| Commit message (Collapse) | Author | Age | Files | Lines |
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* YJIT: Introduce Target::SideExit
* YJIT: Obviate Insn::SideExitContext
* YJIT: Avoid cloning a Context for each insn
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We crashed in some edge cases due to the recent change to not compile
encoded iseqs that are larger than `u16::MAX`.
- Match the C signature of rb_yjit_constant_ic_update() and clamp down
to `IseqIdx` size
- Return failure instead of panicking with `unwrap()` in codegen when
the iseq is too large
Co-authored-by: Maxime Chevalier-Boisvert <maxime.chevalierboisvert@shopify.com>
Co-authored-by: Noah Gibbs <noah.gibbs@shopify.com>
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It was useful for evaluating 6068da8937d7e4358943f95e7450dae7179a7763
but I think we should remove it now to make the logic around
invalidation more straight forward.
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`Rc` and `RefCell` both incur runtime space costs.
In addition, `RefCell` has given us some headaches with the
non obvious borrow panics it likes to throw out. The latest
one started with 7fd53eeb46db261bbc20025cdab70096245a5cbe
and is yet to be resolved.
Since we already rely on the GC to properly reclaim memory for `Block`
and `Branch`, we might as well stop paying the overhead of `Rc` and
`RefCell`. The `RefCell` panics go away with this change, too.
On 25 iterations of `railsbench` with a stats build I got
`yjit_alloc_size: 8,386,129 => 7,348,637`, with the new memory size 87.6%
of the status quo. This makes the metadata and machine code size roughly
line up one-to-one.
The general idea here is to use `&` shared references with
[interior mutability][1] with `Cell`, which doesn't take any extra
space. The `noalias` requirement that `&mut` imposes is way too hard to
meet and verify. Imagine replacing places where we would've gotten
`BorrowError` from `RefCell` with Rust/LLVM miscompiling us due to aliasing
violations. With shared references, we don't have to think about subtle
cases like the GC _sometimes_ calling the mark callback while codegen
has an aliasing reference in a stack frame below. We mostly only need to
worry about liveness, with which the GC already helps.
There is now a clean split between blocks and branches that are not yet
fully constructed and ones that are "in-service", so to speak. Working
with `PendingBranch` and `JITState` don't really involve `unsafe` stuff.
This change allows `Branch` and `Block` to not have as many optional
fields as many of them are only optional during compilation. Fields that
change post-compilation are wrapped in `Cell` to facilitate mutation
through shared references.
I do some `unsafe` dances here. I've included just a couple tests to run
with Miri (`cargo +nightly miri test miri`). We can add more Miri tests
if desired.
[1]: https://doc.rust-lang.org/std/cell/struct.UnsafeCell.html
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The code and comments in there have been disabled by comments for a long
time. The issues that the counter used to solve are now solved more
comprehensively by "runningness" [tracking][1] introduced by Code GC
and [delayed deallocation][2].
Having a single counter doesn't fit our current model where code pages
that could be touched or not are interleaved, anyway.
Just delete the code.
[1]: e7c71c6c9271b0c29f210769159090e17128e740
[2]: a0b0365e905e1ac51998ace7e6fc723406a2f157
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YJIT: Use a boxed slice for outgoing branches
and cme dependencies
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* Add job to check clippy lints in CI
* Address all remaining clippy lints
* Check lints on arm64 as well
* Apply latest clippy lints
* Do not exit 0 on clippy warnings
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Previously we essentially never freed block even after invalidation.
Their reference count never reached zero for a couple of reasons:
1. `Branch::block` formed a cycle with the block holding the branch
2. Strong count on a branch that has ever contained a stub never
reached 0 because we increment the `.clone()` call for
`BranchRef::into_raw()` didn't have a matching decrement.
It's not safe to immediately deallocate blocks during
invalidation since `branch_stub_hit()` can end up
running with a branch pointer from an invalidated branch.
To plug the leaks, we wait until code GC or global invalidation and
deallocate the blocks for iseqs that are definitely not running.
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When we run global invalidation for TracePoints or code GC, we clear out
all blocks in our assumptions table but we don't deallocate the backing
buffers. Let's reclaim some memory during these rare events.
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YJIT: Skip padding jumps to side exits
Co-authored-by: Maxime Chevalier-Boisvert <maxime.chevalierboisvert@shopify.com>
Co-authored-by: Alan Wu <alansi.xingwu@shopify.com>
Co-authored-by: Maxime Chevalier-Boisvert <maxime.chevalierboisvert@shopify.com>
Co-authored-by: Alan Wu <alansi.xingwu@shopify.com>
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* YJIT: Stop wrapping CmePtr with CmeDependency
* YJIT: Fix an outdated comment [ci skip]
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Co-authored-by: Alan Wu <alansi.xingwu@shopify.com>
Co-authored-by: Alan Wu <alansi.xingwu@shopify.com>
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We switch to a new page when we detect dropped_bytes flipping from false
to true. Previously, when we patch code for invalidation during code gc,
we start with the flag being set to true, so we failed to apply patches
that straddle pages. We would write out jumps half way and then stop,
which left the code corrupted.
Reset the flag before patching so we patch across pages properly.
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* YJIT: Count freed ISEQs
* YJIT: Avoid creating payloads for non-JITed ISEQs
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* Add rb_callable_method_entry_or_negative
* YJIT: Implement specialized respond_to?
This implements a specialized respond_to? in YJIT.
* Update yjit/src/codegen.rs
Co-authored-by: Maxime Chevalier-Boisvert <maximechevalierb@gmail.com>
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Previously YARV bytecode implemented constant caching by having a pair
of instructions, opt_getinlinecache and opt_setinlinecache, wrapping a
series of getconstant calls (with putobject providing supporting
arguments).
This commit replaces that pattern with a new instruction,
opt_getconstant_path, handling both getting/setting the inline cache and
fetching the constant on a cache miss.
This is implemented by storing the full constant path as a
null-terminated array of IDs inside of the IC structure. idNULL is used
to signal an absolute constant reference.
$ ./miniruby --dump=insns -e '::Foo::Bar::Baz'
== disasm: #<ISeq:<main>@-e:1 (1,0)-(1,13)> (catch: FALSE)
0000 opt_getconstant_path <ic:0 ::Foo::Bar::Baz> ( 1)[Li]
0002 leave
The motivation for this is that we had increasingly found the need to
disassemble the instructions between the opt_getinlinecache and
opt_setinlinecache in order to determine the constant we are fetching,
or otherwise store metadata.
This disassembly was done:
* In opt_setinlinecache, to register the IC against the constant names
it is using for granular invalidation.
* In rb_iseq_free, to unregister the IC from the invalidation table.
* In YJIT to find the position of a opt_getinlinecache instruction to
invalidate it when the cache is populated
* In YJIT to register the constant names being used for invalidation.
With this change we no longe need disassemly for these (in fact
rb_iseq_each is now unused), as the list of constant names being
referenced is held in the IC. This should also make it possible to make
more optimizations in the future.
This may also reduce the size of iseqs, as previously each segment
required 32 bytes (on 64-bit platforms) for each constant segment. This
implementation only stores one ID per-segment.
There should be no significant performance change between this and the
previous implementation. Previously opt_getinlinecache was a "leaf"
instruction, but it included a jump (almost always to a separate cache
line). Now opt_getconstant_path is a non-leaf (it may
raise/autoload/call const_missing) but it does not jump. These seem to
even out.
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Previously, we patched in an x64 JMP even on A64, which resulted in
invalid machine code. Use the new assembler to generate a jump instead.
Add an assert to make sure patches don't step on each other since it's
less clear cut on A64, where the size of the jump varies depending on
its placement relative to the target.
Fixes a lot of tests that use `set_trace_func` in `test_insns.rb`.
PR: https://github.com/Shopify/ruby/pull/379
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When running with `--yjit-stats` turned on, yjit can inform the user
what the most common exits are. While this is useful information it
doesn't tell you the source location of the code that exited or what the
code that exited looks like. This change intends to fix that.
To use the feature, run yjit with the `--yjit-trace-exits` option,
which will record the backtrace for every exit that occurs. This functionality
requires the stats feature to be turned on. Calling `--yjit-trace-exits`
will automatically set the `--yjit-stats` option.
Users must call `RubyVM::YJIT.dump_exit_locations(filename)` which will
Marshal dump the contents of `RubyVM::YJIT.exit_locations` into a file
based on the passed filename.
*Example usage:*
Given the following script, we write to a file called
`concat_array.dump` the results of `RubyVM::YJIT.exit_locations`.
```ruby
def concat_array
["t", "r", *x = "u", "e"].join
end
1000.times do
concat_array
end
RubyVM::YJIT.dump_exit_locations("concat_array.dump")
```
When we run the file with this branch and the appropriate flags the
stacktrace will be recorded. Note Stackprof needs to be installed or you
need to point to the library directly.
```
./ruby --yjit --yjit-call-threshold=1 --yjit-trace-exits -I/Users/eileencodes/open_source/stackprof/lib test.rb
```
We can then read the dump file with Stackprof:
```
./ruby -I/Users/eileencodes/open_source/stackprof/lib/ /Users/eileencodes/open_source/stackprof/bin/stackprof --text concat_array.dump
```
Results will look similar to the following:
```
==================================
Mode: ()
Samples: 1817 (0.00% miss rate)
GC: 0 (0.00%)
==================================
TOTAL (pct) SAMPLES (pct) FRAME
1001 (55.1%) 1001 (55.1%) concatarray
335 (18.4%) 335 (18.4%) invokeblock
178 (9.8%) 178 (9.8%) send
140 (7.7%) 140 (7.7%) opt_getinlinecache
...etc...
```
Simply inspecting the `concatarray` method will give `SOURCE
UNAVAILABLE` because the source is insns.def.
```
./ruby -I/Users/eileencodes/open_source/stackprof/lib/ /Users/eileencodes/open_source/stackprof/bin/stackprof --text concat_array.dump --method concatarray
```
Result:
```
concatarray (nonexistent.def:1)
samples: 1001 self (55.1%) / 1001 total (55.1%)
callers:
1000 ( 99.9%) Object#concat_array
1 ( 0.1%) Gem.suffixes
callees (0 total):
code:
SOURCE UNAVAILABLE
```
However if we go deeper to the callee we can see the exact
source of the `concatarray` exit.
```
./ruby -I/Users/eileencodes/open_source/stackprof/lib/ /Users/eileencodes/open_source/stackprof/bin/stackprof --text concat_array.dump --method Object#concat_array
```
```
Object#concat_array (/Users/eileencodes/open_source/rust_ruby/test.rb:1)
samples: 0 self (0.0%) / 1000 total (55.0%)
callers:
1000 ( 100.0%) block in <main>
callees (1000 total):
1000 ( 100.0%) concatarray
code:
| 1 | def concat_array
1000 (55.0%) | 2 | ["t", "r", *x = "u", "e"].join
| 3 | end
```
The `--walk` option is recommended for this feature as it make it
easier to traverse the tree of exits.
*Goals of this feature:*
This feature is meant to give more information when working on YJIT.
The idea is that if we know what code is exiting we can decide what
areas to prioritize when fixing exits. In some cases this means adding
prioritizing avoiding certain exits in yjit. In more complex cases it
might mean changing the Ruby code to be more performant when run with
yjit. Ultimately the more information we have about what code is exiting
AND why, the better we can make yjit.
*Known limitations:*
* Due to tracing exits, running this on large codebases like Rails
can be quite slow.
* On complex methods it can still be difficult to pinpoint the exact cause of
an exit.
* Stackprof is a requirement to to view the backtrace information from
the dump file.
Co-authored-by: Aaron Patterson <tenderlove@ruby-lang.org>
Co-authored-by: Aaron Patterson <tenderlove@ruby-lang.org>
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Constants that can't be imported via bindgen should have
a comment saying why not.
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This adopts most suggestions that rust-clippy is confident enough to
auto apply. The manual changes mostly fix manual if-lets and take
opportunities to use the `Default` trait on standard collections.
Co-authored-by: Kevin Newton <kddnewton@gmail.com>
Co-authored-by: Maxime Chevalier-Boisvert <maxime.chevalierboisvert@shopify.com>
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In December 2021, we opened an [issue] to solicit feedback regarding the
porting of the YJIT codebase from C99 to Rust. There were some
reservations, but this project was given the go ahead by Ruby core
developers and Matz. Since then, we have successfully completed the port
of YJIT to Rust.
The new Rust version of YJIT has reached parity with the C version, in
that it passes all the CRuby tests, is able to run all of the YJIT
benchmarks, and performs similarly to the C version (because it works
the same way and largely generates the same machine code). We've even
incorporated some design improvements, such as a more fine-grained
constant invalidation mechanism which we expect will make a big
difference in Ruby on Rails applications.
Because we want to be careful, YJIT is guarded behind a configure
option:
```shell
./configure --enable-yjit # Build YJIT in release mode
./configure --enable-yjit=dev # Build YJIT in dev/debug mode
```
By default, YJIT does not get compiled and cargo/rustc is not required.
If YJIT is built in dev mode, then `cargo` is used to fetch development
dependencies, but when building in release, `cargo` is not required,
only `rustc`. At the moment YJIT requires Rust 1.60.0 or newer.
The YJIT command-line options remain mostly unchanged, and more details
about the build process are documented in `doc/yjit/yjit.md`.
The CI tests have been updated and do not take any more resources than
before.
The development history of the Rust port is available at the following
commit for interested parties:
https://github.com/Shopify/ruby/commit/1fd9573d8b4b65219f1c2407f30a0a60e537f8be
Our hope is that Rust YJIT will be compiled and included as a part of
system packages and compiled binaries of the Ruby 3.2 release. We do not
anticipate any major problems as Rust is well supported on every
platform which YJIT supports, but to make sure that this process works
smoothly, we would like to reach out to those who take care of building
systems packages before the 3.2 release is shipped and resolve any
issues that may come up.
[issue]: https://bugs.ruby-lang.org/issues/18481
Co-authored-by: Maxime Chevalier-Boisvert <maximechevalierb@gmail.com>
Co-authored-by: Noah Gibbs <the.codefolio.guy@gmail.com>
Co-authored-by: Kevin Newton <kddnewton@gmail.com>
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