= AspectJ 1.8.12 _© Copyright 2017 Contributors. All rights reserved._ _Release info: 1.8.12 available 20-Oct-2017_ This is a small release that includes a backport of some 1.9.0 work that improves the performance of Spring AOP (or any system consuming AspectJ in a similar way to Spring). Dave Syer recently created a series of benchmarks for checking the speed of Spring-AspectJ: https://github.com/dsyer/spring-boot-aspectj Here we can see the numbers for AspectJ 1.8.11 (on an older Macbook Pro): [source, text] .... Benchmark (scale) Mode Cnt Score Error Units StartupBenchmark.ltw N/A avgt 10 2.656 ~ 0.166 s/op StartupBenchmark.ltw_100 N/A avgt 10 2.618 ~ 0.063 s/op StartupBenchmark.spring v0_10 avgt 10 2.071 ~ 0.044 s/op StartupBenchmark.spring v1_10 avgt 10 2.210 ~ 0.058 s/op StartupBenchmark.spring v1_100 avgt 10 2.260 ~ 0.068 s/op StartupBenchmark.spring v10_50 avgt 10 2.933 ~ 0.039 s/op StartupBenchmark.spring v20_50 avgt 10 3.832 ~ 0.094 s/op StartupBenchmark.spring v20_100 avgt 10 3.959 ~ 0.047 s/op StartupBenchmark.spring a0_10 avgt 10 2.073 ~ 0.028 s/op StartupBenchmark.spring a1_10 avgt 10 2.729 ~ 0.061 s/op StartupBenchmark.spring a1_100 avgt 10 2.750 ~ 0.029 s/op StartupBenchmark.spring a10_50 avgt 10 7.153 ~ 0.075 s/op StartupBenchmark.spring a10_100 avgt 10 7.152 ~ 0.059 s/op StartupBenchmark.spring a20_50 avgt 10 11.430 ~ 0.105 s/op StartupBenchmark.spring a20_100 avgt 10 11.497 ~ 0.162 s/op .... So this is the average **startup time** of an app affected by aspects applying to the beans involved. Where numbers are referenced the first is the number of aspects/pointcuts and the second is the number of beans. The 'a' indicates an annotation based pointcut vs a non-annotation based pointcut ('v'). Notice things are much worse for annotation based pointcuts. At 20 pointcuts and 50 beans the app is 9 seconds slower to startup. In AspectJ 1.8.12 and 1.9.0.RC1 some work has been done here. The key change is to recognize that the use of annotations with runtime retention is much more likely than annotations with class level retention. Retrieving annotations with class retention is costly because we must open the bytes for the class file and dig around in there (vs runtime retention which are immediately accessible by reflection on the types). In 1.8.11 the actual type of the annotation involved in the matching is ignored and the code will fetch *all* the annotations on the type/method/field being matched against. So even if the match is looking for a runtime retention annotation, we were doing the costly thing of fetching any class retention annotations. In 1.8.12/1.9.0.RC1 we take the type of the match annotation into account - allowing us to skip opening the classfiles in many cases. There is also some deeper work on activating caches that were not previously being used correctly but the primary change is factoring in the annotation type. What difference does that make? AspectJ 1.8.12: [source, text] .... Benchmark (scale) Mode Cnt Score Error Units StartupBenchmark.ltw N/A avgt 10 2.620 ~ 0.130 s/op StartupBenchmark.ltw_100 N/A avgt 10 2.567 ~ 0.038 s/op StartupBenchmark.spring v0_10 avgt 10 2.044 ~ 0.027 s/op StartupBenchmark.spring v1_10 avgt 10 2.195 ~ 0.026 s/op StartupBenchmark.spring v1_100 avgt 10 2.237 ~ 0.039 s/op StartupBenchmark.spring v10_50 avgt 10 2.774 ~ 0.038 s/op StartupBenchmark.spring v20_50 avgt 10 3.488 ~ 0.116 s/op StartupBenchmark.spring v20_100 avgt 10 3.642 ~ 0.080 s/op StartupBenchmark.spring a0_10 avgt 10 2.067 ~ 0.034 s/op StartupBenchmark.spring a1_10 avgt 10 2.159 ~ 0.030 s/op StartupBenchmark.spring a1_100 avgt 10 2.207 ~ 0.020 s/op StartupBenchmark.spring a10_50 avgt 10 2.471 ~ 0.031 s/op StartupBenchmark.spring a10_100 avgt 10 2.517 ~ 0.045 s/op StartupBenchmark.spring a20_50 avgt 10 2.842 ~ 0.049 s/op StartupBenchmark.spring a20_100 avgt 10 2.916 ~ 0.145 s/op .... Look at the a20_100 case - instead of impacting start time by 9 seconds, it impacts it by 1 second.