I'm using YCSB to benchmark a number of different NoSQL databases. However, when playing around with the number of client threads I have a hard time interpreting the throughput vs. latency results.
For example, when benchmarking cassandra running workload a (50/50 reads and updates) with 16 client threads the following command is executed:
bin/ycsb run cassandra-cql -p hosts=xx.xx.xx.xx -p recordcount=525600 -p operationcount=525600 -threads 16 -P workloads/workloada -s > workloada_525600_16_threads_run_res.txt
which gives the following output:
[OVERALL], RunTime(ms), 62751
[OVERALL], Throughput(ops/sec), 8375.962136061577
[TOTAL_GCS_PS_Scavenge], Count, 64
[TOTAL_GC_TIME_PS_Scavenge], Time(ms), 289
[TOTAL_GC_TIME_%_PS_Scavenge], Time(%), 0.46055042947522745
[TOTAL_GCS_PS_MarkSweep], Count, 0
[TOTAL_GC_TIME_PS_MarkSweep], Time(ms), 0
[TOTAL_GC_TIME_%_PS_MarkSweep], Time(%), 0.0
[TOTAL_GCs], Count, 64
[TOTAL_GC_TIME], Time(ms), 289
[TOTAL_GC_TIME_%], Time(%), 0.46055042947522745
[READ], Operations, 262650
[READ], AverageLatency(us), 1844.6075042832667
[READ], MinLatency(us), 290
[READ], MaxLatency(us), 116159
[READ], 95thPercentileLatency(us), 3081
[READ], 99thPercentileLatency(us), 7551
[READ], Return=OK, 262650
[CLEANUP], Operations, 16
[CLEANUP], AverageLatency(us), 139458.5
[CLEANUP], MinLatency(us), 1
[CLEANUP], MaxLatency(us), 2232319
[CLEANUP], 95thPercentileLatency(us), 19
[CLEANUP], 99thPercentileLatency(us), 2232319
[UPDATE], Operations, 262950
[UPDATE], AverageLatency(us), 1764.8220193953223
[UPDATE], MinLatency(us), 208
[UPDATE], MaxLatency(us), 95807
[UPDATE], 95thPercentileLatency(us), 2901
[UPDATE], 99thPercentileLatency(us), 7031
[UPDATE], Return=OK, 262950
Running the same operation with 32 threads I get:
[OVERALL], RunTime(ms), 51785
[OVERALL], Throughput(ops/sec), 10149.65723665154
[TOTAL_GCS_PS_Scavenge], Count, 124
[TOTAL_GC_TIME_PS_Scavenge], Time(ms), 310
[TOTAL_GC_TIME_%_PS_Scavenge], Time(%), 0.5986289466061601
[TOTAL_GCS_PS_MarkSweep], Count, 0
[TOTAL_GC_TIME_PS_MarkSweep], Time(ms), 0
[TOTAL_GC_TIME_%_PS_MarkSweep], Time(%), 0.0
[TOTAL_GCs], Count, 124
[TOTAL_GC_TIME], Time(ms), 310
[TOTAL_GC_TIME_%], Time(%), 0.5986289466061601
[READ], Operations, 262848
[READ], AverageLatency(us), 2947.844628834916
[READ], MinLatency(us), 363
[READ], MaxLatency(us), 194559
[READ], 95thPercentileLatency(us), 5079
[READ], 99thPercentileLatency(us), 11055
[READ], Return=OK, 262848
[CLEANUP], Operations, 32
[CLEANUP], AverageLatency(us), 69601.5625
[CLEANUP], MinLatency(us), 1
[CLEANUP], MaxLatency(us), 2228223
[CLEANUP], 95thPercentileLatency(us), 3
[CLEANUP], 99thPercentileLatency(us), 2228223
[UPDATE], Operations, 262752
[UPDATE], AverageLatency(us), 2881.930485781269
[UPDATE], MinLatency(us), 316
[UPDATE], MaxLatency(us), 203391
[UPDATE], 95thPercentileLatency(us), 4987
[UPDATE], 99thPercentileLatency(us), 10711
[UPDATE], Return=OK, 262752
The overall runtime is lower and thus, the throughput is higher, but the latencies are higher as well.
I'm not quite sure how to interpret these results, and how would you find the "appropriate" number of client threads to run?