jolt/bench
Dmitri Sotnikov ae3f9f6e84
Spike: localize the mandelbrot 15x floor (jolt-5vsp) (#143)
The jolt-vs-hand-Janet-vs-JVM mandelbrot comparison splits the 15.4x floor
into two layers: a Janet-VM floor (~10.8x JVM, optimal while-loop Janet over
unboxed doubles — only native codegen moves it) plus a ~1.43x jolt loop-
lowering overhead on top. The overhead is entirely the loop/recur -> recursive-
closure-called-per-iteration lowering; hand-Janet written the same way matches
jolt, while a while+var/set version is 1.43x faster. So a cheap backend win
(jolt-v28u) sits above the structural native-codegen lever.

Adds the spike artifacts under bench/ and the results writeup; marks the spike
done in the handoff. No source changes.

Co-authored-by: Yogthos <yogthos@gmail.com>
2026-06-16 16:20:40 +00:00
..
binary_trees.clj Add benchmark suite for alloc/dispatch/collection workloads (jolt-1r86) (#135) 2026-06-16 04:41:49 +00:00
collections.clj Add benchmark suite for alloc/dispatch/collection workloads (jolt-1r86) (#135) 2026-06-16 04:41:49 +00:00
dispatch.clj Add benchmark suite for alloc/dispatch/collection workloads (jolt-1r86) (#135) 2026-06-16 04:41:49 +00:00
dump-mandelbrot-emit.janet Spike: localize the mandelbrot 15x floor (jolt-5vsp) (#143) 2026-06-16 16:20:40 +00:00
fib.clj Broaden the benchmark suite; add jolt-vs-JVM scorecard (#140) 2026-06-16 14:50:38 +00:00
mandelbrot-hand-rec.janet Spike: localize the mandelbrot 15x floor (jolt-5vsp) (#143) 2026-06-16 16:20:40 +00:00
mandelbrot-hand.janet Spike: localize the mandelbrot 15x floor (jolt-5vsp) (#143) 2026-06-16 16:20:40 +00:00
mandelbrot.clj Broaden the benchmark suite; add jolt-vs-JVM scorecard (#140) 2026-06-16 14:50:38 +00:00
mono_dispatch.clj Broaden the benchmark suite; add jolt-vs-JVM scorecard (#140) 2026-06-16 14:50:38 +00:00
README.md Broaden the benchmark suite; add jolt-vs-JVM scorecard (#140) 2026-06-16 14:50:38 +00:00
run.sh Broaden the benchmark suite; add jolt-vs-JVM scorecard (#140) 2026-06-16 14:50:38 +00:00

jolt benchmark suite

Benchmarks that isolate the workload axes jolt's optimizing passes target. The ray tracer (examples/ray-tracer) is float-compute-bound — its time is irreducible algorithmic math (hit-testing + transcendentals), and devirt, allocation removal, and type-proving all measured flat on it. So it can't tell us whether those passes work. These benchmarks make each pass's target workload the dominant cost.

Reference: the cross-language suites these draw from — Are We Fast Yet? (Marr et al., DLS '16) and the Computer Language Benchmarks Game. The benchmarks are portable Clojure, so they also run on JVM Clojure for an absolute reference.

Benchmarks

Benchmark Axis Pass it exercises Source
binary-trees allocation / GC pressure (escaping short-lived records) jolt-15jq scalar-replace, jolt-8flj escape analysis CLBG
dispatch polymorphic (megamorphic) protocol dispatch jolt-41m devirt, inline-cache AWFY-style
mono-dispatch monomorphic protocol dispatch (devirt/inline-cache can fire) jolt-41m devirt, jolt-ez5h inline-cache AWFY-style
collections persistent map/vector churn (HAMT / 32-way tries) persistent structures (jolt-684u/0hbr), transients CLBG k-nucleotide-style
mandelbrot pure float compute (tight arith loops, no alloc/dispatch) jolt-3pl native arith, loop codegen CLBG
fib recursion: function-call + integer-arith overhead jolt-3pl native arith, jolt-826 small-fn inlining CLBG

What the ray tracer does not capture and these do: allocation as the bottleneck (~7% there), megamorphic and monomorphic dispatch (its dispatch is monomorphic and cheap), persistent-collection throughput (it uses fixed records, no collections in the hot loop), and isolated compute/call overhead.

Planned additions: Richards / DeltaBlue (heavier OO dispatch), NBody (float control with record state), k-nucleotide proper.

Holistic scorecard

JVM=1 bench/run.sh runs each benchmark on jolt and JVM Clojure and prints the jolt/JVM ratio — the epic's (jolt-ffn) absolute-reference scorecard. As of the broadening (2026-06-16), ratios cluster by axis:

  • pure compute (mandelbrot) is the floor, ~15× — native arith (jolt-3pl) already gets jolt closest to the JVM.
  • collections ~28×, fib ~37×.
  • dispatch ~75× (megamorphic), and mono-dispatch is worse (~110×): the JVM inline-caches a runtime-monomorphic call site to near-free, while jolt does a full registry dispatch regardless (devirt only fires on statically proven receivers, which reduce over a vector doesn't give). This is the signal for the call-site inline cache (jolt-ez5h).
  • allocation (binary-trees) is the widest gap — but also the most inflated by host memory pressure, so read it as "alloc is the worst axis," not a precise multiple. Numbers are machine-specific; regenerate with JVM=1 bench/run.sh.

Running

jpm build && export PATH="$PWD/build:$PATH"
bench/run.sh                      # whole-program optimization on (default)
JOLT_WHOLE_PROGRAM=0 bench/run.sh # WP off, to measure what WP buys
bench/run.sh binary-trees 16      # one benchmark, custom size

A/B against a change

To measure a pass, run the suite on main, then on the branch, back to back (same machine, quiet) — the protocol used for test/bench/core-bench.janet and the ray tracer. Each benchmark prints runs: [...] and mean: N ms; compare the means. A pass is worth landing when it moves a benchmark whose axis it targets, even if the ray tracer stays flat.