etcd_call('/txn', { success: [
{ requestRange: { key: b64(this.etcd_prefix+'/'), range_end: b64(this.etcd_prefix+'0') } },
] }, this.etcd_start_timeout, -1);
this.etcd_watch_revision = BigInt(res.header.revision)+BigInt(1);
const data = JSON.parse(JSON.stringify(Mon.etcd_tree));
for (const response of res.responses)
{
for (const kv of response.response_range.kvs)
{
this.parse_kv(kv);
}
}
this.state = data;
}
all_osds()
{
return Object.keys(this.state.osd.stats);
}
get_osd_tree()
{
this.state.config.placement_tree = this.state.config.placement_tree||{};
const levels = this.state.config.placement_tree.levels||{};
levels.host = levels.host || 100;
levels.osd = levels.osd || 101;
const tree = { '': { children: [] } };
for (const node_id in this.state.config.placement_tree.nodes||{})
{
const node_cfg = this.state.config.placement_tree.nodes[node_id];
if (!node_id || /^\d/.exec(node_id) ||
!node_cfg.level || !levels[node_cfg.level])
{
// All nodes must have non-empty non-numeric IDs and valid levels
continue;
}
tree[node_id] = { id: node_id, level: node_cfg.level, parent: node_cfg.parent, children: [] };
}
// This requires monitor system time to be in sync with OSD system times (at least to some extent)
const down_time = Date.now()/1000 - this.config.osd_out_time;
for (const osd_num of this.all_osds().sort((a, b) => a - b))
{
const stat = this.state.osd.stats[osd_num];
if (stat.size && (this.state.osd.state[osd_num] || Number(stat.time) >= down_time))
{
// Numeric IDs are reserved for OSDs
const reweight = this.state.config.osd[osd_num] && Number(this.state.config.osd[osd_num].reweight) || 1;
tree[osd_num] = tree[osd_num] || { id: osd_num, parent: stat.host };
tree[osd_num].level = 'osd';
tree[osd_num].size = reweight * stat.size / 1024 / 1024 / 1024 / 1024; // terabytes
delete tree[osd_num].children;
}
}
for (const node_id in tree)
{
if (node_id === '')
{
continue;
}
const node_cfg = tree[node_id];
const node_level = levels[node_cfg.level] || node_cfg.level;
let parent_level = node_cfg.parent && tree[node_cfg.parent] && tree[node_cfg.parent].children
&& tree[node_cfg.parent].level;
parent_level = parent_level ? (levels[parent_level] || parent_level) : null;
// Parent's level must be less than child's; OSDs must be leaves
const parent = parent_level && parent_level < node_level ? tree[node_cfg.parent] : '';
tree[parent].children.push(tree[node_id]);
delete node_cfg.parent;
}
return LPOptimizer.flatten_tree(tree[''].children, levels, this.state.config.failure_domain, 'osd');
}
async stop_all_pgs()
{
let has_online = false, paused = true;
for (const pg in this.state.config.pgs.items||{})
{
const cur_state = ((this.state.pg.state[pg]||{}).state||[]).join(',');
if (cur_state != '' && cur_state != 'offline')
{
has_online = true;
}
if (!this.state.config.pgs.items[pg].pause)
{
paused = false;
}
}
if (!paused)
{
console.log('Stopping all PGs before changing PG count');
const new_cfg = JSON.parse(JSON.stringify(this.state.config.pgs));
for (const pg in new_cfg.items)
{
new_cfg.items[pg].pause = true;
}
// Check that no OSDs change their state before we pause PGs
// Doing this we make sure that OSDs don't wake up in the middle of our "transaction"
// and can't see the old PG configuration
const checks = [];
for (const osd_num of this.all_osds())
{
const key = b64(this.etcd_prefix+'/osd/state/'+osd_num);
checks.push({ key, target: 'MOD', result: 'LESS', mod_revision: ''+this.etcd_watch_revision });
}
const res = await this.etcd_call('/txn', {
compare: [
{ key: b64(this.etcd_prefix+'/mon/master'), target: 'LEASE', lease: ''+this.etcd_lease_id },
{ key: b64(this.etcd_prefix+'/config/pgs'), target: 'MOD', mod_revision: ''+this.etcd_watch_revision, result: 'LESS' },
...checks,
],
success: [
{ requestPut: { key: b64(this.etcd_prefix+'/config/pgs'), value: b64(JSON.stringify(new_cfg)) } },
],
}, this.config.etcd_mon_timeout, 0);
if (!res.succeeded)
{
return false;
}
this.state.config.pgs = new_cfg;
}
return !has_online;
}
scale_pg_count(prev_pgs, pg_history, new_pg_count)
{
const old_pg_count = prev_pgs.length;
// Add all possibly intersecting PGs into the history of new PGs
if (!(new_pg_count % old_pg_count))
{
// New PG count is a multiple of the old PG count
const mul = (new_pg_count / old_pg_count);
for (let i = 0; i < new_pg_count; i++)
{
const old_i = Math.floor(new_pg_count / mul);
pg_history[i] = JSON.parse(JSON.stringify(this.state.pg.history[1+old_i]));
}
}
else if (!(old_pg_count % new_pg_count))
{
// Old PG count is a multiple of the new PG count
const mul = (old_pg_count / new_pg_count);
for (let i = 0; i < new_pg_count; i++)
{
pg_history[i] = {
osd_sets: [],
all_peers: [],
};
for (let j = 0; j < mul; j++)
{
pg_history[i].osd_sets.push(prev_pgs[i*mul]);
const hist = this.state.pg.history[1+i*mul+j];
if (hist && hist.osd_sets && hist.osd_sets.length)
{
Array.prototype.push.apply(pg_history[i].osd_sets, hist.osd_sets);
}
if (hist && hist.all_peers && hist.all_peers.length)
{
Array.prototype.push.apply(pg_history[i].all_peers, hist.all_peers);
}
}
}
}
else
{
// Any PG may intersect with any PG after non-multiple PG count change
// So, merge ALL PGs history
let all_sets = {};
let all_peers = {};
for (const pg of prev_pgs)
{
all_sets[pg.join(' ')] = pg;
}
for (const pg in this.state.pg.history)
{
const hist = this.state.pg.history[pg];
if (hist && hist.osd_sets)
{
for (const pg of hist.osd_sets)
{
all_sets[pg.join(' ')] = pg;
}
}
if (hist && hist.all_peers)
{
for (const osd_num of hist.all_peers)
{
all_peers[osd_num] = Number(osd_num);
}
}
}
all_sets = Object.values(all_sets);
all_peers = Object.values(all_peers);
for (let i = 0; i < new_pg_count; i++)
{
pg_history[i] = { osd_sets: all_sets, all_peers };
}
}
// Mark history keys for removed PGs as removed
for (let i = new_pg_count; i < old_pg_count; i++)
{
pg_history[i] = null;
}
if (old_pg_count < new_pg_count)
{
for (let i = new_pg_count-1; i >= 0; i--)
{
prev_pgs[i] = prev_pgs[Math.floor(i/new_pg_count*old_pg_count)];
}
}
else if (old_pg_count > new_pg_count)
{
for (let i = 0; i < new_pg_count; i++)
{
prev_pgs[i] = prev_pgs[Math.round(i/new_pg_count*old_pg_count)];
}
prev_pgs.splice(new_pg_count, old_pg_count-new_pg_count);
}
}
async save_new_pgs(prev_pgs, new_pgs, pg_history, tree_hash)
{
const txn = [], checks = [];
const pg_items = {};
new_pgs.map((osd_set, i) =>
{
osd_set = osd_set.map(osd_num => osd_num === LPOptimizer.NO_OSD ? 0 : osd_num);
const alive_set = osd_set.filter(osd_num => osd_num);
pg_items[i+1] = {
osd_set,
primary: alive_set.length ? alive_set[Math.floor(Math.random()*alive_set.length)] : 0,
};
if (prev_pgs[i] && prev_pgs[i].join(' ') != osd_set.join(' '))
{
pg_history[i] = pg_history[i] || {};
pg_history[i].osd_sets = pg_history[i].osd_sets || [];
pg_history[i].osd_sets.push(prev_pgs[i]);
}
});
for (let i = 0; i < new_pgs.length || i < prev_pgs.length; i++)
{
checks.push({
key: b64(this.etcd_prefix+'/pg/history/'+(i+1)),
target: 'MOD',
mod_revision: ''+this.etcd_watch_revision,
result: 'LESS',
});
if (pg_history[i])
{
txn.push({
requestPut: {
key: b64(this.etcd_prefix+'/pg/history/'+(i+1)),
value: b64(JSON.stringify(pg_history[i])),
},
});
}
else
{
txn.push({
requestDeleteRange: {
key: b64(this.etcd_prefix+'/pg/history/'+(i+1)),
},
});
}
}
this.state.config.pgs = {
hash: tree_hash,
items: pg_items,
};
const res = await this.etcd_call('/txn', {
compare: [
{ key: b64(this.etcd_prefix+'/mon/master'), target: 'LEASE', lease: ''+this.etcd_lease_id },
{ key: b64(this.etcd_prefix+'/config/pgs'), target: 'MOD', mod_revision: ''+this.etcd_watch_revision, result: 'LESS' },
...checks,
],
success: [
{ requestPut: { key: b64(this.etcd_prefix+'/config/pgs'), value: b64(JSON.stringify(this.state.config.pgs)) } },
...txn,
],
}, this.config.etcd_mon_timeout, 0);
return res.succeeded;
}
async recheck_pgs()
{
// Take configuration and state, check it against the stored configuration hash
// Recalculate PGs and save them to etcd if the configuration is changed
const tree_cfg = {
osd_tree: this.get_osd_tree(),
pg_count: this.config.pg_count || Object.keys(this.state.config.pgs.items||{}).length || 128,
max_osd_combinations: this.config.max_osd_combinations,
};
const tree_hash = sha1hex(stableStringify(tree_cfg));
if (this.state.config.pgs.hash != tree_hash)
{
// Something has changed
const prev_pgs = [];
for (const pg in this.state.config.pgs.items||{})
{
prev_pgs[pg-1] = this.state.config.pgs.items[pg].osd_set;
}
const pg_history = [];
const old_pg_count = prev_pgs.length;
let optimize_result;
if (old_pg_count > 0)
{
if (old_pg_count != tree_cfg.pg_count)
{
// PG count changed. Need to bring all PGs down.
if (!await this.stop_all_pgs())
{
this.schedule_recheck();
return;
}
this.scale_pg_count(prev_pgs, pg_history, new_pg_count);
}
optimize_result = await LPOptimizer.optimize_change(prev_pgs, tree_cfg.osd_tree, tree_cfg.max_osd_combinations);
}
else
{
optimize_result = await LPOptimizer.optimize_initial(tree_cfg.osd_tree, tree_cfg.pg_count, tree_cfg.max_osd_combinations);
}
if (!await this.save_new_pgs(prev_pgs, optimize_result.int_pgs, pg_history, tree_hash))
{
console.log('Someone changed PG configuration while we also tried to change it. Retrying in '+this.config.mon_change_timeout+' ms');
this.schedule_recheck();
return;
}
console.log('PG configuration successfully changed');
if (old_pg_count != optimize_result.int_pgs.length)
{
console.log(`PG count changed from: ${old_pg_count} to ${optimize_result.int_pgs.length}`);
}
LPOptimizer.print_change_stats(optimize_result);
}
}
schedule_recheck()
{
if (this.recheck_timer)
{
clearTimeout(this.recheck_timer);
this.recheck_timer = null;
}
this.recheck_timer = setTimeout(() =>
{
this.recheck_timer = null;
this.recheck_pgs().catch(console.error);
}, this.config.mon_change_timeout || 1000);
}
sum_stats()
{
let overflow = false;
this.prev_stats = this.prev_stats || { op_stats: {}, subop_stats: {}, recovery_stats: {} };
const op_stats = {}, subop_stats = {}, recovery_stats = {};
for (const osd in this.state.osd.stats)
{
const st = this.state.osd.stats[osd];
for (const op in st.op_stats||{})
{
op_stats[op] = op_stats[op] || { count: 0n, usec: 0n, bytes: 0n };
op_stats[op].count += BigInt(st.op_stats.count||0);
op_stats[op].usec += BigInt(st.op_stats.usec||0);
op_stats[op].bytes += BigInt(st.op_stats.bytes||0);
}
for (const op in st.subop_stats||{})
{
subop_stats[op] = subop_stats[op] || { count: 0n, usec: 0n };
subop_stats[op].count += BigInt(st.subop_stats.count||0);
subop_stats[op].usec += BigInt(st.subop_stats.usec||0);
}
for (const op in st.recovery_stats||{})
{
recovery_stats[op] = recovery_stats[op] || { count: 0n, bytes: 0n };
recovery_stats[op].count += BigInt(st.recovery_stats.count||0);
recovery_stats[op].bytes += BigInt(st.recovery_stats.bytes||0);
}
}
for (const op in op_stats)
{
if (op_stats[op].count >= 0x10000000000000000n)
{
if (!this.prev_stats.op_stats[op])
{
overflow = true;
}
else
{
op_stats[op].count -= this.prev_stats.op_stats[op].count;
op_stats[op].usec -= this.prev_stats.op_stats[op].usec;
op_stats[op].bytes -= this.prev_stats.op_stats[op].bytes;
}
}
}
for (const op in subop_stats)
{
if (subop_stats[op].count >= 0x10000000000000000n)
{
if (!this.prev_stats.subop_stats[op])
{
overflow = true;
}
else
{
subop_stats[op].count -= this.prev_stats.subop_stats[op].count;
subop_stats[op].usec -= this.prev_stats.subop_stats[op].usec;
}
}
}
for (const op in recovery_stats)
{
if (recovery_stats[op].count >= 0x10000000000000000n)
{
if (!this.prev_stats.recovery_stats[op])
{
overflow = true;
}
else
{
recovery_stats[op].count -= this.prev_stats.recovery_stats[op].count;
recovery_stats[op].bytes -= this.prev_stats.recovery_stats[op].bytes;
}
}
}
const object_counts = { object: 0n, clean: 0n, misplaced: 0n, degraded: 0n, incomplete: 0n };
for (const pg_num in this.state.pg.stats)
{
const st = this.state.pg.stats[pg_num];
for (const k in object_counts)
{
if (st[k+'_count'])
{
object_counts[k] += BigInt(st[k+'_count']);
}
}
}
return (this.prev_stats = { overflow, op_stats, subop_stats, recovery_stats, object_counts });
}
async update_total_stats()
{
const stats = this.sum_stats();
if (!stats.overflow)
{
// Convert to strings, serialize and save
const ser = {};
for (const st of [ 'op_stats', 'subop_stats', 'recovery_stats' ])
{
ser[st] = {};
for (const op in stats[st])
{
ser[st][op] = {};
for (const k in stats[st][op])
{
ser[st][op][k] = ''+stats[st][op][k];
}
}
}
ser.object_counts = {};
for (const k in stats.object_counts)
{
ser.object_counts[k] = ''+stats.object_counts[k];
}
await this.etcd_call('/txn', {
success: [ { requestPut: { key: b64(this.etcd_prefix+'/stats'), value: b64(JSON.stringify(ser)) } } ],
}, this.config.etcd_mon_timeout, 0);
}
}
schedule_update_stats()
{
if (this.stats_timer)
{
clearTimeout(this.stats_timer);
this.stats_timer = null;
}
this.stats_timer = setTimeout(() =>
{
this.stats_timer = null;
this.update_total_stats().catch(console.error);
}, this.config.mon_stats_timeout || 1000);
}
parse_kv(kv)
{
if (!kv || !kv.key)
{
return;
}
kv.key = de64(kv.key);
kv.value = kv.value ? JSON.parse(de64(kv.value)) : null;
const key = kv.key.substr(this.etcd_prefix.length).replace(/^\/+/, '').split('/');
const cur = this.state, orig = Mon.etcd_tree;
for (let i = 0; i < key.length-1; i++)
{
if (!orig[key[i]])
{
console.log('Bad key in etcd: '+kv.key+' = '+kv.value);
return;
}
orig = orig[key[i]];
cur = (cur[key[i]] = cur[key[i]] || {});
}
if (orig[key.length-1])
{
console.log('Bad key in etcd: '+kv.key+' = '+kv.value);
return;
}
cur[key[key.length-1]] = kv.value;
if (key.join('/') === 'config/global')
{
this.state.config.global = this.state.config.global || {};
this.config = this.state.config.global;
this.check_config();
}
}
async etcd_call(path, body, timeout, retries)
{
let retry = 0;
if (retries >= 0 && retries < 1)
{
retries = 1;
}
while (retries < 0 || retry < retries)
{
const base = this.etcd_urls[Math.floor(Math.random()*this.etcd_urls.length)];
const res = await POST(base+path, body, timeout);
if (res.json)
{
if (res.json.error)
{
console.log('etcd returned error: '+res.json.error);
break;
}
return res.json;
}
retry++;
}
this.die();
}
die(err)
{
// In fact we can just try to rejoin
console.fatal(err || 'Cluster connection failed');
process.exit(1);
}
local_ips()
{
const ips = [];
const ifaces = os.networkInterfaces();
for (const ifname in ifaces)
{
for (const iface of ifaces[ifname])
{
if (iface.family == 'IPv4' && !iface.internal)
{
ips.push(iface.address);
}
}
}
return ips;
}
}
function POST(url, body, timeout)
{
return new Promise((ok, no) =>
{
const body_text = Buffer.from(JSON.stringify(body));
let timer_id = timeout > 0 ? setTimeout(() =>
{
if (req)
req.abort();
req = null;
ok({ error: 'timeout' });
}, timeout) : null;
let req = http.request(url, { method: 'POST', headers: {
'Content-Type': 'application/json',
'Content-Length': body_text,
} }, (res) =>
{
if (!req)
{
return;
}
clearTimeout(timer_id);
if (res.statusCode != 200)
{
ok({ error: res.statusCode, response: res });
return;
}
let res_body = '';
res.setEncoding('utf8');
res.on('data', chunk => { res_body += chunk });
res.on('end', () =>
{
try
{
res_body = JSON.parse(res_body);
ok({ response: res, json: res_body });
}
catch (e)
{
ok({ error: e, response: res, body: res_body });
}
});
});
req.write(body_text);
req.end();
});
}
function b64(str)
{
return Buffer.from(str).toString('base64');
}
function de64(str)
{
return Buffer.from(str, 'base64').toString();
}
function sha1hex(str)
{
const hash = crypto.createHash('sha1');
hash.update(str);
return hash.digest('hex');
}

7
mon/package.json → lp/package.json
View File

@ -1,15 +1,14 @@
{
"name": "vitastor-mon",
"name": "rage-mon",
"version": "1.0.0",
"description": "Vitastor SDS monitor service",
"main": "mon-main.js",
"description": "RAGE storage monitor service",
"main": "mon.js",
"scripts": {
"test": "echo \"Error: no test specified\" && exit 1"
},
"author": "Vitaliy Filippov",
"license": "UNLICENSED",
"dependencies": {
"sprintf-js": "^1.1.2",
"ws": "^7.2.5"
}
}

17
mon/test-optimize-undersized.js → lp/test-optimize-undersized.js
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
const LPOptimizer = require('./lp-optimizer.js');
const crush_tree = [
@ -43,31 +40,31 @@ async function run()
{
const cur_tree = {};
console.log('Empty tree:');
let res = await LPOptimizer.optimize_initial({ osd_tree: cur_tree, pg_size: 3, pg_count: 256 });
let res = await LPOptimizer.optimize_initial(cur_tree, 256);
LPOptimizer.print_change_stats(res, false);
console.log('\nAdding 1st failure domain:');
cur_tree['dom1'] = osd_tree['dom1'];
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree: cur_tree, pg_size: 3 });
res = await LPOptimizer.optimize_change(res.int_pgs, cur_tree);
LPOptimizer.print_change_stats(res, false);
console.log('\nAdding 2nd failure domain:');
cur_tree['dom2'] = osd_tree['dom2'];
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree: cur_tree, pg_size: 3 });
res = await LPOptimizer.optimize_change(res.int_pgs, cur_tree);
LPOptimizer.print_change_stats(res, false);
console.log('\nAdding 3rd failure domain:');
cur_tree['dom3'] = osd_tree['dom3'];
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree: cur_tree, pg_size: 3 });
res = await LPOptimizer.optimize_change(res.int_pgs, cur_tree);
LPOptimizer.print_change_stats(res, false);
console.log('\nRemoving 3rd failure domain:');
delete cur_tree['dom3'];
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree: cur_tree, pg_size: 3 });
res = await LPOptimizer.optimize_change(res.int_pgs, cur_tree);
LPOptimizer.print_change_stats(res, false);
console.log('\nRemoving 2nd failure domain:');
delete cur_tree['dom2'];
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree: cur_tree, pg_size: 3 });
res = await LPOptimizer.optimize_change(res.int_pgs, cur_tree);
LPOptimizer.print_change_stats(res, false);
console.log('\nRemoving 1st failure domain:');
delete cur_tree['dom1'];
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree: cur_tree, pg_size: 3 });
res = await LPOptimizer.optimize_change(res.int_pgs, cur_tree);
LPOptimizer.print_change_stats(res, false);
}

35
mon/test-optimize.js → lp/test-optimize.js
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
const LPOptimizer = require('./lp-optimizer.js');
const osd_tree = {
@ -78,37 +75,19 @@ const crush_tree = [
async function run()
{
let res;
// Test: add 1 OSD of almost the same size. Ideal data movement could be 1/12 = 8.33%. Actual is ~13%
// Space efficiency is ~99% in all cases.
console.log('256 PGs, size=2');
res = await LPOptimizer.optimize_initial({ osd_tree, pg_size: 2, pg_count: 256 });
// Space efficiency is ~99.5% in both cases.
let res = await LPOptimizer.optimize_initial(osd_tree, 256);
LPOptimizer.print_change_stats(res, false);
console.log('\nAdding osd.8');
console.log('adding osd.8');
osd_tree[500][8] = 3.58589;
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree, pg_size: 2 });
res = await LPOptimizer.optimize_change(res.int_pgs, osd_tree);
LPOptimizer.print_change_stats(res, false);
console.log('\nRemoving osd.8');
console.log('removing osd.8');
delete osd_tree[500][8];
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree, pg_size: 2 });
res = await LPOptimizer.optimize_change(res.int_pgs, osd_tree);
LPOptimizer.print_change_stats(res, false);
console.log('\n256 PGs, size=3');
res = await LPOptimizer.optimize_initial({ osd_tree, pg_size: 3, pg_count: 256 });
LPOptimizer.print_change_stats(res, false);
console.log('\nAdding osd.8');
osd_tree[500][8] = 3.58589;
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree, pg_size: 3 });
LPOptimizer.print_change_stats(res, false);
console.log('\nRemoving osd.8');
delete osd_tree[500][8];
res = await LPOptimizer.optimize_change({ prev_pgs: res.int_pgs, osd_tree, pg_size: 3 });
LPOptimizer.print_change_stats(res, false);
console.log('\n256 PGs, size=3, failure domain=rack');
res = await LPOptimizer.optimize_initial({ osd_tree: LPOptimizer.flatten_tree(crush_tree, {}, 1, 3), pg_size: 3, pg_count: 256 });
res = await LPOptimizer.optimize_initial(LPOptimizer.flatten_tree(crush_tree, {}, 1, 3), 256);
LPOptimizer.print_change_stats(res, false);
}

50
malloc_or_die.h
View File

@ -1,50 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include <malloc.h>
inline void* memalign_or_die(size_t alignment, size_t size)
{
void *buf = memalign(alignment, size);
if (!buf)
{
printf("Failed to allocate %lu bytes\n", size);
exit(1);
}
return buf;
}
inline void* malloc_or_die(size_t size)
{
void *buf = malloc(size);
if (!buf)
{
printf("Failed to allocate %lu bytes\n", size);
exit(1);
}
return buf;
}
inline void* realloc_or_die(void *ptr, size_t size)
{
void *buf = realloc(ptr, size);
if (!buf)
{
printf("Failed to allocate %lu bytes\n", size);
exit(1);
}
return buf;
}
inline void* calloc_or_die(size_t nmemb, size_t size)
{
void *buf = calloc(nmemb, size);
if (!buf)
{
printf("Failed to allocate %lu bytes\n", size * nmemb);
exit(1);
}
return buf;
}

34
messenger.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include <unistd.h>
#include <fcntl.h>
#include <sys/socket.h>
@ -25,14 +22,6 @@ osd_op_t::~osd_op_t()
}
}
osd_messenger_t::~osd_messenger_t()
{
while (clients.size() > 0)
{
stop_client(clients.begin()->first);
}
}
void osd_messenger_t::connect_peer(uint64_t peer_osd, json11::Json peer_state)
{
if (wanted_peers.find(peer_osd) == wanted_peers.end())
@ -74,7 +63,6 @@ void osd_messenger_t::try_connect_peer(uint64_t peer_osd)
}
wp.cur_addr = wp.address_list[wp.address_index].string_value();
wp.cur_port = wp.port;
wp.connecting = true;
try_connect_peer_addr(peer_osd, wp.cur_addr.c_str(), wp.cur_port);
}
@ -122,9 +110,9 @@ void osd_messenger_t::try_connect_peer_addr(osd_num_t peer_osd, const char *peer
.peer_state = PEER_CONNECTING,
.connect_timeout_id = timeout_id,
.osd_num = peer_osd,
.in_buf = malloc_or_die(receive_buffer_size),
.in_buf = malloc(receive_buffer_size),
};
tfd->set_fd_handler(peer_fd, true, [this](int peer_fd, int epoll_events)
tfd->set_fd_handler(peer_fd, [this](int peer_fd, int epoll_events)
{
// Either OUT (connected) or HUP
handle_connect_epoll(peer_fd);
@ -155,7 +143,8 @@ void osd_messenger_t::handle_connect_epoll(int peer_fd)
int one = 1;
setsockopt(peer_fd, SOL_TCP, TCP_NODELAY, &one, sizeof(one));
cl.peer_state = PEER_CONNECTED;
tfd->set_fd_handler(peer_fd, false, [this](int peer_fd, int epoll_events)
// FIXME Disable EPOLLOUT on this fd
tfd->set_fd_handler(peer_fd, [this](int peer_fd, int epoll_events)
{
handle_peer_epoll(peer_fd, epoll_events);
});
@ -180,10 +169,7 @@ void osd_messenger_t::handle_peer_epoll(int peer_fd, int epoll_events)
if (cl.read_ready == 1)
{
read_ready_clients.push_back(cl.peer_fd);
if (ringloop)
ringloop->wakeup();
else
read_requests();
ringloop->wakeup();
}
}
}
@ -228,6 +214,7 @@ void osd_messenger_t::check_peer_config(osd_client_t & cl)
{
osd_op_t *op = new osd_op_t();
op->op_type = OSD_OP_OUT;
op->send_list.push_back(op->req.buf, OSD_PACKET_SIZE);
op->peer_fd = cl.peer_fd;
op->req = {
.show_conf = {
@ -261,13 +248,12 @@ void osd_messenger_t::check_peer_config(osd_client_t & cl)
{
err = true;
printf("Connected to OSD %lu instead of OSD %lu, peer state is outdated, disconnecting peer\n", config["osd_num"].uint64_value(), cl.osd_num);
on_connect_peer(cl.osd_num, -1);
}
}
if (err)
{
osd_num_t osd_num = cl.osd_num;
stop_client(op->peer_fd);
on_connect_peer(osd_num, -1);
delete op;
return;
}
@ -339,7 +325,7 @@ void osd_messenger_t::stop_client(int peer_fd)
}
}
clients.erase(it);
tfd->set_fd_handler(peer_fd, false, NULL);
tfd->set_fd_handler(peer_fd, NULL);
if (cl.osd_num)
{
osd_peer_fds.erase(cl.osd_num);
@ -395,10 +381,10 @@ void osd_messenger_t::accept_connections(int listen_fd)
.peer_port = ntohs(addr.sin_port),
.peer_fd = peer_fd,
.peer_state = PEER_CONNECTED,
.in_buf = malloc_or_die(receive_buffer_size),
.in_buf = malloc(receive_buffer_size),
};
// Add FD to epoll
tfd->set_fd_handler(peer_fd, false, [this](int peer_fd, int epoll_events)
tfd->set_fd_handler(peer_fd, [this](int peer_fd, int epoll_events)
{
handle_peer_epoll(peer_fd, epoll_events);
});

130
messenger.h
View File

@ -1,18 +1,15 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include <sys/types.h>
#include <stdint.h>
#include <arpa/inet.h>
#include <malloc.h>
#include <set>
#include <map>
#include <deque>
#include <vector>
#include "malloc_or_die.h"
#include "json11/json11.hpp"
#include "osd_ops.h"
#include "timerfd_manager.h"
@ -34,32 +31,13 @@
#define DEFAULT_PEER_CONNECT_INTERVAL 5
#define DEFAULT_PEER_CONNECT_TIMEOUT 5
// Kind of a vector with small-list-optimisation
struct osd_op_buf_list_t
{
int count = 0, alloc = OSD_OP_INLINE_BUF_COUNT, done = 0;
int count = 0, alloc = 0, sent = 0;
iovec *buf = NULL;
iovec inline_buf[OSD_OP_INLINE_BUF_COUNT];
inline osd_op_buf_list_t()
{
buf = inline_buf;
}
inline osd_op_buf_list_t(const osd_op_buf_list_t & other)
{
buf = inline_buf;
append(other);
}
inline osd_op_buf_list_t & operator = (const osd_op_buf_list_t & other)
{
reset();
append(other);
return *this;
}
inline ~osd_op_buf_list_t()
~osd_op_buf_list_t()
{
if (buf && buf != inline_buf)
{
@ -67,103 +45,40 @@ struct osd_op_buf_list_t
}
}
inline void reset()
{
count = 0;
done = 0;
}
inline iovec* get_iovec()
{
return buf + done;
return (buf ? buf : inline_buf) + sent;
}
inline int get_size()
{
return count - done;
}
inline void append(const osd_op_buf_list_t & other)
{
if (count+other.count > alloc)
{
if (buf == inline_buf)
{
int old = alloc;
alloc = (((count+other.count+15)/16)*16);
buf = (iovec*)malloc(sizeof(iovec) * alloc);
if (!buf)
{
printf("Failed to allocate %lu bytes\n", sizeof(iovec) * alloc);
exit(1);
}
memcpy(buf, inline_buf, sizeof(iovec) * old);
}
else
{
alloc = (((count+other.count+15)/16)*16);
buf = (iovec*)realloc(buf, sizeof(iovec) * alloc);
if (!buf)
{
printf("Failed to allocate %lu bytes\n", sizeof(iovec) * alloc);
exit(1);
}
}
}
for (int i = 0; i < other.count; i++)
{
buf[count++] = other.buf[i];
}
return count - sent;
}
inline void push_back(void *nbuf, size_t len)
{
if (count >= alloc)
{
if (buf == inline_buf)
if (!alloc)
{
alloc = OSD_OP_INLINE_BUF_COUNT;
buf = inline_buf;
}
else if (buf == inline_buf)
{
int old = alloc;
alloc = ((alloc/16)*16 + 1);
buf = (iovec*)malloc(sizeof(iovec) * alloc);
if (!buf)
{
printf("Failed to allocate %lu bytes\n", sizeof(iovec) * alloc);
exit(1);
}
memcpy(buf, inline_buf, sizeof(iovec)*old);
}
else
{
alloc = alloc < 16 ? 16 : (alloc+16);
alloc = ((alloc/16)*16 + 1);
buf = (iovec*)realloc(buf, sizeof(iovec) * alloc);
if (!buf)
{
printf("Failed to allocate %lu bytes\n", sizeof(iovec) * alloc);
exit(1);
}
}
}
buf[count++] = { .iov_base = nbuf, .iov_len = len };
}
inline void eat(int result)
{
while (result > 0 && done < count)
{
iovec & iov = buf[done];
if (iov.iov_len <= result)
{
result -= iov.iov_len;
done++;
}
else
{
iov.iov_len -= result;
iov.iov_base += result;
break;
}
}
}
};
struct blockstore_op_t;
@ -183,7 +98,7 @@ struct osd_op_t
osd_primary_op_data_t* op_data = NULL;
std::function<void(osd_op_t*)> callback;
osd_op_buf_list_t iov;
osd_op_buf_list_t send_list;
~osd_op_t();
};
@ -202,11 +117,12 @@ struct osd_client_t
// Read state
int read_ready = 0;
osd_op_t *read_op = NULL;
int read_reply_id = 0;
iovec read_iov;
msghdr read_msg;
void *read_buf = NULL;
int read_remaining = 0;
int read_state = 0;
osd_op_buf_list_t recv_list;
// Incoming operations
std::vector<osd_op_t*> received_ops;
@ -215,14 +131,13 @@ struct osd_client_t
std::deque<osd_op_t*> outbox;
std::map<int, osd_op_t*> sent_ops;
// PGs dirtied by this client's primary-writes
std::set<pool_pg_num_t> dirty_pgs;
// PGs dirtied by this client's primary-writes (FIXME to drop the connection)
std::set<pg_num_t> dirty_pgs;
// Write state
osd_op_t *write_op = NULL;
msghdr write_msg;
int write_state = 0;
osd_op_buf_list_t send_list;
};
struct osd_wanted_peer_t
@ -252,12 +167,10 @@ struct osd_messenger_t
// osd_num_t is only for logging and asserts
osd_num_t osd_num;
// FIXME: make receive_buffer_size configurable
int receive_buffer_size = 64*1024;
int receive_buffer_size = 9000;
int peer_connect_interval = DEFAULT_PEER_CONNECT_INTERVAL;
int peer_connect_timeout = DEFAULT_PEER_CONNECT_TIMEOUT;
int log_level = 0;
bool use_sync_send_recv = false;
std::map<osd_num_t, osd_wanted_peer_t> wanted_peers;
std::map<uint64_t, int> osd_peer_fds;
@ -266,7 +179,6 @@ struct osd_messenger_t
std::map<int, osd_client_t> clients;
std::vector<int> read_ready_clients;
std::vector<int> write_ready_clients;
std::vector<std::function<void()>> set_immediate;
// op statistics
osd_op_stats_t stats;
@ -281,7 +193,6 @@ public:
void read_requests();
void send_replies();
void accept_connections(int listen_fd);
~osd_messenger_t();
protected:
void try_connect_peer(uint64_t osd_num);
@ -296,8 +207,7 @@ protected:
void handle_send(int result, int peer_fd);
bool handle_read(int result, int peer_fd);
bool handle_finished_read(osd_client_t & cl);
void handle_finished_read(osd_client_t & cl);
void handle_op_hdr(osd_client_t *cl);
bool handle_reply_hdr(osd_client_t *cl);
void handle_reply_ready(osd_op_t *op);
void handle_reply_hdr(osd_client_t *cl);
};

112
mon/PGUtil.js
View File

@ -1,112 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
module.exports = {
scale_pg_count,
};
function scale_pg_count(prev_pgs, prev_pg_history, new_pg_history, new_pg_count)
{
const old_pg_count = prev_pgs.length;
// Add all possibly intersecting PGs into the history of new PGs
if (!(new_pg_count % old_pg_count))
{
// New PG count is a multiple of the old PG count
const mul = (new_pg_count / old_pg_count);
for (let i = 0; i < new_pg_count; i++)
{
const old_i = Math.floor(new_pg_count / mul);
new_pg_history[i] = JSON.parse(JSON.stringify(prev_pg_history[1+old_i]));
}
}
else if (!(old_pg_count % new_pg_count))
{
// Old PG count is a multiple of the new PG count
const mul = (old_pg_count / new_pg_count);
for (let i = 0; i < new_pg_count; i++)
{
new_pg_history[i] = {
osd_sets: [],
all_peers: [],
epoch: 0,
};
for (let j = 0; j < mul; j++)
{
new_pg_history[i].osd_sets.push(prev_pgs[i*mul]);
const hist = prev_pg_history[1+i*mul+j];
if (hist && hist.osd_sets && hist.osd_sets.length)
{
Array.prototype.push.apply(new_pg_history[i].osd_sets, hist.osd_sets);
}
if (hist && hist.all_peers && hist.all_peers.length)
{
Array.prototype.push.apply(new_pg_history[i].all_peers, hist.all_peers);
}
if (hist && hist.epoch)
{
new_pg_history[i].epoch = new_pg_history[i].epoch < hist.epoch ? hist.epoch : new_pg_history[i].epoch;
}
}
}
}
else
{
// Any PG may intersect with any PG after non-multiple PG count change
// So, merge ALL PGs history
let all_sets = {};
let all_peers = {};
let max_epoch = 0;
for (const pg of prev_pgs)
{
all_sets[pg.join(' ')] = pg;
}
for (const pg in prev_pg_history)
{
const hist = prev_pg_history[pg];
if (hist && hist.osd_sets)
{
for (const pg of hist.osd_sets)
{
all_sets[pg.join(' ')] = pg;
}
}
if (hist && hist.all_peers)
{
for (const osd_num of hist.all_peers)
{
all_peers[osd_num] = Number(osd_num);
}
}
if (hist && hist.epoch)
{
max_epoch = max_epoch < hist.epoch ? hist.epoch : max_epoch;
}
}
all_sets = Object.values(all_sets);
all_peers = Object.values(all_peers);
for (let i = 0; i < new_pg_count; i++)
{
new_pg_history[i] = { osd_sets: all_sets, all_peers, epoch: max_epoch };
}
}
// Mark history keys for removed PGs as removed
for (let i = new_pg_count; i < old_pg_count; i++)
{
new_pg_history[i] = null;
}
if (old_pg_count < new_pg_count)
{
for (let i = new_pg_count-1; i >= 0; i--)
{
prev_pgs[i] = prev_pgs[Math.floor(i/new_pg_count*old_pg_count)];
}
}
else if (old_pg_count > new_pg_count)
{
for (let i = 0; i < new_pg_count; i++)
{
prev_pgs[i] = prev_pgs[Math.round(i/new_pg_count*old_pg_count)];
}
prev_pgs.splice(new_pg_count, old_pg_count-new_pg_count);
}
}

159
mon/afr.js
View File

@ -1,159 +0,0 @@
// Functions to calculate Annualized Failure Rate of your cluster
// if you know AFR of your drives, number of drives, expected rebalance time
// and replication factor
// License: VNPL-1.0 (see README.md for details)
const { sprintf } = require('sprintf-js');
module.exports = {
cluster_afr_fullmesh,
failure_rate_fullmesh,
cluster_afr,
print_cluster_afr,
c_n_k,
};
print_cluster_afr({ n_hosts: 4, n_drives: 6, afr_drive: 0.03, afr_host: 0.05, capacity: 4000, speed: 0.1, replicas: 2 });
print_cluster_afr({ n_hosts: 4, n_drives: 3, afr_drive: 0.03, capacity: 4000, speed: 0.1, replicas: 2 });
print_cluster_afr({ n_hosts: 4, n_drives: 3, afr_drive: 0.03, afr_host: 0.05, capacity: 4000, speed: 0.1, replicas: 2 });
print_cluster_afr({ n_hosts: 4, n_drives: 3, afr_drive: 0.03, capacity: 4000, speed: 0.1, ec: [ 2, 1 ] });
print_cluster_afr({ n_hosts: 4, n_drives: 3, afr_drive: 0.03, afr_host: 0.05, capacity: 4000, speed: 0.1, ec: [ 2, 1 ] });
print_cluster_afr({ n_hosts: 10, n_drives: 10, afr_drive: 0.1, capacity: 8000, speed: 0.02, replicas: 2 });
print_cluster_afr({ n_hosts: 10, n_drives: 10, afr_drive: 0.1, afr_host: 0.05, capacity: 8000, speed: 0.02, replicas: 2 });
print_cluster_afr({ n_hosts: 10, n_drives: 10, afr_drive: 0.1, capacity: 8000, speed: 0.02, replicas: 3 });
print_cluster_afr({ n_hosts: 10, n_drives: 10, afr_drive: 0.1, afr_host: 0.05, capacity: 8000, speed: 0.02, replicas: 3 });
print_cluster_afr({ n_hosts: 10, n_drives: 10, afr_drive: 0.1, capacity: 8000, speed: 0.02, replicas: 3, pgs: 100 });
print_cluster_afr({ n_hosts: 10, n_drives: 10, afr_drive: 0.1, afr_host: 0.05, capacity: 8000, speed: 0.02, replicas: 3, pgs: 100 });
print_cluster_afr({ n_hosts: 10, n_drives: 10, afr_drive: 0.1, afr_host: 0.05, capacity: 8000, speed: 0.02, replicas: 3, pgs: 100, degraded_replacement: 1 });
/******** "FULL MESH": ASSUME EACH OSD COMMUNICATES WITH ALL OTHER OSDS ********/
// Estimate AFR of the cluster
// n - number of drives
// afr - annualized failure rate of a single drive
// l - expected rebalance time in days after a single drive failure
// k - replication factor / number of drives that must fail at the same time for the cluster to fail
function cluster_afr_fullmesh(n, afr, l, k)
{
return 1 - (1 - afr * failure_rate_fullmesh(n-(k-1), afr*l/365, k-1)) ** (n-(k-1));
}
// Probability of at least <f> failures in a cluster with <n> drives with AFR=<a>
function failure_rate_fullmesh(n, a, f)
{
if (f <= 0)
{
return (1-a)**n;
}
let p = 1;
for (let i = 0; i < f; i++)
{
p -= c_n_k(n, i) * (1-a)**(n-i) * a**i;
}
return p;
}
/******** PGS: EACH OSD ONLY COMMUNICATES WITH <pgs> OTHER OSDs ********/
// <n> hosts of <m> drives of <capacity> GB, each able to backfill at <speed> GB/s,
// <k> replicas, <pgs> unique peer PGs per OSD
//
// For each of n*m drives: P(drive fails in a year) * P(any of its peers fail in <l*365> next days).
// More peers per OSD increase rebalance speed (more drives work together to resilver) if you
// let them finish rebalance BEFORE replacing the failed drive.
// At the same time, more peers per OSD increase probability of any of them to fail!
//
// Probability of all except one drives in a replica group to fail is (AFR^(k-1)).
// So with <x> PGs it becomes ~ (x * (AFR*L/365)^(k-1)). Interesting but reasonable consequence
// is that, with k=2, total failure rate doesn't depend on number of peers per OSD,
// because it gets increased linearly by increased number of peers to fail
// and decreased linearly by reduced rebalance time.
function cluster_afr_pgs({ n_hosts, n_drives, afr_drive, capacity, speed, replicas, pgs = 1, degraded_replacement })
{
pgs = Math.min(pgs, (n_hosts-1)*n_drives/(replicas-1));
const l = capacity/(degraded_replacement ? 1 : pgs)/speed/86400/365;
return 1 - (1 - afr_drive * (1-(1-(afr_drive*l)**(replicas-1))**pgs)) ** (n_hosts*n_drives);
}
function cluster_afr_pgs_ec({ n_hosts, n_drives, afr_drive, capacity, speed, ec: [ ec_data, ec_parity ], pgs = 1, degraded_replacement })
{
const ec_total = ec_data+ec_parity;
pgs = Math.min(pgs, (n_hosts-1)*n_drives/(ec_total-1));
const l = capacity/(degraded_replacement ? 1 : pgs)/speed/86400/365;
return 1 - (1 - afr_drive * (1-(1-failure_rate_fullmesh(ec_total-1, afr_drive*l, ec_parity))**pgs)) ** (n_hosts*n_drives);
}
// Same as above, but also take server failures into account
function cluster_afr_pgs_hosts({ n_hosts, n_drives, afr_drive, afr_host, capacity, speed, replicas, pgs = 1, degraded_replacement })
{
let otherhosts = Math.min(pgs, (n_hosts-1)/(replicas-1));
pgs = Math.min(pgs, (n_hosts-1)*n_drives/(replicas-1));
let pgh = Math.min(pgs*n_drives, (n_hosts-1)*n_drives/(replicas-1));
const ld = capacity/(degraded_replacement ? 1 : pgs)/speed/86400/365;
const lh = n_drives*capacity/pgs/speed/86400/365;
const p1 = ((afr_drive+afr_host*pgs/otherhosts)*lh);
const p2 = ((afr_drive+afr_host*pgs/otherhosts)*ld);
return 1 - ((1 - afr_host * (1-(1-p1**(replicas-1))**pgh)) ** n_hosts) *
((1 - afr_drive * (1-(1-p2**(replicas-1))**pgs)) ** (n_hosts*n_drives));
}
function cluster_afr_pgs_ec_hosts({ n_hosts, n_drives, afr_drive, afr_host, capacity, speed, ec: [ ec_data, ec_parity ], pgs = 1, degraded_replacement })
{
const ec_total = ec_data+ec_parity;
const otherhosts = Math.min(pgs, (n_hosts-1)/(ec_total-1));
pgs = Math.min(pgs, (n_hosts-1)*n_drives/(ec_total-1));
const pgh = Math.min(pgs*n_drives, (n_hosts-1)*n_drives/(ec_total-1));
const ld = capacity/(degraded_replacement ? 1 : pgs)/speed/86400/365;
const lh = n_drives*capacity/pgs/speed/86400/365;
const p1 = ((afr_drive+afr_host*pgs/otherhosts)*lh);
const p2 = ((afr_drive+afr_host*pgs/otherhosts)*ld);
return 1 - ((1 - afr_host * (1-(1-failure_rate_fullmesh(ec_total-1, p1, ec_parity))**pgh)) ** n_hosts) *
((1 - afr_drive * (1-(1-failure_rate_fullmesh(ec_total-1, p2, ec_parity))**pgs)) ** (n_hosts*n_drives));
}
// Wrapper for 4 above functions
function cluster_afr(config)
{
if (config.ec && config.afr_host)
{
return cluster_afr_pgs_ec_hosts(config);
}
else if (config.ec)
{
return cluster_afr_pgs_ec(config);
}
else if (config.afr_host)
{
return cluster_afr_pgs_hosts(config);
}
else
{
return cluster_afr_pgs(config);
}
}
function print_cluster_afr(config)
{
console.log(
`${config.n_hosts} nodes with ${config.n_drives} ${sprintf("%.1f", config.capacity/1000)}TB drives`+
`, capable to backfill at ${sprintf("%.1f", config.speed*1000)} MB/s, drive AFR ${sprintf("%.1f", config.afr_drive*100)}%`+
(config.afr_host ? `, host AFR ${sprintf("%.1f", config.afr_host*100)}%` : '')+
(config.ec ? `, EC ${config.ec[0]}+${config.ec[1]}` : `, ${config.replicas} replicas`)+
`, ${config.pgs||1} PG per OSD`+
(config.degraded_replacement ? `\n...and you don't let the rebalance finish before replacing drives` : '')
);
console.log('-> '+sprintf("%.7f%%", 100*cluster_afr(config))+'\n');
}
/******** UTILITY ********/
// Combination count
function c_n_k(n, k)
{
let r = 1;
for (let i = 0; i < k; i++)
{
r *= (n-i) / (i+1);
}
return r;
}

136
mon/make-units.sh
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@ -1,136 +0,0 @@
#!/bin/bash
# Example startup script generator
# Of course this isn't a production solution yet, this is just for tests
# Copyright (c) Vitaliy Filippov, 2019+
# License: MIT
IP=`ip -json a s | jq -r '.[].addr_info[] | select(.broadcast == "10.115.0.255") | .local'`
[ "$IP" != "" ] || exit 1
useradd vitastor
chmod 755 /root
BASE=${IP/*./}
BASE=$(((BASE-10)*12))
cat >/etc/systemd/system/vitastor.target <<EOF
[Unit]
Description=vitastor target
[Install]
WantedBy=multi-user.target
EOF
i=1
for DEV in `ls /dev/disk/by-id/ | grep ata-INTEL_SSDSC2KB`; do
dd if=/dev/zero of=/dev/disk/by-id/$DEV bs=1048576 count=$(((427814912+1048575)/1048576+2))
dd if=/dev/zero of=/dev/disk/by-id/$DEV bs=1048576 count=$(((427814912+1048575)/1048576+2)) seek=$((1920377991168/1048576))
cat >/etc/systemd/system/vitastor-osd$((BASE+i)).service <<EOF
[Unit]
Description=Vitastor object storage daemon osd.$((BASE+i))
After=network-online.target local-fs.target time-sync.target
Wants=network-online.target local-fs.target time-sync.target
PartOf=vitastor.target
[Service]
LimitNOFILE=1048576
LimitNPROC=1048576
LimitMEMLOCK=infinity
ExecStart=/root/vitastor/osd \\
--etcd_address $IP:2379/v3 \\
--bind_address $IP \\
--osd_num $((BASE+i)) \\
--disable_data_fsync 1 \\
--disable_device_lock 1 \\
--immediate_commit all \\
--flusher_count 8 \\
--disk_alignment 4096 --journal_block_size 4096 --meta_block_size 4096 \\
--journal_no_same_sector_overwrites true \\
--journal_sector_buffer_count 1024 \\
--journal_offset 0 \\
--meta_offset 16777216 \\
--data_offset 427814912 \\
--data_size $((1920377991168-427814912)) \\
--data_device /dev/disk/by-id/$DEV
WorkingDirectory=/root/vitastor
ExecStartPre=+chown vitastor:vitastor /dev/disk/by-id/$DEV
User=vitastor
PrivateTmp=false
TasksMax=infinity
Restart=always
StartLimitInterval=0
StartLimitIntervalSec=0
RestartSec=10
[Install]
WantedBy=vitastor.target
EOF
systemctl enable vitastor-osd$((BASE+i))
i=$((i+1))
cat >/etc/systemd/system/vitastor-osd$((BASE+i)).service <<EOF
[Unit]
Description=Vitastor object storage daemon osd.$((BASE+i))
After=network-online.target local-fs.target time-sync.target
Wants=network-online.target local-fs.target time-sync.target
PartOf=vitastor.target
[Service]
LimitNOFILE=1048576
LimitNPROC=1048576
LimitMEMLOCK=infinity
ExecStart=/root/vitastor/osd \\
--etcd_address $IP:2379/v3 \\
--bind_address $IP \\
--osd_num $((BASE+i)) \\
--disable_data_fsync 1 \\
--immediate_commit all \\
--flusher_count 8 \\
--disk_alignment 4096 --journal_block_size 4096 --meta_block_size 4096 \\
--journal_no_same_sector_overwrites true \\
--journal_sector_buffer_count 1024 \\
--journal_offset 1920377991168 \\
--meta_offset $((1920377991168+16777216)) \\
--data_offset $((1920377991168+427814912)) \\
--data_size $((1920377991168-427814912)) \\
--data_device /dev/disk/by-id/$DEV
WorkingDirectory=/root/vitastor
ExecStartPre=+chown vitastor:vitastor /dev/disk/by-id/$DEV
User=vitastor
PrivateTmp=false
TasksMax=infinity
Restart=always
StartLimitInterval=0
StartLimitIntervalSec=0
RestartSec=10
[Install]
WantedBy=vitastor.target
EOF
systemctl enable vitastor-osd$((BASE+i))
i=$((i+1))
done
exit
node mon-main.js --etcd_url 'http://10.115.0.10:2379,http://10.115.0.11:2379,http://10.115.0.12:2379,http://10.115.0.13:2379' --etcd_prefix '/vitastor' --etcd_start_timeout 5
podman run -d --network host --restart always -v /var/lib/etcd0.etcd:/etcd0.etcd --name etcd quay.io/coreos/etcd:v3.4.13 etcd -name etcd0 \
-advertise-client-urls http://10.115.0.10:2379 -listen-client-urls http://10.115.0.10:2379 \
-initial-advertise-peer-urls http://10.115.0.10:2380 -listen-peer-urls http://10.115.0.10:2380 \
-initial-cluster-token vitastor-etcd-1 -initial-cluster etcd0=http://10.115.0.10:2380,etcd1=http://10.115.0.11:2380,etcd2=http://10.115.0.12:2380,etcd3=http://10.115.0.13:2380 \
-initial-cluster-state new --max-txn-ops=100000 --auto-compaction-retention=10 --auto-compaction-mode=revision
etcdctl --endpoints http://10.115.0.10:2379 put /vitastor/config/global '{"immediate_commit":"all"}'
etcdctl --endpoints http://10.115.0.10:2379 put /vitastor/config/pools '{"1":{"name":"testpool","scheme":"replicated","pg_size":2,"pg_minsize":1,"pg_count":48,"failure_domain":"host"}}'
#let pgs = {};
#for (let n = 0; n < 48; n++) { let i = n/2 | 0; pgs[1+n] = { osd_set: [ (1+i%12+(i/12 | 0)*24), (1+12+i%12+(i/12 | 0)*24) ], primary: (1+(n%2)*12+i%12+(i/12 | 0)*24) }; };
#console.log(JSON.stringify({ items: { 1: pgs } }));
#etcdctl --endpoints http://10.115.0.10:2379 put /vitastor/config/pgs ...
# --disk_alignment 4096 --journal_block_size 4096 --meta_block_size 4096 \\
# --data_offset 427814912 \\
# --disk_alignment 4096 --journal_block_size 512 --meta_block_size 512 \\
# --data_offset 433434624 \\

1169
mon/mon.js
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56
mon/simple-offsets.js
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@ -1,56 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: MIT
// Simple tool to calculate journal and metadata offsets for a single device
// Will be replaced by smarter tools in the future
const child_process = require('child_process');
async function run()
{
const options = {
object_size: 128*1024,
bitmap_granularity: 4096,
journal_size: 16*1024*1024,
device_block_size: 4096,
journal_offset: 0,
device_size: 0,
};
for (let i = 2; i < process.argv.length; i++)
{
if (process.argv[i].substr(0, 2) == '--')
{
options[process.argv[i].substr(2)] = process.argv[i+1];
i++;
}
}
const device_size = Number(options.device_size || await system("blockdev --getsize64 "+options.device));
if (!device_size)
{
process.stderr.write('Failed to get device size\n');
process.exit(1);
}
options.journal_offset = Math.ceil(options.journal_offset/options.device_block_size)*options.device_block_size;
const meta_offset = options.journal_offset + Math.ceil(options.journal_size/options.device_block_size)*options.device_block_size;
const entries_per_block = Math.floor(options.device_block_size / (24 + options.object_size/options.bitmap_granularity/8));
const object_count = Math.floor((device_size-meta_offset)/options.object_size);
const meta_size = Math.ceil(object_count / entries_per_block) * options.device_block_size;
const data_offset = meta_offset + meta_size;
const meta_size_fmt = (meta_size > 1024*1024*1024 ? Math.round(meta_size/1024/1024/1024*100)/100+" GB"
: Math.round(meta_size/1024/1024*100)/100+" MB");
process.stdout.write(
`Metadata size: ${meta_size_fmt}\n`+
`Options for the OSD:\n`+
` --journal_offset ${options.journal_offset}\n`+
` --meta_offset ${meta_offset}\n`+
` --data_offset ${data_offset}\n`+
(options.device_size ? ` --data_size ${device_size-data_offset}\n` : '')
);
}
function system(cmd)
{
return new Promise((ok, no) => child_process.exec(cmd, { maxBuffer: 64*1024*1024 }, (err, stdout, stderr) => (err ? no(err) : ok(stdout))));
}
run().catch(console.error);

78
mon/stable-stringify.js
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@ -1,78 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: MIT
function stableStringify(obj, opts)
{
if (!opts)
opts = {};
if (typeof opts === 'function')
opts = { cmp: opts };
let space = opts.space || '';
if (typeof space === 'number')
space = Array(space+1).join(' ');
const cycles = (typeof opts.cycles === 'boolean') ? opts.cycles : false;
const cmp = opts.cmp && (function (f)
{
return function (node)
{
return function (a, b)
{
let aobj = { key: a, value: node[a] };
let bobj = { key: b, value: node[b] };
return f(aobj, bobj);
};
};
})(opts.cmp);
const seen = new Map();
return (function stringify (parent, key, node, level)
{
const indent = space ? ('\n' + new Array(level + 1).join(space)) : '';
const colonSeparator = space ? ': ' : ':';
if (node === undefined)
{
return;
}
if (typeof node !== 'object' || node === null)
{
return JSON.stringify(node);
}
if (node instanceof Array)
{
const out = [];
for (let i = 0; i < node.length; i++)
{
const item = stringify(node, i, node[i], level+1) || JSON.stringify(null);
out.push(indent + space + item);
}
return '[' + out.join(',') + indent + ']';
}
else
{
if (seen.has(node))
{
if (cycles)
return JSON.stringify('__cycle__');
throw new TypeError('Converting circular structure to JSON');
}
else
seen.set(node, true);
const keys = Object.keys(node).sort(cmp && cmp(node));
const out = [];
for (let i = 0; i < keys.length; i++)
{
const key = keys[i];
const value = stringify(node, key, node[key], level+1);
if (!value)
continue;
const keyValue = JSON.stringify(key)
+ colonSeparator
+ value;
out.push(indent + space + keyValue);
}
seen.delete(node);
return '{' + out.join(',') + indent + '}';
}
})({ '': obj }, '', obj, 0);
}
module.exports = stableStringify;

130
mon/test-nonuniform.js
View File

@ -1,130 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
// Interesting real-world example coming from Ceph with EC and compression enabled.
// EC parity chunks can't be compressed as efficiently as data chunks,
// thus they occupy more space (2.26x more space) in OSD object stores.
// This leads to really uneven OSD fill ratio in Ceph even when PGs are perfectly balanced.
// But we support this case with the "parity_space" parameter in optimize_initial()/optimize_change().
const LPOptimizer = require('./lp-optimizer.js');
const osd_tree = {
ripper5: {
osd0: 3.493144989013672,
osd1: 3.493144989013672,
osd2: 3.454082489013672,
osd12: 3.461894989013672,
},
ripper7: {
osd4: 3.638690948486328,
osd5: 3.638690948486328,
osd6: 3.638690948486328,
},
ripper4: {
osd9: 3.4609375,
osd10: 3.4609375,
osd11: 3.4609375,
},
ripper6: {
osd3: 3.5849609375,
osd7: 3.5859336853027344,
osd8: 3.638690948486328,
osd13: 3.461894989013672
},
};
const prev_pgs = [[12,7,5],[6,11,12],[3,6,9],[10,0,5],[2,5,13],[9,8,6],[3,4,12],[7,4,12],[12,11,13],[13,6,0],[4,13,10],[9,7,6],[7,10,0],[10,8,0],[3,10,2],[3,0,4],[6,13,0],[13,10,0],[13,10,5],[8,11,6],[3,9,2],[2,8,5],[8,9,5],[3,12,11],[0,7,4],[13,11,1],[11,3,12],[12,8,10],[7,5,12],[2,13,5],[7,11,0],[13,2,6],[0,6,8],[13,1,6],[0,13,4],[0,8,10],[4,10,0],[8,12,4],[8,12,9],[12,7,4],[13,9,5],[3,2,11],[1,9,7],[1,8,5],[5,12,9],[3,5,12],[2,8,10],[0,8,4],[1,4,11],[7,10,2],[12,13,5],[3,1,11],[7,1,4],[4,12,8],[7,0,9],[11,1,8],[3,0,5],[11,13,0],[1,13,5],[12,7,10],[12,8,4],[11,13,5],[0,11,6],[2,11,3],[13,1,11],[2,7,10],[7,10,12],[7,12,10],[12,11,5],[13,12,10],[2,3,9],[4,3,9],[13,2,5],[7,12,6],[12,10,13],[9,8,1],[13,1,5],[9,5,12],[5,11,7],[6,2,9],[8,11,6],[12,5,8],[6,13,1],[7,6,11],[2,3,6],[8,5,9],[1,13,6],[9,3,2],[7,11,1],[3,10,1],[0,11,7],[3,0,5],[1,3,6],[6,0,9],[3,11,4],[8,10,2],[13,1,9],[12,6,9],[3,12,9],[12,8,9],[7,5,0],[8,12,5],[0,11,3],[12,11,13],[0,7,11],[0,3,10],[1,3,11],[2,7,11],[13,2,6],[9,12,13],[8,2,4],[0,7,4],[5,13,0],[13,12,9],[1,9,8],[0,10,3],[3,5,10],[7,12,9],[2,13,4],[12,7,5],[9,2,7],[3,2,9],[6,2,7],[3,1,9],[4,3,2],[5,3,11],[0,7,6],[1,6,13],[7,10,2],[12,4,8],[13,12,6],[7,5,11],[6,2,3],[2,7,6],[2,3,10],[2,7,10],[11,12,6],[0,13,5],[10,2,4],[13,0,11],[7,0,6],[8,9,4],[8,4,11],[7,11,2],[3,4,2],[6,1,3],[7,2,11],[8,9,4],[11,4,8],[10,3,1],[2,10,13],[1,7,11],[13,11,12],[2,6,9],[10,0,13],[7,10,4],[0,11,13],[13,10,1],[7,5,0],[7,12,10],[3,1,4],[7,1,5],[3,11,5],[7,5,0],[1,3,5],[10,5,12],[0,3,9],[7,1,11],[11,8,12],[3,6,2],[7,12,9],[7,11,12],[4,11,3],[0,11,13],[13,2,5],[1,5,8],[0,11,8],[3,5,1],[11,0,6],[3,11,2],[11,8,12],[4,1,3],[10,13,4],[13,9,6],[2,3,10],[12,7,9],[10,0,4],[10,13,2],[3,11,1],[7,2,9],[1,7,4],[13,1,4],[7,0,6],[5,3,9],[10,0,7],[0,7,10],[3,6,10],[13,0,5],[8,4,1],[3,1,10],[2,10,13],[13,0,5],[13,10,2],[12,7,9],[6,8,10],[6,1,8],[10,8,1],[13,5,0],[5,11,3],[7,6,1],[8,5,9],[2,13,11],[10,12,4],[13,4,1],[2,13,4],[11,7,0],[2,9,7],[1,7,6],[8,0,4],[8,1,9],[7,10,12],[13,9,6],[7,6,11],[13,0,4],[1,8,4],[3,12,5],[10,3,1],[10,2,13],[2,4,8],[6,2,3],[3,0,10],[6,7,12],[8,12,5],[3,0,6],[13,12,10],[11,3,6],[9,0,13],[10,0,6],[7,5,2],[1,3,11],[7,10,2],[2,9,8],[11,13,12],[0,8,4],[8,12,11],[6,0,3],[1,13,4],[11,8,2],[12,3,6],[4,7,1],[7,6,12],[3,10,6],[0,10,7],[8,9,1],[0,10,6],[8,10,1]]
.map(pg => pg.map(n => 'osd'+n));
const by_osd = {};
for (let i = 0; i < prev_pgs.length; i++)
{
for (let j = 0; j < prev_pgs[i].length; j++)
{
by_osd[prev_pgs[i][j]] = by_osd[prev_pgs[i][j]] || [];
by_osd[prev_pgs[i][j]][j] = (by_osd[prev_pgs[i][j]][j] || 0) + 1;
}
}
/*
This set of PGs was balanced by hand, by heavily tuning OSD weights in Ceph:
{
osd0: 4.2,
osd1: 3.5,
osd2: 3.45409,
osd3: 4.5,
osd4: 1.4,
osd5: 1.4,
osd6: 1.75,
osd7: 4.5,
osd8: 4.4,
osd9: 2.2,
osd10: 2.7,
osd11: 2,
osd12: 3.4,
osd13: 3.4,
}
EC+compression is a nightmare in Ceph, yeah :))
To calculate the average ratio between data chunks and parity chunks we
calculate the number of PG chunks for each chunk role for each OSD:
{
osd12: [ 18, 22, 17 ],
osd7: [ 35, 22, 8 ],
osd5: [ 6, 17, 27 ],
osd6: [ 13, 12, 28 ],
osd11: [ 13, 26, 20 ],
osd3: [ 30, 20, 10 ],
osd9: [ 8, 12, 26 ],
osd10: [ 15, 23, 20 ],
osd0: [ 22, 22, 14 ],
osd2: [ 22, 16, 16 ],
osd13: [ 29, 19, 13 ],
osd8: [ 20, 18, 12 ],
osd4: [ 8, 10, 28 ],
osd1: [ 17, 17, 17 ]
}
And now we can pick a pair of OSDs and determine the ratio by solving the following:
osd5 = 23*X + 27*Y = 3249728140
osd13 = 48*X + 13*Y = 2991675992
=>
osd5 - 27/13*osd13 = 23*X - 27/13*48*X = -76.6923076923077*X = -2963752766.46154
=>
X = 38644720.1243731
Y = (osd5-23*X)/27 = 87440725.0792377
Y/X = 2.26268232239284 ~= 2.26
Which means that parity chunks are compressed ~2.26 times worse than data chunks.
Fine, let's try to optimize for it.
*/
async function run()
{
const all_weights = Object.assign({}, ...Object.values(osd_tree));
const total_weight = Object.values(all_weights).reduce((a, c) => Number(a) + Number(c), 0);
const eff = LPOptimizer.pg_list_space_efficiency(prev_pgs, all_weights, 2, 2.26);
const orig = eff*4.26 / total_weight;
console.log('Original efficiency was: '+Math.round(orig*10000)/100+' %');
let prev = await LPOptimizer.optimize_initial({ osd_tree, pg_size: 3, pg_count: 256, parity_space: 2.26 });
LPOptimizer.print_change_stats(prev);
let next = await LPOptimizer.optimize_change({ prev_pgs, osd_tree, pg_size: 3, max_combinations: 10000, parity_space: 2.26 });
LPOptimizer.print_change_stats(next);
}
run().catch(console.error);

242
msgr_receive.cpp
View File

@ -1,67 +1,48 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include "messenger.h"
void osd_messenger_t::read_requests()
{
for (int i = 0; i < read_ready_clients.size(); i++)
while (read_ready_clients.size() > 0)
{
int peer_fd = read_ready_clients[i];
int peer_fd = read_ready_clients[0];
auto & cl = clients[peer_fd];
if (cl.read_remaining < receive_buffer_size)
if (!cl.read_op || cl.read_remaining < receive_buffer_size)
{
cl.read_iov.iov_base = cl.in_buf;
cl.read_iov.iov_len = receive_buffer_size;
cl.read_msg.msg_iov = &cl.read_iov;
cl.read_msg.msg_iovlen = 1;
}
else
{
cl.read_iov.iov_base = 0;
cl.read_iov.iov_base = cl.read_buf;
cl.read_iov.iov_len = cl.read_remaining;
cl.read_msg.msg_iov = cl.recv_list.get_iovec();
cl.read_msg.msg_iovlen = cl.recv_list.get_size();
}
if (ringloop && !use_sync_send_recv)
cl.read_msg.msg_iov = &cl.read_iov;
cl.read_msg.msg_iovlen = 1;
read_ready_clients.erase(read_ready_clients.begin(), read_ready_clients.begin() + 1);
int result = recvmsg(peer_fd, &cl.read_msg, 0);
if (result < 0)
{
io_uring_sqe* sqe = ringloop->get_sqe();
if (!sqe)
{
read_ready_clients.erase(read_ready_clients.begin(), read_ready_clients.begin() + i);
return;
}
ring_data_t* data = ((ring_data_t*)sqe->user_data);
data->callback = [this, peer_fd](ring_data_t *data) { handle_read(data->res, peer_fd); };
my_uring_prep_recvmsg(sqe, peer_fd, &cl.read_msg, 0);
result = -errno;
}
else
{
int result = recvmsg(peer_fd, &cl.read_msg, 0);
if (result < 0)
{
result = -errno;
}
handle_read(result, peer_fd);
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("recvmsg done %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
handle_read(result, peer_fd);
}
read_ready_clients.clear();
}
bool osd_messenger_t::handle_read(int result, int peer_fd)
{
bool ret = false;
auto cl_it = clients.find(peer_fd);
if (cl_it != clients.end())
{
auto & cl = cl_it->second;
if (result <= 0 && result != -EAGAIN)
if (result < 0 && result != -EAGAIN)
{
// this is a client socket, so don't panic on error. just disconnect it
if (result != 0)
{
printf("Client %d socket read error: %d (%s). Disconnecting client\n", peer_fd, -result, strerror(-result));
}
// this is a client socket, so don't panic. just disconnect it
printf("Client %d socket read error: %d (%s). Disconnecting client\n", peer_fd, -result, strerror(-result));
stop_client(peer_fd);
return false;
}
@ -89,37 +70,27 @@ bool osd_messenger_t::handle_read(int result, int peer_fd)
cl.read_op = new osd_op_t;
cl.read_op->peer_fd = peer_fd;
cl.read_op->op_type = OSD_OP_IN;
cl.recv_list.push_back(cl.read_op->req.buf, OSD_PACKET_SIZE);
cl.read_buf = cl.read_op->req.buf;
cl.read_remaining = OSD_PACKET_SIZE;
cl.read_state = CL_READ_HDR;
}
while (cl.recv_list.done < cl.recv_list.count && remain > 0)
if (cl.read_remaining > remain)
{
iovec* cur = cl.recv_list.get_iovec();
if (cur->iov_len > remain)
{
memcpy(cur->iov_base, curbuf, remain);
cl.read_remaining -= remain;
cur->iov_len -= remain;
cur->iov_base += remain;
remain = 0;
}
else
{
memcpy(cur->iov_base, curbuf, cur->iov_len);
curbuf += cur->iov_len;
cl.read_remaining -= cur->iov_len;
remain -= cur->iov_len;
cur->iov_len = 0;
cl.recv_list.done++;
}
memcpy(cl.read_buf, curbuf, remain);
cl.read_remaining -= remain;
cl.read_buf += remain;
remain = 0;
if (cl.read_remaining <= 0)
handle_finished_read(cl);
}
if (cl.recv_list.done >= cl.recv_list.count)
else
{
if (!handle_finished_read(cl))
{
goto fin;
}
memcpy(cl.read_buf, curbuf, cl.read_remaining);
curbuf += cl.read_remaining;
remain -= cl.read_remaining;
cl.read_remaining = 0;
cl.read_buf = NULL;
handle_finished_read(cl);
}
}
}
@ -127,34 +98,27 @@ bool osd_messenger_t::handle_read(int result, int peer_fd)
{
// Long data
cl.read_remaining -= result;
cl.recv_list.eat(result);
if (cl.recv_list.done >= cl.recv_list.count)
cl.read_buf += result;
if (cl.read_remaining <= 0)
{
handle_finished_read(cl);
}
}
if (result >= cl.read_iov.iov_len)
{
ret = true;
return true;
}
}
}
fin:
for (auto cb: set_immediate)
{
cb();
}
set_immediate.clear();
return ret;
return false;
}
bool osd_messenger_t::handle_finished_read(osd_client_t & cl)
void osd_messenger_t::handle_finished_read(osd_client_t & cl)
{
cl.recv_list.reset();
if (cl.read_state == CL_READ_HDR)
{
if (cl.read_op->req.hdr.magic == SECONDARY_OSD_REPLY_MAGIC)
return handle_reply_hdr(&cl);
handle_reply_hdr(&cl);
else
handle_op_hdr(&cl);
}
@ -162,146 +126,150 @@ bool osd_messenger_t::handle_finished_read(osd_client_t & cl)
{
// Operation is ready
cl.received_ops.push_back(cl.read_op);
set_immediate.push_back([this, op = cl.read_op]() { exec_op(op); });
exec_op(cl.read_op);
cl.read_op = NULL;
cl.read_state = 0;
}
else if (cl.read_state == CL_READ_REPLY_DATA)
{
// Reply is ready
handle_reply_ready(cl.read_op);
auto req_it = cl.sent_ops.find(cl.read_reply_id);
osd_op_t *request = req_it->second;
cl.sent_ops.erase(req_it);
cl.read_reply_id = 0;
delete cl.read_op;
cl.read_op = NULL;
cl.read_state = 0;
// Measure subop latency
timespec tv_end;
clock_gettime(CLOCK_REALTIME, &tv_end);
stats.subop_stat_count[request->req.hdr.opcode]++;
if (!stats.subop_stat_count[request->req.hdr.opcode])
{
stats.subop_stat_count[request->req.hdr.opcode]++;
stats.subop_stat_sum[request->req.hdr.opcode] = 0;
}
stats.subop_stat_sum[request->req.hdr.opcode] += (
(tv_end.tv_sec - request->tv_begin.tv_sec)*1000000 +
(tv_end.tv_nsec - request->tv_begin.tv_nsec)/1000
);
request->callback(request);
}
else
{
assert(0);
}
return true;
}
void osd_messenger_t::handle_op_hdr(osd_client_t *cl)
{
osd_op_t *cur_op = cl->read_op;
if (cur_op->req.hdr.opcode == OSD_OP_SEC_READ)
if (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_READ)
{
if (cur_op->req.sec_rw.len > 0)
cur_op->buf = memalign_or_die(MEM_ALIGNMENT, cur_op->req.sec_rw.len);
cur_op->buf = memalign(MEM_ALIGNMENT, cur_op->req.sec_rw.len);
cl->read_remaining = 0;
}
else if (cur_op->req.hdr.opcode == OSD_OP_SEC_WRITE ||
cur_op->req.hdr.opcode == OSD_OP_SEC_WRITE_STABLE)
else if (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_WRITE)
{
if (cur_op->req.sec_rw.len > 0)
cur_op->buf = memalign_or_die(MEM_ALIGNMENT, cur_op->req.sec_rw.len);
cur_op->buf = memalign(MEM_ALIGNMENT, cur_op->req.sec_rw.len);
cl->read_remaining = cur_op->req.sec_rw.len;
}
else if (cur_op->req.hdr.opcode == OSD_OP_SEC_STABILIZE ||
cur_op->req.hdr.opcode == OSD_OP_SEC_ROLLBACK)
else if (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_STABILIZE ||
cur_op->req.hdr.opcode == OSD_OP_SECONDARY_ROLLBACK)
{
if (cur_op->req.sec_stab.len > 0)
cur_op->buf = memalign_or_die(MEM_ALIGNMENT, cur_op->req.sec_stab.len);
cur_op->buf = memalign(MEM_ALIGNMENT, cur_op->req.sec_stab.len);
cl->read_remaining = cur_op->req.sec_stab.len;
}
else if (cur_op->req.hdr.opcode == OSD_OP_READ)
{
if (cur_op->req.rw.len > 0)
cur_op->buf = memalign(MEM_ALIGNMENT, cur_op->req.rw.len);
cl->read_remaining = 0;
}
else if (cur_op->req.hdr.opcode == OSD_OP_WRITE)
{
if (cur_op->req.rw.len > 0)
cur_op->buf = memalign_or_die(MEM_ALIGNMENT, cur_op->req.rw.len);
cur_op->buf = memalign(MEM_ALIGNMENT, cur_op->req.rw.len);
cl->read_remaining = cur_op->req.rw.len;
}
if (cl->read_remaining > 0)
{
// Read data
cl->recv_list.push_back(cur_op->buf, cl->read_remaining);
cl->read_buf = cur_op->buf;
cl->read_state = CL_READ_DATA;
}
else
{
// Operation is ready
cl->received_ops.push_back(cur_op);
set_immediate.push_back([this, cur_op]() { exec_op(cur_op); });
cl->read_op = NULL;
cl->read_state = 0;
cl->received_ops.push_back(cur_op);
exec_op(cur_op);
}
}
bool osd_messenger_t::handle_reply_hdr(osd_client_t *cl)
void osd_messenger_t::handle_reply_hdr(osd_client_t *cl)
{
auto req_it = cl->sent_ops.find(cl->read_op->req.hdr.id);
osd_op_t *cur_op = cl->read_op;
auto req_it = cl->sent_ops.find(cur_op->req.hdr.id);
if (req_it == cl->sent_ops.end())
{
// Command out of sync. Drop connection
printf("Client %d command out of sync: id %lu\n", cl->peer_fd, cl->read_op->req.hdr.id);
printf("Client %d command out of sync: id %lu\n", cl->peer_fd, cur_op->req.hdr.id);
stop_client(cl->peer_fd);
return false;
return;
}
osd_op_t *op = req_it->second;
memcpy(op->reply.buf, cl->read_op->req.buf, OSD_PACKET_SIZE);
cl->sent_ops.erase(req_it);
if ((op->reply.hdr.opcode == OSD_OP_SEC_READ || op->reply.hdr.opcode == OSD_OP_READ) &&
memcpy(op->reply.buf, cur_op->req.buf, OSD_PACKET_SIZE);
if ((op->reply.hdr.opcode == OSD_OP_SECONDARY_READ || op->reply.hdr.opcode == OSD_OP_READ) &&
op->reply.hdr.retval > 0)
{
// Read data. In this case we assume that the buffer is preallocated by the caller (!)
assert(op->iov.count > 0);
cl->recv_list.append(op->iov);
delete cl->read_op;
cl->read_op = op;
assert(op->buf);
cl->read_state = CL_READ_REPLY_DATA;
cl->read_reply_id = op->req.hdr.id;
cl->read_buf = op->buf;
cl->read_remaining = op->reply.hdr.retval;
}
else if (op->reply.hdr.opcode == OSD_OP_SEC_LIST && op->reply.hdr.retval > 0)
else if (op->reply.hdr.opcode == OSD_OP_SECONDARY_LIST && op->reply.hdr.retval > 0)
{
assert(!op->iov.count);
delete cl->read_op;
cl->read_op = op;
op->buf = memalign(MEM_ALIGNMENT, sizeof(obj_ver_id) * op->reply.hdr.retval);
cl->read_state = CL_READ_REPLY_DATA;
cl->read_reply_id = op->req.hdr.id;
cl->read_buf = op->buf;
cl->read_remaining = sizeof(obj_ver_id) * op->reply.hdr.retval;
op->buf = memalign_or_die(MEM_ALIGNMENT, cl->read_remaining);
cl->recv_list.push_back(op->buf, cl->read_remaining);
}
else if (op->reply.hdr.opcode == OSD_OP_SHOW_CONFIG && op->reply.hdr.retval > 0)
{
assert(!op->iov.count);
delete cl->read_op;
cl->read_op = op;
op->buf = malloc(op->reply.hdr.retval);
cl->read_state = CL_READ_REPLY_DATA;
cl->read_reply_id = op->req.hdr.id;
cl->read_buf = op->buf;
cl->read_remaining = op->reply.hdr.retval;
op->buf = malloc_or_die(op->reply.hdr.retval);
cl->recv_list.push_back(op->buf, op->reply.hdr.retval);
}
else
{
// It's fine to reuse cl->read_op for the next reply
handle_reply_ready(op);
cl->recv_list.push_back(cl->read_op->req.buf, OSD_PACKET_SIZE);
cl->read_remaining = OSD_PACKET_SIZE;
cl->read_state = CL_READ_HDR;
}
return true;
}
void osd_messenger_t::handle_reply_ready(osd_op_t *op)
{
// Measure subop latency
timespec tv_end;
clock_gettime(CLOCK_REALTIME, &tv_end);
stats.subop_stat_count[op->req.hdr.opcode]++;
if (!stats.subop_stat_count[op->req.hdr.opcode])
{
delete cl->read_op;
cl->read_state = 0;
cl->read_op = NULL;
cl->sent_ops.erase(req_it);
// Measure subop latency
timespec tv_end;
clock_gettime(CLOCK_REALTIME, &tv_end);
stats.subop_stat_count[op->req.hdr.opcode]++;
stats.subop_stat_sum[op->req.hdr.opcode] = 0;
}
stats.subop_stat_sum[op->req.hdr.opcode] += (
(tv_end.tv_sec - op->tv_begin.tv_sec)*1000000 +
(tv_end.tv_nsec - op->tv_begin.tv_nsec)/1000
);
set_immediate.push_back([this, op]()
{
if (!stats.subop_stat_count[op->req.hdr.opcode])
{
stats.subop_stat_count[op->req.hdr.opcode]++;
stats.subop_stat_sum[op->req.hdr.opcode] = 0;
}
stats.subop_stat_sum[op->req.hdr.opcode] += (
(tv_end.tv_sec - op->tv_begin.tv_sec)*1000000 +
(tv_end.tv_nsec - op->tv_begin.tv_nsec)/1000
);
// Copy lambda to be unaffected by `delete op`
std::function<void(osd_op_t*)>(op->callback)(op);
});
}
}

102
msgr_send.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include "messenger.h"
void osd_messenger_t::outbox_push(osd_op_t *cur_op)
@ -31,14 +28,7 @@ void osd_messenger_t::outbox_push(osd_op_t *cur_op)
}
}
cl.outbox.push_back(cur_op);
if (!ringloop)
{
while (cl.write_op || cl.outbox.size())
{
try_send(cl);
}
}
else if (cl.write_op || cl.outbox.size() > 1 || !try_send(cl))
if (cl.write_op || cl.outbox.size() > 1 || !try_send(cl))
{
if (cl.write_state == 0)
{
@ -79,71 +69,35 @@ bool osd_messenger_t::try_send(osd_client_t & cl)
{
stats.op_stat_bytes[cl.write_op->req.hdr.opcode] += cl.write_op->req.rw.len;
}
else if (cl.write_op->req.hdr.opcode == OSD_OP_SEC_READ ||
cl.write_op->req.hdr.opcode == OSD_OP_SEC_WRITE ||
cl.write_op->req.hdr.opcode == OSD_OP_SEC_WRITE_STABLE)
else if (cl.write_op->req.hdr.opcode == OSD_OP_SECONDARY_READ ||
cl.write_op->req.hdr.opcode == OSD_OP_SECONDARY_WRITE)
{
stats.op_stat_bytes[cl.write_op->req.hdr.opcode] += cl.write_op->req.sec_rw.len;
}
cl.send_list.push_back(cl.write_op->reply.buf, OSD_PACKET_SIZE);
if (cl.write_op->req.hdr.opcode == OSD_OP_READ ||
cl.write_op->req.hdr.opcode == OSD_OP_SEC_READ ||
cl.write_op->req.hdr.opcode == OSD_OP_SEC_LIST ||
cl.write_op->req.hdr.opcode == OSD_OP_SHOW_CONFIG)
{
cl.send_list.append(cl.write_op->iov);
}
}
else
{
cl.send_list.push_back(cl.write_op->req.buf, OSD_PACKET_SIZE);
if (cl.write_op->req.hdr.opcode == OSD_OP_WRITE ||
cl.write_op->req.hdr.opcode == OSD_OP_SEC_WRITE ||
cl.write_op->req.hdr.opcode == OSD_OP_SEC_WRITE_STABLE ||
cl.write_op->req.hdr.opcode == OSD_OP_SEC_STABILIZE ||
cl.write_op->req.hdr.opcode == OSD_OP_SEC_ROLLBACK)
{
cl.send_list.append(cl.write_op->iov);
}
}
}
cl.write_msg.msg_iov = cl.send_list.get_iovec();
cl.write_msg.msg_iovlen = cl.send_list.get_size();
if (ringloop && !use_sync_send_recv)
cl.write_msg.msg_iov = cl.write_op->send_list.get_iovec();
cl.write_msg.msg_iovlen = cl.write_op->send_list.get_size();
int result = sendmsg(peer_fd, &cl.write_msg, MSG_NOSIGNAL);
if (result < 0)
result = -errno;
{
io_uring_sqe* sqe = ringloop->get_sqe();
if (!sqe)
{
return false;
}
ring_data_t* data = ((ring_data_t*)sqe->user_data);
data->callback = [this, peer_fd](ring_data_t *data) { handle_send(data->res, peer_fd); };
my_uring_prep_sendmsg(sqe, peer_fd, &cl.write_msg, 0);
}
else
{
int result = sendmsg(peer_fd, &cl.write_msg, MSG_NOSIGNAL);
if (result < 0)
{
result = -errno;
}
handle_send(result, peer_fd);
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("sendmsg done %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
handle_send(result, peer_fd);
return true;
}
void osd_messenger_t::send_replies()
{
for (int i = 0; i < write_ready_clients.size(); i++)
while (write_ready_clients.size() > 0)
{
int peer_fd = write_ready_clients[i];
if (!try_send(clients[peer_fd]))
{
write_ready_clients.erase(write_ready_clients.begin(), write_ready_clients.begin() + i);
return;
}
auto & cl = clients[write_ready_clients[0]];
write_ready_clients.erase(write_ready_clients.begin(), write_ready_clients.begin() + 1);
try_send(cl);
}
write_ready_clients.clear();
}
void osd_messenger_t::handle_send(int result, int peer_fd)
@ -161,14 +115,28 @@ void osd_messenger_t::handle_send(int result, int peer_fd)
}
if (result >= 0)
{
cl.send_list.eat(result);
if (cl.send_list.done >= cl.send_list.count)
osd_op_t *cur_op = cl.write_op;
while (result > 0 && cur_op->send_list.sent < cur_op->send_list.count)
{
iovec & iov = cur_op->send_list.buf[cur_op->send_list.sent];
if (iov.iov_len <= result)
{
result -= iov.iov_len;
cur_op->send_list.sent++;
}
else
{
iov.iov_len -= result;
iov.iov_base += result;
break;
}
}
if (cur_op->send_list.sent >= cur_op->send_list.count)
{
// Done
cl.send_list.reset();
if (cl.write_op->op_type == OSD_OP_IN)
if (cur_op->op_type == OSD_OP_IN)
{
delete cl.write_op;
delete cur_op;
}
else
{

673
nbd_proxy.cpp
View File

@ -1,673 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
// Similar to qemu-nbd, but sets timeout and uses io_uring
#include <linux/nbd.h>
#include <sys/ioctl.h>
#include <sys/socket.h>
#include <netinet/in.h>
#include <netinet/tcp.h>
#include <arpa/inet.h>
#include <sys/un.h>
#include <unistd.h>
#include <fcntl.h>
#include <signal.h>
#include "epoll_manager.h"
#include "cluster_client.h"
const char *exe_name = NULL;
class nbd_proxy
{
protected:
uint64_t inode = 0;
ring_loop_t *ringloop = NULL;
epoll_manager_t *epmgr = NULL;
cluster_client_t *cli = NULL;
ring_consumer_t consumer;
std::vector<iovec> send_list, next_send_list;
std::vector<void*> to_free;
int nbd_fd = -1;
void *recv_buf = NULL;
int receive_buffer_size = 9000;
nbd_request cur_req;
cluster_op_t *cur_op = NULL;
void *cur_buf = NULL;
int cur_left = 0;
int read_state = 0;
int read_ready = 0;
msghdr read_msg = { 0 }, send_msg = { 0 };
iovec read_iov = { 0 };
public:
static json11::Json::object parse_args(int narg, const char *args[])
{
json11::Json::object cfg;
int pos = 0;
for (int i = 1; i < narg; i++)
{
if (!strcmp(args[i], "-h") || !strcmp(args[i], "--help"))
{
help();
}
else if (args[i][0] == '-' && args[i][1] == '-')
{
const char *opt = args[i]+2;
cfg[opt] = !strcmp(opt, "json") || i == narg-1 ? "1" : args[++i];
}
else if (pos == 0)
{
cfg["command"] = args[i];
pos++;
}
else if (pos == 1 && (cfg["command"] == "map" || cfg["command"] == "unmap"))
{
int n = 0;
if (sscanf(args[i], "/dev/nbd%d", &n) > 0)
cfg["dev_num"] = n;
else
cfg["dev_num"] = args[i];
pos++;
}
}
return cfg;
}
void exec(json11::Json cfg)
{
if (cfg["command"] == "map")
{
start(cfg);
}
else if (cfg["command"] == "unmap")
{
if (cfg["dev_num"].is_null())
{
fprintf(stderr, "device name or number is missing\n");
exit(1);
}
unmap(cfg["dev_num"].uint64_value());
}
else if (cfg["command"] == "list" || cfg["command"] == "list-mapped")
{
auto mapped = list_mapped();
print_mapped(mapped, !cfg["json"].is_null());
}
else
{
help();
}
}
static void help()
{
printf(
"Vitastor NBD proxy\n"
"(c) Vitaliy Filippov, 2020 (VNPL-1.0 or GNU GPL 2.0+)\n\n"
"USAGE:\n"
" %s map --etcd_address <etcd_address> --pool <pool> --inode <inode> --size <size in bytes>\n"
" %s unmap /dev/nbd0\n"
" %s list [--json]\n",
exe_name, exe_name, exe_name
);
exit(0);
}
void unmap(int dev_num)
{
char path[64] = { 0 };
sprintf(path, "/dev/nbd%d", dev_num);
int r, nbd = open(path, O_RDWR);
if (nbd < 0)
{
perror("open");
exit(1);
}
r = ioctl(nbd, NBD_DISCONNECT);
if (r < 0)
{
perror("NBD_DISCONNECT");
exit(1);
}
close(nbd);
}
void start(json11::Json cfg)
{
// Check options
if (cfg["etcd_address"].string_value() == "")
{
fprintf(stderr, "etcd_address is missing\n");
exit(1);
}
if (!cfg["size"].uint64_value())
{
fprintf(stderr, "device size is missing\n");
exit(1);
}
inode = cfg["inode"].uint64_value();
uint64_t pool = cfg["pool"].uint64_value();
if (pool)
{
inode = (inode & ((1l << (64-POOL_ID_BITS)) - 1)) | (pool << (64-POOL_ID_BITS));
}
if (!(inode >> (64-POOL_ID_BITS)))
{
fprintf(stderr, "pool is missing\n");
exit(1);
}
// Initialize NBD
int sockfd[2];
if (socketpair(AF_UNIX, SOCK_STREAM, 0, sockfd) < 0)
{
perror("socketpair");
exit(1);
}
fcntl(sockfd[0], F_SETFL, fcntl(sockfd[0], F_GETFL, 0) | O_NONBLOCK);
nbd_fd = sockfd[0];
load_module();
if (!cfg["dev_num"].is_null())
{
if (run_nbd(sockfd, cfg["dev_num"].int64_value(), cfg["size"].uint64_value(), NBD_FLAG_SEND_FLUSH, 30) < 0)
{
perror("run_nbd");
exit(1);
}
}
else
{
// Find an unused device
int i = 0;
while (true)
{
int r = run_nbd(sockfd, i, cfg["size"].uint64_value(), NBD_FLAG_SEND_FLUSH, 30);
if (r == 0)
{
printf("/dev/nbd%d\n", i);
break;
}
else if (r == -1 && errno == ENOENT)
{
fprintf(stderr, "No free NBD devices found\n");
exit(1);
}
else if (r == -2 && errno == EBUSY)
{
i++;
}
else
{
printf("%d %d\n", r, errno);
perror("run_nbd");
exit(1);
}
}
}
if (cfg["foreground"].is_null())
{
daemonize();
}
// Create client
ringloop = new ring_loop_t(512);
epmgr = new epoll_manager_t(ringloop);
cli = new cluster_client_t(ringloop, epmgr->tfd, cfg);
// Initialize read state
read_state = CL_READ_HDR;
recv_buf = malloc_or_die(receive_buffer_size);
cur_buf = &cur_req;
cur_left = sizeof(nbd_request);
consumer.loop = [this]()
{
submit_read();
submit_send();
ringloop->submit();
};
ringloop->register_consumer(&consumer);
// Add FD to epoll
epmgr->tfd->set_fd_handler(sockfd[0], false, [this](int peer_fd, int epoll_events)
{
read_ready++;
submit_read();
});
while (1)
{
ringloop->loop();
ringloop->wait();
}
}
void load_module()
{
if (access("/sys/module/nbd", F_OK))
{
return;
}
int r;
if ((r = system("modprobe nbd")) != 0)
{
if (r < 0)
perror("Failed to load NBD kernel module");
else
fprintf(stderr, "Failed to load NBD kernel module\n");
exit(1);
}
}
void daemonize()
{
if (fork())
exit(0);
setsid();
if (fork())
exit(0);
chdir("/");
close(0);
close(1);
close(2);
open("/dev/null", O_RDONLY);
open("/dev/null", O_WRONLY);
open("/dev/null", O_WRONLY);
}
json11::Json::object list_mapped()
{
const char *self_filename = exe_name;
for (int i = 0; exe_name[i] != 0; i++)
{
if (exe_name[i] == '/')
self_filename = exe_name+i+1;
}
char path[64] = { 0 };
json11::Json::object mapped;
int dev_num = -1;
int pid;
while (true)
{
dev_num++;
sprintf(path, "/sys/block/nbd%d", dev_num);
if (access(path, F_OK) != 0)
break;
sprintf(path, "/sys/block/nbd%d/pid", dev_num);
std::string pid_str = read_file(path);
if (pid_str == "")
continue;
if (sscanf(pid_str.c_str(), "%d", &pid) < 1)
{
printf("Failed to read pid from /sys/block/nbd%d/pid\n", dev_num);
continue;
}
sprintf(path, "/proc/%d/cmdline", pid);
std::string cmdline = read_file(path);
std::vector<const char*> argv;
int last = 0;
for (int i = 0; i < cmdline.size(); i++)
{
if (cmdline[i] == 0)
{
argv.push_back(cmdline.c_str()+last);
last = i+1;
}
}
if (argv.size() > 0)
{
const char *pid_filename = argv[0];
for (int i = 0; argv[0][i] != 0; i++)
{
if (argv[0][i] == '/')
pid_filename = argv[0]+i+1;
}
if (!strcmp(pid_filename, self_filename))
{
json11::Json::object cfg = nbd_proxy::parse_args(argv.size(), argv.data());
if (cfg["command"] == "map")
{
cfg.erase("command");
cfg["pid"] = pid;
mapped["/dev/nbd"+std::to_string(dev_num)] = cfg;
}
}
}
}
return mapped;
}
void print_mapped(json11::Json mapped, bool json)
{
if (json)
{
printf("%s\n", mapped.dump().c_str());
}
else
{
for (auto & dev: mapped.object_items())
{
printf("%s\n", dev.first.c_str());
for (auto & k: dev.second.object_items())
{
printf("%s: %s\n", k.first.c_str(), k.second.string_value().c_str());
}
printf("\n");
}
}
}
std::string read_file(char *path)
{
int fd = open(path, O_RDONLY);
if (fd < 0)
{
if (errno == ENOENT)
return "";
auto err = "open "+std::string(path);
perror(err.c_str());
exit(1);
}
std::string r;
while (true)
{
int l = r.size();
r.resize(l + 1024);
int rd = read(fd, (void*)(r.c_str() + l), 1024);
if (rd <= 0)
{
r.resize(l);
break;
}
r.resize(l + rd);
}
close(fd);
return r;
}
protected:
int run_nbd(int sockfd[2], int dev_num, uint64_t size, uint64_t flags, unsigned timeout)
{
// Check handle size
assert(sizeof(cur_req.handle) == 8);
char path[64] = { 0 };
sprintf(path, "/dev/nbd%d", dev_num);
int r, nbd = open(path, O_RDWR), qd_fd;
if (nbd < 0)
{
return -1;
}
r = ioctl(nbd, NBD_SET_SOCK, sockfd[1]);
if (r < 0)
{
goto end_close;
}
r = ioctl(nbd, NBD_SET_BLKSIZE, 4096);
if (r < 0)
{
goto end_unmap;
}
r = ioctl(nbd, NBD_SET_SIZE, size);
if (r < 0)
{
goto end_unmap;
}
ioctl(nbd, NBD_SET_FLAGS, flags);
if (timeout >= 0)
{
r = ioctl(nbd, NBD_SET_TIMEOUT, (unsigned long)timeout);
if (r < 0)
{
goto end_unmap;
}
}
// Configure request size
sprintf(path, "/sys/block/nbd%d/queue/max_sectors_kb", dev_num);
qd_fd = open(path, O_WRONLY);
if (qd_fd < 0)
{
goto end_unmap;
}
write(qd_fd, "32768", 5);
close(qd_fd);
if (!fork())
{
// Run in child
close(sockfd[0]);
r = ioctl(nbd, NBD_DO_IT);
if (r < 0)
{
fprintf(stderr, "NBD device terminated with error: %s\n", strerror(errno));
kill(getppid(), SIGTERM);
}
close(sockfd[1]);
ioctl(nbd, NBD_CLEAR_QUE);
ioctl(nbd, NBD_CLEAR_SOCK);
exit(0);
}
close(sockfd[1]);
close(nbd);
return 0;
end_close:
r = errno;
close(nbd);
errno = r;
return -2;
end_unmap:
r = errno;
ioctl(nbd, NBD_CLEAR_SOCK);
close(nbd);
errno = r;
return -3;
}
void submit_send()
{
if (!send_list.size() || send_msg.msg_iovlen > 0)
{
return;
}
io_uring_sqe* sqe = ringloop->get_sqe();
if (!sqe)
{
return;
}
ring_data_t* data = ((ring_data_t*)sqe->user_data);
data->callback = [this](ring_data_t *data) { handle_send(data->res); };
send_msg.msg_iov = send_list.data();
send_msg.msg_iovlen = send_list.size();
my_uring_prep_sendmsg(sqe, nbd_fd, &send_msg, MSG_ZEROCOPY);
}
void handle_send(int result)
{
send_msg.msg_iovlen = 0;
if (result < 0 && result != -EAGAIN)
{
fprintf(stderr, "Socket disconnected: %s\n", strerror(-result));
exit(1);
}
int to_eat = 0;
while (result > 0 && to_eat < send_list.size())
{
if (result >= send_list[to_eat].iov_len)
{
free(to_free[to_eat]);
result -= send_list[to_eat].iov_len;
to_eat++;
}
else
{
send_list[to_eat].iov_base += result;
send_list[to_eat].iov_len -= result;
break;
}
}
if (to_eat > 0)
{
send_list.erase(send_list.begin(), send_list.begin() + to_eat);
to_free.erase(to_free.begin(), to_free.begin() + to_eat);
}
for (int i = 0; i < next_send_list.size(); i++)
{
send_list.push_back(next_send_list[i]);
}
next_send_list.clear();
if (send_list.size() > 0)
{
ringloop->wakeup();
}
}
void submit_read()
{
if (!read_ready || read_msg.msg_iovlen > 0)
{
return;
}
io_uring_sqe* sqe = ringloop->get_sqe();
if (!sqe)
{
return;
}
ring_data_t* data = ((ring_data_t*)sqe->user_data);
data->callback = [this](ring_data_t *data) { handle_read(data->res); };
if (cur_left < receive_buffer_size)
{
read_iov.iov_base = recv_buf;
read_iov.iov_len = receive_buffer_size;
}
else
{
read_iov.iov_base = cur_buf;
read_iov.iov_len = cur_left;
}
read_msg.msg_iov = &read_iov;
read_msg.msg_iovlen = 1;
my_uring_prep_recvmsg(sqe, nbd_fd, &read_msg, 0);
}
void handle_read(int result)
{
read_msg.msg_iovlen = 0;
if (result < 0 && result != -EAGAIN)
{
fprintf(stderr, "Socket disconnected: %s\n", strerror(-result));
exit(1);
}
if (result == -EAGAIN || result < read_iov.iov_len)
{
read_ready--;
}
if (read_ready > 0)
{
ringloop->wakeup();
}
void *b = recv_buf;
while (result > 0)
{
if (read_iov.iov_base == recv_buf)
{
int inc = result >= cur_left ? cur_left : result;
memcpy(cur_buf, b, inc);
cur_left -= inc;
result -= inc;
cur_buf += inc;
b += inc;
}
else
{
assert(result <= cur_left);
cur_left -= result;
result = 0;
}
if (cur_left <= 0)
{
handle_finished_read();
}
}
}
void handle_finished_read()
{
if (read_state == CL_READ_HDR)
{
int req_type = be32toh(cur_req.type);
if (be32toh(cur_req.magic) != NBD_REQUEST_MAGIC ||
req_type != NBD_CMD_READ && req_type != NBD_CMD_WRITE && req_type != NBD_CMD_FLUSH)
{
printf("Unexpected request: magic=%x type=%x, terminating\n", cur_req.magic, req_type);
exit(1);
}
uint64_t handle = *((uint64_t*)cur_req.handle);
#ifdef DEBUG
printf("request %lx +%x %lx\n", be64toh(cur_req.from), be32toh(cur_req.len), handle);
#endif
void *buf = NULL;
cluster_op_t *op = new cluster_op_t;
if (req_type == NBD_CMD_READ || req_type == NBD_CMD_WRITE)
{
op->opcode = req_type == NBD_CMD_READ ? OSD_OP_READ : OSD_OP_WRITE;
op->inode = inode;
op->offset = be64toh(cur_req.from);
op->len = be32toh(cur_req.len);
buf = malloc_or_die(sizeof(nbd_reply) + op->len);
op->iov.push_back(buf + sizeof(nbd_reply), op->len);
}
else if (req_type == NBD_CMD_FLUSH)
{
op->opcode = OSD_OP_SYNC;
buf = malloc_or_die(sizeof(nbd_reply));
}
op->callback = [this, buf, handle](cluster_op_t *op)
{
#ifdef DEBUG
printf("reply %lx e=%d\n", handle, op->retval);
#endif
nbd_reply *reply = (nbd_reply*)buf;
reply->magic = htobe32(NBD_REPLY_MAGIC);
memcpy(reply->handle, &handle, 8);
reply->error = htobe32(op->retval < 0 ? -op->retval : 0);
auto & to_list = send_msg.msg_iovlen > 0 ? next_send_list : send_list;
if (op->retval < 0 || op->opcode != OSD_OP_READ)
to_list.push_back({ .iov_base = buf, .iov_len = sizeof(nbd_reply) });
else
to_list.push_back({ .iov_base = buf, .iov_len = sizeof(nbd_reply) + op->len });
to_free.push_back(buf);
delete op;
ringloop->wakeup();
};
if (req_type == NBD_CMD_WRITE)
{
cur_op = op;
cur_buf = buf + sizeof(nbd_reply);
cur_left = op->len;
read_state = CL_READ_DATA;
}
else
{
cur_op = NULL;
cur_buf = &cur_req;
cur_left = sizeof(nbd_request);
read_state = CL_READ_HDR;
cli->execute(op);
}
}
else
{
cli->execute(cur_op);
cur_op = NULL;
cur_buf = &cur_req;
cur_left = sizeof(nbd_request);
read_state = CL_READ_HDR;
}
}
};
int main(int narg, const char *args[])
{
setvbuf(stdout, NULL, _IONBF, 0);
setvbuf(stderr, NULL, _IONBF, 0);
exe_name = args[0];
nbd_proxy *p = new nbd_proxy();
p->exec(nbd_proxy::parse_args(narg, args));
return 0;
}

3
object_id.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include <stdint.h>

150
osd.cpp
View File

@ -1,7 +1,5 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <sys/socket.h>
#include <sys/epoll.h>
#include <sys/poll.h>
#include <netinet/in.h>
#include <netinet/tcp.h>
@ -9,6 +7,25 @@
#include "osd.h"
#define MAX_EPOLL_EVENTS 64
const char* osd_op_names[] = {
"",
"read",
"write",
"sync",
"stabilize",
"rollback",
"delete",
"sync_stab_all",
"list",
"show_config",
"primary_read",
"primary_write",
"primary_sync",
"primary_delete",
};
osd_t::osd_t(blockstore_config_t & config, blockstore_t *bs, ring_loop_t *ringloop)
{
this->config = config;
@ -21,9 +38,13 @@ osd_t::osd_t(blockstore_config_t & config, blockstore_t *bs, ring_loop_t *ringlo
parse_config(config);
epmgr = new epoll_manager_t(ringloop);
this->tfd = epmgr->tfd;
epoll_fd = epoll_create(1);
if (epoll_fd < 0)
{
throw std::runtime_error(std::string("epoll_create: ") + strerror(errno));
}
this->tfd = new timerfd_manager_t([this](int fd, std::function<void(int, int)> handler) { set_fd_handler(fd, handler); });
this->tfd->set_timer(print_stats_interval*1000, true, [this](int timer_id)
{
print_stats();
@ -42,8 +63,13 @@ osd_t::osd_t(blockstore_config_t & config, blockstore_t *bs, ring_loop_t *ringlo
osd_t::~osd_t()
{
if (tfd)
{
delete tfd;
tfd = NULL;
}
ringloop->unregister_consumer(&consumer);
delete epmgr;
close(epoll_fd);
close(listen_fd);
}
@ -83,6 +109,12 @@ void osd_t::parse_config(blockstore_config_t & config)
if (client_queue_depth < 128)
client_queue_depth = 128;
}
if (config.find("pg_stripe_size") != config.end())
{
pg_stripe_size = strtoull(config["pg_stripe_size"].c_str(), NULL, 10);
if (!pg_stripe_size || !bs_block_size || pg_stripe_size < bs_block_size || (pg_stripe_size % bs_block_size) != 0)
pg_stripe_size = DEFAULT_PG_STRIPE_SIZE;
}
recovery_queue_depth = strtoull(config["recovery_queue_depth"].c_str(), NULL, 10);
if (recovery_queue_depth < 1 || recovery_queue_depth > MAX_RECOVERY_QUEUE)
recovery_queue_depth = DEFAULT_RECOVERY_QUEUE;
@ -149,10 +181,15 @@ void osd_t::bind_socket()
fcntl(listen_fd, F_SETFL, fcntl(listen_fd, F_GETFL, 0) | O_NONBLOCK);
epmgr->set_fd_handler(listen_fd, false, [this](int fd, int events)
epoll_event ev;
ev.data.fd = listen_fd;
ev.events = EPOLLIN | EPOLLET;
if (epoll_ctl(epoll_fd, EPOLL_CTL_ADD, listen_fd, &ev) < 0)
{
c_cli.accept_connections(listen_fd);
});
close(listen_fd);
close(epoll_fd);
throw std::runtime_error(std::string("epoll_ctl: ") + strerror(errno));
}
}
bool osd_t::shutdown()
@ -167,12 +204,86 @@ bool osd_t::shutdown()
void osd_t::loop()
{
if (!wait_state)
{
handle_epoll_events();
wait_state = 1;
}
handle_peers();
c_cli.read_requests();
c_cli.send_replies();
ringloop->submit();
}
void osd_t::set_fd_handler(int fd, std::function<void(int, int)> handler)
{
if (handler != NULL)
{
bool exists = epoll_handlers.find(fd) != epoll_handlers.end();
epoll_event ev;
ev.data.fd = fd;
ev.events = EPOLLOUT | EPOLLIN | EPOLLRDHUP | EPOLLET;
if (epoll_ctl(epoll_fd, exists ? EPOLL_CTL_MOD : EPOLL_CTL_ADD, fd, &ev) < 0)
{
throw std::runtime_error(std::string("epoll_ctl: ") + strerror(errno));
}
epoll_handlers[fd] = handler;
}
else
{
if (epoll_ctl(epoll_fd, EPOLL_CTL_DEL, fd, NULL) < 0 && errno != ENOENT)
{
throw std::runtime_error(std::string("epoll_ctl: ") + strerror(errno));
}
epoll_handlers.erase(fd);
}
}
void osd_t::handle_epoll_events()
{
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("epoll %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
io_uring_sqe *sqe = ringloop->get_sqe();
if (!sqe)
{
throw std::runtime_error("can't get SQE, will fall out of sync with EPOLLET");
}
ring_data_t *data = ((ring_data_t*)sqe->user_data);
my_uring_prep_poll_add(sqe, epoll_fd, POLLIN);
data->callback = [this](ring_data_t *data)
{
if (data->res < 0)
{
throw std::runtime_error(std::string("epoll failed: ") + strerror(-data->res));
}
handle_epoll_events();
};
ringloop->submit();
int nfds;
epoll_event events[MAX_EPOLL_EVENTS];
restart:
nfds = epoll_wait(epoll_fd, events, MAX_EPOLL_EVENTS, 0);
for (int i = 0; i < nfds; i++)
{
if (events[i].data.fd == listen_fd)
{
c_cli.accept_connections(listen_fd);
}
else
{
auto & cb = epoll_handlers[events[i].data.fd];
cb(events[i].data.fd, events[i].events);
}
}
if (nfds == MAX_EPOLL_EVENTS)
{
goto restart;
}
}
void osd_t::exec_op(osd_op_t *cur_op)
{
clock_gettime(CLOCK_REALTIME, &cur_op->tv_begin);
@ -183,28 +294,21 @@ void osd_t::exec_op(osd_op_t *cur_op)
return;
}
inflight_ops++;
cur_op->send_list.push_back(cur_op->reply.buf, OSD_PACKET_SIZE);
if (cur_op->req.hdr.magic != SECONDARY_OSD_OP_MAGIC ||
cur_op->req.hdr.opcode < OSD_OP_MIN || cur_op->req.hdr.opcode > OSD_OP_MAX ||
((cur_op->req.hdr.opcode == OSD_OP_SEC_READ ||
cur_op->req.hdr.opcode == OSD_OP_SEC_WRITE ||
cur_op->req.hdr.opcode == OSD_OP_SEC_WRITE_STABLE) &&
(cur_op->req.sec_rw.len > OSD_RW_MAX ||
cur_op->req.sec_rw.len % bs_disk_alignment ||
cur_op->req.sec_rw.offset % bs_disk_alignment)) ||
((cur_op->req.hdr.opcode == OSD_OP_READ ||
cur_op->req.hdr.opcode == OSD_OP_WRITE ||
cur_op->req.hdr.opcode == OSD_OP_DELETE) &&
(cur_op->req.rw.len > OSD_RW_MAX ||
cur_op->req.rw.len % bs_disk_alignment ||
cur_op->req.rw.offset % bs_disk_alignment)))
(cur_op->req.hdr.opcode == OSD_OP_SECONDARY_READ || cur_op->req.hdr.opcode == OSD_OP_SECONDARY_WRITE) &&
(cur_op->req.sec_rw.len > OSD_RW_MAX || cur_op->req.sec_rw.len % bs_disk_alignment || cur_op->req.sec_rw.offset % bs_disk_alignment) ||
(cur_op->req.hdr.opcode == OSD_OP_READ || cur_op->req.hdr.opcode == OSD_OP_WRITE || cur_op->req.hdr.opcode == OSD_OP_DELETE) &&
(cur_op->req.rw.len > OSD_RW_MAX || cur_op->req.rw.len % bs_disk_alignment || cur_op->req.rw.offset % bs_disk_alignment))
{
// Bad command
finish_op(cur_op, -EINVAL);
return;
}
if (readonly &&
cur_op->req.hdr.opcode != OSD_OP_SEC_READ &&
cur_op->req.hdr.opcode != OSD_OP_SEC_LIST &&
cur_op->req.hdr.opcode != OSD_OP_SECONDARY_READ &&
cur_op->req.hdr.opcode != OSD_OP_SECONDARY_LIST &&
cur_op->req.hdr.opcode != OSD_OP_READ &&
cur_op->req.hdr.opcode != OSD_OP_SHOW_CONFIG)
{

46
osd.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#include <sys/types.h>
@ -19,7 +16,6 @@
#include "blockstore.h"
#include "ringloop.h"
#include "timerfd_manager.h"
#include "epoll_manager.h"
#include "osd_peering_pg.h"
#include "messenger.h"
#include "etcd_state_client.h"
@ -37,9 +33,12 @@
#define DEFAULT_AUTOSYNC_INTERVAL 5
#define MAX_RECOVERY_QUEUE 2048
#define DEFAULT_RECOVERY_QUEUE 4
#define DEFAULT_PG_STRIPE_SIZE 4*1024*1024 // 4 MB by default
//#define OSD_STUB
extern const char* osd_op_names[];
struct osd_object_id_t
{
osd_num_t osd_num;
@ -50,6 +49,7 @@ struct osd_recovery_op_t
{
int st = 0;
bool degraded = false;
pg_num_t pg_num = 0;
object_id oid = { 0 };
osd_op_t *osd_op = NULL;
};
@ -83,19 +83,18 @@ class osd_t
std::string etcd_lease_id;
json11::Json self_state;
bool loading_peer_config = false;
std::set<pool_pg_num_t> pg_state_dirty;
std::set<pg_num_t> pg_state_dirty;
bool pg_config_applied = false;
bool etcd_reporting_pg_state = false;
bool etcd_reporting_stats = false;
// peers and PGs
std::map<pool_id_t, pg_num_t> pg_counts;
std::map<pool_pg_num_t, pg_t> pgs;
std::set<pool_pg_num_t> dirty_pgs;
std::set<osd_num_t> dirty_osds;
std::map<pg_num_t, pg_t> pgs;
std::set<pg_num_t> dirty_pgs;
uint64_t misplaced_objects = 0, degraded_objects = 0, incomplete_objects = 0;
int peering_state = 0;
unsigned pg_count = 0;
std::map<object_id, osd_recovery_op_t> recovery_ops;
osd_op_t *autosync_op = NULL;
@ -109,13 +108,16 @@ class osd_t
int inflight_ops = 0;
blockstore_t *bs;
uint32_t bs_block_size, bs_disk_alignment;
uint64_t pg_stripe_size = DEFAULT_PG_STRIPE_SIZE;
ring_loop_t *ringloop;
timerfd_manager_t *tfd = NULL;
epoll_manager_t *epmgr = NULL;
int wait_state = 0;
int epoll_fd = 0;
int listening_port = 0;
int listen_fd = 0;
ring_consumer_t consumer;
std::map<int, std::function<void(int, int)>> epoll_handlers;
// op statistics
osd_op_stats_t prev_stats;
@ -126,8 +128,7 @@ class osd_t
// cluster connection
void parse_config(blockstore_config_t & config);
void init_cluster();
void on_change_osd_state_hook(osd_num_t peer_osd);
void on_change_pg_history_hook(pool_id_t pool_id, pg_num_t pg_num);
void on_change_osd_state_hook(uint64_t osd_num);
void on_change_etcd_state_hook(json11::Json::object & changes);
void on_load_config_hook(json11::Json::object & changes);
json11::Json on_load_pgs_checks_hook();
@ -148,22 +149,24 @@ class osd_t
// event loop, socket read/write
void loop();
void set_fd_handler(int fd, std::function<void(int, int)> handler);
void handle_epoll_events();
// peer handling (primary OSD logic)
void parse_test_peer(std::string peer);
void handle_peers();
void repeer_pgs(osd_num_t osd_num);
void start_pg_peering(pg_t & pg);
void start_pg_peering(pg_num_t pg_num);
void submit_sync_and_list_subop(osd_num_t role_osd, pg_peering_state_t *ps);
void submit_list_subop(osd_num_t role_osd, pg_peering_state_t *ps);
void discard_list_subop(osd_op_t *list_op);
bool stop_pg(pg_t & pg);
bool stop_pg(pg_num_t pg_num);
void finish_stop_pg(pg_t & pg);
// flushing, recovery and backfill
void submit_pg_flush_ops(pg_t & pg);
void handle_flush_op(bool rollback, pool_id_t pool_id, pg_num_t pg_num, pg_flush_batch_t *fb, osd_num_t peer_osd, int retval);
void submit_flush_op(pool_id_t pool_id, pg_num_t pg_num, pg_flush_batch_t *fb, bool rollback, osd_num_t peer_osd, int count, obj_ver_id *data);
void submit_pg_flush_ops(pg_num_t pg_num);
void handle_flush_op(bool rollback, pg_num_t pg_num, pg_flush_batch_t *fb, osd_num_t peer_osd, int retval);
void submit_flush_op(pg_num_t pg_num, pg_flush_batch_t *fb, bool rollback, osd_num_t peer_osd, int count, obj_ver_id *data);
bool pick_next_recovery(osd_recovery_op_t &op);
void submit_recovery_op(osd_recovery_op_t *op);
bool continue_recovery();
@ -194,16 +197,13 @@ class osd_t
void handle_primary_bs_subop(osd_op_t *subop);
void add_bs_subop_stats(osd_op_t *subop);
void pg_cancel_write_queue(pg_t & pg, osd_op_t *first_op, object_id oid, int retval);
void submit_primary_subops(int submit_type, uint64_t op_version, int pg_size, const uint64_t* osd_set, osd_op_t *cur_op);
void submit_primary_del_subops(osd_op_t *cur_op, uint64_t *cur_set, uint64_t set_size, pg_osd_set_t & loc_set);
void submit_primary_subops(int submit_type, int read_pg_size, const uint64_t* osd_set, osd_op_t *cur_op);
void submit_primary_del_subops(osd_op_t *cur_op, uint64_t *cur_set, pg_osd_set_t & loc_set);
void submit_primary_sync_subops(osd_op_t *cur_op);
void submit_primary_stab_subops(osd_op_t *cur_op);
inline pg_num_t map_to_pg(object_id oid, uint64_t pg_stripe_size)
inline pg_num_t map_to_pg(object_id oid)
{
uint64_t pg_count = pg_counts[INODE_POOL(oid.inode)];
if (!pg_count)
pg_count = 1;
return (oid.inode + oid.stripe / pg_stripe_size) % pg_count + 1;
}

331
osd_cluster.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "osd.h"
#include "base64.h"
#include "etcd_state_client.h"
@ -17,7 +14,7 @@ void osd_t::init_cluster()
{
if (run_primary)
{
// Test version of clustering code with 1 pool, 1 PG and 2 peers
// Test version of clustering code with 1 PG and 2 peers
// Example: peers = 2:127.0.0.1:11204,3:127.0.0.1:11205
std::string peerstr = config["peers"];
while (peerstr.size())
@ -30,16 +27,15 @@ void osd_t::init_cluster()
{
throw std::runtime_error("run_primary requires at least 2 peers");
}
pgs[{ 1, 1 }] = (pg_t){
pgs[1] = (pg_t){
.state = PG_PEERING,
.pg_cursize = 0,
.pool_id = 1,
.pg_num = 1,
.target_set = { 1, 2, 3 },
.cur_set = { 0, 0, 0 },
};
report_pg_state(pgs[{ 1, 1 }]);
pg_counts[1] = 1;
report_pg_state(pgs[1]);
pg_count = 1;
}
bind_socket();
}
@ -47,8 +43,7 @@ void osd_t::init_cluster()
{
st_cli.tfd = tfd;
st_cli.log_level = log_level;
st_cli.on_change_osd_state_hook = [this](osd_num_t peer_osd) { on_change_osd_state_hook(peer_osd); };
st_cli.on_change_pg_history_hook = [this](pool_id_t pool_id, pg_num_t pg_num) { on_change_pg_history_hook(pool_id, pg_num); };
st_cli.on_change_osd_state_hook = [this](uint64_t peer_osd) { on_change_osd_state_hook(peer_osd); };
st_cli.on_change_hook = [this](json11::Json::object & changes) { on_change_etcd_state_hook(changes); };
st_cli.on_load_config_hook = [this](json11::Json::object & cfg) { on_load_config_hook(cfg); };
st_cli.load_pgs_checks_hook = [this]() { return on_load_pgs_checks_hook(); };
@ -187,7 +182,7 @@ void osd_t::report_statistics()
pg_stats["write_osd_set"] = pg.cur_set;
txn.push_back(json11::Json::object {
{ "request_put", json11::Json::object {
{ "key", base64_encode(st_cli.etcd_prefix+"/pg/stats/"+std::to_string(pg.pool_id)+"/"+std::to_string(pg.pg_num)) },
{ "key", base64_encode(st_cli.etcd_prefix+"/pg/stats/"+std::to_string(pg.pg_num)) },
{ "value", base64_encode(json11::Json(pg_stats).dump()) },
} }
});
@ -212,7 +207,7 @@ void osd_t::report_statistics()
});
}
void osd_t::on_change_osd_state_hook(osd_num_t peer_osd)
void osd_t::on_change_osd_state_hook(uint64_t peer_osd)
{
if (c_cli.wanted_peers.find(peer_osd) != c_cli.wanted_peers.end())
{
@ -227,30 +222,6 @@ void osd_t::on_change_etcd_state_hook(json11::Json::object & changes)
apply_pg_config();
}
void osd_t::on_change_pg_history_hook(pool_id_t pool_id, pg_num_t pg_num)
{
auto pg_it = pgs.find({
.pool_id = pool_id,
.pg_num = pg_num,
});
if (pg_it != pgs.end() && pg_it->second.epoch > pg_it->second.reported_epoch &&
st_cli.pool_config[pool_id].pg_config[pg_num].epoch >= pg_it->second.epoch)
{
pg_it->second.reported_epoch = st_cli.pool_config[pool_id].pg_config[pg_num].epoch;
object_id oid = { 0 };
bool first = true;
for (auto op: pg_it->second.write_queue)
{
if (first || oid != op.first)
{
oid = op.first;
first = false;
continue_primary_write(op.second);
}
}
}
}
void osd_t::on_load_config_hook(json11::Json::object & global_config)
{
blockstore_config_t osd_config = this->config;
@ -458,156 +429,149 @@ void osd_t::on_load_pgs_hook(bool success)
void osd_t::apply_pg_count()
{
for (auto & pool_item: st_cli.pool_config)
pg_num_t pg_count = st_cli.pg_config.size();
if (pg_count > 0 && (st_cli.pg_config.begin()->first != 1 || std::prev(st_cli.pg_config.end())->first != pg_count))
{
if (pool_item.second.real_pg_count != 0 &&
pool_item.second.real_pg_count != pg_counts[pool_item.first])
printf("Invalid PG configuration: PG numbers don't cover the whole 1..%d range\n", pg_count);
force_stop(1);
return;
}
if (this->pg_count != 0 && this->pg_count != pg_count)
{
// Check that all PGs are offline. It is not allowed to change PG count when any PGs are online
// The external tool must wait for all PGs to come down before changing PG count
// If it doesn't wait, a restarted OSD may apply the new count immediately which will lead to bugs
// So an OSD just dies if it detects PG count change while there are active PGs
int still_active = 0;
for (auto & kv: pgs)
{
// Check that all pool PGs are offline. It is not allowed to change PG count when any PGs are online
// The external tool must wait for all PGs to come down before changing PG count
// If it doesn't wait, a restarted OSD may apply the new count immediately which will lead to bugs
// So an OSD just dies if it detects PG count change while there are active PGs
int still_active = 0;
for (auto & kv: pgs)
if (kv.second.state & PG_ACTIVE)
{
if (kv.first.pool_id == pool_item.first && (kv.second.state & PG_ACTIVE))
{
still_active++;
}
}
if (still_active > 0)
{
printf("[OSD %lu] PG count change detected, but %d PG(s) are still active. This is not allowed. Exiting\n", this->osd_num, still_active);
force_stop(1);
return;
still_active++;
}
}
this->pg_counts[pool_item.first] = pool_item.second.real_pg_count;
if (still_active > 0)
{
printf("[OSD %lu] PG count change detected, but %d PG(s) are still active. This is not allowed. Exiting\n", this->osd_num, still_active);
force_stop(1);
return;
}
}
this->pg_count = pg_count;
}
void osd_t::apply_pg_config()
{
bool all_applied = true;
for (auto & pool_item: st_cli.pool_config)
for (auto & kv: st_cli.pg_config)
{
auto pool_id = pool_item.first;
for (auto & kv: pool_item.second.pg_config)
pg_num_t pg_num = kv.first;
auto & pg_cfg = kv.second;
bool take = pg_cfg.exists && pg_cfg.primary == this->osd_num &&
!pg_cfg.pause && (!pg_cfg.cur_primary || pg_cfg.cur_primary == this->osd_num);
bool currently_taken = this->pgs.find(pg_num) != this->pgs.end() &&
this->pgs[pg_num].state != PG_OFFLINE;
if (currently_taken && !take)
{
pg_num_t pg_num = kv.first;
auto & pg_cfg = kv.second;
bool take = pg_cfg.exists && pg_cfg.primary == this->osd_num &&
!pg_cfg.pause && (!pg_cfg.cur_primary || pg_cfg.cur_primary == this->osd_num);
auto pg_it = this->pgs.find({ .pool_id = pool_id, .pg_num = pg_num });
bool currently_taken = pg_it != this->pgs.end() && pg_it->second.state != PG_OFFLINE;
if (currently_taken && !take)
// Stop this PG
stop_pg(pg_num);
}
else if (take)
{
// Take this PG
std::set<osd_num_t> all_peers;
for (osd_num_t pg_osd: pg_cfg.target_set)
{
// Stop this PG
stop_pg(pg_it->second);
if (pg_osd != 0)
{
all_peers.insert(pg_osd);
}
}
else if (take)
for (osd_num_t pg_osd: pg_cfg.all_peers)
{
// Take this PG
std::set<osd_num_t> all_peers;
for (osd_num_t pg_osd: pg_cfg.target_set)
if (pg_osd != 0)
{
all_peers.insert(pg_osd);
}
}
for (auto & hist_item: pg_cfg.target_history)
{
for (auto pg_osd: hist_item)
{
if (pg_osd != 0)
{
all_peers.insert(pg_osd);
}
}
for (osd_num_t pg_osd: pg_cfg.all_peers)
}
if (currently_taken)
{
if (this->pgs[pg_num].state & (PG_ACTIVE | PG_INCOMPLETE | PG_PEERING))
{
if (pg_osd != 0)
if (this->pgs[pg_num].target_set == pg_cfg.target_set)
{
all_peers.insert(pg_osd);
}
}
for (auto & hist_item: pg_cfg.target_history)
{
for (auto pg_osd: hist_item)
{
if (pg_osd != 0)
{
all_peers.insert(pg_osd);
}
}
}
if (currently_taken)
{
if (pg_it->second.state & (PG_ACTIVE | PG_INCOMPLETE | PG_PEERING))
{
if (pg_it->second.target_set == pg_cfg.target_set)
{
// No change in osd_set; history changes are ignored
continue;
}
else
{
// Stop PG, reapply change after stopping
stop_pg(pg_it->second);
all_applied = false;
continue;
}
}
else if (pg_it->second.state & PG_STOPPING)
{
// Reapply change after stopping
all_applied = false;
// No change in osd_set; history changes are ignored
continue;
}
else if (pg_it->second.state & PG_STARTING)
{
if (pg_cfg.cur_primary == this->osd_num)
{
// PG locked, continue
}
else
{
// Reapply change after locking the PG
all_applied = false;
continue;
}
}
else
{
throw std::runtime_error("Unexpected PG "+std::to_string(pg_num)+" state: "+std::to_string(pg_it->second.state));
// Stop PG, reapply change after stopping
stop_pg(pg_num);
all_applied = false;
continue;
}
}
auto & pg = this->pgs[{ .pool_id = pool_id, .pg_num = pg_num }];
pg = (pg_t){
.state = pg_cfg.cur_primary == this->osd_num ? PG_PEERING : PG_STARTING,
.scheme = pool_item.second.scheme,
.pg_cursize = 0,
.pg_size = pool_item.second.pg_size,
.pg_minsize = pool_item.second.pg_minsize,
.pool_id = pool_id,
.pg_num = pg_num,
.reported_epoch = pg_cfg.epoch,
.target_history = pg_cfg.target_history,
.all_peers = std::vector<osd_num_t>(all_peers.begin(), all_peers.end()),
.target_set = pg_cfg.target_set,
};
this->pg_state_dirty.insert({ .pool_id = pool_id, .pg_num = pg_num });
pg.print_state();
if (pg_cfg.cur_primary == this->osd_num)
else if (this->pgs[pg_num].state & PG_STOPPING)
{
// Add peers
for (auto pg_osd: all_peers)
// Reapply change after stopping
all_applied = false;
continue;
}
else if (this->pgs[pg_num].state & PG_STARTING)
{
if (pg_cfg.cur_primary == this->osd_num)
{
if (pg_osd != this->osd_num && c_cli.osd_peer_fds.find(pg_osd) == c_cli.osd_peer_fds.end())
{
c_cli.connect_peer(pg_osd, st_cli.peer_states[pg_osd]);
}
// PG locked, continue
}
else
{
// Reapply change after locking the PG
all_applied = false;
continue;
}
start_pg_peering(pg);
}
else
{
// Reapply change after locking the PG
all_applied = false;
throw std::runtime_error("Unexpected PG "+std::to_string(pg_num)+" state: "+std::to_string(this->pgs[pg_num].state));
}
}
this->pgs[pg_num] = (pg_t){
.state = pg_cfg.cur_primary == this->osd_num ? PG_PEERING : PG_STARTING,
.pg_cursize = 0,
.pg_num = pg_num,
.target_history = pg_cfg.target_history,
.all_peers = std::vector<osd_num_t>(all_peers.begin(), all_peers.end()),
.target_set = pg_cfg.target_set,
};
this->pg_state_dirty.insert(pg_num);
this->pgs[pg_num].print_state();
if (pg_cfg.cur_primary == this->osd_num)
{
// Add peers
for (auto pg_osd: all_peers)
{
if (pg_osd != this->osd_num && c_cli.osd_peer_fds.find(pg_osd) == c_cli.osd_peer_fds.end())
{
c_cli.connect_peer(pg_osd, st_cli.peer_states[pg_osd]);
}
}
start_pg_peering(pg_num);
}
else
{
// Reapply change after locking the PG
all_applied = false;
}
}
}
report_pg_states();
@ -620,7 +584,8 @@ void osd_t::report_pg_states()
{
return;
}
std::vector<std::pair<pool_pg_num_t,bool>> reporting_pgs;
etcd_reporting_pg_state = true;
std::vector<std::pair<pg_num_t,bool>> reporting_pgs;
json11::Json::array checks;
json11::Json::array success;
json11::Json::array failure;
@ -632,8 +597,8 @@ void osd_t::report_pg_states()
continue;
}
auto & pg = pg_it->second;
reporting_pgs.push_back({ *it, pg.history_changed });
std::string state_key_base64 = base64_encode(st_cli.etcd_prefix+"/pg/state/"+std::to_string(pg.pool_id)+"/"+std::to_string(pg.pg_num));
reporting_pgs.push_back({ pg.pg_num, pg.history_changed });
std::string state_key_base64 = base64_encode(st_cli.etcd_prefix+"/pg/state/"+std::to_string(pg.pg_num));
if (pg.state == PG_STARTING)
{
// Check that the PG key does not exist
@ -675,7 +640,7 @@ void osd_t::report_pg_states()
}
success.push_back(json11::Json::object {
{ "request_put", json11::Json::object {
{ "key", state_key_base64 },
{ "key", base64_encode(st_cli.etcd_prefix+"/pg/state/"+std::to_string(pg.pg_num)) },
{ "value", base64_encode(json11::Json(json11::Json::object {
{ "primary", this->osd_num },
{ "state", pg_state_keywords },
@ -686,26 +651,26 @@ void osd_t::report_pg_states()
});
if (pg.history_changed)
{
// Prevent race conditions (for the case when the monitor is updating this key at the same time)
pg.history_changed = false;
std::string history_key = base64_encode(st_cli.etcd_prefix+"/pg/history/"+std::to_string(pg.pool_id)+"/"+std::to_string(pg.pg_num));
json11::Json::object history_value = {
{ "epoch", pg.epoch },
{ "all_peers", pg.all_peers },
{ "osd_sets", pg.target_history },
};
checks.push_back(json11::Json::object {
{ "target", "MOD" },
{ "key", history_key },
{ "result", "LESS" },
{ "mod_revision", st_cli.etcd_watch_revision+1 },
});
success.push_back(json11::Json::object {
{ "request_put", json11::Json::object {
{ "key", history_key },
{ "value", base64_encode(json11::Json(history_value).dump()) },
} }
});
if (pg.state == PG_ACTIVE)
{
success.push_back(json11::Json::object {
{ "request_delete_range", json11::Json::object {
{ "key", base64_encode(st_cli.etcd_prefix+"/pg/history/"+std::to_string(pg.pg_num)) },
} }
});
}
else if (pg.state == (PG_ACTIVE|PG_LEFT_ON_DEAD))
{
success.push_back(json11::Json::object {
{ "request_put", json11::Json::object {
{ "key", base64_encode(st_cli.etcd_prefix+"/pg/history/"+std::to_string(pg.pg_num)) },
{ "value", base64_encode(json11::Json(json11::Json::object {
{ "all_peers", pg.all_peers },
}).dump()) },
} }
});
}
}
}
failure.push_back(json11::Json::object {
@ -715,7 +680,6 @@ void osd_t::report_pg_states()
});
}
pg_state_dirty.clear();
etcd_reporting_pg_state = true;
st_cli.etcd_txn(json11::Json::object {
{ "compare", checks }, { "success", success }, { "failure", failure }
}, ETCD_QUICK_TIMEOUT, [this, reporting_pgs](std::string err, json11::Json data)
@ -741,23 +705,14 @@ void osd_t::report_pg_states()
if (res["kvs"].array_items().size())
{
auto kv = st_cli.parse_etcd_kv(res["kvs"][0]);
if (kv.key.substr(st_cli.etcd_prefix.length()+10) == st_cli.etcd_prefix+"/pg/state/")
pg_num_t pg_num = stoull_full(kv.key.substr(st_cli.etcd_prefix.length()+10));
auto pg_it = pgs.find(pg_num);
if (pg_it != pgs.end() && pg_it->second.state != PG_OFFLINE && pg_it->second.state != PG_STARTING)
{
pool_id_t pool_id = 0;
pg_num_t pg_num = 0;
char null_byte = 0;
sscanf(kv.key.c_str() + st_cli.etcd_prefix.length()+10, "%u/%u%c", &pool_id, &pg_num, &null_byte);
if (null_byte == 0)
{
auto pg_it = pgs.find({ .pool_id = pool_id, .pg_num = pg_num });
if (pg_it != pgs.end() && pg_it->second.state != PG_OFFLINE && pg_it->second.state != PG_STARTING)
{
// Live PG state update failed
printf("Failed to report state of pool %u PG %u which is live. Race condition detected, exiting\n", pool_id, pg_num);
force_stop(1);
return;
}
}
// Live PG state update failed
printf("Failed to report state of PG %u which is live. Race condition detected, exiting\n", pg_num);
force_stop(1);
return;
}
}
}

36
osd_flush.cpp
View File

@ -1,12 +1,10 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "osd.h"
#define FLUSH_BATCH 512
void osd_t::submit_pg_flush_ops(pg_t & pg)
void osd_t::submit_pg_flush_ops(pg_num_t pg_num)
{
pg_t & pg = pgs[pg_num];
pg_flush_batch_t *fb = new pg_flush_batch_t();
pg.flush_batch = fb;
auto it = pg.flush_actions.begin(), prev_it = pg.flush_actions.begin();
@ -47,7 +45,7 @@ void osd_t::submit_pg_flush_ops(pg_t & pg)
if (l.second.size() > 0)
{
fb->flush_ops++;
submit_flush_op(pg.pool_id, pg.pg_num, fb, true, l.first, l.second.size(), l.second.data());
submit_flush_op(pg.pg_num, fb, true, l.first, l.second.size(), l.second.data());
}
}
for (auto & l: fb->stable_lists)
@ -55,15 +53,14 @@ void osd_t::submit_pg_flush_ops(pg_t & pg)
if (l.second.size() > 0)
{
fb->flush_ops++;
submit_flush_op(pg.pool_id, pg.pg_num, fb, false, l.first, l.second.size(), l.second.data());
submit_flush_op(pg.pg_num, fb, false, l.first, l.second.size(), l.second.data());
}
}
}
void osd_t::handle_flush_op(bool rollback, pool_id_t pool_id, pg_num_t pg_num, pg_flush_batch_t *fb, osd_num_t peer_osd, int retval)
void osd_t::handle_flush_op(bool rollback, pg_num_t pg_num, pg_flush_batch_t *fb, osd_num_t peer_osd, int retval)
{
pool_pg_num_t pg_id = { .pool_id = pool_id, .pg_num = pg_num };
if (pgs.find(pg_id) == pgs.end() || pgs[pg_id].flush_batch != fb)
if (pgs.find(pg_num) == pgs.end() || pgs[pg_num].flush_batch != fb)
{
// Throw the result away
return;
@ -95,7 +92,7 @@ void osd_t::handle_flush_op(bool rollback, pool_id_t pool_id, pg_num_t pg_num, p
{
// This flush batch is done
std::vector<osd_op_t*> continue_ops;
auto & pg = pgs[pg_id];
auto & pg = pgs[pg_num];
auto it = pg.flush_actions.begin(), prev_it = it;
auto erase_start = it;
while (1)
@ -156,11 +153,11 @@ void osd_t::handle_flush_op(bool rollback, pool_id_t pool_id, pg_num_t pg_num, p
}
}
void osd_t::submit_flush_op(pool_id_t pool_id, pg_num_t pg_num, pg_flush_batch_t *fb, bool rollback, osd_num_t peer_osd, int count, obj_ver_id *data)
void osd_t::submit_flush_op(pg_num_t pg_num, pg_flush_batch_t *fb, bool rollback, osd_num_t peer_osd, int count, obj_ver_id *data)
{
osd_op_t *op = new osd_op_t();
// Copy buffer so it gets freed along with the operation
op->buf = malloc_or_die(sizeof(obj_ver_id) * count);
op->buf = malloc(sizeof(obj_ver_id) * count);
memcpy(op->buf, data, sizeof(obj_ver_id) * count);
if (peer_osd == this->osd_num)
{
@ -168,10 +165,10 @@ void osd_t::submit_flush_op(pool_id_t pool_id, pg_num_t pg_num, pg_flush_batch_t
clock_gettime(CLOCK_REALTIME, &op->tv_begin);
op->bs_op = new blockstore_op_t({
.opcode = (uint64_t)(rollback ? BS_OP_ROLLBACK : BS_OP_STABLE),
.callback = [this, op, pool_id, pg_num, fb](blockstore_op_t *bs_op)
.callback = [this, op, pg_num, fb](blockstore_op_t *bs_op)
{
add_bs_subop_stats(op);
handle_flush_op(bs_op->opcode == BS_OP_ROLLBACK, pool_id, pg_num, fb, this->osd_num, bs_op->retval);
handle_flush_op(bs_op->opcode == BS_OP_ROLLBACK, pg_num, fb, this->osd_num, bs_op->retval);
delete op->bs_op;
op->bs_op = NULL;
delete op;
@ -186,21 +183,22 @@ void osd_t::submit_flush_op(pool_id_t pool_id, pg_num_t pg_num, pg_flush_batch_t
// Peer
int peer_fd = c_cli.osd_peer_fds[peer_osd];
op->op_type = OSD_OP_OUT;
op->iov.push_back(op->buf, count * sizeof(obj_ver_id));
op->send_list.push_back(op->req.buf, OSD_PACKET_SIZE);
op->send_list.push_back(op->buf, count * sizeof(obj_ver_id));
op->peer_fd = peer_fd;
op->req = {
.sec_stab = {
.header = {
.magic = SECONDARY_OSD_OP_MAGIC,
.id = c_cli.next_subop_id++,
.opcode = (uint64_t)(rollback ? OSD_OP_SEC_ROLLBACK : OSD_OP_SEC_STABILIZE),
.opcode = (uint64_t)(rollback ? OSD_OP_SECONDARY_ROLLBACK : OSD_OP_SECONDARY_STABILIZE),
},
.len = count * sizeof(obj_ver_id),
},
};
op->callback = [this, pool_id, pg_num, fb, peer_osd](osd_op_t *op)
op->callback = [this, pg_num, fb, peer_osd](osd_op_t *op)
{
handle_flush_op(op->req.hdr.opcode == OSD_OP_SEC_ROLLBACK, pool_id, pg_num, fb, peer_osd, op->reply.hdr.retval);
handle_flush_op(op->req.hdr.opcode == OSD_OP_SECONDARY_ROLLBACK, pg_num, fb, peer_osd, op->reply.hdr.retval);
delete op;
};
c_cli.outbox_push(op);
@ -218,6 +216,7 @@ bool osd_t::pick_next_recovery(osd_recovery_op_t &op)
if (recovery_ops.find(obj_it->first) == recovery_ops.end())
{
op.degraded = true;
op.pg_num = pg_it->first;
op.oid = obj_it->first;
return true;
}
@ -233,6 +232,7 @@ bool osd_t::pick_next_recovery(osd_recovery_op_t &op)
if (recovery_ops.find(obj_it->first) == recovery_ops.end())
{
op.degraded = false;
op.pg_num = pg_it->first;
op.oid = obj_it->first;
return true;
}

23
osd_id.h
View File

@ -1,27 +1,4 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#define POOL_SCHEME_REPLICATED 1
#define POOL_SCHEME_XOR 2
#define POOL_ID_MAX 0x10000
#define POOL_ID_BITS 16
#define INODE_POOL(inode) (pool_id_t)((inode) >> (64 - POOL_ID_BITS))
// Pool ID is 16 bits long
typedef uint32_t pool_id_t;
typedef uint64_t osd_num_t;
typedef uint32_t pg_num_t;
struct pool_pg_num_t
{
pool_id_t pool_id;
pg_num_t pg_num;
};
inline bool operator < (const pool_pg_num_t & a, const pool_pg_num_t & b)
{
return a.pool_id < b.pool_id || a.pool_id == b.pool_id && a.pg_num < b.pg_num;
}

5
osd_main.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "osd.h"
#include <signal.h>
@ -21,8 +18,6 @@ static void handle_sigint(int sig)
int main(int narg, char *args[])
{
setvbuf(stdout, NULL, _IONBF, 0);
setvbuf(stderr, NULL, _IONBF, 0);
if (sizeof(osd_any_op_t) > OSD_PACKET_SIZE ||
sizeof(osd_any_reply_t) > OSD_PACKET_SIZE)
{

22
osd_ops.cpp
View File

@ -1,22 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include "osd_ops.h"
const char* osd_op_names[] = {
"",
"read",
"write",
"write_stable",
"sync",
"stabilize",
"rollback",
"delete",
"sync_stab_all",
"list",
"show_config",
"primary_read",
"primary_write",
"primary_sync",
"primary_delete",
};

37
osd_ops.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include "object_id.h"
@ -13,21 +10,20 @@
#define OSD_PACKET_SIZE 0x80
// Opcodes
#define OSD_OP_MIN 1
#define OSD_OP_SEC_READ 1
#define OSD_OP_SEC_WRITE 2
#define OSD_OP_SEC_WRITE_STABLE 3
#define OSD_OP_SEC_SYNC 4
#define OSD_OP_SEC_STABILIZE 5
#define OSD_OP_SEC_ROLLBACK 6
#define OSD_OP_SEC_DELETE 7
#define OSD_OP_TEST_SYNC_STAB_ALL 8
#define OSD_OP_SEC_LIST 9
#define OSD_OP_SHOW_CONFIG 10
#define OSD_OP_READ 11
#define OSD_OP_WRITE 12
#define OSD_OP_SYNC 13
#define OSD_OP_DELETE 14
#define OSD_OP_MAX 14
#define OSD_OP_SECONDARY_READ 1
#define OSD_OP_SECONDARY_WRITE 2
#define OSD_OP_SECONDARY_SYNC 3
#define OSD_OP_SECONDARY_STABILIZE 4
#define OSD_OP_SECONDARY_ROLLBACK 5
#define OSD_OP_SECONDARY_DELETE 6
#define OSD_OP_TEST_SYNC_STAB_ALL 7
#define OSD_OP_SECONDARY_LIST 8
#define OSD_OP_SHOW_CONFIG 9
#define OSD_OP_READ 10
#define OSD_OP_WRITE 11
#define OSD_OP_SYNC 12
#define OSD_OP_DELETE 13
#define OSD_OP_MAX 13
// Alignment & limit for read/write operations
#ifndef MEM_ALIGNMENT
#define MEM_ALIGNMENT 512
@ -138,10 +134,7 @@ struct __attribute__((__packed__)) osd_op_secondary_list_t
osd_op_header_t header;
// placement group total number and total count
pg_num_t list_pg, pg_count;
// size of an area that maps to one PG continuously
uint64_t pg_stripe_size;
// inode range (used to select pools)
uint64_t min_inode, max_inode;
};
struct __attribute__((__packed__)) osd_reply_secondary_list_t
@ -209,5 +202,3 @@ union osd_any_reply_t
osd_reply_sync_t sync;
uint8_t buf[OSD_PACKET_SIZE];
};
extern const char* osd_op_names[];

65
osd_peering.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <netinet/tcp.h>
#include <sys/epoll.h>
@ -29,7 +26,7 @@ void osd_t::handle_peers()
degraded_objects += p.second.degraded_objects.size();
if ((p.second.state & (PG_ACTIVE | PG_HAS_UNCLEAN)) == (PG_ACTIVE | PG_HAS_UNCLEAN))
peering_state = peering_state | OSD_FLUSHING_PGS;
else if (p.second.state & PG_ACTIVE)
else
peering_state = peering_state | OSD_RECOVERING;
}
else
@ -53,7 +50,7 @@ void osd_t::handle_peers()
{
if (!p.second.flush_batch)
{
submit_pg_flush_ops(p.second);
submit_pg_flush_ops(p.first);
}
still = true;
}
@ -92,15 +89,16 @@ void osd_t::repeer_pgs(osd_num_t peer_osd)
{
// Repeer this pg
printf("[PG %u] Repeer because of OSD %lu\n", p.second.pg_num, peer_osd);
start_pg_peering(p.second);
start_pg_peering(p.second.pg_num);
}
}
}
}
// Repeer on each connect/disconnect peer event
void osd_t::start_pg_peering(pg_t & pg)
void osd_t::start_pg_peering(pg_num_t pg_num)
{
auto & pg = pgs[pg_num];
pg.state = PG_PEERING;
this->peering_state |= OSD_PEERING_PGS;
report_pg_state(pg);
@ -125,32 +123,16 @@ void osd_t::start_pg_peering(pg_t & pg)
cancel_primary_write(p.second);
}
pg.write_queue.clear();
uint64_t pg_stripe_size = st_cli.pool_config[pg.pool_id].pg_stripe_size;
for (auto it = unstable_writes.begin(); it != unstable_writes.end(); )
{
// Forget this PG's unstable writes
if (INODE_POOL(it->first.oid.inode) == pg.pool_id && map_to_pg(it->first.oid, pg_stripe_size) == pg.pg_num)
pg_num_t n = (it->first.oid.inode + it->first.oid.stripe / pg_stripe_size) % pg_count + 1;
if (n == pg.pg_num)
unstable_writes.erase(it++);
else
it++;
}
dirty_pgs.erase({ .pool_id = pg.pool_id, .pg_num = pg.pg_num });
// Drop connections of clients who have this PG in dirty_pgs
if (immediate_commit != IMMEDIATE_ALL)
{
std::vector<int> to_stop;
for (auto & cp: c_cli.clients)
{
if (cp.second.dirty_pgs.find({ .pool_id = pg.pool_id, .pg_num = pg.pg_num }) != cp.second.dirty_pgs.end())
{
to_stop.push_back(cp.first);
}
}
for (auto peer_fd: to_stop)
{
c_cli.stop_client(peer_fd);
}
}
dirty_pgs.erase(pg.pg_num);
// Calculate current write OSD set
pg.pg_cursize = 0;
pg.cur_set.resize(pg.target_set.size());
@ -188,7 +170,6 @@ void osd_t::start_pg_peering(pg_t & pg)
{
pg.state = PG_INCOMPLETE;
report_pg_state(pg);
return;
}
}
}
@ -196,7 +177,6 @@ void osd_t::start_pg_peering(pg_t & pg)
{
pg.state = PG_INCOMPLETE;
report_pg_state(pg);
return;
}
std::set<osd_num_t> cur_peers;
for (auto pg_osd: pg.all_peers)
@ -253,7 +233,6 @@ void osd_t::start_pg_peering(pg_t & pg)
if (!pg.peering_state)
{
pg.peering_state = new pg_peering_state_t();
pg.peering_state->pool_id = pg.pool_id;
pg.peering_state->pg_num = pg.pg_num;
}
for (osd_num_t peer_osd: cur_peers)
@ -308,13 +287,14 @@ void osd_t::submit_sync_and_list_subop(osd_num_t role_osd, pg_peering_state_t *p
auto & cl = c_cli.clients.at(c_cli.osd_peer_fds[role_osd]);
osd_op_t *op = new osd_op_t();
op->op_type = OSD_OP_OUT;
op->send_list.push_back(op->req.buf, OSD_PACKET_SIZE);
op->peer_fd = cl.peer_fd;
op->req = {
.sec_sync = {
.header = {
.magic = SECONDARY_OSD_OP_MAGIC,
.id = c_cli.next_subop_id++,
.opcode = OSD_OP_SEC_SYNC,
.opcode = OSD_OP_SECONDARY_SYNC,
},
},
};
@ -349,10 +329,8 @@ void osd_t::submit_list_subop(osd_num_t role_osd, pg_peering_state_t *ps)
clock_gettime(CLOCK_REALTIME, &op->tv_begin);
op->bs_op = new blockstore_op_t();
op->bs_op->opcode = BS_OP_LIST;
op->bs_op->oid.stripe = st_cli.pool_config[ps->pool_id].pg_stripe_size;
op->bs_op->oid.inode = ((uint64_t)ps->pool_id << (64 - POOL_ID_BITS));
op->bs_op->version = ((uint64_t)(ps->pool_id+1) << (64 - POOL_ID_BITS)) - 1;
op->bs_op->len = pg_counts[ps->pool_id];
op->bs_op->oid.stripe = pg_stripe_size;
op->bs_op->len = pg_count;
op->bs_op->offset = ps->pg_num-1;
op->bs_op->callback = [this, ps, op, role_osd](blockstore_op_t *bs_op)
{
@ -383,19 +361,18 @@ void osd_t::submit_list_subop(osd_num_t role_osd, pg_peering_state_t *ps)
// Peer
osd_op_t *op = new osd_op_t();
op->op_type = OSD_OP_OUT;
op->send_list.push_back(op->req.buf, OSD_PACKET_SIZE);
op->peer_fd = c_cli.osd_peer_fds[role_osd];
op->req = {
.sec_list = {
.header = {
.magic = SECONDARY_OSD_OP_MAGIC,
.id = c_cli.next_subop_id++,
.opcode = OSD_OP_SEC_LIST,
.opcode = OSD_OP_SECONDARY_LIST,
},
.list_pg = ps->pg_num,
.pg_count = pg_counts[ps->pool_id],
.pg_stripe_size = st_cli.pool_config[ps->pool_id].pg_stripe_size,
.min_inode = ((uint64_t)(ps->pool_id) << (64 - POOL_ID_BITS)),
.max_inode = ((uint64_t)(ps->pool_id+1) << (64 - POOL_ID_BITS)) - 1,
.pg_count = pg_count,
.pg_stripe_size = pg_stripe_size,
},
};
op->callback = [this, ps, role_osd](osd_op_t *op)
@ -451,8 +428,14 @@ void osd_t::discard_list_subop(osd_op_t *list_op)
}
}
bool osd_t::stop_pg(pg_t & pg)
bool osd_t::stop_pg(pg_num_t pg_num)
{
auto pg_it = pgs.find(pg_num);
if (pg_it == pgs.end())
{
return false;
}
auto & pg = pg_it->second;
if (pg.peering_state)
{
// Stop peering
@ -495,7 +478,7 @@ void osd_t::finish_stop_pg(pg_t & pg)
void osd_t::report_pg_state(pg_t & pg)
{
pg.print_state();
this->pg_state_dirty.insert({ .pool_id = pg.pool_id, .pg_num = pg.pg_num });
this->pg_state_dirty.insert(pg.pg_num);
if (pg.state == PG_ACTIVE && (pg.target_history.size() > 0 || pg.all_peers.size() > pg.target_set.size()))
{
// Clear history of active+clean PGs

127
osd_peering_pg.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "osd_peering_pg.h"
struct obj_ver_role
@ -36,7 +33,6 @@ struct obj_piece_ver_t
struct pg_obj_state_check_t
{
pg_t *pg;
bool replicated = false;
std::vector<obj_ver_role> list;
int list_pos;
int obj_start = 0, obj_end = 0, ver_start = 0, ver_end = 0;
@ -45,7 +41,7 @@ struct pg_obj_state_check_t
uint64_t last_ver = 0;
uint64_t target_ver = 0;
uint64_t n_copies = 0, has_roles = 0, n_roles = 0, n_stable = 0, n_mismatched = 0;
uint64_t n_unstable = 0, n_invalid = 0;
uint64_t n_unstable = 0, n_buggy = 0;
pg_osd_set_t osd_set;
int log_level;
@ -77,12 +73,6 @@ void pg_obj_state_check_t::walk()
{
finish_object();
}
if (pg->state & PG_HAS_INVALID)
{
// Stop PGs with "invalid" objects
pg->state = PG_INCOMPLETE | PG_HAS_INVALID;
return;
}
if (pg->pg_cursize < pg->pg_size)
{
pg->state |= PG_DEGRADED;
@ -102,7 +92,7 @@ void pg_obj_state_check_t::start_object()
target_ver = 0;
ver_start = list_pos;
has_roles = n_copies = n_roles = n_stable = n_mismatched = 0;
n_unstable = n_invalid = 0;
n_unstable = n_buggy = 0;
}
void pg_obj_state_check_t::handle_version()
@ -121,11 +111,11 @@ void pg_obj_state_check_t::handle_version()
has_roles = n_copies = n_roles = n_stable = n_mismatched = 0;
last_ver = list[list_pos].version;
}
unsigned replica = (list[list_pos].oid.stripe & STRIPE_MASK);
int replica = (list[list_pos].oid.stripe & STRIPE_MASK);
n_copies++;
if (replicated && replica > 0 || replica >= pg->pg_size)
if (replica >= pg->pg_size)
{
n_invalid++;
n_buggy++;
}
else
{
@ -133,32 +123,14 @@ void pg_obj_state_check_t::handle_version()
{
n_stable++;
}
if (replicated)
if (pg->cur_set[replica] != list[list_pos].osd_num)
{
int i;
for (i = 0; i < pg->cur_set.size(); i++)
{
if (pg->cur_set[i] == list[list_pos].osd_num)
{
break;
}
}
if (i == pg->cur_set.size())
{
n_mismatched++;
}
n_mismatched++;
}
else
if (!(has_roles & (1 << replica)))
{
if (pg->cur_set[replica] != list[list_pos].osd_num)
{
n_mismatched++;
}
if (!(has_roles & (1 << replica)))
{
has_roles = has_roles | (1 << replica);
n_roles++;
}
has_roles = has_roles | (1 << replica);
n_roles++;
}
}
}
@ -179,14 +151,11 @@ void pg_obj_state_check_t::finish_object()
obj_end = list_pos;
// Remember the decision
uint64_t state = 0;
if (n_invalid > 0)
if (n_buggy > 0)
{
// It's not allowed to change the replication scheme for a pool other than by recreating it
// So we must bring the PG offline
state = OBJ_INCOMPLETE;
pg->state |= PG_HAS_INVALID;
pg->total_count++;
return;
state = OBJ_BUGGY;
// FIXME: bring pg offline
throw std::runtime_error("buggy object state");
}
if (n_unstable > 0)
{
@ -232,7 +201,7 @@ void pg_obj_state_check_t::finish_object()
{
return;
}
if (!replicated && n_roles < pg->pg_minsize)
if (n_roles < pg->pg_minsize)
{
if (log_level > 1)
{
@ -241,7 +210,7 @@ void pg_obj_state_check_t::finish_object()
state = OBJ_INCOMPLETE;
pg->state = pg->state | PG_HAS_INCOMPLETE;
}
else if ((replicated ? n_copies : n_roles) < pg->pg_cursize)
else if (n_roles < pg->pg_cursize)
{
if (log_level > 1)
{
@ -250,31 +219,29 @@ void pg_obj_state_check_t::finish_object()
state = OBJ_DEGRADED;
pg->state = pg->state | PG_HAS_DEGRADED;
}
else if (n_mismatched > 0)
if (n_mismatched > 0)
{
if (log_level > 1 && (replicated || n_roles >= pg->pg_cursize))
if (n_roles >= pg->pg_cursize && log_level > 1)
{
printf("Object is misplaced: inode=%lu stripe=%lu version=%lu/%lu\n", oid.inode, oid.stripe, target_ver, max_ver);
}
state |= OBJ_MISPLACED;
pg->state = pg->state | PG_HAS_MISPLACED;
}
if (log_level > 1 && ((replicated ? n_copies : n_roles) < pg->pg_cursize || n_mismatched > 0))
if (log_level > 1 && (n_roles < pg->pg_cursize || n_mismatched > 0))
{
if (log_level > 2)
{
for (int i = obj_start; i < obj_end; i++)
{
printf("v%lu present on: osd %lu, role %ld%s\n", list[i].version, list[i].osd_num,
(list[i].oid.stripe & STRIPE_MASK), list[i].is_stable ? " (stable)" : "");
printf("v%lu present on: osd %lu, role %ld%s\n", list[i].version, list[i].osd_num, (list[i].oid.stripe & STRIPE_MASK), list[i].is_stable ? " (stable)" : "");
}
}
else
{
for (int i = ver_start; i < ver_end; i++)
{
printf("Target version present on: osd %lu, role %ld%s\n", list[i].osd_num,
(list[i].oid.stripe & STRIPE_MASK), list[i].is_stable ? " (stable)" : "");
printf("Target version present on: osd %lu, role %ld%s\n", list[i].osd_num, (list[i].oid.stripe & STRIPE_MASK), list[i].is_stable ? " (stable)" : "");
}
}
}
@ -311,11 +278,8 @@ void pg_obj_state_check_t::finish_object()
.osd_num = list[i].osd_num,
.outdated = true,
});
if (!(state & (OBJ_INCOMPLETE | OBJ_DEGRADED)))
{
state |= OBJ_MISPLACED;
pg->state = pg->state | PG_HAS_MISPLACED;
}
state |= OBJ_MISPLACED;
pg->state = pg->state | PG_HAS_MISPLACED;
}
}
}
@ -333,34 +297,16 @@ void pg_obj_state_check_t::finish_object()
if (it == pg->state_dict.end())
{
std::vector<uint64_t> read_target;
if (replicated)
read_target.resize(pg->pg_size);
for (int i = 0; i < pg->pg_size; i++)
{
for (auto & o: osd_set)
{
if (!o.outdated)
{
read_target.push_back(o.osd_num);
}
}
while (read_target.size() < pg->pg_size)
{
// FIXME: This is because we then use .data() and assume it's at least <pg_size> long
read_target.push_back(0);
}
read_target[i] = 0;
}
else
for (auto & o: osd_set)
{
read_target.resize(pg->pg_size);
for (int i = 0; i < pg->pg_size; i++)
if (!o.outdated)
{
read_target[i] = 0;
}
for (auto & o: osd_set)
{
if (!o.outdated)
{
read_target[o.role] = o.osd_num;
}
read_target[o.role] = o.osd_num;
}
}
pg->state_dict[osd_set] = {
@ -397,9 +343,7 @@ void pg_t::calc_object_states(int log_level)
pg_obj_state_check_t st;
st.log_level = log_level;
st.pg = this;
st.replicated = (this->scheme == POOL_SCHEME_REPLICATED);
auto ps = peering_state;
epoch = 0;
for (auto it: ps->list_results)
{
auto nstab = it.second.stable_count;
@ -410,10 +354,6 @@ void pg_t::calc_object_states(int log_level)
obj_ver_id *ov = it.second.buf;
for (uint64_t i = 0; i < n; i++, ov++)
{
if ((ov->version >> (64-PG_EPOCH_BITS)) > epoch)
{
epoch = (ov->version >> (64-PG_EPOCH_BITS));
}
st.list[start+i] = {
.oid = ov->oid,
.version = ov->version,
@ -429,17 +369,12 @@ void pg_t::calc_object_states(int log_level)
std::sort(st.list.begin(), st.list.end());
// Walk over it and check object states
st.walk();
if (this->state & (PG_DEGRADED|PG_LEFT_ON_DEAD))
{
assert(epoch != ((1ul << PG_EPOCH_BITS)-1));
epoch++;
}
}
void pg_t::print_state()
{
printf(
"[PG %u] is %s%s%s%s%s%s%s%s%s%s%s%s%s (%lu objects)\n", pg_num,
"[PG %u] is %s%s%s%s%s%s%s%s%s%s%s (%lu objects)\n", pg_num,
(state & PG_STARTING) ? "starting" : "",
(state & PG_OFFLINE) ? "offline" : "",
(state & PG_PEERING) ? "peering" : "",
@ -451,8 +386,6 @@ void pg_t::print_state()
(state & PG_HAS_DEGRADED) ? " + has_degraded" : "",
(state & PG_HAS_MISPLACED) ? " + has_misplaced" : "",
(state & PG_HAS_UNCLEAN) ? " + has_unclean" : "",
(state & PG_HAS_INVALID) ? " + has_invalid" : "",
(state & PG_LEFT_ON_DEAD) ? " + left_on_dead" : "",
total_count
);
}

14
osd_peering_pg.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <map>
#include <unordered_map>
#include <vector>
@ -12,8 +9,6 @@
#include "osd_ops.h"
#include "pg_states.h"
#define PG_EPOCH_BITS 48
struct pg_obj_loc_t
{
uint64_t role;
@ -47,7 +42,6 @@ struct pg_peering_state_t
// osd_num -> list result
std::unordered_map<osd_num_t, osd_op_t*> list_ops;
std::unordered_map<osd_num_t, pg_list_result_t> list_results;
pool_id_t pool_id = 0;
pg_num_t pg_num = 0;
};
@ -75,13 +69,9 @@ struct pg_flush_batch_t
struct pg_t
{
int state = 0;
uint64_t scheme = 0;
uint64_t pg_cursize = 0, pg_size = 0, pg_minsize = 0;
pool_id_t pool_id = 0;
pg_num_t pg_num = 0;
uint64_t pg_cursize = 3, pg_size = 3, pg_minsize = 2;
pg_num_t pg_num;
uint64_t clean_count = 0, total_count = 0;
// epoch number - should increase with each non-clean activation of the PG
uint64_t epoch = 0, reported_epoch = 0;
// target history and all potential peers
std::vector<std::vector<osd_num_t>> target_history;
std::vector<osd_num_t> all_peers;

5
osd_peering_pg_test.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#define _LARGEFILE64_SOURCE
#include "osd_peering_pg.h"
@ -31,7 +28,7 @@ int main(int argc, char *argv[])
for (uint64_t osd_num = 1; osd_num <= 3; osd_num++)
{
pg_list_result_t r = {
.buf = (obj_ver_id*)malloc_or_die(sizeof(obj_ver_id) * 1024*1024*8),
.buf = (obj_ver_id*)malloc(sizeof(obj_ver_id) * 1024*1024*8),
.total_count = 1024*1024*8,
.stable_count = (uint64_t)(1024*1024*8 - (osd_num == 1 ? 10 : 0)),
};

324
osd_primary.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "osd_primary.h"
// read: read directly or read paired stripe(s), reconstruct, return
@ -16,17 +13,15 @@ bool osd_t::prepare_primary_rw(osd_op_t *cur_op)
{
// PG number is calculated from the offset
// Our EC scheme stores data in fixed chunks equal to (K*block size)
// K = pg_minsize in case of EC/XOR, or 1 for replicated pools
pool_id_t pool_id = INODE_POOL(cur_op->req.rw.inode);
auto & pool_cfg = st_cli.pool_config[pool_id];
uint64_t pg_block_size = bs_block_size * (pool_cfg.scheme == POOL_SCHEME_REPLICATED ? 1 : pool_cfg.pg_minsize);
// K = pg_minsize and will be a property of the inode. Not it's hardcoded (FIXME)
uint64_t pg_block_size = bs_block_size * 2;
object_id oid = {
.inode = cur_op->req.rw.inode,
// oid.stripe = starting offset of the parity stripe
.stripe = (cur_op->req.rw.offset/pg_block_size)*pg_block_size,
};
pg_num_t pg_num = (cur_op->req.rw.inode + oid.stripe/pool_cfg.pg_stripe_size) % pg_counts[pool_id] + 1;
auto pg_it = pgs.find({ .pool_id = pool_id, .pg_num = pg_num });
pg_num_t pg_num = (cur_op->req.rw.inode + oid.stripe/pg_stripe_size) % pg_count + 1;
auto pg_it = pgs.find(pg_num);
if (pg_it == pgs.end() || !(pg_it->second.state & PG_ACTIVE))
{
// This OSD is not primary for this PG or the PG is inactive
@ -40,16 +35,14 @@ bool osd_t::prepare_primary_rw(osd_op_t *cur_op)
finish_op(cur_op, -EINVAL);
return false;
}
osd_primary_op_data_t *op_data = (osd_primary_op_data_t*)calloc_or_die(
1, sizeof(osd_primary_op_data_t) + sizeof(osd_rmw_stripe_t) * (pool_cfg.scheme == POOL_SCHEME_REPLICATED ? 1 : pg_it->second.pg_size)
osd_primary_op_data_t *op_data = (osd_primary_op_data_t*)calloc(
sizeof(osd_primary_op_data_t) + sizeof(osd_rmw_stripe_t) * pg_it->second.pg_size, 1
);
op_data->pg_num = pg_num;
op_data->oid = oid;
op_data->stripes = ((osd_rmw_stripe_t*)(op_data+1));
op_data->scheme = pool_cfg.scheme;
cur_op->op_data = op_data;
split_stripes((pool_cfg.scheme == POOL_SCHEME_REPLICATED ? 1 : pg_it->second.pg_minsize),
bs_block_size, (uint32_t)(cur_op->req.rw.offset - oid.stripe), cur_op->req.rw.len, op_data->stripes);
split_stripes(pg_it->second.pg_minsize, bs_block_size, (uint32_t)(cur_op->req.rw.offset - oid.stripe), cur_op->req.rw.len, op_data->stripes);
pg_it->second.inflight++;
return true;
}
@ -93,8 +86,8 @@ void osd_t::continue_primary_read(osd_op_t *cur_op)
if (op_data->st == 1) goto resume_1;
else if (op_data->st == 2) goto resume_2;
{
auto & pg = pgs[{ .pool_id = INODE_POOL(op_data->oid.inode), .pg_num = op_data->pg_num }];
for (int role = 0; role < (op_data->scheme == POOL_SCHEME_REPLICATED ? 1 : pg.pg_minsize); role++)
auto & pg = pgs[op_data->pg_num];
for (int role = 0; role < pg.pg_minsize; role++)
{
op_data->stripes[role].read_start = op_data->stripes[role].req_start;
op_data->stripes[role].read_end = op_data->stripes[role].req_end;
@ -102,13 +95,12 @@ void osd_t::continue_primary_read(osd_op_t *cur_op)
// Determine version
auto vo_it = pg.ver_override.find(op_data->oid);
op_data->target_ver = vo_it != pg.ver_override.end() ? vo_it->second : UINT64_MAX;
if (pg.state == PG_ACTIVE || op_data->scheme == POOL_SCHEME_REPLICATED)
if (pg.state == PG_ACTIVE)
{
// Fast happy-path
cur_op->buf = alloc_read_buffer(op_data->stripes,
(op_data->scheme == POOL_SCHEME_REPLICATED ? 1 : pg.pg_minsize), 0);
submit_primary_subops(SUBMIT_READ, op_data->target_ver,
(op_data->scheme == POOL_SCHEME_REPLICATED ? pg.pg_size : pg.pg_minsize), pg.cur_set.data(), cur_op);
cur_op->buf = alloc_read_buffer(op_data->stripes, pg.pg_minsize, 0);
submit_primary_subops(SUBMIT_READ, pg.pg_minsize, pg.cur_set.data(), cur_op);
cur_op->send_list.push_back(cur_op->buf, cur_op->req.rw.len);
op_data->st = 1;
}
else
@ -125,7 +117,7 @@ void osd_t::continue_primary_read(osd_op_t *cur_op)
op_data->pg_size = pg.pg_size;
op_data->degraded = 1;
cur_op->buf = alloc_read_buffer(op_data->stripes, pg.pg_size, 0);
submit_primary_subops(SUBMIT_READ, op_data->target_ver, pg.pg_size, cur_set, cur_op);
submit_primary_subops(SUBMIT_READ, pg.pg_size, cur_set, cur_op);
op_data->st = 1;
}
}
@ -146,22 +138,18 @@ resume_2:
{
if (stripes[role].read_end != 0 && stripes[role].missing)
{
reconstruct_stripe_xor(stripes, op_data->pg_size, role);
reconstruct_stripe(stripes, op_data->pg_size, role);
}
if (stripes[role].req_end != 0)
{
// Send buffer in parts to avoid copying
cur_op->iov.push_back(
cur_op->send_list.push_back(
stripes[role].read_buf + (stripes[role].req_start - stripes[role].read_start),
stripes[role].req_end - stripes[role].req_start
);
}
}
}
else
{
cur_op->iov.push_back(cur_op->buf, cur_op->req.rw.len);
}
finish_op(cur_op, cur_op->req.rw.len);
}
@ -199,7 +187,7 @@ void osd_t::continue_primary_write(osd_op_t *cur_op)
return;
}
osd_primary_op_data_t *op_data = cur_op->op_data;
auto & pg = pgs[{ .pool_id = INODE_POOL(op_data->oid.inode), .pg_num = op_data->pg_num }];
auto & pg = pgs[op_data->pg_num];
if (op_data->st == 1) goto resume_1;
else if (op_data->st == 2) goto resume_2;
else if (op_data->st == 3) goto resume_3;
@ -209,8 +197,8 @@ void osd_t::continue_primary_write(osd_op_t *cur_op)
else if (op_data->st == 7) goto resume_7;
else if (op_data->st == 8) goto resume_8;
else if (op_data->st == 9) goto resume_9;
else if (op_data->st == 10) goto resume_10;
assert(op_data->st == 0);
printf("primary_write\n");
if (!check_write_queue(cur_op, pg))
{
return;
@ -218,30 +206,12 @@ void osd_t::continue_primary_write(osd_op_t *cur_op)
resume_1:
// Determine blocks to read and write
// Missing chunks are allowed to be overwritten even in incomplete objects
// FIXME: Allow to do small writes to the old (degraded/misplaced) OSD set for lower performance impact
// FIXME: Allow to do small writes to the old (degraded/misplaced) OSD set for the lower performance impact
op_data->prev_set = get_object_osd_set(pg, op_data->oid, pg.cur_set.data(), &op_data->object_state);
if (op_data->scheme == POOL_SCHEME_REPLICATED)
{
// Simplified algorithm
op_data->stripes[0].write_start = op_data->stripes[0].req_start;
op_data->stripes[0].write_end = op_data->stripes[0].req_end;
op_data->stripes[0].write_buf = cur_op->buf;
if (pg.cur_set.data() != op_data->prev_set && (op_data->stripes[0].write_start != 0 ||
op_data->stripes[0].write_end != bs_block_size))
{
// Object is degraded/misplaced and will be moved to <write_osd_set>
op_data->stripes[0].read_start = 0;
op_data->stripes[0].read_end = bs_block_size;
cur_op->rmw_buf = op_data->stripes[0].read_buf = memalign_or_die(MEM_ALIGNMENT, bs_block_size);
}
}
else
{
cur_op->rmw_buf = calc_rmw(cur_op->buf, op_data->stripes, op_data->prev_set,
pg.pg_size, pg.pg_minsize, pg.pg_cursize, pg.cur_set.data(), bs_block_size);
}
cur_op->rmw_buf = calc_rmw(cur_op->buf, op_data->stripes, op_data->prev_set,
pg.pg_size, pg.pg_minsize, pg.pg_cursize, pg.cur_set.data(), bs_block_size);
// Read required blocks
submit_primary_subops(SUBMIT_RMW_READ, UINT64_MAX, pg.pg_size, op_data->prev_set, cur_op);
submit_primary_subops(SUBMIT_RMW_READ, pg.pg_size, op_data->prev_set, cur_op);
resume_2:
op_data->st = 2;
return;
@ -253,56 +223,10 @@ resume_3:
}
// Save version override for parallel reads
pg.ver_override[op_data->oid] = op_data->fact_ver;
if (op_data->scheme == POOL_SCHEME_REPLICATED)
{
// Only (possibly) copy new data from the request into the recovery buffer
if (pg.cur_set.data() != op_data->prev_set && (op_data->stripes[0].write_start != 0 ||
op_data->stripes[0].write_end != bs_block_size))
{
memcpy(
op_data->stripes[0].read_buf + op_data->stripes[0].req_start,
op_data->stripes[0].write_buf,
op_data->stripes[0].req_end - op_data->stripes[0].req_start
);
op_data->stripes[0].write_buf = op_data->stripes[0].read_buf;
op_data->stripes[0].write_start = 0;
op_data->stripes[0].write_end = bs_block_size;
}
}
else
{
// Recover missing stripes, calculate parity
calc_rmw_parity_xor(op_data->stripes, pg.pg_size, op_data->prev_set, pg.cur_set.data(), bs_block_size);
}
// Recover missing stripes, calculate parity
calc_rmw_parity(op_data->stripes, pg.pg_size, op_data->prev_set, pg.cur_set.data(), bs_block_size);
// Send writes
if ((op_data->fact_ver >> (64-PG_EPOCH_BITS)) < pg.epoch)
{
op_data->target_ver = ((uint64_t)pg.epoch << (64-PG_EPOCH_BITS)) | 1;
}
else
{
if ((op_data->fact_ver & (1ul<<(64-PG_EPOCH_BITS) - 1)) == (1ul<<(64-PG_EPOCH_BITS) - 1))
{
assert(pg.epoch != ((1ul << PG_EPOCH_BITS)-1));
pg.epoch++;
}
op_data->target_ver = op_data->fact_ver + 1;
}
if (pg.epoch > pg.reported_epoch)
{
// Report newer epoch before writing
// FIXME: We may report only one PG state here...
this->pg_state_dirty.insert({ .pool_id = pg.pool_id, .pg_num = pg.pg_num });
pg.history_changed = true;
report_pg_states();
resume_10:
if (pg.epoch > pg.reported_epoch)
{
op_data->st = 10;
return;
}
}
submit_primary_subops(SUBMIT_WRITE, op_data->target_ver, pg.pg_size, pg.cur_set.data(), cur_op);
submit_primary_subops(SUBMIT_WRITE, pg.pg_size, pg.cur_set.data(), cur_op);
resume_4:
op_data->st = 4;
return;
@ -328,7 +252,7 @@ resume_5:
recovery_stat_count[0][recovery_type]++;
recovery_stat_bytes[0][recovery_type] = 0;
}
for (int role = 0; role < (op_data->scheme == POOL_SCHEME_REPLICATED ? 1 : pg.pg_size); role++)
for (int role = 0; role < pg.pg_size; role++)
{
recovery_stat_bytes[0][recovery_type] += op_data->stripes[role].write_end - op_data->stripes[role].write_start;
}
@ -336,7 +260,7 @@ resume_5:
if (op_data->object_state->state & OBJ_MISPLACED)
{
// Remove extra chunks
submit_primary_del_subops(cur_op, pg.cur_set.data(), pg.pg_size, op_data->object_state->osd_set);
submit_primary_del_subops(cur_op, pg.cur_set.data(), op_data->object_state->osd_set);
if (op_data->n_subops > 0)
{
resume_8:
@ -393,76 +317,60 @@ bool osd_t::remember_unstable_write(osd_op_t *cur_op, pg_t & pg, pg_osd_set_t &
}
if (immediate_commit == IMMEDIATE_ALL)
{
if (op_data->scheme != POOL_SCHEME_REPLICATED)
op_data->unstable_write_osds = new std::vector<unstable_osd_num_t>();
op_data->unstable_writes = new obj_ver_id[loc_set.size()];
{
// Send STABILIZE ops immediately
op_data->unstable_write_osds = new std::vector<unstable_osd_num_t>();
op_data->unstable_writes = new obj_ver_id[loc_set.size()];
{
int last_start = 0;
for (auto & chunk: loc_set)
{
op_data->unstable_writes[last_start] = (obj_ver_id){
.oid = {
.inode = op_data->oid.inode,
.stripe = op_data->oid.stripe | chunk.role,
},
.version = op_data->fact_ver,
};
op_data->unstable_write_osds->push_back((unstable_osd_num_t){
.osd_num = chunk.osd_num,
.start = last_start,
.len = 1,
});
last_start++;
}
}
submit_primary_stab_subops(cur_op);
resume_6:
op_data->st = 6;
return false;
resume_7:
// FIXME: Free those in the destructor?
delete op_data->unstable_write_osds;
delete[] op_data->unstable_writes;
op_data->unstable_writes = NULL;
op_data->unstable_write_osds = NULL;
if (op_data->errors > 0)
{
pg_cancel_write_queue(pg, cur_op, op_data->oid, op_data->epipe > 0 ? -EPIPE : -EIO);
return false;
}
}
}
else
{
if (op_data->scheme != POOL_SCHEME_REPLICATED)
{
// Remember version as unstable for EC/XOR
int last_start = 0;
for (auto & chunk: loc_set)
{
this->dirty_osds.insert(chunk.osd_num);
this->unstable_writes[(osd_object_id_t){
.osd_num = chunk.osd_num,
op_data->unstable_writes[last_start] = (obj_ver_id){
.oid = {
.inode = op_data->oid.inode,
.stripe = op_data->oid.stripe | chunk.role,
},
}] = op_data->fact_ver;
.version = op_data->fact_ver,
};
op_data->unstable_write_osds->push_back((unstable_osd_num_t){
.osd_num = chunk.osd_num,
.start = last_start,
.len = 1,
});
last_start++;
}
}
else
submit_primary_stab_subops(cur_op);
resume_6:
op_data->st = 6;
return false;
resume_7:
// FIXME: Free those in the destructor?
delete op_data->unstable_write_osds;
delete[] op_data->unstable_writes;
op_data->unstable_writes = NULL;
op_data->unstable_write_osds = NULL;
if (op_data->errors > 0)
{
// Only remember to sync OSDs for replicated pools
for (auto & chunk: loc_set)
{
this->dirty_osds.insert(chunk.osd_num);
}
pg_cancel_write_queue(pg, cur_op, op_data->oid, op_data->epipe > 0 ? -EPIPE : -EIO);
return false;
}
}
else
{
// Remember version as unstable
for (auto & chunk: loc_set)
{
this->unstable_writes[(osd_object_id_t){
.osd_num = chunk.osd_num,
.oid = {
.inode = op_data->oid.inode,
.stripe = op_data->oid.stripe | chunk.role,
},
}] = op_data->fact_ver;
}
// Remember PG as dirty to drop the connection when PG goes offline
// (this is required because of the "lazy sync")
c_cli.clients[cur_op->peer_fd].dirty_pgs.insert({ .pool_id = pg.pool_id, .pg_num = pg.pg_num });
dirty_pgs.insert({ .pool_id = pg.pool_id, .pg_num = pg.pg_num });
c_cli.clients[cur_op->peer_fd].dirty_pgs.insert(op_data->pg_num);
dirty_pgs.insert(op_data->pg_num);
}
return true;
}
@ -472,7 +380,7 @@ void osd_t::continue_primary_sync(osd_op_t *cur_op)
{
if (!cur_op->op_data)
{
cur_op->op_data = (osd_primary_op_data_t*)calloc_or_die(1, sizeof(osd_primary_op_data_t));
cur_op->op_data = (osd_primary_op_data_t*)calloc(sizeof(osd_primary_op_data_t), 1);
}
osd_primary_op_data_t *op_data = cur_op->op_data;
if (op_data->st == 1) goto resume_1;
@ -482,6 +390,7 @@ void osd_t::continue_primary_sync(osd_op_t *cur_op)
else if (op_data->st == 5) goto resume_5;
else if (op_data->st == 6) goto resume_6;
assert(op_data->st == 0);
printf("primary_sync\n");
if (syncs_in_progress.size() > 0)
{
// Wait for previous syncs, if any
@ -496,7 +405,7 @@ resume_1:
syncs_in_progress.push_back(cur_op);
}
resume_2:
if (dirty_osds.size() == 0)
if (unstable_writes.size() == 0)
{
// Nothing to sync
goto finish;
@ -504,10 +413,11 @@ resume_2:
// Save and clear unstable_writes
// In theory it is possible to do in on a per-client basis, but this seems to be an unnecessary complication
// It would be cool not to copy these here at all, but someone has to deduplicate them by object IDs anyway
if (unstable_writes.size() > 0)
{
op_data->unstable_write_osds = new std::vector<unstable_osd_num_t>();
op_data->unstable_writes = new obj_ver_id[this->unstable_writes.size()];
op_data->dirty_pgs = new pg_num_t[dirty_pgs.size()];
op_data->dirty_pg_count = dirty_pgs.size();
osd_num_t last_osd = 0;
int last_start = 0, last_end = 0;
for (auto it = this->unstable_writes.begin(); it != this->unstable_writes.end(); it++)
@ -539,14 +449,6 @@ resume_2:
.len = last_end - last_start,
});
}
this->unstable_writes.clear();
}
{
void *dirty_buf = malloc_or_die(sizeof(pool_pg_num_t)*dirty_pgs.size() + sizeof(osd_num_t)*dirty_osds.size());
op_data->dirty_pgs = (pool_pg_num_t*)dirty_buf;
op_data->dirty_osds = (osd_num_t*)(dirty_buf + sizeof(pool_pg_num_t)*dirty_pgs.size());
op_data->dirty_pg_count = dirty_pgs.size();
op_data->dirty_osd_count = dirty_osds.size();
int dpg = 0;
for (auto dirty_pg_num: dirty_pgs)
{
@ -554,12 +456,7 @@ resume_2:
op_data->dirty_pgs[dpg++] = dirty_pg_num;
}
dirty_pgs.clear();
dpg = 0;
for (auto osd_num: dirty_osds)
{
op_data->dirty_osds[dpg++] = osd_num;
}
dirty_osds.clear();
this->unstable_writes.clear();
}
if (immediate_commit != IMMEDIATE_ALL)
{
@ -574,48 +471,30 @@ resume_4:
goto resume_6;
}
}
if (op_data->unstable_writes)
{
// Stabilize version sets, if any
submit_primary_stab_subops(cur_op);
// Stabilize version sets
submit_primary_stab_subops(cur_op);
resume_5:
op_data->st = 5;
return;
}
op_data->st = 5;
return;
resume_6:
if (op_data->errors > 0)
{
// Return PGs and OSDs back into their dirty sets
for (int i = 0; i < op_data->dirty_pg_count; i++)
// Return objects back into the unstable write set
for (auto unstable_osd: *(op_data->unstable_write_osds))
{
dirty_pgs.insert(op_data->dirty_pgs[i]);
}
for (int i = 0; i < op_data->dirty_osd_count; i++)
{
dirty_osds.insert(op_data->dirty_osds[i]);
}
if (op_data->unstable_writes)
{
// Return objects back into the unstable write set
for (auto unstable_osd: *(op_data->unstable_write_osds))
for (int i = 0; i < unstable_osd.len; i++)
{
for (int i = 0; i < unstable_osd.len; i++)
// Except those from peered PGs
auto & w = op_data->unstable_writes[i];
pg_num_t wpg = map_to_pg(w.oid);
if (pgs[wpg].state & PG_ACTIVE)
{
// Except those from peered PGs
auto & w = op_data->unstable_writes[i];
pool_pg_num_t wpg = {
.pool_id = INODE_POOL(w.oid.inode),
.pg_num = map_to_pg(w.oid, st_cli.pool_config.at(INODE_POOL(w.oid.inode)).pg_stripe_size),
};
if (pgs[wpg].state & PG_ACTIVE)
{
uint64_t & dest = this->unstable_writes[(osd_object_id_t){
.osd_num = unstable_osd.osd_num,
.oid = w.oid,
}];
dest = dest < w.version ? w.version : dest;
dirty_pgs.insert(wpg);
}
uint64_t & dest = this->unstable_writes[(osd_object_id_t){
.osd_num = unstable_osd.osd_num,
.oid = w.oid,
}];
dest = dest < w.version ? w.version : dest;
dirty_pgs.insert(wpg);
}
}
}
@ -630,16 +509,11 @@ resume_6:
}
}
// FIXME: Free those in the destructor?
free(op_data->dirty_pgs);
op_data->dirty_pgs = NULL;
op_data->dirty_osds = NULL;
if (op_data->unstable_writes)
{
delete op_data->unstable_write_osds;
delete[] op_data->unstable_writes;
op_data->unstable_writes = NULL;
op_data->unstable_write_osds = NULL;
}
delete op_data->dirty_pgs;
delete op_data->unstable_write_osds;
delete[] op_data->unstable_writes;
op_data->unstable_writes = NULL;
op_data->unstable_write_osds = NULL;
if (op_data->errors > 0)
{
finish_op(cur_op, op_data->epipe > 0 ? -EPIPE : -EIO);
@ -718,7 +592,7 @@ void osd_t::continue_primary_del(osd_op_t *cur_op)
return;
}
osd_primary_op_data_t *op_data = cur_op->op_data;
auto & pg = pgs[{ .pool_id = INODE_POOL(op_data->oid.inode), .pg_num = op_data->pg_num }];
auto & pg = pgs[op_data->pg_num];
if (op_data->st == 1) goto resume_1;
else if (op_data->st == 2) goto resume_2;
else if (op_data->st == 3) goto resume_3;
@ -739,7 +613,7 @@ resume_1:
// Determine which OSDs contain this object and delete it
op_data->prev_set = get_object_osd_set(pg, op_data->oid, pg.cur_set.data(), &op_data->object_state);
// Submit 1 read to determine the actual version number
submit_primary_subops(SUBMIT_RMW_READ, UINT64_MAX, pg.pg_size, op_data->prev_set, cur_op);
submit_primary_subops(SUBMIT_RMW_READ, pg.pg_size, op_data->prev_set, cur_op);
resume_2:
op_data->st = 2;
return;
@ -753,7 +627,7 @@ resume_3:
pg.ver_override[op_data->oid] = op_data->fact_ver;
// Submit deletes
op_data->fact_ver++;
submit_primary_del_subops(cur_op, NULL, 0, op_data->object_state ? op_data->object_state->osd_set : pg.cur_loc_set);
submit_primary_del_subops(cur_op, NULL, op_data->object_state ? op_data->object_state->osd_set : pg.cur_loc_set);
resume_4:
op_data->st = 4;
return;

8
osd_primary.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#include "osd.h"
@ -23,7 +20,6 @@ struct osd_primary_op_data_t
object_id oid;
uint64_t target_ver;
uint64_t fact_ver = 0;
uint64_t scheme = 0;
int n_subops = 0, done = 0, errors = 0, epipe = 0;
int degraded = 0, pg_size, pg_minsize;
osd_rmw_stripe_t *stripes;
@ -33,9 +29,7 @@ struct osd_primary_op_data_t
// for sync. oops, requires freeing
std::vector<unstable_osd_num_t> *unstable_write_osds = NULL;
pool_pg_num_t *dirty_pgs = NULL;
pg_num_t *dirty_pgs = NULL;
int dirty_pg_count = 0;
osd_num_t *dirty_osds = NULL;
int dirty_osd_count = 0;
obj_ver_id *unstable_writes = NULL;
};

134
osd_primary_subops.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "osd_primary.h"
void osd_t::autosync()
@ -40,7 +37,7 @@ void osd_t::finish_op(osd_op_t *cur_op, int retval)
{
if (cur_op->op_data->pg_num > 0)
{
auto & pg = pgs[{ .pool_id = INODE_POOL(cur_op->op_data->oid.inode), .pg_num = cur_op->op_data->pg_num }];
auto & pg = pgs[cur_op->op_data->pg_num];
pg.inflight--;
assert(pg.inflight >= 0);
if ((pg.state & PG_STOPPING) && pg.inflight == 0 && !pg.flush_batch)
@ -79,12 +76,11 @@ void osd_t::finish_op(osd_op_t *cur_op, int retval)
}
}
void osd_t::submit_primary_subops(int submit_type, uint64_t op_version, int pg_size, const uint64_t* osd_set, osd_op_t *cur_op)
void osd_t::submit_primary_subops(int submit_type, int pg_size, const uint64_t* osd_set, osd_op_t *cur_op)
{
bool wr = submit_type == SUBMIT_WRITE;
bool w = submit_type == SUBMIT_WRITE;
osd_primary_op_data_t *op_data = cur_op->op_data;
osd_rmw_stripe_t *stripes = op_data->stripes;
bool rep = op_data->scheme == POOL_SCHEME_REPLICATED;
// Allocate subops
int n_subops = 0, zero_read = -1;
for (int role = 0; role < pg_size; role++)
@ -93,12 +89,12 @@ void osd_t::submit_primary_subops(int submit_type, uint64_t op_version, int pg_s
{
zero_read = role;
}
if (osd_set[role] != 0 && (wr || !rep && stripes[role].read_end != 0))
if (osd_set[role] != 0 && (w || stripes[role].read_end != 0))
{
n_subops++;
}
}
if (!n_subops && (submit_type == SUBMIT_RMW_READ || rep))
if (!n_subops && submit_type == SUBMIT_RMW_READ)
{
n_subops = 1;
}
@ -106,6 +102,7 @@ void osd_t::submit_primary_subops(int submit_type, uint64_t op_version, int pg_s
{
zero_read = -1;
}
uint64_t op_version = w ? op_data->fact_ver+1 : (submit_type == SUBMIT_RMW_READ ? UINT64_MAX : op_data->target_ver);
osd_op_t *subops = new osd_op_t[n_subops];
op_data->fact_ver = 0;
op_data->done = op_data->errors = 0;
@ -115,37 +112,36 @@ void osd_t::submit_primary_subops(int submit_type, uint64_t op_version, int pg_s
for (int role = 0; role < pg_size; role++)
{
// We always submit zero-length writes to all replicas, even if the stripe is not modified
if (!(wr || !rep && stripes[role].read_end != 0 || zero_read == role))
if (!(w || stripes[role].read_end != 0 || zero_read == role))
{
continue;
}
osd_num_t role_osd_num = osd_set[role];
if (role_osd_num != 0)
{
int stripe_num = rep ? 0 : role;
if (role_osd_num == this->osd_num)
{
clock_gettime(CLOCK_REALTIME, &subops[i].tv_begin);
subops[i].op_type = (uint64_t)cur_op;
subops[i].bs_op = new blockstore_op_t({
.opcode = (uint64_t)(wr ? (rep ? BS_OP_WRITE_STABLE : BS_OP_WRITE) : BS_OP_READ),
.opcode = (uint64_t)(w ? BS_OP_WRITE : BS_OP_READ),
.callback = [subop = &subops[i], this](blockstore_op_t *bs_subop)
{
handle_primary_bs_subop(subop);
},
.oid = {
.inode = op_data->oid.inode,
.stripe = op_data->oid.stripe | stripe_num,
.stripe = op_data->oid.stripe | role,
},
.version = op_version,
.offset = wr ? stripes[stripe_num].write_start : stripes[stripe_num].read_start,
.len = wr ? stripes[stripe_num].write_end - stripes[stripe_num].write_start : stripes[stripe_num].read_end - stripes[stripe_num].read_start,
.buf = wr ? stripes[stripe_num].write_buf : stripes[stripe_num].read_buf,
.offset = w ? stripes[role].write_start : stripes[role].read_start,
.len = w ? stripes[role].write_end - stripes[role].write_start : stripes[role].read_end - stripes[role].read_start,
.buf = w ? stripes[role].write_buf : stripes[role].read_buf,
});
#ifdef OSD_DEBUG
printf(
"Submit %s to local: %lx:%lx v%lu %u-%u\n", wr ? "write" : "read",
op_data->oid.inode, op_data->oid.stripe | stripe_num, op_version,
"Submit %s to local: %lu:%lu v%lu %u-%u\n", w ? "write" : "read",
op_data->oid.inode, op_data->oid.stripe | role, op_version,
subops[i].bs_op->offset, subops[i].bs_op->len
);
#endif
@ -154,46 +150,40 @@ void osd_t::submit_primary_subops(int submit_type, uint64_t op_version, int pg_s
else
{
subops[i].op_type = OSD_OP_OUT;
subops[i].send_list.push_back(subops[i].req.buf, OSD_PACKET_SIZE);
subops[i].peer_fd = c_cli.osd_peer_fds.at(role_osd_num);
subops[i].req.sec_rw = {
.header = {
.magic = SECONDARY_OSD_OP_MAGIC,
.id = c_cli.next_subop_id++,
.opcode = (uint64_t)(wr ? (rep ? OSD_OP_SEC_WRITE_STABLE : OSD_OP_SEC_WRITE) : OSD_OP_SEC_READ),
.opcode = (uint64_t)(w ? OSD_OP_SECONDARY_WRITE : OSD_OP_SECONDARY_READ),
},
.oid = {
.inode = op_data->oid.inode,
.stripe = op_data->oid.stripe | stripe_num,
.stripe = op_data->oid.stripe | role,
},
.version = op_version,
.offset = wr ? stripes[stripe_num].write_start : stripes[stripe_num].read_start,
.len = wr ? stripes[stripe_num].write_end - stripes[stripe_num].write_start : stripes[stripe_num].read_end - stripes[stripe_num].read_start,
.offset = w ? stripes[role].write_start : stripes[role].read_start,
.len = w ? stripes[role].write_end - stripes[role].write_start : stripes[role].read_end - stripes[role].read_start,
};
#ifdef OSD_DEBUG
printf(
"Submit %s to osd %lu: %lx:%lx v%lu %u-%u\n", wr ? "write" : "read", role_osd_num,
op_data->oid.inode, op_data->oid.stripe | stripe_num, op_version,
"Submit %s to osd %lu: %lu:%lu v%lu %u-%u\n", w ? "write" : "read", role_osd_num,
op_data->oid.inode, op_data->oid.stripe | role, op_version,
subops[i].req.sec_rw.offset, subops[i].req.sec_rw.len
);
#endif
if (wr)
subops[i].buf = w ? stripes[role].write_buf : stripes[role].read_buf;
if (w && stripes[role].write_end > 0)
{
if (stripes[stripe_num].write_end > stripes[stripe_num].write_start)
{
subops[i].iov.push_back(stripes[stripe_num].write_buf, stripes[stripe_num].write_end - stripes[stripe_num].write_start);
}
}
else
{
if (stripes[stripe_num].read_end > stripes[stripe_num].read_start)
{
subops[i].iov.push_back(stripes[stripe_num].read_buf, stripes[stripe_num].read_end - stripes[stripe_num].read_start);
}
subops[i].send_list.push_back(stripes[role].write_buf, stripes[role].write_end - stripes[role].write_start);
}
subops[i].callback = [cur_op, this](osd_op_t *subop)
{
int fail_fd = subop->req.hdr.opcode == OSD_OP_SEC_WRITE &&
int fail_fd = subop->req.hdr.opcode == OSD_OP_SECONDARY_WRITE &&
subop->reply.hdr.retval != subop->req.sec_rw.len ? subop->peer_fd : -1;
// so it doesn't get freed
subop->buf = NULL;
handle_primary_subop(subop, cur_op);
if (fail_fd >= 0)
{
@ -210,23 +200,21 @@ void osd_t::submit_primary_subops(int submit_type, uint64_t op_version, int pg_s
static uint64_t bs_op_to_osd_op[] = {
0,
OSD_OP_SEC_READ, // BS_OP_READ = 1
OSD_OP_SEC_WRITE, // BS_OP_WRITE = 2
OSD_OP_SEC_WRITE_STABLE, // BS_OP_WRITE_STABLE = 3
OSD_OP_SEC_SYNC, // BS_OP_SYNC = 4
OSD_OP_SEC_STABILIZE, // BS_OP_STABLE = 5
OSD_OP_SEC_DELETE, // BS_OP_DELETE = 6
OSD_OP_SEC_LIST, // BS_OP_LIST = 7
OSD_OP_SEC_ROLLBACK, // BS_OP_ROLLBACK = 8
OSD_OP_TEST_SYNC_STAB_ALL, // BS_OP_SYNC_STAB_ALL = 9
OSD_OP_SECONDARY_READ, // BS_OP_READ
OSD_OP_SECONDARY_WRITE, // BS_OP_WRITE
OSD_OP_SECONDARY_SYNC, // BS_OP_SYNC
OSD_OP_SECONDARY_STABILIZE, // BS_OP_STABLE
OSD_OP_SECONDARY_DELETE, // BS_OP_DELETE
OSD_OP_SECONDARY_LIST, // BS_OP_LIST
OSD_OP_SECONDARY_ROLLBACK, // BS_OP_ROLLBACK
OSD_OP_TEST_SYNC_STAB_ALL, // BS_OP_SYNC_STAB_ALL
};
void osd_t::handle_primary_bs_subop(osd_op_t *subop)
{
osd_op_t *cur_op = (osd_op_t*)subop->op_type;
blockstore_op_t *bs_op = subop->bs_op;
int expected = bs_op->opcode == BS_OP_READ || bs_op->opcode == BS_OP_WRITE
|| bs_op->opcode == BS_OP_WRITE_STABLE ? bs_op->len : 0;
int expected = bs_op->opcode == BS_OP_READ || bs_op->opcode == BS_OP_WRITE ? bs_op->len : 0;
if (bs_op->retval != expected && bs_op->opcode != BS_OP_READ)
{
// die
@ -238,7 +226,7 @@ void osd_t::handle_primary_bs_subop(osd_op_t *subop)
add_bs_subop_stats(subop);
subop->req.hdr.opcode = bs_op_to_osd_op[bs_op->opcode];
subop->reply.hdr.retval = bs_op->retval;
if (bs_op->opcode == BS_OP_READ || bs_op->opcode == BS_OP_WRITE || bs_op->opcode == BS_OP_WRITE_STABLE)
if (bs_op->opcode == BS_OP_READ || bs_op->opcode == BS_OP_WRITE)
{
subop->req.sec_rw.len = bs_op->len;
subop->reply.sec_rw.version = bs_op->version;
@ -265,7 +253,7 @@ void osd_t::add_bs_subop_stats(osd_op_t *subop)
(tv_end.tv_sec - subop->tv_begin.tv_sec)*1000000 +
(tv_end.tv_nsec - subop->tv_begin.tv_nsec)/1000
);
if (opcode == OSD_OP_SEC_READ || opcode == OSD_OP_SEC_WRITE)
if (opcode == OSD_OP_SECONDARY_READ || opcode == OSD_OP_SECONDARY_WRITE)
{
c_cli.stats.op_stat_bytes[opcode] += subop->bs_op->len;
}
@ -275,8 +263,8 @@ void osd_t::handle_primary_subop(osd_op_t *subop, osd_op_t *cur_op)
{
uint64_t opcode = subop->req.hdr.opcode;
int retval = subop->reply.hdr.retval;
int expected = opcode == OSD_OP_SEC_READ || opcode == OSD_OP_SEC_WRITE
|| opcode == OSD_OP_SEC_WRITE_STABLE ? subop->req.sec_rw.len : 0;
int expected = opcode == OSD_OP_SECONDARY_READ || opcode == OSD_OP_SECONDARY_WRITE
? subop->req.sec_rw.len : 0;
osd_primary_op_data_t *op_data = cur_op->op_data;
if (retval != expected)
{
@ -290,7 +278,7 @@ void osd_t::handle_primary_subop(osd_op_t *subop, osd_op_t *cur_op)
else
{
op_data->done++;
if (opcode == OSD_OP_SEC_READ || opcode == OSD_OP_SEC_WRITE || opcode == OSD_OP_SEC_WRITE_STABLE)
if (opcode == OSD_OP_SECONDARY_READ || opcode == OSD_OP_SECONDARY_WRITE)
{
uint64_t version = subop->reply.sec_rw.version;
#ifdef OSD_DEBUG
@ -353,27 +341,13 @@ void osd_t::cancel_primary_write(osd_op_t *cur_op)
}
}
static bool contains_osd(osd_num_t *osd_set, uint64_t size, osd_num_t osd_num)
{
for (uint64_t i = 0; i < size; i++)
{
if (osd_set[i] == osd_num)
{
return true;
}
}
return false;
}
void osd_t::submit_primary_del_subops(osd_op_t *cur_op, osd_num_t *cur_set, uint64_t set_size, pg_osd_set_t & loc_set)
void osd_t::submit_primary_del_subops(osd_op_t *cur_op, uint64_t *cur_set, pg_osd_set_t & loc_set)
{
osd_primary_op_data_t *op_data = cur_op->op_data;
bool rep = op_data->scheme == POOL_SCHEME_REPLICATED;
int extra_chunks = 0;
// ordered comparison for EC/XOR, unordered for replicated pools
for (auto & chunk: loc_set)
{
if (!cur_set || (rep ? !contains_osd(cur_set, set_size, chunk.osd_num) : chunk.osd_num != cur_set[chunk.role]))
if (!cur_set || chunk.osd_num != cur_set[chunk.role])
{
extra_chunks++;
}
@ -389,9 +363,8 @@ void osd_t::submit_primary_del_subops(osd_op_t *cur_op, osd_num_t *cur_set, uint
int i = 0;
for (auto & chunk: loc_set)
{
if (!cur_set || (rep ? !contains_osd(cur_set, set_size, chunk.osd_num) : chunk.osd_num != cur_set[chunk.role]))
if (!cur_set || chunk.osd_num != cur_set[chunk.role])
{
int stripe_num = op_data->scheme == POOL_SCHEME_REPLICATED ? 0 : chunk.role;
if (chunk.osd_num == this->osd_num)
{
clock_gettime(CLOCK_REALTIME, &subops[i].tv_begin);
@ -404,7 +377,7 @@ void osd_t::submit_primary_del_subops(osd_op_t *cur_op, osd_num_t *cur_set, uint
},
.oid = {
.inode = op_data->oid.inode,
.stripe = op_data->oid.stripe | stripe_num,
.stripe = op_data->oid.stripe | chunk.role,
},
// Same version as write
.version = op_data->fact_ver,
@ -414,16 +387,17 @@ void osd_t::submit_primary_del_subops(osd_op_t *cur_op, osd_num_t *cur_set, uint
else
{
subops[i].op_type = OSD_OP_OUT;
subops[i].send_list.push_back(subops[i].req.buf, OSD_PACKET_SIZE);
subops[i].peer_fd = c_cli.osd_peer_fds.at(chunk.osd_num);
subops[i].req.sec_del = {
.header = {
.magic = SECONDARY_OSD_OP_MAGIC,
.id = c_cli.next_subop_id++,
.opcode = OSD_OP_SEC_DELETE,
.opcode = OSD_OP_SECONDARY_DELETE,
},
.oid = {
.inode = op_data->oid.inode,
.stripe = op_data->oid.stripe | stripe_num,
.stripe = op_data->oid.stripe | chunk.role,
},
// Same version as write
.version = op_data->fact_ver,
@ -448,14 +422,14 @@ void osd_t::submit_primary_del_subops(osd_op_t *cur_op, osd_num_t *cur_set, uint
void osd_t::submit_primary_sync_subops(osd_op_t *cur_op)
{
osd_primary_op_data_t *op_data = cur_op->op_data;
int n_osds = op_data->dirty_osd_count;
int n_osds = op_data->unstable_write_osds->size();
osd_op_t *subops = new osd_op_t[n_osds];
op_data->done = op_data->errors = 0;
op_data->n_subops = n_osds;
op_data->subops = subops;
for (int i = 0; i < n_osds; i++)
{
osd_num_t sync_osd = op_data->dirty_osds[i];
osd_num_t sync_osd = (*(op_data->unstable_write_osds))[i].osd_num;
if (sync_osd == this->osd_num)
{
clock_gettime(CLOCK_REALTIME, &subops[i].tv_begin);
@ -472,12 +446,13 @@ void osd_t::submit_primary_sync_subops(osd_op_t *cur_op)
else
{
subops[i].op_type = OSD_OP_OUT;
subops[i].send_list.push_back(subops[i].req.buf, OSD_PACKET_SIZE);
subops[i].peer_fd = c_cli.osd_peer_fds.at(sync_osd);
subops[i].req.sec_sync = {
.header = {
.magic = SECONDARY_OSD_OP_MAGIC,
.id = c_cli.next_subop_id++,
.opcode = OSD_OP_SEC_SYNC,
.opcode = OSD_OP_SECONDARY_SYNC,
},
};
subops[i].callback = [cur_op, this](osd_op_t *subop)
@ -524,16 +499,17 @@ void osd_t::submit_primary_stab_subops(osd_op_t *cur_op)
else
{
subops[i].op_type = OSD_OP_OUT;
subops[i].send_list.push_back(subops[i].req.buf, OSD_PACKET_SIZE);
subops[i].peer_fd = c_cli.osd_peer_fds.at(stab_osd.osd_num);
subops[i].req.sec_stab = {
.header = {
.magic = SECONDARY_OSD_OP_MAGIC,
.id = c_cli.next_subop_id++,
.opcode = OSD_OP_SEC_STABILIZE,
.opcode = OSD_OP_SECONDARY_STABILIZE,
},
.len = (uint64_t)(stab_osd.len * sizeof(obj_ver_id)),
};
subops[i].iov.push_back(op_data->unstable_writes + stab_osd.start, stab_osd.len * sizeof(obj_ver_id));
subops[i].send_list.push_back(op_data->unstable_writes + stab_osd.start, stab_osd.len * sizeof(obj_ver_id));
subops[i].callback = [cur_op, this](osd_op_t *subop)
{
int fail_fd = subop->reply.hdr.retval != 0 ? subop->peer_fd : -1;

28
osd_rmw.cpp
View File

@ -1,11 +1,8 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <malloc.h>
#include <string.h>
#include <assert.h>
#include "xor.h"
#include "osd_rmw.h"
#include "malloc_or_die.h"
static inline void extend_read(uint32_t start, uint32_t end, osd_rmw_stripe_t & stripe)
{
@ -75,7 +72,7 @@ void split_stripes(uint64_t pg_minsize, uint32_t bs_block_size, uint32_t start,
}
}
void reconstruct_stripe_xor(osd_rmw_stripe_t *stripes, int pg_size, int role)
void reconstruct_stripe(osd_rmw_stripe_t *stripes, int pg_size, int role)
{
int prev = -2;
for (int other = 0; other < pg_size; other++)
@ -155,7 +152,7 @@ void* alloc_read_buffer(osd_rmw_stripe_t *stripes, int read_pg_size, uint64_t ad
}
}
// Allocate buffer
void *buf = memalign_or_die(MEM_ALIGNMENT, buf_size);
void *buf = memalign(MEM_ALIGNMENT, buf_size);
uint64_t buf_pos = add_size;
for (int role = 0; role < read_pg_size; role++)
{
@ -210,8 +207,9 @@ void* calc_rmw(void *request_buf, osd_rmw_stripe_t *stripes, uint64_t *read_osd_
// Object is degraded/misplaced and will be moved to <write_osd_set>
for (int role = 0; role < pg_size; role++)
{
if (write_osd_set[role] != read_osd_set[role] && write_osd_set[role] != 0)
if (write_osd_set[role] != read_osd_set[role])
{
// FIXME: For EC more than 2+1: handle case when write_osd_set == 0 and read_osd_set != 0
// We need to get data for any moved / recovered chunk
// And we need a continuous write buffer so we'll only optimize
// for the case when the whole chunk is ovewritten in the request
@ -359,22 +357,21 @@ static void xor_multiple_buffers(buf_len_t *xor1, int n1, buf_len_t *xor2, int n
}
}
void calc_rmw_parity_xor(osd_rmw_stripe_t *stripes, int pg_size, uint64_t *read_osd_set, uint64_t *write_osd_set, uint32_t chunk_size)
void calc_rmw_parity(osd_rmw_stripe_t *stripes, int pg_size, uint64_t *read_osd_set, uint64_t *write_osd_set, uint32_t chunk_size)
{
int pg_minsize = pg_size-1;
for (int role = 0; role < pg_size; role++)
{
if (stripes[role].read_end != 0 && stripes[role].missing)
{
// Reconstruct missing stripe (XOR k+1)
reconstruct_stripe_xor(stripes, pg_size, role);
// Reconstruct missing stripe (EC k+1)
reconstruct_stripe(stripes, pg_size, role);
break;
}
}
uint32_t start = 0, end = 0;
if (write_osd_set[pg_minsize] != 0 || write_osd_set != read_osd_set)
if (!stripes[pg_minsize].missing || write_osd_set != read_osd_set)
{
// Required for the next two if()s
for (int role = 0; role < pg_minsize; role++)
{
if (stripes[role].req_end != 0)
@ -388,9 +385,10 @@ void calc_rmw_parity_xor(osd_rmw_stripe_t *stripes, int pg_size, uint64_t *read_
{
for (int role = 0; role < pg_minsize; role++)
{
if (write_osd_set[role] != read_osd_set[role] && write_osd_set[role] != 0 &&
if (write_osd_set[role] != read_osd_set[role] &&
(stripes[role].req_start != 0 || stripes[role].req_end != chunk_size))
{
// FIXME again, handle case when write_osd_set[role] is 0
// Copy modified chunk into the read buffer to write it back
memcpy(
stripes[role].read_buf + stripes[role].req_start,
@ -403,9 +401,9 @@ void calc_rmw_parity_xor(osd_rmw_stripe_t *stripes, int pg_size, uint64_t *read_
}
}
}
if (write_osd_set[pg_minsize] != 0 && end != 0)
if (!stripes[pg_minsize].missing && end != 0)
{
// Calculate new parity (XOR k+1)
// Calculate new parity (EC k+1)
int parity = pg_minsize, prev = -2;
for (int other = 0; other < pg_minsize; other++)
{

7
osd_rmw.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#include <stdint.h>
@ -28,7 +25,7 @@ struct osd_rmw_stripe_t
void split_stripes(uint64_t pg_minsize, uint32_t bs_block_size, uint32_t start, uint32_t len, osd_rmw_stripe_t *stripes);
void reconstruct_stripe_xor(osd_rmw_stripe_t *stripes, int pg_size, int role);
void reconstruct_stripe(osd_rmw_stripe_t *stripes, int pg_size, int role);
int extend_missing_stripes(osd_rmw_stripe_t *stripes, osd_num_t *osd_set, int minsize, int size);
@ -37,4 +34,4 @@ void* alloc_read_buffer(osd_rmw_stripe_t *stripes, int read_pg_size, uint64_t ad
void* calc_rmw(void *request_buf, osd_rmw_stripe_t *stripes, uint64_t *read_osd_set,
uint64_t pg_size, uint64_t pg_minsize, uint64_t pg_cursize, uint64_t *write_osd_set, uint64_t chunk_size);
void calc_rmw_parity_xor(osd_rmw_stripe_t *stripes, int pg_size, uint64_t *read_osd_set, uint64_t *write_osd_set, uint32_t chunk_size);
void calc_rmw_parity(osd_rmw_stripe_t *stripes, int pg_size, uint64_t *read_osd_set, uint64_t *write_osd_set, uint32_t chunk_size);

17
osd_rmw_test.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <string.h>
#include "osd_rmw.cpp"
#include "test_pattern.h"
@ -61,7 +58,7 @@ Cases:
input buffer: [ write0, write1 ],
rmw buffer: [ write2, read0, read1, read2 ],
}
then, after calc_rmw_parity_xor(): {
then, after calc_rmw_parity(): {
write: [ [ 128K-4K, 128K ], [ 0, 128K ], [ 0, 128K ] ],
write1==read1,
}
@ -85,7 +82,7 @@ Cases:
input buffer: NULL,
rmw buffer: [ read0, read1, read2 ],
}
then, after calc_rmw_parity_xor(): {
then, after calc_rmw_parity(): {
write: [ [ 0, 128K ], [ 0, 0 ], [ 0, 0 ] ],
write0==read0,
}
@ -185,7 +182,7 @@ void test4()
set_pattern(stripes[0].read_buf, 128*1024, PATTERN1); // old data
set_pattern(stripes[1].read_buf, 128*1024-4096, UINT64_MAX); // didn't read it, it's missing
set_pattern(stripes[2].read_buf, 128*1024-4096, 0); // old parity = 0
calc_rmw_parity_xor(stripes, 3, osd_set, osd_set, 128*1024);
calc_rmw_parity(stripes, 3, osd_set, osd_set, 128*1024);
check_pattern(stripes[2].write_buf, 4096, PATTERN0^PATTERN1); // new parity
check_pattern(stripes[2].write_buf+4096, 128*1024-4096*2, 0); // new parity
check_pattern(stripes[2].write_buf+128*1024-4096, 4096, PATTERN0^PATTERN1); // new parity
@ -271,7 +268,7 @@ void test7()
set_pattern(stripes[0].read_buf, 128*1024, PATTERN1); // old data
set_pattern(stripes[1].read_buf, 128*1024, UINT64_MAX); // didn't read it, it's missing
set_pattern(stripes[2].read_buf, 128*1024, 0); // old parity = 0
calc_rmw_parity_xor(stripes, 3, osd_set, write_osd_set, 128*1024);
calc_rmw_parity(stripes, 3, osd_set, write_osd_set, 128*1024);
assert(stripes[0].write_start == 128*1024-4096 && stripes[0].write_end == 128*1024);
assert(stripes[1].write_start == 0 && stripes[1].write_end == 128*1024);
assert(stripes[2].write_start == 0 && stripes[2].write_end == 128*1024);
@ -309,7 +306,7 @@ void test8()
// Test 8.2
set_pattern(write_buf, 128*1024+4096, PATTERN0);
set_pattern(stripes[1].read_buf, 128*1024-4096, PATTERN1);
calc_rmw_parity_xor(stripes, 3, osd_set, write_osd_set, 128*1024);
calc_rmw_parity(stripes, 3, osd_set, write_osd_set, 128*1024);
assert(stripes[0].write_start == 0 && stripes[0].write_end == 128*1024); // recheck again
assert(stripes[1].write_start == 0 && stripes[1].write_end == 4096); // recheck again
assert(stripes[2].write_start == 0 && stripes[2].write_end == 128*1024); // recheck again
@ -347,10 +344,10 @@ void test9()
assert(stripes[0].write_buf == NULL);
assert(stripes[1].write_buf == NULL);
assert(stripes[2].write_buf == NULL);
// Test 9.2
// Test 8.2
set_pattern(stripes[1].read_buf, 128*1024, 0);
set_pattern(stripes[2].read_buf, 128*1024, PATTERN1);
calc_rmw_parity_xor(stripes, 3, osd_set, write_osd_set, 128*1024);
calc_rmw_parity(stripes, 3, osd_set, write_osd_set, 128*1024);
assert(stripes[0].write_start == 0 && stripes[0].write_end == 128*1024);
assert(stripes[1].write_start == 0 && stripes[1].write_end == 0);
assert(stripes[2].write_start == 0 && stripes[2].write_end == 0);

55
osd_secondary.cpp
View File

@ -1,34 +1,30 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include "osd.h"
#include "json11/json11.hpp"
void osd_t::secondary_op_callback(osd_op_t *op)
{
if (op->req.hdr.opcode == OSD_OP_SEC_READ ||
op->req.hdr.opcode == OSD_OP_SEC_WRITE ||
op->req.hdr.opcode == OSD_OP_SEC_WRITE_STABLE)
if (op->req.hdr.opcode == OSD_OP_SECONDARY_READ ||
op->req.hdr.opcode == OSD_OP_SECONDARY_WRITE)
{
op->reply.sec_rw.version = op->bs_op->version;
}
else if (op->req.hdr.opcode == OSD_OP_SEC_DELETE)
else if (op->req.hdr.opcode == OSD_OP_SECONDARY_DELETE)
{
op->reply.sec_del.version = op->bs_op->version;
}
if (op->req.hdr.opcode == OSD_OP_SEC_READ &&
if (op->req.hdr.opcode == OSD_OP_SECONDARY_READ &&
op->bs_op->retval > 0)
{
op->iov.push_back(op->buf, op->bs_op->retval);
op->send_list.push_back(op->buf, op->bs_op->retval);
}
else if (op->req.hdr.opcode == OSD_OP_SEC_LIST)
else if (op->req.hdr.opcode == OSD_OP_SECONDARY_LIST)
{
// allocated by blockstore
op->buf = op->bs_op->buf;
if (op->bs_op->retval > 0)
{
op->iov.push_back(op->buf, op->bs_op->retval * sizeof(obj_ver_id));
op->send_list.push_back(op->buf, op->bs_op->retval * sizeof(obj_ver_id));
}
op->reply.sec_list.stable_count = op->bs_op->version;
}
@ -42,18 +38,16 @@ void osd_t::exec_secondary(osd_op_t *cur_op)
{
cur_op->bs_op = new blockstore_op_t();
cur_op->bs_op->callback = [this, cur_op](blockstore_op_t* bs_op) { secondary_op_callback(cur_op); };
cur_op->bs_op->opcode = (cur_op->req.hdr.opcode == OSD_OP_SEC_READ ? BS_OP_READ
: (cur_op->req.hdr.opcode == OSD_OP_SEC_WRITE ? BS_OP_WRITE
: (cur_op->req.hdr.opcode == OSD_OP_SEC_WRITE_STABLE ? BS_OP_WRITE_STABLE
: (cur_op->req.hdr.opcode == OSD_OP_SEC_SYNC ? BS_OP_SYNC
: (cur_op->req.hdr.opcode == OSD_OP_SEC_STABILIZE ? BS_OP_STABLE
: (cur_op->req.hdr.opcode == OSD_OP_SEC_ROLLBACK ? BS_OP_ROLLBACK
: (cur_op->req.hdr.opcode == OSD_OP_SEC_DELETE ? BS_OP_DELETE
: (cur_op->req.hdr.opcode == OSD_OP_SEC_LIST ? BS_OP_LIST
: -1))))))));
if (cur_op->req.hdr.opcode == OSD_OP_SEC_READ ||
cur_op->req.hdr.opcode == OSD_OP_SEC_WRITE ||
cur_op->req.hdr.opcode == OSD_OP_SEC_WRITE_STABLE)
cur_op->bs_op->opcode = (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_READ ? BS_OP_READ
: (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_WRITE ? BS_OP_WRITE
: (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_SYNC ? BS_OP_SYNC
: (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_STABILIZE ? BS_OP_STABLE
: (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_ROLLBACK ? BS_OP_ROLLBACK
: (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_DELETE ? BS_OP_DELETE
: (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_LIST ? BS_OP_LIST
: -1)))))));
if (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_READ ||
cur_op->req.hdr.opcode == OSD_OP_SECONDARY_WRITE)
{
cur_op->bs_op->oid = cur_op->req.sec_rw.oid;
cur_op->bs_op->version = cur_op->req.sec_rw.version;
@ -64,7 +58,7 @@ void osd_t::exec_secondary(osd_op_t *cur_op)
cur_op->bs_op->retval = cur_op->bs_op->len;
#endif
}
else if (cur_op->req.hdr.opcode == OSD_OP_SEC_DELETE)
else if (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_DELETE)
{
cur_op->bs_op->oid = cur_op->req.sec_del.oid;
cur_op->bs_op->version = cur_op->req.sec_del.version;
@ -72,8 +66,8 @@ void osd_t::exec_secondary(osd_op_t *cur_op)
cur_op->bs_op->retval = 0;
#endif
}
else if (cur_op->req.hdr.opcode == OSD_OP_SEC_STABILIZE ||
cur_op->req.hdr.opcode == OSD_OP_SEC_ROLLBACK)
else if (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_STABILIZE ||
cur_op->req.hdr.opcode == OSD_OP_SECONDARY_ROLLBACK)
{
cur_op->bs_op->len = cur_op->req.sec_stab.len/sizeof(obj_ver_id);
cur_op->bs_op->buf = cur_op->buf;
@ -81,12 +75,11 @@ void osd_t::exec_secondary(osd_op_t *cur_op)
cur_op->bs_op->retval = 0;
#endif
}
else if (cur_op->req.hdr.opcode == OSD_OP_SEC_LIST)
else if (cur_op->req.hdr.opcode == OSD_OP_SECONDARY_LIST)
{
if (cur_op->req.sec_list.pg_count < cur_op->req.sec_list.list_pg)
{
// requested pg number is greater than total pg count
printf("Invalid LIST request: pg count %u < pg number %u\n", cur_op->req.sec_list.pg_count, cur_op->req.sec_list.list_pg);
cur_op->bs_op->retval = -EINVAL;
secondary_op_callback(cur_op);
return;
@ -94,8 +87,6 @@ void osd_t::exec_secondary(osd_op_t *cur_op)
cur_op->bs_op->oid.stripe = cur_op->req.sec_list.pg_stripe_size;
cur_op->bs_op->len = cur_op->req.sec_list.pg_count;
cur_op->bs_op->offset = cur_op->req.sec_list.list_pg - 1;
cur_op->bs_op->oid.inode = cur_op->req.sec_list.min_inode;
cur_op->bs_op->version = cur_op->req.sec_list.max_inode;
#ifdef OSD_STUB
cur_op->bs_op->retval = 0;
cur_op->bs_op->buf = NULL;
@ -112,9 +103,9 @@ void osd_t::exec_show_config(osd_op_t *cur_op)
{
// FIXME: Send the real config, not its source
std::string cfg_str = json11::Json(config).dump();
cur_op->buf = malloc_or_die(cfg_str.size()+1);
cur_op->buf = malloc(cfg_str.size()+1);
memcpy(cur_op->buf, cfg_str.c_str(), cfg_str.size()+1);
cur_op->iov.push_back(cur_op->buf, cfg_str.size()+1);
cur_op->send_list.push_back(cur_op->buf, cfg_str.size()+1);
finish_op(cur_op, cfg_str.size()+1);
}

17
osd_test.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <sys/types.h>
#include <sys/socket.h>
#include <netinet/in.h>
@ -187,7 +184,7 @@ uint64_t test_read(int connect_fd, uint64_t inode, uint64_t stripe, uint64_t ver
osd_any_reply_t reply;
op.hdr.magic = SECONDARY_OSD_OP_MAGIC;
op.hdr.id = 1;
op.hdr.opcode = OSD_OP_SEC_READ;
op.hdr.opcode = OSD_OP_SECONDARY_READ;
op.sec_rw.oid = {
.inode = inode,
.stripe = stripe,
@ -211,8 +208,8 @@ uint64_t test_read(int connect_fd, uint64_t inode, uint64_t stripe, uint64_t ver
return 0;
}
free(data);
printf("Read %lx:%lx v%lu = v%lu\n", inode, stripe, version, reply.sec_rw.version);
op.hdr.opcode = OSD_OP_SEC_LIST;
printf("Read %lu:%lu v%lu = v%lu\n", inode, stripe, version, reply.sec_rw.version);
op.hdr.opcode = OSD_OP_SECONDARY_LIST;
op.sec_list.list_pg = 1;
op.sec_list.pg_count = 1;
op.sec_list.pg_stripe_size = 4*1024*1024;
@ -235,7 +232,7 @@ uint64_t test_read(int connect_fd, uint64_t inode, uint64_t stripe, uint64_t ver
{
if (ov[i].oid.inode == inode && (ov[i].oid.stripe & ~(4096-1)) == (stripe & ~(4096-1)))
{
printf("list: %lx:%lx v%lu stable=%d\n", ov[i].oid.inode, ov[i].oid.stripe, ov[i].version, i < reply.sec_list.stable_count ? 1 : 0);
printf("list: %lu:%lu v%lu stable=%d\n", ov[i].oid.inode, ov[i].oid.stripe, ov[i].version, i < reply.sec_list.stable_count ? 1 : 0);
}
}
return 0;
@ -247,7 +244,7 @@ uint64_t test_write(int connect_fd, uint64_t inode, uint64_t stripe, uint64_t ve
osd_any_reply_t reply;
op.hdr.magic = SECONDARY_OSD_OP_MAGIC;
op.hdr.id = 1;
op.hdr.opcode = OSD_OP_SEC_WRITE;
op.hdr.opcode = OSD_OP_SECONDARY_WRITE;
op.sec_rw.oid = {
.inode = inode,
.stripe = stripe,
@ -357,7 +354,7 @@ void test_list_stab(int connect_fd)
osd_any_reply_t reply;
op.hdr.magic = SECONDARY_OSD_OP_MAGIC;
op.hdr.id = 1;
op.hdr.opcode = OSD_OP_SEC_LIST;
op.hdr.opcode = OSD_OP_SECONDARY_LIST;
op.sec_list.pg_count = 0;
assert(write_blocking(connect_fd, op.buf, OSD_PACKET_SIZE) == OSD_PACKET_SIZE);
int r = read_blocking(connect_fd, reply.buf, OSD_PACKET_SIZE);
@ -373,7 +370,7 @@ void test_list_stab(int connect_fd)
// Stabilize in portions of 32 entries
if (i - last_start >= 32 || i == total_count)
{
op.hdr.opcode = OSD_OP_SEC_STABILIZE;
op.hdr.opcode = OSD_OP_SECONDARY_STABILIZE;
op.sec_stab.len = sizeof(obj_ver_id) * (i - last_start);
assert(write_blocking(connect_fd, op.buf, OSD_PACKET_SIZE) == OSD_PACKET_SIZE);
assert(write_blocking(connect_fd, data + last_start, op.sec_stab.len) == op.sec_stab.len);

11
pg_states.cpp
View File

@ -1,11 +1,8 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include "pg_states.h"
const int pg_state_bit_count = 14;
const int pg_state_bit_count = 13;
const int pg_state_bits[14] = {
const int pg_state_bits[13] = {
PG_STARTING,
PG_PEERING,
PG_INCOMPLETE,
@ -17,11 +14,10 @@ const int pg_state_bits[14] = {
PG_HAS_DEGRADED,
PG_HAS_MISPLACED,
PG_HAS_UNCLEAN,
PG_HAS_INVALID,
PG_LEFT_ON_DEAD,
};
const char *pg_state_names[14] = {
const char *pg_state_names[13] = {
"starting",
"peering",
"incomplete",
@ -33,6 +29,5 @@ const char *pg_state_names[14] = {
"has_degraded",
"has_misplaced",
"has_unclean",
"has_invalid",
"left_on_dead",
};

10
pg_states.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
// Placement group states
@ -18,11 +15,9 @@
#define PG_HAS_DEGRADED (1<<8)
#define PG_HAS_MISPLACED (1<<9)
#define PG_HAS_UNCLEAN (1<<10)
#define PG_HAS_INVALID (1<<11)
#define PG_LEFT_ON_DEAD (1<<12)
#define PG_LEFT_ON_DEAD (1<<11)
// Lower bits that represent object role (EC 0/1/2... or always 0 with replication)
// 12 bits is a safe default that doesn't depend on pg_stripe_size or pg_block_size
// FIXME: Safe default that doesn't depend on pg_stripe_size or pg_block_size
#define STRIPE_MASK ((uint64_t)4096 - 1)
// OSD object states
@ -31,6 +26,7 @@
#define OBJ_MISPLACED 0x08
#define OBJ_NEEDS_STABLE 0x10000
#define OBJ_NEEDS_ROLLBACK 0x20000
#define OBJ_BUGGY 0x80000
extern const int pg_state_bits[];
extern const char *pg_state_names[];

400
qemu_driver.c
View File

@ -1,400 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
// QEMU block driver
#define _GNU_SOURCE
#include "qemu/osdep.h"
#include "qemu/units.h"
#include "block/block_int.h"
#include "block/qdict.h"
#include "qapi/error.h"
#include "qapi/qmp/qdict.h"
#include "qapi/qmp/qerror.h"
#include "qemu/uri.h"
#include "qemu/error-report.h"
#include "qemu/module.h"
#include "qemu/option.h"
#include "qemu/cutils.h"
#include "qemu_proxy.h"
typedef struct VitastorClient
{
void *proxy;
char *etcd_host;
char *etcd_prefix;
uint64_t inode;
uint64_t pool;
uint64_t size;
int readonly;
QemuMutex mutex;
} VitastorClient;
typedef struct VitastorRPC
{
BlockDriverState *bs;
Coroutine *co;
QEMUIOVector *iov;
int ret;
int complete;
} VitastorRPC;
static char *qemu_rbd_next_tok(char *src, char delim, char **p)
{
char *end;
*p = NULL;
for (end = src; *end; ++end)
{
if (*end == delim)
break;
if (*end == '\\' && end[1] != '\0')
end++;
}
if (*end == delim)
{
*p = end + 1;
*end = '\0';
}
return src;
}
static void qemu_rbd_unescape(char *src)
{
char *p;
for (p = src; *src; ++src, ++p)
{
if (*src == '\\' && src[1] != '\0')
src++;
*p = *src;
}
*p = '\0';
}
// vitastor[:key=value]*
// vitastor:etcd_host=127.0.0.1:inode=1:pool=1
static void vitastor_parse_filename(const char *filename, QDict *options, Error **errp)
{
const char *start;
char *p, *buf;
if (!strstart(filename, "vitastor:", &start))
{
error_setg(errp, "File name must start with 'vitastor:'");
return;
}
buf = g_strdup(start);
p = buf;
// The following are all key/value pairs
while (p)
{
char *name, *value;
name = qemu_rbd_next_tok(p, '=', &p);
if (!p)
{
error_setg(errp, "conf option %s has no value", name);
break;
}
qemu_rbd_unescape(name);
value = qemu_rbd_next_tok(p, ':', &p);
qemu_rbd_unescape(value);
if (!strcmp(name, "inode") || !strcmp(name, "pool") || !strcmp(name, "size"))
{
unsigned long long num_val;
if (parse_uint_full(value, &num_val, 0))
{
error_setg(errp, "Illegal %s: %s", name, value);
goto out;
}
qdict_put_int(options, name, num_val);
}
else
{
qdict_put_str(options, name, value);
}
}
if (!qdict_get_try_int(options, "inode", 0))
{
error_setg(errp, "inode is missing");
goto out;
}
if (!(qdict_get_try_int(options, "inode", 0) >> (64-POOL_ID_BITS)) &&
!qdict_get_try_int(options, "pool", 0))
{
error_setg(errp, "pool number is missing");
goto out;
}
if (!qdict_get_try_int(options, "size", 0))
{
error_setg(errp, "size is missing");
goto out;
}
if (!qdict_get_str(options, "etcd_host"))
{
error_setg(errp, "etcd_host is missing");
goto out;
}
out:
g_free(buf);
return;
}
static int vitastor_file_open(BlockDriverState *bs, QDict *options, int flags, Error **errp)
{
VitastorClient *client = bs->opaque;
int64_t ret = 0;
client->etcd_host = g_strdup(qdict_get_try_str(options, "etcd_host"));
client->etcd_prefix = g_strdup(qdict_get_try_str(options, "etcd_prefix"));
client->inode = qdict_get_int(options, "inode");
client->pool = qdict_get_int(options, "pool");
if (client->pool)
client->inode = (client->inode & ((1l << (64-POOL_ID_BITS)) - 1)) | (client->pool << (64-POOL_ID_BITS));
client->size = qdict_get_int(options, "size");
client->readonly = (flags & BDRV_O_RDWR) ? 1 : 0;
client->proxy = vitastor_proxy_create(bdrv_get_aio_context(bs), client->etcd_host, client->etcd_prefix);
//client->aio_context = bdrv_get_aio_context(bs);
bs->total_sectors = client->size / BDRV_SECTOR_SIZE;
qdict_del(options, "etcd_host");
qdict_del(options, "etcd_prefix");
qdict_del(options, "inode");
qdict_del(options, "pool");
qdict_del(options, "size");
qemu_mutex_init(&client->mutex);
return ret;
}
static void vitastor_close(BlockDriverState *bs)
{
VitastorClient *client = bs->opaque;
vitastor_proxy_destroy(client->proxy);
qemu_mutex_destroy(&client->mutex);
g_free(client->etcd_host);
if (client->etcd_prefix)
g_free(client->etcd_prefix);
}
static int vitastor_probe_blocksizes(BlockDriverState *bs, BlockSizes *bsz)
{
bsz->phys = 4096;
bsz->log = 4096;
return 0;
}
static int coroutine_fn vitastor_co_create_opts(
#if QEMU_VERSION_MAJOR >= 4
BlockDriver *drv,
#endif
const char *url, QemuOpts *opts, Error **errp)
{
QDict *options;
int ret;
options = qdict_new();
vitastor_parse_filename(url, options, errp);
if (*errp)
{
ret = -1;
goto out;
}
// inodes don't require creation in Vitastor. FIXME: They will when there will be some metadata
ret = 0;
out:
qobject_unref(options);
return ret;
}
static int coroutine_fn vitastor_co_truncate(BlockDriverState *bs, int64_t offset,
#if QEMU_VERSION_MAJOR >= 4
bool exact,
#endif
PreallocMode prealloc, Error **errp)
{
VitastorClient *client = bs->opaque;
if (prealloc != PREALLOC_MODE_OFF)
{
error_setg(errp, "Unsupported preallocation mode '%s'", PreallocMode_str(prealloc));
return -ENOTSUP;
}
// TODO: Resize inode to <offset> bytes
client->size = offset / BDRV_SECTOR_SIZE;
return 0;
}
static int vitastor_get_info(BlockDriverState *bs, BlockDriverInfo *bdi)
{
bdi->cluster_size = 4096;
return 0;
}
static int64_t vitastor_getlength(BlockDriverState *bs)
{
VitastorClient *client = bs->opaque;
return client->size;
}
static void vitastor_refresh_limits(BlockDriverState *bs, Error **errp)
{
bs->bl.request_alignment = 4096;
bs->bl.min_mem_alignment = 4096;
bs->bl.opt_mem_alignment = 4096;
}
static int64_t vitastor_get_allocated_file_size(BlockDriverState *bs)
{
return 0;
}
static void vitastor_co_init_task(BlockDriverState *bs, VitastorRPC *task)
{
*task = (VitastorRPC) {
.co = qemu_coroutine_self(),
.bs = bs,
};
}
static void vitastor_co_generic_bh_cb(int retval, void *opaque)
{
VitastorRPC *task = opaque;
task->ret = retval;
task->complete = 1;
if (qemu_coroutine_self() != task->co)
{
aio_co_wake(task->co);
}
}
static int coroutine_fn vitastor_co_preadv(BlockDriverState *bs, uint64_t offset, uint64_t bytes, QEMUIOVector *iov, int flags)
{
VitastorClient *client = bs->opaque;
VitastorRPC task;
vitastor_co_init_task(bs, &task);
task.iov = iov;
qemu_mutex_lock(&client->mutex);
vitastor_proxy_rw(0, client->proxy, client->inode, offset, bytes, iov->iov, iov->niov, vitastor_co_generic_bh_cb, &task);
qemu_mutex_unlock(&client->mutex);
while (!task.complete)
{
qemu_coroutine_yield();
}
return task.ret;
}
static int coroutine_fn vitastor_co_pwritev(BlockDriverState *bs, uint64_t offset, uint64_t bytes, QEMUIOVector *iov, int flags)
{
VitastorClient *client = bs->opaque;
VitastorRPC task;
vitastor_co_init_task(bs, &task);
task.iov = iov;
qemu_mutex_lock(&client->mutex);
vitastor_proxy_rw(1, client->proxy, client->inode, offset, bytes, iov->iov, iov->niov, vitastor_co_generic_bh_cb, &task);
qemu_mutex_unlock(&client->mutex);
while (!task.complete)
{
qemu_coroutine_yield();
}
return task.ret;
}
static int coroutine_fn vitastor_co_flush(BlockDriverState *bs)
{
VitastorClient *client = bs->opaque;
VitastorRPC task;
vitastor_co_init_task(bs, &task);
qemu_mutex_lock(&client->mutex);
vitastor_proxy_sync(client->proxy, vitastor_co_generic_bh_cb, &task);
qemu_mutex_unlock(&client->mutex);
while (!task.complete)
{
qemu_coroutine_yield();
}
return task.ret;
}
static QemuOptsList vitastor_create_opts = {
.name = "vitastor-create-opts",
.head = QTAILQ_HEAD_INITIALIZER(vitastor_create_opts.head),
.desc = {
{
.name = BLOCK_OPT_SIZE,
.type = QEMU_OPT_SIZE,
.help = "Virtual disk size"
},
{ /* end of list */ }
}
};
static const char *vitastor_strong_runtime_opts[] = {
"inode",
"pool",
"etcd_host",
"etcd_prefix",
NULL
};
static BlockDriver bdrv_vitastor = {
.format_name = "vitastor",
.protocol_name = "vitastor",
.instance_size = sizeof(VitastorClient),
.bdrv_parse_filename = vitastor_parse_filename,
.bdrv_has_zero_init = bdrv_has_zero_init_1,
#if QEMU_VERSION_MAJOR >= 4
.bdrv_has_zero_init_truncate = bdrv_has_zero_init_1,
#endif
.bdrv_get_info = vitastor_get_info,
.bdrv_getlength = vitastor_getlength,
.bdrv_probe_blocksizes = vitastor_probe_blocksizes,
.bdrv_refresh_limits = vitastor_refresh_limits,
// FIXME: Implement it along with per-inode statistics
//.bdrv_get_allocated_file_size = vitastor_get_allocated_file_size,
.bdrv_file_open = vitastor_file_open,
.bdrv_close = vitastor_close,
// Option list for the create operation
.create_opts = &vitastor_create_opts,
// For qmp_blockdev_create(), used by the qemu monitor / QAPI
// Requires patching QAPI IDL, thus unimplemented
//.bdrv_co_create = vitastor_co_create,
// For bdrv_create(), used by qemu-img
.bdrv_co_create_opts = vitastor_co_create_opts,
.bdrv_co_truncate = vitastor_co_truncate,
.bdrv_co_preadv = vitastor_co_preadv,
.bdrv_co_pwritev = vitastor_co_pwritev,
.bdrv_co_flush_to_disk = vitastor_co_flush,
#if QEMU_VERSION_MAJOR >= 4
.strong_runtime_opts = vitastor_strong_runtime_opts,
#endif
};
static void vitastor_block_init(void)
{
bdrv_register(&bdrv_vitastor);
}
block_init(vitastor_block_init);

130
qemu_proxy.cpp
View File

@ -1,130 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
// C-C++ proxy for the QEMU driver
// (QEMU headers don't compile with g++)
#include <sys/epoll.h>
#include "cluster_client.h"
typedef void* AioContext;
#include "qemu_proxy.h"
extern "C"
{
// QEMU
typedef void IOHandler(void *opaque);
void aio_set_fd_handler(AioContext *ctx, int fd, int is_external, IOHandler *fd_read, IOHandler *fd_write, void *poll_fn, void *opaque);
}
struct QemuProxyData
{
int fd;
std::function<void(int, int)> callback;
};
class QemuProxy
{
std::map<int, QemuProxyData> handlers;
public:
timerfd_manager_t *tfd;
cluster_client_t *cli;
AioContext *ctx;
QemuProxy(AioContext *ctx, const char *etcd_host, const char *etcd_prefix)
{
this->ctx = ctx;
json11::Json cfg = json11::Json::object {
{ "etcd_address", std::string(etcd_host) },
{ "etcd_prefix", std::string(etcd_prefix ? etcd_prefix : "/vitastor") },
};
tfd = new timerfd_manager_t([this](int fd, bool wr, std::function<void(int, int)> callback) { set_fd_handler(fd, wr, callback); });
cli = new cluster_client_t(NULL, tfd, cfg);
}
~QemuProxy()
{
cli->stop();
delete cli;
delete tfd;
}
void set_fd_handler(int fd, bool wr, std::function<void(int, int)> callback)
{
if (callback != NULL)
{
handlers[fd] = { .fd = fd, .callback = callback };
aio_set_fd_handler(ctx, fd, false, &QemuProxy::read_handler, wr ? &QemuProxy::write_handler : NULL, NULL, &handlers[fd]);
}
else
{
handlers.erase(fd);
aio_set_fd_handler(ctx, fd, false, NULL, NULL, NULL, NULL);
}
}
static void read_handler(void *opaque)
{
QemuProxyData *data = (QemuProxyData *)opaque;
data->callback(data->fd, EPOLLIN);
}
static void write_handler(void *opaque)
{
QemuProxyData *data = (QemuProxyData *)opaque;
data->callback(data->fd, EPOLLOUT);
}
};
extern "C" {
void* vitastor_proxy_create(AioContext *ctx, const char *etcd_host, const char *etcd_prefix)
{
QemuProxy *p = new QemuProxy(ctx, etcd_host, etcd_prefix);
return p;
}
void vitastor_proxy_destroy(void *client)
{
QemuProxy *p = (QemuProxy*)client;
delete p;
}
void vitastor_proxy_rw(int write, void *client, uint64_t inode, uint64_t offset, uint64_t len,
iovec *iov, int iovcnt, VitastorIOHandler cb, void *opaque)
{
QemuProxy *p = (QemuProxy*)client;
cluster_op_t *op = new cluster_op_t;
op->opcode = write ? OSD_OP_WRITE : OSD_OP_READ;
op->inode = inode;
op->offset = offset;
op->len = len;
for (int i = 0; i < iovcnt; i++)
{
op->iov.push_back(iov[i].iov_base, iov[i].iov_len);
}
op->callback = [cb, opaque](cluster_op_t *op)
{
cb(op->retval, opaque);
delete op;
};
p->cli->execute(op);
}
void vitastor_proxy_sync(void *client, VitastorIOHandler cb, void *opaque)
{
QemuProxy *p = (QemuProxy*)client;
cluster_op_t *op = new cluster_op_t;
op->opcode = OSD_OP_SYNC;
op->callback = [cb, opaque](cluster_op_t *op)
{
cb(op->retval, opaque);
delete op;
};
p->cli->execute(op);
}
}

29
qemu_proxy.h
View File

@ -1,29 +0,0 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#ifndef VITASTOR_QEMU_PROXY_H
#define VITASTOR_QEMU_PROXY_H
#ifndef POOL_ID_BITS
#define POOL_ID_BITS 16
#endif
#include <stdint.h>
#include <sys/uio.h>
#ifdef __cplusplus
extern "C" {
#endif
// Our exports
typedef void VitastorIOHandler(int retval, void *opaque);
void* vitastor_proxy_create(AioContext *ctx, const char *etcd_host, const char *etcd_prefix);
void vitastor_proxy_destroy(void *client);
void vitastor_proxy_rw(int write, void *client, uint64_t inode, uint64_t offset, uint64_t len,
struct iovec *iov, int iovcnt, VitastorIOHandler cb, void *opaque);
void vitastor_proxy_sync(void *client, VitastorIOHandler cb, void *opaque);
#ifdef __cplusplus
}
#endif
#endif

3
ringloop.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include "ringloop.h"
ring_loop_t::ring_loop_t(int qd)

13
ringloop.h
View File

@ -1,12 +1,11 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#ifndef _LARGEFILE64_SOURCE
#define _LARGEFILE64_SOURCE
#endif
#include <stdio.h>
#include <time.h>
#include <string.h>
#include <assert.h>
#include <liburing.h>
@ -161,7 +160,13 @@ public:
}
inline int submit()
{
return io_uring_submit(&ring);
int r = io_uring_submit(&ring);
{
timespec now;
clock_gettime(CLOCK_REALTIME, &now);
printf("submit %s %d %ld.%06ld\n", __FILE__, __LINE__, now.tv_sec, now.tv_nsec/1000);
}
return r;
}
inline int wait()
{

3
rw_blocking.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include <errno.h>
#include <stdlib.h>
#include <stdio.h>

3
rw_blocking.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include <unistd.h>

7
stub_bench.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
/**
* Stub benchmarker
*/
@ -126,7 +123,7 @@ void run_bench(int peer_fd)
// read
op.hdr.magic = SECONDARY_OSD_OP_MAGIC;
op.hdr.id = 1;
op.hdr.opcode = OSD_OP_SEC_READ;
op.hdr.opcode = OSD_OP_SECONDARY_READ;
op.sec_rw.oid.inode = 3;
op.sec_rw.oid.stripe = (rand() << 17) % (1 << 29); // 512 MB
op.sec_rw.version = 0;
@ -152,7 +149,7 @@ void run_bench(int peer_fd)
// write
op.hdr.magic = SECONDARY_OSD_OP_MAGIC;
op.hdr.id = 1;
op.hdr.opcode = OSD_OP_SEC_WRITE;
op.hdr.opcode = OSD_OP_SECONDARY_WRITE;
op.sec_rw.oid.inode = 3;
op.sec_rw.oid.stripe = (rand() << 17) % (1 << 29); // 512 MB
op.sec_rw.version = 0;

7
stub_osd.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
/**
* Stub "OSD" to test & compare network performance with sync read/write and io_uring
*
@ -133,7 +130,7 @@ void run_stub(int peer_fd)
reply.hdr.magic = SECONDARY_OSD_REPLY_MAGIC;
reply.hdr.id = op.hdr.id;
reply.hdr.opcode = op.hdr.opcode;
if (op.hdr.opcode == OSD_OP_SEC_READ)
if (op.hdr.opcode == OSD_OP_SECONDARY_READ)
{
reply.hdr.retval = op.sec_rw.len;
buf = malloc(op.sec_rw.len);
@ -144,7 +141,7 @@ void run_stub(int peer_fd)
if (r < op.sec_rw.len)
break;
}
else if (op.hdr.opcode == OSD_OP_SEC_WRITE || op.hdr.opcode == OSD_OP_SEC_WRITE_STABLE)
else if (op.hdr.opcode == OSD_OP_SECONDARY_WRITE)
{
buf = malloc(op.sec_rw.len);
r = read_blocking(peer_fd, buf, op.sec_rw.len);

12
stub_uring_osd.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
/**
* Stub "OSD" implemented on top of osd_messenger to test & compare
* network performance with sync read/write and io_uring
@ -41,7 +38,7 @@ int main(int narg, char *args[])
msgr->exec_op = [msgr](osd_op_t *op) { stub_exec_op(msgr, op); };
// Accept new connections
int listen_fd = bind_stub("0.0.0.0", 11203);
epmgr->set_fd_handler(listen_fd, false, [listen_fd, msgr](int fd, int events)
epmgr->set_fd_handler(listen_fd, [listen_fd, msgr](int fd, int events)
{
msgr->accept_connections(listen_fd);
});
@ -108,13 +105,14 @@ void stub_exec_op(osd_messenger_t *msgr, osd_op_t *op)
op->reply.hdr.magic = SECONDARY_OSD_REPLY_MAGIC;
op->reply.hdr.id = op->req.hdr.id;
op->reply.hdr.opcode = op->req.hdr.opcode;
if (op->req.hdr.opcode == OSD_OP_SEC_READ)
op->send_list.push_back(op->reply.buf, OSD_PACKET_SIZE);
if (op->req.hdr.opcode == OSD_OP_SECONDARY_READ)
{
op->reply.hdr.retval = op->req.sec_rw.len;
op->buf = malloc(op->req.sec_rw.len);
op->iov.push_back(op->buf, op->req.sec_rw.len);
op->send_list.push_back(op->buf, op->req.sec_rw.len);
}
else if (op->req.hdr.opcode == OSD_OP_SEC_WRITE || op->req.hdr.opcode == OSD_OP_SEC_WRITE_STABLE)
else if (op->req.hdr.opcode == OSD_OP_SECONDARY_WRITE)
{
op->reply.hdr.retval = op->req.sec_rw.len;
}

3
test.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#define _LARGEFILE64_SOURCE
#include <sys/types.h>
#include <sys/ioctl.h>

3
test_allocator.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <stdio.h>
#include "allocator.h"

3
test_blockstore.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#include <malloc.h>
#include "timerfd_interval.h"
#include "blockstore.h"

3
test_pattern.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 (see README.md for details)
#pragma once
#include <assert.h>

3
timerfd_interval.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include <sys/timerfd.h>
#include <sys/poll.h>
#include <unistd.h>

3
timerfd_interval.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include "ringloop.h"

9
timerfd_manager.cpp
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#include <sys/timerfd.h>
#include <sys/poll.h>
#include <sys/epoll.h>
@ -9,7 +6,7 @@
#include <string.h>
#include "timerfd_manager.h"
timerfd_manager_t::timerfd_manager_t(std::function<void(int, bool, std::function<void(int, int)>)> set_fd_handler)
timerfd_manager_t::timerfd_manager_t(std::function<void(int, std::function<void(int, int)>)> set_fd_handler)
{
this->set_fd_handler = set_fd_handler;
wait_state = 0;
@ -18,7 +15,7 @@ timerfd_manager_t::timerfd_manager_t(std::function<void(int, bool, std::function
{
throw std::runtime_error(std::string("timerfd_create: ") + strerror(errno));
}
set_fd_handler(timerfd, false, [this](int fd, int events)
set_fd_handler(timerfd, [this](int fd, int events)
{
handle_readable();
});
@ -26,7 +23,7 @@ timerfd_manager_t::timerfd_manager_t(std::function<void(int, bool, std::function
timerfd_manager_t::~timerfd_manager_t()
{
set_fd_handler(timerfd, false, NULL);
set_fd_handler(timerfd, NULL);
close(timerfd);
}

7
timerfd_manager.h
View File

@ -1,6 +1,3 @@
// Copyright (c) Vitaliy Filippov, 2019+
// License: VNPL-1.0 or GNU GPL-2.0+ (see README.md for details)
#pragma once
#include <time.h>
@ -29,9 +26,9 @@ class timerfd_manager_t
void trigger_nearest();
void handle_readable();
public:
std::function<void(int, bool, std::function<void(int, int)>)> set_fd_handler;
std::function<void(int, std::function<void(int, int)>)> set_fd_handler;
timerfd_manager_t(std::function<void(int, bool, std::function<void(int, int)>)> set_fd_handler);
timerfd_manager_t(std::function<void(int, std::function<void(int, int)>)> set_fd_handler);
~timerfd_manager_t();
int set_timer(uint64_t millis, bool repeat, std::function<void(int)> callback);
void clear_timer(int timer_id);

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