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Diffstat (limited to 'src/test/isolation/specs/deadlock-parallel.spec')
-rw-r--r-- | src/test/isolation/specs/deadlock-parallel.spec | 113 |
1 files changed, 113 insertions, 0 deletions
diff --git a/src/test/isolation/specs/deadlock-parallel.spec b/src/test/isolation/specs/deadlock-parallel.spec new file mode 100644 index 0000000..a050a49 --- /dev/null +++ b/src/test/isolation/specs/deadlock-parallel.spec @@ -0,0 +1,113 @@ +# Test deadlock resolution with parallel process groups. + +# It's fairly hard to get parallel worker processes to block on locks, +# since generally they don't want any locks their leader didn't already +# take. We cheat like mad here by making a function that takes a lock, +# and is incorrectly marked parallel-safe so that it can execute in a worker. + +# Note that we explicitly override any global settings of isolation level +# or force_parallel_mode, to ensure we're testing what we intend to. + +# Otherwise, this is morally equivalent to deadlock-soft.spec: +# Four-process deadlock with two hard edges and two soft edges. +# d2 waits for e1 (soft edge), e1 waits for d1 (hard edge), +# d1 waits for e2 (soft edge), e2 waits for d2 (hard edge). +# The deadlock detector resolves the deadlock by reversing the d1-e2 edge, +# unblocking d1. + +# However ... it's not actually that well-defined whether the deadlock +# detector will prefer to unblock d1 or d2. It depends on which backend +# is first to run DeadLockCheck after the deadlock condition is created: +# that backend will search outwards from its own wait condition, and will +# first find a loop involving the *other* lock. We encourage that to be +# one of the d2a1 parallel workers, which will therefore unblock d1a2 +# workers, by setting a shorter deadlock_timeout in session d2. But on +# slow machines, one or more d1a2 workers may not yet have reached their +# lock waits, so that they're not unblocked by the first DeadLockCheck. +# The next DeadLockCheck may choose to unblock the d2a1 workers instead, +# which would allow d2a1 to complete before d1a2, causing the test to +# freeze up because isolationtester isn't expecting that completion order. +# (In effect, we have an undetectable deadlock because d2 is waiting for +# d1's completion, but on the client side.) To fix this, introduce an +# additional lock (advisory lock 3), which is initially taken by d1 and +# then d2a1 will wait for it after completing the main part of the test. +# In this way, the deadlock detector can see that d1 must be completed +# first, regardless of timing. + +setup +{ + create function lock_share(int,int) returns int language sql as + 'select pg_advisory_xact_lock_shared($1); select 1;' parallel safe; + + create function lock_excl(int,int) returns int language sql as + 'select pg_advisory_xact_lock($1); select 1;' parallel safe; + + create table bigt as select x from generate_series(1, 10000) x; + analyze bigt; +} + +teardown +{ + drop function lock_share(int,int); + drop function lock_excl(int,int); + drop table bigt; +} + +session d1 +setup { BEGIN isolation level repeatable read; + SET force_parallel_mode = off; + SET deadlock_timeout = '10s'; +} +# these locks will be taken in the leader, so they will persist: +step d1a1 { SELECT lock_share(1,x), lock_excl(3,x) FROM bigt LIMIT 1; } +# this causes all the parallel workers to take locks: +step d1a2 { SET force_parallel_mode = on; + SET parallel_setup_cost = 0; + SET parallel_tuple_cost = 0; + SET min_parallel_table_scan_size = 0; + SET parallel_leader_participation = off; + SET max_parallel_workers_per_gather = 3; + SELECT sum(lock_share(2,x)) FROM bigt; } +step d1c { COMMIT; } + +session d2 +setup { BEGIN isolation level repeatable read; + SET force_parallel_mode = off; + SET deadlock_timeout = '10ms'; +} +# this lock will be taken in the leader, so it will persist: +step d2a2 { select lock_share(2,x) FROM bigt LIMIT 1; } +# this causes all the parallel workers to take locks; +# after which, make the leader take lock 3 to prevent client-driven deadlock +step d2a1 { SET force_parallel_mode = on; + SET parallel_setup_cost = 0; + SET parallel_tuple_cost = 0; + SET min_parallel_table_scan_size = 0; + SET parallel_leader_participation = off; + SET max_parallel_workers_per_gather = 3; + SELECT sum(lock_share(1,x)) FROM bigt; + SET force_parallel_mode = off; + RESET parallel_setup_cost; + RESET parallel_tuple_cost; + SELECT lock_share(3,x) FROM bigt LIMIT 1; } +step d2c { COMMIT; } + +session e1 +setup { BEGIN isolation level repeatable read; + SET force_parallel_mode = on; + SET deadlock_timeout = '10s'; +} +# this lock will be taken in a parallel worker, but we don't need it to persist +step e1l { SELECT lock_excl(1,x) FROM bigt LIMIT 1; } +step e1c { COMMIT; } + +session e2 +setup { BEGIN isolation level repeatable read; + SET force_parallel_mode = on; + SET deadlock_timeout = '10s'; +} +# this lock will be taken in a parallel worker, but we don't need it to persist +step e2l { SELECT lock_excl(2,x) FROM bigt LIMIT 1; } +step e2c { COMMIT; } + +permutation d1a1 d2a2 e1l e2l d1a2 d2a1 d1c e1c d2c e2c |