Fix indentation in vm_setivar_default
---
vm_insnhelper.c | 6 +++---
1 file changed, 3 insertions(+), 3 deletions(-)
[Bug #19469] Fix crash when resizing generic iv list
The following script can sometimes trigger a crash:
```ruby
GC.stress = true
class Array
def foo(bool)
if bool
@a = 1
@b = 2
@c = 1
else
@c = 1
end
end
end
obj = []
obj.foo(true)
obj2 = []
obj2.foo(false)
obj3 = []
obj3.foo(true)
```
This is because vm_setivar_default calls rb_ensure_generic_iv_list_size
to resize the iv list. However, the call to gen_ivtbl_resize reallocs
the iv list, and then inserts into the generic iv table. If the
st_insert triggers a GC then the old iv list will be read during
marking, causing a use-after-free bug.
Co-Authored-By: Jemma Issroff <jemmaissroff@gmail.com>
---
internal/variable.h | 2 +-
variable.c | 23 ++++++++++++++++++-----
vm_insnhelper.c | 4 ++--
3 files changed, 21 insertions(+), 8 deletions(-)
Avoid checking interrupt when loading iseq
MIME-Version: 1.0
Content-Type: text/plain; charset=UTF-8
Content-Transfer-Encoding: 8bit
The interrupt check will unintentionally release the VM lock when loading an iseq.
And this will cause issues with the `debug` gem's
[`ObjectSpace.each_iseq` method](0fcfc28aca/ext/debug/iseq_collector.c (L61-L67)),
which wraps iseqs with a wrapper and exposes their internal states when they're actually not ready to be used.
And when that happens, errors like this would occur and kill the `debug` gem's thread:
```
DEBUGGER: ReaderThreadError: uninitialized InstructionSequence
┃ DEBUGGER: Disconnected.
┃ ["/opt/rubies/ruby-3.2.0/lib/ruby/gems/3.2.0/gems/debug-1.7.1/lib/debug/breakpoint.rb:247:in `absolute_path'",
┃ "/opt/rubies/ruby-3.2.0/lib/ruby/gems/3.2.0/gems/debug-1.7.1/lib/debug/breakpoint.rb:247:in `block in iterate_iseq'",
┃ "/opt/rubies/ruby-3.2.0/lib/ruby/gems/3.2.0/gems/debug-1.7.1/lib/debug/breakpoint.rb:246:in `each_iseq'",
...
```
A way to reproduce the issue is to satisfy these conditions at the same time:
1. `debug` gem calling `ObjectSpace.each_iseq` (e.g. [activating a `LineBreakpoint`](0fcfc28aca/lib/debug/breakpoint.rb (L246))).
2. A large amount of iseq being loaded from another thread (possibly through the `bootsnap` gem).
3. 1 and 2 iterating through the same iseq(s) at the same time.
Because this issue requires external dependencies and a rather complicated timing setup to reproduce, I wasn't able to write a test case for it.
But here's some pseudo code to help reproduce it:
```rb
require "debug/session"
Thread.new do
100.times do
ObjectSpace.each_iseq do |iseq|
iseq.absolute_path
end
end
end
sleep 0.1
load_a_bunch_of_iseq
possibly_through_bootsnap
```
[Bug #19348]
Co-authored-by: Peter Zhu <peter@peterzhu.ca>
---
compile.c | 2 +-
vm_core.h | 1 +
vm_insnhelper.c | 11 +++++++++++
3 files changed, 13 insertions(+), 1 deletion(-)
I noticed this while running test_yjit with --mjit-call-threshold=1,
which redefines `Integer#<`. When Ruby is monkey-patched,
MJIT itself could be broken.
Similarly, Ruby scripts could break MJIT in many different ways. I
prepared the same set of hooks as YJIT so that we could possibly
override it and disable it on those moments. Every constant under
RubyVM::MJIT is private and thus it's an unsupported behavior though.
When an object becomes "too complex" (in other words it has too many
variations in the shape tree), we transition it to use a "too complex"
shape and use a hash for storing instance variables.
Without this patch, there were rare cases where shape tree growth could
"explode" and cause performance degradation on what would otherwise have
been cached fast paths.
This patch puts a limit on shape tree growth, and gracefully degrades in
the rare case where there could be a factorial growth in the shape tree.
For example:
```ruby
class NG; end
HUGE_NUMBER.times do
NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1)
end
```
We consider objects to be "too complex" when the object's class has more
than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and
the object introduces a new variation (a new leaf node) associated with
that class.
For example, new variations on instances of the following class would be
considered "too complex" because those instances create more than 8
leaves in the shape tree:
```ruby
class Foo; end
9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) }
```
However, the following class is *not* too complex because it only has
one leaf in the shape tree:
```ruby
class Foo
def initialize
@a = @b = @c = @d = @e = @f = @g = @h = @i = nil
end
end
9.times { Foo.new }
``
This case is rare, so we don't expect this change to impact performance
of most applications, but it needs to be handled.
Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
Since edc7af48ac, we now no longer have
undef ivar transitions. Instead, we rebuild the shapes table. When we do
this, we need to ensure that we retain our capacities on shapes.
* YJIT: implement getconstant YARV instruction
* Constant id is not a pointer
* Stack operands must be read after jit_prepare_routine_call
Co-authored-by: Takashi Kokubun <takashikkbn@gmail.com>
Cases like this:
```ruby
obj = Object.new
loop do
obj.instance_variable_set(:@foo, 1)
obj.remove_instance_variable(:@foo)
end
```
can cause us to use many more shapes than we want (and even run out).
This commit changes the code such that when an instance variable is
removed, we'll walk up the shape tree, find the shape, then rebuild any
child nodes that happened to be below the "targetted for removal" IV.
This also requires moving any instance variables so that indexes derived
from the shape tree will work correctly.
Co-Authored-By: Jemma Issroff <jemmaissroff@gmail.com>
Co-authored-by: John Hawthorn <jhawthorn@github.com>
Prior to this commit the `OPTIMIZED_CMP` macro relied on a method lookup
to determine whether `<=>` was overridden. The result of the lookup was
cached, but only for the duration of the specific method that
initialized the cmp_opt_data cache structure.
With this method lookup, `[x,y].max` is slower than doing `x > y ?
x : y` even though there's an optimized instruction for "new array max".
(John noticed somebody a proposed micro-optimization based on this fact
in https://github.com/mastodon/mastodon/pull/19903.)
```rb
a, b = 1, 2
Benchmark.ips do |bm|
bm.report('conditional') { a > b ? a : b }
bm.report('method') { [a, b].max }
bm.compare!
end
```
Before:
```
Comparison:
conditional: 22603733.2 i/s
method: 19820412.7 i/s - 1.14x (± 0.00) slower
```
This commit replaces the method lookup with a new CMP basic op, which
gives the examples above equivalent performance.
After:
```
Comparison:
method: 24022466.5 i/s
conditional: 23851094.2 i/s - same-ish: difference falls within
error
```
Relevant benchmarks show an improvement to Array#max and Array#min when
not using the optimized newarray_max instruction as well. They are
noticeably faster for small arrays with the relevant types, and the same
or maybe a touch faster on larger arrays.
```
$ make benchmark COMPARE_RUBY=<master@5958c305> ITEM=array_min
$ make benchmark COMPARE_RUBY=<master@5958c305> ITEM=array_max
```
The benchmarks added in this commit also look generally improved.
Co-authored-by: John Hawthorn <jhawthorn@github.com>
We can loosely predict the number of ivar sets on a class based on the
number of iv set instructions in the initialize method. This should give
us a more accurate estimate to use for initial size pool allocation,
which should in turn give us more cache hits.
obj_ivar_set and vm_setivar_slowpath is essentially doing the same thing,
but the code is duplicated and not quite implemented in the same way,
which could cause bugs. This commit refactors vm_setivar_slowpath to use
obj_ivar_set.
Since object shapes store the capacity of an object, we no longer
need the numiv field on RObjects. This gives us one extra slot which
we can use to give embedded objects one more instance variable (for a
total of 3 ivs). This commit removes the concept of numiv from RObject.
This commit adds a `capacity` field to shapes, and adds shape
transitions whenever an object's capacity changes. Objects which are
allocated out of a bigger size pool will also make a transition from the
root shape to the shape with the correct capacity for their size pool
when they are allocated.
This commit will allow us to remove numiv from objects completely, and
will also mean we can guarantee that if two objects share shapes, their
IVs are in the same positions (an embedded and extended object cannot
share shapes). This will enable us to implement ivar sets in YJIT using
object shapes.
Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
* Avoid RCLASS_IV_TBL in marshal.c
* Avoid RCLASS_IV_TBL for class names
* Avoid RCLASS_IV_TBL for autoload
* Avoid RCLASS_IV_TBL for class variables
* Avoid copying RCLASS_IV_TBL onto ICLASSes
* Use object shapes for Class and Module IVs
This patch pushes dummy frames when loading code for the
profiling purpose.
The following methods push a dummy frame:
* `Kernel#require`
* `Kernel#load`
* `RubyVM::InstructionSequence.compile_file`
* `RubyVM::InstructionSequence.load_from_binary`
https://bugs.ruby-lang.org/issues/18559
Shapes provides us with an (almost) exact count of instance variables.
We only need to check for Qundef when an IV has been "undefined"
Prefer to use ROBJECT_IV_COUNT when iterating IVs
The inline cache is initialized by vm_cc_attr_index_set only when
vm_cc_markable(cc). However, vm_getivar attempted to read the cache
even if the cc is not vm_cc_markable.
This caused a condition that depends on uninitialized value.
Here is an output of valgrind:
```
==10483== Conditional jump or move depends on uninitialised value(s)
==10483== at 0x4C1D60: vm_getivar (vm_insnhelper.c:1171)
==10483== by 0x4C1D60: vm_call_ivar (vm_insnhelper.c:3257)
==10483== by 0x4E8E48: vm_call_symbol (vm_insnhelper.c:3481)
==10483== by 0x4EAD8C: vm_sendish (vm_insnhelper.c:5035)
==10483== by 0x4C62B2: vm_exec_core (insns.def:820)
==10483== by 0x4DD519: rb_vm_exec (vm.c:0)
==10483== by 0x4F00B3: invoke_block (vm.c:1417)
==10483== by 0x4F00B3: invoke_iseq_block_from_c (vm.c:1473)
==10483== by 0x4F00B3: invoke_block_from_c_bh (vm.c:1491)
==10483== by 0x4D42B6: rb_yield (vm_eval.c:0)
==10483== by 0x259128: rb_ary_each (array.c:2733)
==10483== by 0x4E8730: vm_call_cfunc_with_frame (vm_insnhelper.c:3227)
==10483== by 0x4EAD8C: vm_sendish (vm_insnhelper.c:5035)
==10483== by 0x4C6254: vm_exec_core (insns.def:801)
==10483== by 0x4DD519: rb_vm_exec (vm.c:0)
==10483==
```
In fact, the CI on FreeBSD 12 started failing since ad63b668e2.
```
gmake[1]: Entering directory '/usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby'
/usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:924:in `complete': undefined method `complete' for nil:NilClass (NoMethodError)
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1816:in `block in visit'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1815:in `reverse_each'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1815:in `visit'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1847:in `block in complete'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1846:in `catch'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1846:in `complete'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1640:in `block in parse_in_order'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1632:in `catch'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1632:in `parse_in_order'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1626:in `order!'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1732:in `permute!'
from /usr/home/chkbuild/chkbuild/tmp/build/20221011T163003Z/ruby/lib/optparse.rb:1757:in `parse!'
from ./ext/extmk.rb:359:in `parse_args'
from ./ext/extmk.rb:396:in `<main>'
```
This change adds a guard to read the cache only when vm_cc_markable(cc).
It might be better to initialize the cache as INVALID_SHAPE_ID when the
cc is not vm_cc_markable.
Prior to this commit, we were reading and writing ivar index and
shape ID in inline caches in two separate instructions when
getting and setting ivars. This meant there was a race condition
with ractors and these caches where one ractor could change
a value in the cache while another was still reading from it.
This commit instead reads and writes shape ID and ivar index to
inline caches atomically so there is no longer a race condition.
Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
Co-Authored-By: John Hawthorn <john@hawthorn.email>
Before d594a5a8bd, we were only
asserting that the value on an ivar_get was ractor_sharable if the
object was a T_OBJECT and also ractor shareable. We should still
be doing this check only if the object is a T_OBJECT and ractor
shareable
Object Shapes is used for accessing instance variables and representing the
"frozenness" of objects. Object instances have a "shape" and the shape
represents some attributes of the object (currently which instance variables are
set and the "frozenness"). Shapes form a tree data structure, and when a new
instance variable is set on an object, that object "transitions" to a new shape
in the shape tree. Each shape has an ID that is used for caching. The shape
structure is independent of class, so objects of different types can have the
same shape.
For example:
```ruby
class Foo
def initialize
# Starts with shape id 0
@a = 1 # transitions to shape id 1
@b = 1 # transitions to shape id 2
end
end
class Bar
def initialize
# Starts with shape id 0
@a = 1 # transitions to shape id 1
@b = 1 # transitions to shape id 2
end
end
foo = Foo.new # `foo` has shape id 2
bar = Bar.new # `bar` has shape id 2
```
Both `foo` and `bar` instances have the same shape because they both set
instance variables of the same name in the same order.
This technique can help to improve inline cache hits as well as generate more
efficient machine code in JIT compilers.
This commit also adds some methods for debugging shapes on objects. See
`RubyVM::Shape` for more details.
For more context on Object Shapes, see [Feature: #18776]
Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
Co-Authored-By: Eileen M. Uchitelle <eileencodes@gmail.com>
Co-Authored-By: John Hawthorn <john@hawthorn.email>
Object Shapes is used for accessing instance variables and representing the
"frozenness" of objects. Object instances have a "shape" and the shape
represents some attributes of the object (currently which instance variables are
set and the "frozenness"). Shapes form a tree data structure, and when a new
instance variable is set on an object, that object "transitions" to a new shape
in the shape tree. Each shape has an ID that is used for caching. The shape
structure is independent of class, so objects of different types can have the
same shape.
For example:
```ruby
class Foo
def initialize
# Starts with shape id 0
@a = 1 # transitions to shape id 1
@b = 1 # transitions to shape id 2
end
end
class Bar
def initialize
# Starts with shape id 0
@a = 1 # transitions to shape id 1
@b = 1 # transitions to shape id 2
end
end
foo = Foo.new # `foo` has shape id 2
bar = Bar.new # `bar` has shape id 2
```
Both `foo` and `bar` instances have the same shape because they both set
instance variables of the same name in the same order.
This technique can help to improve inline cache hits as well as generate more
efficient machine code in JIT compilers.
This commit also adds some methods for debugging shapes on objects. See
`RubyVM::Shape` for more details.
For more context on Object Shapes, see [Feature: #18776]
Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
Co-Authored-By: Eileen M. Uchitelle <eileencodes@gmail.com>
Co-Authored-By: John Hawthorn <john@hawthorn.email>
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.
* Create code generation func
* Make rb_vm_concat_array available to use in Rust
* Map opcode to code gen func
* Implement code gen for concatarray
* Add test for concatarray
* Use new asm backend
* Add comment to C func wrapper
opt_aref_with is an optimized instruction for accessing a Hash using a
non-frozen string key (ie. from a file without frozen_string_literal).
It attempts to avoid allocating the string, and instead silently using a
frozen string (hash string keys are always fstrings).
Because this is just an optimization, it should be invisible to the
user. However, previously this optimization was could be seen via hashes
with default procs.
For example, previously:
h = Hash.new { |h, k| k.frozen? }
str = "foo"
h[str] # false
h["foo"] # true when optimizations enabled
This commit checks that the Hash doesn't have a default proc when using
opt_aref_with.
Fixes case where Object includes a module that defines a constant,
then using class/module keyword to define the same constant on
Object itself.
Implements [Feature #18832]
`rb_str_concat` does a lot of type checking we can easily bypass.
```
| |compare-ruby|built-ruby|
|:--------------|-----------:|---------:|
|string_concat | 362.007k| 398.965k|
| | -| 1.10x|
```
NARUSE, Yui
Takashi Kokubun
Jemma Issroff
Maxime Chevalier-Boisvert
Aaron Patterson
Daniel Colson
Peter Zhu
S-H-GAMELINKS
John Hawthorn
Koichi Sasada
Nobuyoshi Nakada
Yusuke Endoh
卜部昌平
Jean Boussier
Maple Ong
Jeremy Evans
Dave Schwantes