Great patch.
I'm looking forward to seeing evaluation results.

Questions:

• how to use parent id?
• how to find next id with additional ivar?

We want object shapes to be enabled on 32 bit systems and 64 bit systems so that limits us to the bottom 32 bits of the Object header.

Might be a silly question, but how popular are 32bits systems these days? Would it be acceptable to make objects a bit bigger on 32 bits systems so that both 32bits and 64bits Ruby have a 32bit shape IDs?

Thanks for the feedback, Koichi.

ko1 (Koichi Sasada) wrote in #note-3:

• how to use parent id?

The rb_shape type is as follows:

struct rb_shape {
    VALUE flags;
    struct rb_shape * parent;
    struct rb_id_table * edges;
    struct rb_id_table * iv_table;
    ID edge_name;
};

parent is a pointer on the shape itself, and we use it primarily for GC

• how to find next id with additional ivar?

When we add a new ivar, if there is no transition we have to find a new ID. Right now we're doing a linear scan of available IDs. Once we're confident in shape ID GC, we'll switch the algorithm to something more efficient like using a bitmap

byroot (Jean Boussier) wrote in #note-4:

We want object shapes to be enabled on 32 bit systems and 64 bit systems so that limits us to the bottom 32 bits of the Object header.

Might be a silly question, but how popular are 32bits systems these days? Would it be acceptable to make objects a bit bigger on 32 bits systems so that both 32bits and 64bits Ruby have a 32bit shape IDs?

I'm not sure how popular 32 bit systems are, especially where high performance is a requirement. But I do think the broader question of "how much work should we do to support 32 bit systems?" is something we should think about. For now I think we can make shapes work well on 32 bit machines so I'm not too worried about it at this point (though it definitely would be easier if we had more than 16 bits 😆)

it definitely would be easier if we had more than 16 bits

Yeah, my worry is that while the Shopify monolith is probably among the bigger codebases, ~40k out of ~65k is really not that much leeway.

byroot (Jean Boussier) wrote in #note-7:

it definitely would be easier if we had more than 16 bits

Yeah, my worry is that while the Shopify monolith is probably among the bigger codebases, ~40k out of ~65k is really not that much leeway.

When we measured on Shopify core it was before we had started implementing shape GC. There were ~40k shapes, but that was the total number of shapes ever seen. Hopefully with shape GC we'll see a lower number of live shapes.

If you call memoized methods in a different order, would that cause instances of the same class to have multiple shapes?

If you call memoized methods in a different order, would that cause instances of the same class to have multiple shapes?

Yes.

jemmai (Jemma Issroff) wrote in #note-5:

When we add a new ivar, if there is no transition we have to find a new ID. Right now we're doing a linear scan of available IDs. Once we're confident in shape ID GC, we'll switch the algorithm to something more efficient like using a bitmap

Ah, my question was how to find an existing transition.

struct rb_id_table * edges;

and I understand edges manages the next transitions. Thanks.

These are our proposed code changes to implement Object Shapes in CRuby.

I think it would be a good idea to open a draft pull request so that it's easier to look at the diff and comment on it.

We also ran YJIT-bench and got the following results:

Can you guys investigate a bit why there are large slowdowns with YJIT?

I believe you said you had written code to make use of object shapes in YJIT. I would have expected the performance difference to be small. Since it's so big,
I suspect that maybe there are a large number of side-exits happening, or something like that.

We could pair over it tomorrow if that's helpful. It's probably not difficult to fix.

I think it would be a good idea to open a draft pull request so that it's easier to look at the diff and comment on it.

Good idea, here is a draft PR and updated it above as well

Can you guys investigate a bit why there are large slowdowns with YJIT?

We realized we accidentally ran these in debug mode. We will get new numbers and repost them, sorry about that!

After running the YJIT benchmarks in release mode, we found that setting instance variables is, indeed, slower on our branch than the master branch.

YJIT is not exiting. YJIT is calling out to rb_vm_setinstancevariable to set instance variables. We disassembled this function on both master and our branch and it looks like the compiler is emitting unfortunate machine code on our branch. It looks like we are spilling data to the stack where we weren't in master.

On the left is the machine code in our branch, on the right is the machine code for master. It looks like the machine code on our branch is spilling data to the stack and we think this is why there's a speed difference. We can work on changing the C code to get more efficient machine code.

It's unfortunate that there are spills there and there might be ways to reduce that by reorganizing the code a bit, but I would expect the performance impact of the spills to be relatively small, because in practice in most kinds of software, there are many times more ivar reads than ivar writes, and those spills are a drop in the bucket.

Also, if you look at the getivar benchmark before and after, you can see that the speedup went from 9.95 to 1.01. That suggests that we're probably side-exiting or not running the getinstancevariable code in YJIT for some reason. IMO getinstancevariable should be the first place to look.

About the general principle, since Ruby is used on many production environment by many companies, non-optional feature needs to be production ready.

It means it shouldn't have a downside including CPU performance, Memory consumption, and so on. Since YJIT is already concerned as a production feature, it's also a downside if it cause slow down of YJIT. Also note that increasing code complexity is also a downside.

Though a critical downside needs to be fixed, a small downside can be accepted if it has a larger upside. For example code complexity, it is accepted while it introduces a enough performance improvement compared to the complexity.

As far as I understand, the Object Shape is introduce to improve performance and it's complex. Therefore it needs to show some performance improvement compared to the code complexity before we merge it to ruby-master.

Thank you for this important work. In particular I think shapes will be very useful in the future to improve the performance of keyword arguments.

The following comments/nitpicks may be irrelevant (or I may have misunderstood the code completely), but I had to get them off my brain:

(1) It would be nice to convert the magic numbers into constants. So maybe we could have #define SHAPE_BITS 16 and #define SHAPE_MASK ((1<<SHAPE_BITS)-1) and then other constants that derive from that, and maybe it would be possible to compile a version with 17-bit shapes.

(2) It looks to me like rb_shape_get_iv_index is really critical to performance, but the linked-list structure has bad performance characteristics for locality of memory access. If an object has 6 ivars you need to read 7 non-contiguous structs for each ivar access. It should be much faster if each shape struct had the full list of IDs in the shape. With a SIMD instruction it would be super-fast to find the index for a given ID, but even without SIMD the memory locality would be much better.

(3) The frozen flag is represented as a different root shape, but this results in many extra shapes that are not used by any object:

def initialize(a,b,c,d)
  @a,@b,@c,@d = a,b,c,d
  freeze
end

0(root) -> 2(@a) -> 3(@a,@b) -> 4(@a,@b,@c) -> 5(@a,@b,@c,@d)

1(frozen) -> 6(@a) -> 7(@a,@b) -> 8(@a,@b,@c) -> 9(@a,@b,@c,@d)

If the frozen flag was represented by a leaf node, this would use fewer shapes. (It would also mirror the order of operations and the fact that after freezing it's not possible add more ivars.)

0(root) -> 1(@a) -> 2(@a,@b) -> 3(@a,@b,@c) -> 4(@a,@b,@c,@d)
                                               |
                                               5(@a,@b,@c,@d,frozen)

Dan0042 (Daniel DeLorme) wrote in #note-19:

In particular I think shapes will be very useful in the future to improve the performance of keyword arguments.

Can you explain how shapes could improve performance of keyword arguments? Nobody else has mentioned the possibility yet, and I'm not sure how they are related.

(3) The frozen flag is represented as a different root shape, but this results in many extra shapes that are not used by any object:

def initialize(a,b,c,d)
  @a,@b,@c,@d = a,b,c,d
  freeze
end

0(root) -> 2(@a) -> 3(@a,@b) -> 4(@a,@b,@c) -> 5(@a,@b,@c,@d)

1(frozen) -> 6(@a) -> 7(@a,@b) -> 8(@a,@b,@c) -> 9(@a,@b,@c,@d)

If an object is frozen, you cannot add instance variables to it. I don't see how you could generate shapes 6-9 in your example. I would guess the implementation already works similarly to the leaf node approach you suggested.

Dan0042 (Daniel DeLorme) wrote in #note-19:

Thank you for this important work. In particular I think shapes will be very useful in the future to improve the performance of keyword arguments.

I don't think this will have any impact on keyword arguments.

(2) It looks to me like rb_shape_get_iv_index is really critical to performance, but the linked-list structure has bad performance characteristics for locality of memory access. If an object has 6 ivars you need to read 7 non-contiguous structs for each ivar access. It should be much faster if each shape struct had the full list of IDs in the shape. With a SIMD instruction it would be super-fast to find the index for a given ID, but even without SIMD the memory locality would be much better.

rb_shape_get_iv_index is rarely called because the index is stored in the inline cache. We only need to call this when the cache misses. It does make cache misses expensive in terms of CPU, but memory is reduced.

(3) The frozen flag is represented as a different root shape, but this results in many extra shapes that are not used by any object:

def initialize(a,b,c,d)
  @a,@b,@c,@d = a,b,c,d
  freeze
end

0(root) -> 2(@a) -> 3(@a,@b) -> 4(@a,@b,@c) -> 5(@a,@b,@c,@d)

1(frozen) -> 6(@a) -> 7(@a,@b) -> 8(@a,@b,@c) -> 9(@a,@b,@c,@d)

This case can't happen because you can't add ivars after an object has been frozen.

We have a "frozen root shape" just as an optimization for objects that go from the root shape and are immediately frozen. For example when using the frozing_string_literals directive. Objects that are not T_OBJECT, T_CLASS, or T_MODULE store their shape id in the gen iv table. We didn't want to make a geniv table for every object that goes from root -> frozen (again think of the number of frozen string literals in an application), so we pre-allocate that shape, then assign it "at birth" (using the frozen bit to indicate that we're using the "frozen root shape" singleton).

If the frozen flag was represented by a leaf node, this would use fewer shapes. (It would also mirror the order of operations and the fact that after freezing it's not possible add more ivars.)

0(root) -> 1(@a) -> 2(@a,@b) -> 3(@a,@b,@c) -> 4(@a,@b,@c,@d)
                                               |
                                               5(@a,@b,@c,@d,frozen)

It's currently implemented this way. :)

naruse (Yui NARUSE) wrote in #note-18:

About the general principle, since Ruby is used on many production environment by many companies, non-optional feature needs to be production ready.

It means it shouldn't have a downside including CPU performance, Memory consumption, and so on. Since YJIT is already concerned as a production feature, it's also a downside if it cause slow down of YJIT. Also note that increasing code complexity is also a downside.

Though a critical downside needs to be fixed, a small downside can be accepted if it has a larger upside. For example code complexity, it is accepted while it introduces a enough performance improvement compared to the complexity.

As far as I understand, the Object Shape is introduce to improve performance and it's complex. Therefore it needs to show some performance improvement compared to the code complexity before we merge it to ruby-master.

We're working to fix the YJIT cases. I think we can see higher speeds in YJIT using Object Shapes than the current caching mechanisms as the machine code YJIT generates can be much more simple.

For the non-JIT case, we're seeing good improvements in some benchmarks like this:

|vm_ivar_init_subclass      |      6.104M|   12.928M|
|                           |           -|     2.12x|

This is a case where shapes can hit inline caches but the current mechanism cannot, like this code:

class A
  def initialize
    @a = 1
    @b = 1
  end
end

class B < A; end

loop do
  A.new
  B.new
end

Our current cache cannot hit because the classes change, but shapes can hit because the shapes are the same.

As for complexity, I think the strategy is easier to understand than our current caching mechanism and it actually simplifies cache checks. We only need to compare shape id, not class serial + frozen status. Code complexity is hard to measure though, and I admit this patch is pretty big. 😅

Reference keyword arguments - what we're doing is using the same idea of shapes, but applying them to the keyword arguments hash to be able to extract keyword arguments without any control-flow. We can implement keyword arguments like this with just a single machine-word comparison overhead over positional arguments.

https://www.youtube.com/watch?v=RVqY1FRUm_8

tenderlovemaking (Aaron Patterson) wrote in #note-21:

It's currently implemented this way. :)

Ok, thank you for the explanation. I got completely confused by the role of the frozen root shape. Sorry for the noise.

jeremyevans0 (Jeremy Evans) wrote in #note-20:

Can you explain how shapes could improve performance of keyword arguments? Nobody else has mentioned the possibility yet, and I'm not sure how they are related.

Well, I believe shapes can be considered a general-purpose mechanism to store "named tuples" or "hash of symbols" kind of data structures.

Keyword arguments like foo(a:1, b:2) are already pretty efficient because they use a strategy similar to shapes (VM_CALL_KWARG) where keys {a,b} are stored once per-callsite and values [1,2] are passed on the stack (IIRC).

But as soon as you have a splat you need to allocate a hash on the heap. (VM_CALL_KW_SPLAT)

h = {c:3, d:4}
foo(a:1, b:2, **h)

With shapes you could start with {a,b} and then add the hash keys to get shape {a,b,c,d} and pass all values [1,2,3,4] plus the shape id on the stack. No need to allocate a hash and associated st_table/ar_table. I think.

With shapes you could start with {a,b} and then add the hash keys to get shape {a,b,c,d} and pass all values [1,2,3,4] plus the shape id on the stack.

Yes that's the idea in the video I linked.

Summary¶

The implementation has been updated to solve some performance problems and simplify both source code and generated code.

The performance of this branch against multiple benchmarks, including microbenchmarks, RailsBench and YJIT Bench show that the performance of Object Shapes is equivalent to, if not better than, the existing ivar implementation.

We have also improved the memory overhead and made it half of what it was previously.

Overall, code complexity has been decreased, memory overhead is small and performance is better or on par with master. We think this is a good state for this feature to be merged. We would like to get feedback from Ruby committers on this PR or in this issue for that reason.

Details¶

Since our previous update, we have made the following changes:

• The shape ID is now 32 bits on 64 bit machines when debugging is disabled. This gives us significantly more shapes in most cases. When debugging is enabled, Ractor check mode is also enabled. Ractor check mode stores the Ractor ID in the flags bits, and shapes needs to use that space too. Given this constraint, when debug mode is enabled Shapes only consumes 16 bits leaving the other 16 bits for Ractor IDs.
• The shape ID is now stored in the upper 32 bits of the flags field. This ensures a consistent location for finding the shape id. All objects allocated from the heap will have their shape id stored in the top 32 bits. This simplifies looking up the shape id for a given object, which reduces code complexity. It also simplifies the machine code emitted from the JIT.
• On platforms that support mmap, we now use mmap to allocate the shape list. Since mmap lazily maps to physical pages, this allows us to lazily allocate space for the shape list.

CPU performance¶

These are our updated perfomance results:

Microbenchmarks¶

We ran microbenchmarks comparing master to object shapes and got the following results:

$  make benchmark ITEM=vm_ivar
...
compare-ruby: ruby 3.2.0dev (2022-09-13T06:44:29Z master 316b44df09) [arm64-darwin21]
built-ruby: ruby 3.2.0dev (2022-09-13T11:25:59Z object-shapes-prot.. ef42354c33) [arm64-darwin21]
# Iteration per second (i/s)

|                           |compare-ruby|built-ruby|
|:--------------------------|-----------:|---------:|
|vm_ivar                    |    100.020M|  108.705M|
|                           |           -|     1.09x|
|vm_ivar_embedded_obj_init  |     33.584M|   33.415M|
|                           |       1.01x|         -|
|vm_ivar_extended_obj_init  |     26.073M|   26.635M|
|                           |           -|     1.02x|
|vm_ivar_generic_get        |     16.599M|   18.103M|
|                           |           -|     1.09x|
|vm_ivar_generic_set        |     12.505M|   18.616M|
|                           |           -|     1.49x|
|vm_ivar_get                |       8.533|     8.566|
|                           |           -|     1.00x|
|vm_ivar_get_uninitialized  |     81.117M|   79.294M|
|                           |       1.02x|         -|
|vm_ivar_lazy_set           |       1.921|     1.949|
|                           |           -|     1.01x|
|vm_ivar_of_class           |      8.359M|    9.094M|
|                           |           -|     1.09x|
|vm_ivar_of_class_set       |     10.678M|   10.331M|
|                           |       1.03x|         -|
|vm_ivar_set                |     90.398M|   92.034M|
|                           |           -|     1.02x|
|vm_ivar_set_on_instance    |      14.269|    14.307|
|                           |           -|     1.00x|
|vm_ivar_init_subclass      |      6.048M|   13.029M|
|                           |           -|     2.15x|

Class instance variables have never benefited from inline caching, so always take the non-cached slow path. Object shapes made the slow path slower, so the vm_ivar_of_class_set benchmark slowdown is expected.

As follow up to object shapes, @jhawthorn (John Hawthorn) is planning to re-implement instance variables on classes to use arrays instead of st_tables. With his change, class instance variables will be able to realize the benefits of object shapes by taking the cached, fast path.

Railsbench¶

We ran Railsbench 10 times on master and shapes, and got the following results:

Master:

ruby 3.2.0dev (2022-09-13T06:44:29Z master 316b44df09) [arm64-darwin21]
Request per second: 1898.3 [#/s] (mean)
Request per second: 1890.8 [#/s] (mean)
Request per second: 1894.7 [#/s] (mean)
Request per second: 1885.0 [#/s] (mean)
Request per second: 1868.2 [#/s] (mean)
Request per second: 1884.2 [#/s] (mean)
Request per second: 1860.6 [#/s] (mean)
Request per second: 1902.1 [#/s] (mean)
Request per second: 1927.1 [#/s] (mean)
Request per second: 1894.8 [#/s] (mean)

This averages to 1890.58 requests per second

Shapes:

ruby 3.2.0dev (2022-09-13T11:25:59Z object-shapes-prot.. ef42354c33) [arm64-darwin21]
Request per second: 1901.9 [#/s] (mean)
Request per second: 1900.1 [#/s] (mean)
Request per second: 1903.1 [#/s] (mean)
Request per second: 1902.2 [#/s] (mean)
Request per second: 1905.2 [#/s] (mean)
Request per second: 1903.0 [#/s] (mean)
Request per second: 1910.7 [#/s] (mean)
Request per second: 1916.3 [#/s] (mean)
Request per second: 1905.6 [#/s] (mean)
Request per second: 1894.4 [#/s] (mean)

This averages to 1904.25 requests per second

YJIT Bench:¶

We ran YJIT Bench on master and shapes, excluding benchmarks which do not measure instance variables, and got the following results:

Master:

ruby_version="ruby 3.2.0dev (2022-09-13T06:44:29Z master 316b44df09) [x86_64-linux]"
git_branch="master"
git_commit="316b44df09"

-------------  -----------  ----------  ---------  ----------  -----------  ------------
bench          interp (ms)  stddev (%)  yjit (ms)  stddev (%)  interp/yjit  yjit 1st itr
activerecord   115.5        0.3         74.7       2.1         1.55         1.31        
chunky_png     748.0        0.1         500.9      0.1         1.49         1.46        
erubi          260.4        0.6         202.8      1.0         1.28         1.25        
erubi_rails    18.4         2.0         13.2       3.5         1.39         0.50        
getivar        91.9         1.4         23.1       0.2         3.98         0.98        
hexapdf        2183.0       0.9         1479.4     3.0         1.48         1.31        
liquid-render  144.3        0.4         87.6       1.5         1.65         1.32        
mail           125.6        0.2         104.5      0.3         1.20         0.81        
optcarrot      5013.9       0.7         2227.7     0.5         2.25         2.20        
psych-load     1804.1       0.1         1333.0     0.0         1.35         1.35        
railsbench     1933.3       1.1         1442.5     1.6         1.34         1.20        
rubykon        9838.4       0.4         4915.1     0.2         2.00         2.11        
setivar        64.9         1.4         27.9       3.1         2.32         1.01        

Shapes:

ruby_version="ruby 3.2.0dev (2022-09-13T11:25:59Z object-shapes-prot.. ef42354c33) [x86_64-linux]"
git_branch="object-shapes-prototyping"    
git_commit="ef42354c33"

-------------  -----------  ----------  ---------  ----------  -----------  ------------

bench          interp (ms)  stddev (%)  yjit (ms)  stddev (%)  interp/yjit  yjit 1st itr
activerecord   118.6        0.1         76.4       0.2         1.55         1.27
chunky_png     760.5        0.2         488.8      0.3         1.56         1.52
erubi          252.4        0.6         199.9      1.0         1.26         1.25
erubi_rails    18.5         2.5         13.7       3.3         1.35         0.53
getivar        89.8         1.2         23.3       0.0         3.85         1.00
hexapdf        2364.9       1.0         1649.2     2.8         1.43         1.30
liquid-render  147.3        0.6         90.3       1.7         1.63         1.30
mail           128.7        0.3         106.0      0.2         1.21         0.82
optcarrot      5170.7       0.8         2681.7     0.3         1.93         1.88
psych-load     1786.4       0.1         1480.2     0.0         1.21         1.20
railsbench     1988.9       0.8         1482.4     1.7         1.34         1.23
rubykon        9729.6       1.2         4841.3     1.7         2.01         2.17
setivar        61.6         0.3         32.2       0.1         1.91         1.00 

Here are comparison numbers between the two measurements. (> 1 means shapes is faster, < 1 means master is faster):

bench			interp (shapes / master)    yjit (shapes / master)
activerecord		1.03                        1.02
chunky_png		1.02                        0.98
erubi			0.97                        0.99
erubi_rails		1.01                        1.04
getivar			0.98                        1.01
hexapdf			1.08                        1.11
liquid-render		1.02                        1.03
mail			1.02                        1.01
optcarrot		1.03                        1.20
psych-load		0.99                        1.11
railsbench		1.03                        1.03
rubykon			0.99                        0.98
setivar			0.95                        1.15

Memory consumption¶

Due to the mmap change, our memory consumption has decreased since our last update. Measuring execution of an empty script over 10 runs, we saw an average consumption of 29,107,814 bytes on master, and 29,273,293 bytes with object shapes. This means on an empty script, shapes has a 0.5% memory increase. Obviously, this difference would represent a significantly lower percentage memory increase on larger, production-scale applications.

Code complexity¶

We have reduced overall code complexity by:

• Removing the iv_index table on the class and replacing it with a shape tree which can be used independent of object types
• Reducing the checks in the set instance variable and get instance variable cached code paths by removing the frozen check, class serial check and vm_ic_entry_p check in favor of a shape check.

The code below is the fast code path (cache hit case) for setting instance variables. (Assertions and debug counters removed for clarity.)

Master:

if (LIKELY(!RB_OBJ_FROZEN_RAW(obj))) {
    if (LIKELY(
        (vm_ic_entry_p(ic) && ic->entry->class_serial == RCLASS_SERIAL(RBASIC(obj)->klass)))) {

        if (UNLIKELY(index >= ROBJECT_NUMIV(obj))) {
            rb_init_iv_list(obj);
        }
        VALUE *ptr = ROBJECT_IVPTR(obj);
        RB_OBJ_WRITE(obj, &ptr[index], val);
        return val;
    }
}

Shapes:

shape_id_t shape_id = ROBJECT_SHAPE_ID(obj);

if (shape_id == source_shape_id) {
    if (dest_shape_id != shape_id) {
        if (UNLIKELY(index >= ROBJECT_NUMIV(obj))) {
            rb_init_iv_list(obj);
        }
        ROBJECT_SET_SHAPE_ID(obj, dest_shape_id);
    }

    VALUE *ptr = ROBJECT_IVPTR(obj);
    RB_OBJ_WRITE(obj, &ptr[index], val);
    return val;
}

• Reducing the number of instructions for instance variable access in YJIT. Here are the x86_64 assembly code instructions generated by YJIT which represent guard comparisons for getting instance variables:

Master:

# guard known class
0x55cfff14857a: movabs rcx, 0x7f3e1fceb0f8
0x55cfff148584: cmp qword ptr [rax + 8], rcx
0x55cfff148588: jne 0x55d007137491
0x55cfff14858e: mov rax, qword ptr [r13 + 0x18]
# Is the IV in range?
0x55cfff148592: cmp qword ptr [rax + 0x10], 0
0x55cfff148597: jbe 0x55d007137446
# guard embedded getivar
# Is object embedded?
0x55cfff14859d: test word ptr [rax], 0x2000
0x55cfff1485a2: je 0x55d0071374aa

Shapes:

# guard shape, embedded, and T_*
0x55a89f8c7cff: mov rcx, qword ptr [rax]
0x55a89f8c7d02: movabs r11, 0xffff00000000201f
0x55a89f8c7d0c: and rcx, r11
0x55a89f8c7d0f: movabs r11, 0x58000000002001
0x55a89f8c7d19: cmp rcx, r11
0x55a89f8c7d1c: jne 0x55a8a78b5d4e

The shapes code has one comparison and one memory read whereas the master code has three comparisons and four memory reads.

Conclusion¶

As we said at the beginning of this update, based on the metrics and rationale described above, we think object shapes is ready to merge. Please give us feedback on our PR or this issue.

Thank you!

The performance numbers look good and I'm very happy with the improvements that you've made wrt shape ids being 32 bits. It's also nice to see that the generated code for property accesses in YJIT is shorter than before.

There seems to be a (likely minor) bug in the PR that should be fixed before we merge but besides that the PR looks to me like it's in a mergeable state, it delivers on what was promised.