Hear ye, hear ye: Wastrel and Hoot means REPL!

Which is to say, Wastrel can now make native binaries out of WebAssembly files as produced by the Hoot Scheme toolchain, up to and including a full read-eval-print loop. Like the REPL on the Hoot web page, but instead of requiring a browser, you can just run it on your console. Amazing stuff!

try it at home

First, we need the latest Hoot. Build it from source, then compile a simple REPL:

echo '(import (hoot repl)) (spawn-repl)' > repl.scm
./pre-inst-env hoot compile -fruntime-modules -o repl.wasm repl.scm

This takes about a minute. The resulting wasm file has a pretty full standard library including a full macro expander and evaluator.

Normally Hoot would do some aggressive tree-shaking to discard any definitions not used by the program, but with a REPL we don’t know what we might need. So, we pass -fruntime-modules to instruct Hoot to record all modules and their bindings in a central registry, so they can be looked up at run-time. This results in a 6.6 MB Wasm file; with tree-shaking we would have been at 1.2 MB.

Next, build Wastrel from source, and compile our new repl.wasm:

wastrel compile -o repl repl.wasm

This takes about 5 minutes on my machine: about 3 minutes to generate all the C, about 6.6MLOC all in all, split into a couple hundred files of about 30KLOC each, and then 2 minutes to compile with GCC and link-time optimization (parallelised over 32 cores in my case). I have some ideas to golf the first part down a bit, but the the GCC side will resist improvements.

Finally, the moment of truth:

$ ./repl
Hoot 0.8.0

Enter `,help' for help.
(hoot user)> "hello, world!"
=> "hello, world!"
(hoot user)>

statics

When I first got the REPL working last week, I gasped out loud: it’s alive, it’s alive!!! Now that some days have passed, I am finally able to look a bit more dispassionately at where we’re at.

Firstly, let’s look at the compiled binary itself. By default, Wastrel passes the -g flag to GCC, which results in binaries with embedded debug information. Which is to say, my ./repl is chonky: 180 MB!! Stripped, it’s “just” 33 MB. 92% of that is in the .text (code) section. I would like a smaller binary, but it’s what we got for now: each byte in the Wasm file corresponds to around 5 bytes in the x86-64 instruction stream.

As for dependencies, this is a pretty minimal binary, though dynamically linked to libc:

linux-vdso.so.1 (0x00007f6c19fb0000)
libm.so.6 => /gnu/store/…-glibc-2.41/lib/libm.so.6 (0x00007f6c19eba000)
libgcc_s.so.1 => /gnu/store/…-gcc-15.2.0-lib/lib/libgcc_s.so.1 (0x00007f6c19e8d000)
libc.so.6 => /gnu/store/…-glibc-2.41/lib/libc.so.6 (0x00007f6c19c9f000)
/gnu/store/…-glibc-2.41/lib/ld-linux-x86-64.so.2 (0x00007f6c19fb2000)

Our compiled ./repl includes a garbage collector from Whippet, about which, more in a minute. For now, we just note that our use of Whippet introduces no run-time dependencies.

dynamics

Just running the REPL with WASTREL_PRINT_STATS=1 in the environment, it seems that the REPL has a peak live data size of 4MB or so, but for some reason uses 15 MB total. It takes about 17 ms to start up and then exit.

These numbers I give are consistent over a choice of particular garbage collector implementations: the default --gc=stack-conservative-parallel-generational-mmc, or the non-generational stack-conservative-parallel-mmc, or the Boehm-Demers-Weiser bdw. Benchmarking collectors is a bit gnarly because the dynamic heap growth heuristics aren’t the same between the various collectors; by default, the heap grows to 15 MB or so with all collectors, but whether it chooses to collect or expand the heap in response to allocation affects startup timing. I get the above startup numbers by setting GC_OPTIONS=heap-size=15m,heap-size-policy=fixed in the environment.

Hoot implements Guile Scheme, so we can also benchmark Hoot against Guile. Given the following test program that sums the leaf values for ten thousand quad trees of height 5:

(define (quads depth)
  (if (zero? depth)
      1
      (vector (quads (- depth 1))
              (quads (- depth 1))
              (quads (- depth 1))
              (quads (- depth 1)))))
(define (sum-quad q)
  (if (vector? q)
      (+ (sum-quad (vector-ref q 0))
         (sum-quad (vector-ref q 1))
         (sum-quad (vector-ref q 2))
         (sum-quad (vector-ref q 3)))
      q))

(define (sum-of-sums n depth)
  (let lp ((n n) (sum 0))
    (if (zero? n)
        sum
        (lp (- n 1)
            (+ sum (sum-quad (quads depth)))))))


(sum-of-sums #e1e4 5)

We can cat it to our repl to see how we do:

Hoot 0.8.0

Enter `,help' for help.
(hoot user)> => 10240000
(hoot user)>
Completed 3 major collections (281 minor).
4445.267 ms total time (84.214 stopped); 4556.235 ms CPU time (189.188 stopped).
0.256 ms median pause time, 0.272 p95, 7.168 max.
Heap size is 28.269 MB (max 28.269 MB); peak live data 9.388 MB.

That is to say, 4.44s, of which 0.084s was spent in garbage collection pauses. The default collector configuration is generational, which can result in some odd heap growth patterns; as it happens, this workload runs fine in a 15MB heap. Pause time as a percentage of total run-time is very low, so all the various GCs perform the same, more or less; we seem to be benchmarking eval more than the GC itself.

Is our Wastrel-compiled repl performance good? Well, we can evaluate it in two ways. Firstly, against Chrome or Firefox, which can run the same program; if I paste in the above program in the REPL over at the Hoot web site, it takes about 5 or 6 times as long to complete, respectively. Wastrel wins!

I can also try this program under Guile itself: if I eval it in Guile, it takes about 3.5s. Granted, Guile’s implementation of the same source language is different, and it benefits from a number of representational tricks, for example using just two words for a pair instead of four on Hoot+Wastrel. But these numbers are in the same ballpark, which is heartening. Compiling the test program instead of interpreting is about 10× faster with both Wastrel and Guile, with a similar relative ratio.

Finally, I should note that Hoot’s binaries are pretty well optimized in many ways, but not in all the ways. Notably, they use too many locals, and the post-pass to fix this is unimplemented, and last time I checked (a long time ago!), wasm-opt didn’t work on our binaries. I should take another look some time.

generational?

This week I dotted all the t’s and crossed all the i’s to emit write barriers when we mutate the value of a field to store a new GC-managed data type, allowing me to enable the sticky mark-bit variant of the Immix-inspired mostly-marking collector. It seems to work fine, though this kind of generational collector still baffles me sometimes.

With all of this, Wastrel’s GC-using binaries use a stack-conservative, parallel, generational collector that can compact the heap as needed. This collector supports multiple concurrent mutator threads, though Wastrel doesn’t do threading yet. Other collectors can be chosen at compile-time, though always-moving collectors are off the table due to not emitting stack maps.

The neat thing is that any language that compiles to Wasm can have any of these collectors! And when the Whippet GC library gets another collector or another mode on an existing collector, you can have that too.

missing pieces

The biggest missing piece for Wastrel and Hoot is some kind of asynchrony, similar to JavaScript Promise Integration (JSPI), and somewhat related to stack switching. You want Wasm programs to be able to wait on external events, and Wastrel doesn’t support that yet.

Other than that, it would be lovely to experiment with Wasm shared-everything threads at some point.

what’s next

So I have an ahead-of-time Wasm compiler. It does GC and lots of neat things. Its performance is state-of-the-art. It implements a few standard libraries, including WASI 0.1 and Hoot. It can make a pretty good standalone Guile REPL. But what the hell is it for?

Friends, I... I don’t know! It’s really cool, but I don’t yet know who needs it. I have a few purposes of my own (pushing Wasm standards, performance work on Whippet, etc), but you or someone you know needs a wastrel, do let me know at wingo@igalia.com: I would love to be able to spend more time hacking in this area.

Until next time, happy compiling to all!

Accessibility

#

When we think of accessibility, we tend to picture it as something designed for a small minority. The reality is much broader: 16% of the world’s population — 1.3 billion people — live with a significant disability¹. In Brazil alone, where I live, that means around 14.4 million people report some form of disability². And those numbers capture only permanent disabilities.

Hello friends! Today, a quick note: the Wastrel ahead-of-time WebAssembly compiler now supports managed memory via garbage collection!

hello, world

The quickest demo I have is that you should check out and build wastrel itself:

git clone https://codeberg.org/andywingo/wastrel
cd wastrel
guix shell
# alternately: sudo apt install guile-3.0 guile-3.0-dev \
#    pkg-config gcc automake autoconf make
autoreconf -vif && ./configure
make -j

Then run a quick check with hello, world:

$ ./pre-inst-env wastrel examples/simple-string.wat
Hello, world!

Now give a check to gcbench, a classic GC micro-benchmark:

$ WASTREL_PRINT_STATS=1 ./pre-inst-env wastrel examples/gcbench.wat
Garbage Collector Test
 Creating long-lived binary tree of depth 16
 Creating a long-lived array of 500000 doubles
Creating 33824 trees of depth 4
	Top-down construction: 10.189 msec
	Bottom-up construction: 8.629 msec
Creating 8256 trees of depth 6
	Top-down construction: 8.075 msec
	Bottom-up construction: 8.754 msec
Creating 2052 trees of depth 8
	Top-down construction: 7.980 msec
	Bottom-up construction: 8.030 msec
Creating 512 trees of depth 10
	Top-down construction: 7.719 msec
	Bottom-up construction: 9.631 msec
Creating 128 trees of depth 12
	Top-down construction: 11.084 msec
	Bottom-up construction: 9.315 msec
Creating 32 trees of depth 14
	Top-down construction: 9.023 msec
	Bottom-up construction: 20.670 msec
Creating 8 trees of depth 16
	Top-down construction: 9.212 msec
	Bottom-up construction: 9.002 msec
Completed 32 major collections (0 minor).
138.673 ms total time (12.603 stopped); 209.372 ms CPU time (83.327 stopped).
0.368 ms median pause time, 0.512 p95, 0.800 max.
Heap size is 26.739 MB (max 26.739 MB); peak live data 5.548 MB.

We set WASTREL_PRINT_STATS=1 to get those last 4 lines. So, this is a microbenchmark: it runs for only 138 ms, and the heap is tiny (26.7 MB). It does collect 30 times, which is something.

is it good?

I know what you are thinking: OK, it’s a microbenchmark, but can it tell us anything about how Wastrel compares to V8? Well, probably so:

$ guix shell node time -- \
   time node js-runtime/run.js -- \
     js-runtime/wtf8.wasm examples/gcbench.wasm
Garbage Collector Test
[... some output elided ...]
total_heap_size: 48082944
[...]
0.23user 0.03system 0:00.20elapsed 128%CPU (0avgtext+0avgdata 87844maxresident)k
0inputs+0outputs (0major+13325minor)pagefaults 0swaps

Which is to say, V8 takes more CPU time (230ms vs 209ms) and more wall-clock time (200ms vs 138ms). Also it uses twice as much managed memory (48 MB vs 26.7 MB), and more than that for the total process (88 MB vs 34 MB, not shown).

improving on v8, really?

Let’s try with quads, which at least has a larger active heap size. This time we’ll compile a binary and then run it:

$ ./pre-inst-env wastrel compile -o quads examples/quads.wat
$ WASTREL_PRINT_STATS=1 guix shell time -- time ./quads 
Making quad tree of depth 10 (1398101 nodes).
	construction: 23.274 msec
Allocating garbage tree of depth 9 (349525 nodes), 60 times, validating live tree each time.
	allocation loop: 826.310 msec
	quads test: 860.018 msec
Completed 26 major collections (0 minor).
848.825 ms total time (85.533 stopped); 1349.199 ms CPU time (585.936 stopped).
3.456 ms median pause time, 3.840 p95, 5.888 max.
Heap size is 133.333 MB (max 133.333 MB); peak live data 82.416 MB.
1.35user 0.01system 0:00.86elapsed 157%CPU (0avgtext+0avgdata 141496maxresident)k
0inputs+0outputs (0major+231minor)pagefaults 0swaps

Compare to V8 via node:

$ guix shell node time -- time node js-runtime/run.js -- js-runtime/wtf8.wasm examples/quads.wasm
Making quad tree of depth 10 (1398101 nodes).
	construction: 64.524 msec
Allocating garbage tree of depth 9 (349525 nodes), 60 times, validating live tree each time.
	allocation loop: 2288.092 msec
	quads test: 2394.361 msec
total_heap_size: 156798976
[...]
3.74user 0.24system 0:02.46elapsed 161%CPU (0avgtext+0avgdata 382992maxresident)k
0inputs+0outputs (0major+87866minor)pagefaults 0swaps

Which is to say, wastrel is almost three times as fast, while using almost three times less memory: 2460ms (v8) vs 849ms (wastrel), and 383MB vs 141 MB.

zowee!

So, yes, the V8 times include the time to compile the wasm module on the fly. No idea what is going on with tiering, either, but I understand that tiering up is a thing these days; this is node v22.14, released about a year ago, for what that’s worth. Also, there is a V8-specific module to do some impedance-matching with regards to strings; in Wastrel they are WTF-8 byte arrays, whereas in Node they are JS strings. But it’s not a string benchmark, so I doubt that’s a significant factor.

I think the performance edge comes in having the program ahead-of-time: you can statically allocate type checks, statically allocate object shapes, and the compiler can see through it all. But I don’t really know yet, as I just got everything working this week.

Wastrel with GC is demo-quality, thus far. If you’re interested in the back-story and the making-of, see my intro to Wastrel article from October, or the FOSDEM talk from last week:

Slides here, if that’s your thing.

More to share on this next week, but for now I just wanted to get the word out. Happy hacking and have a nice weekend!

Hey hey happy new year, friends! Today I was going over some V8 code that touched pre-tenuring: allocating objects directly in the old space instead of the nursery. I knew the theory here but I had never looked into the mechanism. Today’s post is a quick overview of how it’s done.

allocation sites

In a JavaScript program, there are a number of source code locations that allocate. Statistically speaking, any given allocation is likely to be short-lived, so generational garbage collection partitions freshly-allocated objects into their own space. In that way, when the system runs out of memory, it can preferentially reclaim memory from the nursery space instead of groveling over the whole heap.

But you know what they say: there are lies, damn lies, and statistics. Some programs are outliers, allocating objects in such a way that they don’t die young, or at least not young enough. In those cases, allocating into the nursery is just overhead, because minor collection won’t reclaim much memory (because too many objects survive), and because of useless copying as the object is scavenged within the nursery or promoted into the old generation. It would have been better to eagerly tenure such allocations into the old generation in the first place. (The more I think about it, the funnier pre-tenuring is as a term; what if some PhD programs could pre-allocate their graduates into named chairs? Is going straight to industry the equivalent of dying young? Does collaborating on a paper with a full professor imply a write barrier? But I digress.)

Among the set of allocation sites in a program, a subset should pre-tenure their objects. How can we know which ones? There is a literature of static techniques, but this is JavaScript, so the answer in general is dynamic: we should observe how many objects survive collection, organized by allocation site, then optimize to assume that the future will be like the past, falling back to a general path if the assumptions fail to hold.

my runtime doth object

The high-level overview of how V8 implements pre-tenuring is based on per-program-point AllocationSite objects, and per-allocation AllocationMemento objects that point back to their corresponding AllocationSite. Initially, V8 doesn’t know what program points would profit from pre-tenuring, and instead allocates everything in the nursery. Here’s a quick picture:

Here we show that there are two allocation sites, Site1 and Site2. V8 is currently allocating into a linear allocation buffer (LAB) in the nursery, and has allocated three objects. After each of these objects is an AllocationMemento; in this example, M1 and M3 are AllocationMemento objects that point to Site1 and M2 points to Site2. When V8 allocates an object, it increments the “created” counter on the corresponding AllocationSite (if available; it’s possible an allocation comes from C++ or something where we don’t have an AllocationSite).

When the free space in the LAB is too small for an allocation, V8 gets another LAB, or collects if there are no more LABs in the nursery. When V8 does a minor collection, as the scavenger visits objects, it will look to see if the object is followed by an AllocationMemento. If so, it dereferences the memento to find the AllocationSite, then increments its “found” counter, and adds the AllocationSite to a set. Once an AllocationSite has had 100 allocations, it is enqueued for a pre-tenuring decision; sites with 85% survival get marked for pre-tenuring.

If an allocation site is marked as needing pre-tenuring, the code in which it is embedded it will get de-optimized, and then next time it is optimized, the code generator arranges to allocate into the old generation instead of the default nursery.

Finally, if a major collection collects more than 90% of the old generation, V8 resets all pre-tenured allocation sites, under the assumption that pre-tenuring was actually premature.

tenure for me but not for thee

What kinds of allocation sites are eligible for pre-tenuring? Sometimes it depends on object kind; wasm memories, for example, are almost always long-lived, so they are always pre-tenured. Sometimes it depends on who is doing the allocation; allocations from the bootstrapper, literals allocated by the parser, and many allocations from C++ go straight to the old generation. And sometimes the compiler has enough information to determine that pre-tenuring might be a good idea, as when it generates a store of a fresh object to a field in an known-old object.

But otherwise I thought that the whole AllocationSite mechanism would apply generally, to any object creation. It turns out, nope: it seems to only apply to object literals, array literals, and new Array. Weird, right? I guess it makes sense in that these are the ways to create objects that also creates the field values at creation-time, allowing the whole block to be allocated to the same space. If instead you make a pre-tenured object and then initialize it via a sequence of stores, this would likely create old-to-new edges, preventing the new objects from dying young while incurring the penalty of copying and write barriers. Still, I think there is probably some juice to squeeze here for pre-tenuring of class-style allocations, at least in the optimizing compiler or in short inline caches.

I suspect this state of affairs is somewhat historical, as the AllocationSite mechanism seems to have originated with typed array storage strategies and V8’s “boilerplate” object literal allocators; both of these predate per-AllocationSite pre-tenuring decisions.

fin

Well that’s adaptive pre-tenuring in V8! I thought the “just stick a memento after the object” approach is pleasantly simple, and if you are only bumping creation counters from baseline compilation tiers, it likely amortizes out to a win. But does the restricted application to literals point to a fundamental constraint, or is it just accident? If you have any insight, let me know :) Until then, happy hacking!