Files
seaweedfs/test/benchmark/fuse_db
Chris Lu 76783f3d71 test: add FUSE database load/durability/perf benchmark (#9980)
* test: add FUSE database load/durability/perf benchmark

Runs MySQL (InnoDB) and SQLite with ~1GB datadirs on a SeaweedFS FUSE
mount. Two parts:

- durability: normal shutdown, kill -9, and crash-during-write all keep
  every fsync-committed row (verified by integrity check + row count +
  contiguous prefix + per-row CRC).
- performance: FUSE vs the same local disk. fsync/commit latency is the
  dominant cost (~0.13ms -> ~1.18ms), so small transactions run ~9-12x
  slower while bulk loads and warm reads stay close.

Harness is path-independent (runtime under $SEAWEED_BENCH_WORK) and only
touches its own processes on non-default ports.

* test/benchmark/fuse_db: portable to Linux + crash-safe progress

- export MYSQL_BIN; mysql_bench.py falls back to PATH when unset
- unmount via fusermount/fusermount3 (non-root Linux), then umount/diskutil
- atomic progress write (tmp+fsync+rename); treat empty progress file as 0
- reuse a single PRNG in the perf probe so RNG init doesn't skew timings

* test/benchmark/fuse_db: validate inputs, add subprocess timeout

- mysql_bench.py: 1800s timeout on mysql CLI calls; reject db names that
  aren't plain identifiers (interpolated into SQL)
- sqlite_gen.py / sqlite_verify.py: allowlist journal/synchronous modes and
  the verify mode so a typo can't silently weaken durability or relax checks
- run_mysql.sh: durable atomic progress write (tmp+fsync+rename), matching
  sqlite_gen.py; quote $LB in both crash-test verify calls
2026-06-15 13:25:27 -07:00
..

FUSE database load / durability / performance benchmark

Runs MySQL (InnoDB) and SQLite with their data files on a SeaweedFS FUSE mount, with ~1 GB datasets, and answers two questions:

  1. Durability — does any committed data get lost across normal shutdown, an unexpected kill -9, or a crash during active writes?
  2. Performance — how much slower is the FUSE mount than the local disk for the same workload (bulk load, OLTP commits, scans, raw fsync)?

Each row carries a CRC32 of an incompressible (so ~1 GB actually hits the volumes) deterministic payload; verification checks integrity_check/CHECK TABLE, exact row count, contiguous-id prefix, and a per-row CRC recompute.

Results (single node, macOS arm64 + macFUSE, weed 4.34, local NVMe, 2026-06-15)

Durability — 6/6 PASS, no committed data lost, no corruption

scenario what SQLite MySQL
A normal shutdown graceful DB stop, unmount, cluster stop, restart, verify PASS PASS
B unexpected (kill -9) kill -9 db+mount+cluster, restart, recover, verify PASS PASS
C crash during writes kill -9 mid-load, restart, recover, verify committed prefix PASS PASS

Scenario C confirmed correct recovery: the in-flight transaction rolled back, every fsync-committed row survived as a contiguous prefix (InnoDB redo recovery ~9 s).

Performance — FUSE vs host (same disk, same durability settings)

Raw filesystem:

metric host FUSE FUSE slower
seq write +fsync 2336 MB/s 369 MB/s 6.3x
seq read (warm) 3435 MB/s 1422 MB/s 2.4x
fsync latency 0.13 ms 1.18 ms 9x

SQLite (1 GB, journal=DELETE, synchronous=FULL):

metric host FUSE FUSE slower
bulk load 5.8 s (177 MB/s) 11.6 s (88 MB/s) 2.0x
OLTP 1-row txns 1987 tx/s 171 tx/s 11.6x
full scan (warm) 316 MB/s 427 MB/s ~equal (python-bound)

MySQL/InnoDB (1 GB, trx_commit=1, flush_method=fsync):

metric host FUSE FUSE slower
bulk load 24.4 s (42 MB/s) 32.9 s (31 MB/s) 1.35x
OLTP 1-row commits 10542 tx/s 1144 tx/s 9.2x
full scan 2419 MB/s 430 MB/s 5.6x

Takeaway: the cost is dominated by fsync/commit latency (0.13 → 1.18 ms, ~9x) because every durable commit uploads the chunk to the volume + persists the filer chunk-manifest over loopback. Small fsync'd transactions are ~9-12x slower; bulk loads (commits amortized) are 1.3-2x slower; warm/sequential reads are close to host. These are single-node loopback numbers — a real cluster (remote volumes, replication) adds network RTT + replica fsync per commit.

Durability caveat (test scope)

kill -9 terminates the processes while the OS keeps running, so everything that reached the OS page cache (all fsync'd data) survives — this faithfully tests process/daemon crashes and is what passed 6/6. It does not simulate true power loss (page cache lost). The FUSE mount uploads chunks without fsync=true (weed/mount/weedfs_write.go builds UploadOption with no Fsync), so the volume does not fsync .dat per upload and the filer leveldb likely does not sync per write; under a real power cut, recently-"committed" data that only reached the page cache could be lost. A VM hard-reset / power-loss test on real hardware is the follow-up to close that gap.

Requirements

  • weed on $PATH (or set WEED=/path/to/weed)
  • macFUSE (macOS) or libfuse (Linux)
  • python3, sqlite3
  • MySQL/MariaDB install; set MYSQL_BASE to its prefix (default macOS Homebrew /opt/homebrew/opt/mysql; must contain bin/mysqld, bin/mysql, bin/mysqladmin). For mysql_bench.py on a non-default install, also set MYSQL_BIN=/path/to/mysql.

Run

Runtime artifacts (cluster, mount, logs) go to $SEAWEED_BENCH_WORK (default /tmp/seaweedfs_fuse_db_bench), kept out of the repo.

cd test/benchmark/fuse_db
bash bin/run_sqlite.sh   > results/sqlite.log   2>&1   # SQLite durability suite
bash bin/run_mysql.sh    > results/mysql.log    2>&1   # MySQL durability suite
bash bin/compare.sh      > results/compare.log  2>&1   # FUSE vs host performance

The harness manages only its own processes (via pidfiles) on non-default ports (9555/9560/9565, mysqld 3308); it never runs pkill weed, so other SeaweedFS instances on the box are untouched.

Files

bin/lib.sh           cluster/mount/mysqld lifecycle helpers (start/stop/kill, clean state)
bin/run_sqlite.sh    SQLite 1GB load + A/B/C crash scenarios
bin/run_mysql.sh     MySQL 1GB load + A/B/C crash scenarios
bin/compare.sh       FUSE-vs-host driver
bin/sqlite_gen.py    deterministic incompressible SQLite loader (progress/ref files)
bin/sqlite_verify.py SQLite integrity + count + prefix + per-row CRC verifier
bin/sqlite_bench.py  SQLite load/OLTP/scan timing probe
bin/mysql_bench.py   MySQL load/OLTP/scan timing probe (via mysql CLI)
bin/fsbench.py       raw seq-write / fsync-latency / seq-read microbenchmark

The numbers above are the reference baseline; rerun the scripts to reproduce. Run output is written to results/*.log, which is gitignored (repo-wide *.log rule) -- not checked in.