ruby.git/insns.def, branch v3_4_9 The Ruby Programming Language Optimize instructions when creating an array just to call `include?` (#12123) 2024-11-26T19:31:08+00:00 Randy Stauner randy.stauner@shopify.com 2024-11-26T19:31:08+00:00 1dd40ec18a55ff46f52d0ba44ff5d7923f57c08f * Add opt_duparray_send insn to skip the allocation on `#include?` If the method isn't going to modify the array we don't need to copy it. This avoids the allocation / array copy for things like `[:a, :b].include?(x)`. This adds a BOP for include? and tracks redefinition for it on Array. Co-authored-by: Andrew Novoselac <andrew.novoselac@shopify.com> * YJIT: Implement opt_duparray_send include_p Co-authored-by: Andrew Novoselac <andrew.novoselac@shopify.com> * Update opt_newarray_send to support simple forms of include?(arg) Similar to opt_duparray_send but for non-static arrays. * YJIT: Implement opt_newarray_send include_p --------- Co-authored-by: Andrew Novoselac <andrew.novoselac@shopify.com> 
* Add opt_duparray_send insn to skip the allocation on `#include?`

If the method isn't going to modify the array we don't need to copy it.
This avoids the allocation / array copy for things like `[:a, :b].include?(x)`.

This adds a BOP for include? and tracks redefinition for it on Array.

Co-authored-by: Andrew Novoselac <andrew.novoselac@shopify.com>

* YJIT: Implement opt_duparray_send include_p

Co-authored-by: Andrew Novoselac <andrew.novoselac@shopify.com>

* Update opt_newarray_send to support simple forms of include?(arg)

Similar to opt_duparray_send but for non-static arrays.

* YJIT: Implement opt_newarray_send include_p

---------

Co-authored-by: Andrew Novoselac <andrew.novoselac@shopify.com>
 Optimized instruction for Hash#freeze 2024-09-05T10:46:02+00:00 Étienne Barrié etienne.barrie@gmail.com 2024-08-05T10:31:24+00:00 bf9879791af11a20e50921551220c08d1c7f7f02 If a Hash which is empty or only using literals is frozen, we detect this as a peephole optimization and change the instructions to be `opt_hash_freeze`. [Feature #20684] Co-authored-by: Jean Boussier <byroot@ruby-lang.org> 
If a Hash which is empty or only using literals is frozen, we detect
this as a peephole optimization and change the instructions to be
`opt_hash_freeze`.

[Feature #20684]

Co-authored-by: Jean Boussier <byroot@ruby-lang.org>
Optimized instruction for Array#freeze 2024-09-05T10:46:02+00:00 Étienne Barrié etienne.barrie@gmail.com 2024-07-29T10:15:02+00:00 a99707cd9c6a1d53cf8ebc883dc210219bd67a28 If an Array which is empty or only using literals is frozen, we detect this as a peephole optimization and change the instructions to be `opt_ary_freeze`. [Feature #20684] Co-authored-by: Jean Boussier <byroot@ruby-lang.org> 
If an Array which is empty or only using literals is frozen, we detect
this as a peephole optimization and change the instructions to be
`opt_ary_freeze`.

[Feature #20684]

Co-authored-by: Jean Boussier <byroot@ruby-lang.org>
Delete newarraykwsplat 2024-08-13T20:56:35+00:00 Alan Wu XrXr@users.noreply.github.com 2024-08-13T20:56:35+00:00 525008cd7879a047e3c310eb63dcef901b23be56 The pushtoarraykwsplat instruction was designed to replace newarraykwsplat, and we now meet the condition for deletion mentioned in 77c1233f79a0f96a081b70da533fbbde4f3037fa. 
The pushtoarraykwsplat instruction was designed to replace newarraykwsplat,
and we now meet the condition for deletion mentioned in
77c1233f79a0f96a081b70da533fbbde4f3037fa.
 Expand opt_newarray_send to support Array#pack with buffer keyword arg 2024-07-29T20:26:58+00:00 Randy Stauner randy.stauner@shopify.com 2024-07-20T17:03:02+00:00 acbb8d4fb56ac3b5894991760a075dbef78d10e3 Use an enum for the method arg instead of needing to add an id that doesn't map to an actual method name. $ ruby --dump=insns -e 'b = "x"; [v].pack("E*", buffer: b)' before: ``` == disasm: #<ISeq:<main>@-e:1 (1,0)-(1,34)> local table (size: 1, argc: 0 [opts: 0, rest: -1, post: 0, block: -1, kw: -1@-1, kwrest: -1]) [ 1] b@0 0000 putchilledstring "x" ( 1)[Li] 0002 setlocal_WC_0 b@0 0004 putself 0005 opt_send_without_block <calldata!mid:v, argc:0, FCALL|VCALL|ARGS_SIMPLE> 0007 newarray 1 0009 putchilledstring "E*" 0011 getlocal_WC_0 b@0 0013 opt_send_without_block <calldata!mid:pack, argc:2, kw:[#<Symbol:0x000000000023110c>], KWARG> 0015 leave ``` after: ``` == disasm: #<ISeq:<main>@-e:1 (1,0)-(1,34)> local table (size: 1, argc: 0 [opts: 0, rest: -1, post: 0, block: -1, kw: -1@-1, kwrest: -1]) [ 1] b@0 0000 putchilledstring "x" ( 1)[Li] 0002 setlocal_WC_0 b@0 0004 putself 0005 opt_send_without_block <calldata!mid:v, argc:0, FCALL|VCALL|ARGS_SIMPLE> 0007 putchilledstring "E*" 0009 getlocal b@0, 0 0012 opt_newarray_send 3, 5 0015 leave ``` 
Use an enum for the method arg instead of needing to add an id
that doesn't map to an actual method name.

$ ruby --dump=insns -e 'b = "x"; [v].pack("E*", buffer: b)'

before:

```
== disasm: #<ISeq:<main>@-e:1 (1,0)-(1,34)>
local table (size: 1, argc: 0 [opts: 0, rest: -1, post: 0, block: -1, kw: -1@-1, kwrest: -1])
[ 1] b@0
0000 putchilledstring                       "x"                       (   1)[Li]
0002 setlocal_WC_0                          b@0
0004 putself
0005 opt_send_without_block                 <calldata!mid:v, argc:0, FCALL|VCALL|ARGS_SIMPLE>
0007 newarray                               1
0009 putchilledstring                       "E*"
0011 getlocal_WC_0                          b@0
0013 opt_send_without_block                 <calldata!mid:pack, argc:2, kw:[#<Symbol:0x000000000023110c>], KWARG>
0015 leave
```

after:

```
== disasm: #<ISeq:<main>@-e:1 (1,0)-(1,34)>
local table (size: 1, argc: 0 [opts: 0, rest: -1, post: 0, block: -1, kw: -1@-1, kwrest: -1])
[ 1] b@0
0000 putchilledstring                       "x"                       (   1)[Li]
0002 setlocal_WC_0                          b@0
0004 putself
0005 opt_send_without_block                 <calldata!mid:v, argc:0, FCALL|VCALL|ARGS_SIMPLE>
0007 putchilledstring                       "E*"
0009 getlocal                               b@0, 0
0012 opt_newarray_send                      3, 5
0015 leave
```
Refactor so we don't have _cd 2024-06-18T16:28:25+00:00 Aaron Patterson tenderlove@ruby-lang.org 2024-06-03T22:48:13+00:00 a661c82972d1b4e3fc26662639b3a55c673ecb5e This should make the diff more clean 
This should make the diff more clean
Add two new instructions for forwarding calls 2024-06-18T16:28:25+00:00 Aaron Patterson tenderlove@ruby-lang.org 2024-06-03T21:20:04+00:00 cc97a270080d2c6eb9dbdd2b9793ab549b6bb44d This commit adds `sendforward` and `invokesuperforward` for forwarding parameters to calls Co-authored-by: Matt Valentine-House <matt@eightbitraptor.com> 
This commit adds `sendforward` and `invokesuperforward` for forwarding
parameters to calls

Co-authored-by: Matt Valentine-House <matt@eightbitraptor.com>
Optimized forwarding callers and callees 2024-06-18T16:28:25+00:00 Aaron Patterson tenderlove@ruby-lang.org 2024-04-15T17:48:53+00:00 cdf33ed5f37f9649c482c3ba1d245f0d80ac01ce This patch optimizes forwarding callers and callees. It only optimizes methods that only take `...` as their parameter, and then pass `...` to other calls. Calls it optimizes look like this: ```ruby def bar(a) = a def foo(...) = bar(...) # optimized foo(123) ``` ```ruby def bar(a) = a def foo(...) = bar(1, 2, ...) # optimized foo(123) ``` ```ruby def bar(*a) = a def foo(...) list = [1, 2] bar(*list, ...) # optimized end foo(123) ``` All variants of the above but using `super` are also optimized, including a bare super like this: ```ruby def foo(...) super end ``` This patch eliminates intermediate allocations made when calling methods that accept `...`. We can observe allocation elimination like this: ```ruby def m x = GC.stat(:total_allocated_objects) yield GC.stat(:total_allocated_objects) - x end def bar(a) = a def foo(...) = bar(...) def test m { foo(123) } end test p test # allocates 1 object on master, but 0 objects with this patch ``` ```ruby def bar(a, b:) = a + b def foo(...) = bar(...) def test m { foo(1, b: 2) } end test p test # allocates 2 objects on master, but 0 objects with this patch ``` How does it work? ----------------- This patch works by using a dynamic stack size when passing forwarded parameters to callees. The caller's info object (known as the "CI") contains the stack size of the parameters, so we pass the CI object itself as a parameter to the callee. When forwarding parameters, the forwarding ISeq uses the caller's CI to determine how much stack to copy, then copies the caller's stack before calling the callee. The CI at the forwarded call site is adjusted using information from the caller's CI. I think this description is kind of confusing, so let's walk through an example with code. ```ruby def delegatee(a, b) = a + b def delegator(...) delegatee(...) # CI2 (FORWARDING) end def caller delegator(1, 2) # CI1 (argc: 2) end ``` Before we call the delegator method, the stack looks like this: ``` Executing Line | Code | Stack ---------------+---------------------------------------+-------- 1| def delegatee(a, b) = a + b | self 2| | 1 3| def delegator(...) | 2 4| # | 5| delegatee(...) # CI2 (FORWARDING) | 6| end | 7| | 8| def caller | -> 9| delegator(1, 2) # CI1 (argc: 2) | 10| end | ``` The ISeq for `delegator` is tagged as "forwardable", so when `caller` calls in to `delegator`, it writes `CI1` on to the stack as a local variable for the `delegator` method. The `delegator` method has a special local called `...` that holds the caller's CI object. Here is the ISeq disasm fo `delegator`: ``` == disasm: #<ISeq:delegator@-e:1 (1,0)-(1,39)> local table (size: 1, argc: 0 [opts: 0, rest: -1, post: 0, block: -1, kw: -1@-1, kwrest: -1]) [ 1] "..."@0 0000 putself ( 1)[LiCa] 0001 getlocal_WC_0 "..."@0 0003 send <calldata!mid:delegatee, argc:0, FCALL|FORWARDING>, nil 0006 leave [Re] ``` The local called `...` will contain the caller's CI: CI1. Here is the stack when we enter `delegator`: ``` Executing Line | Code | Stack ---------------+---------------------------------------+-------- 1| def delegatee(a, b) = a + b | self 2| | 1 3| def delegator(...) | 2 -> 4| # | CI1 (argc: 2) 5| delegatee(...) # CI2 (FORWARDING) | cref_or_me 6| end | specval 7| | type 8| def caller | 9| delegator(1, 2) # CI1 (argc: 2) | 10| end | ``` The CI at `delegatee` on line 5 is tagged as "FORWARDING", so it knows to memcopy the caller's stack before calling `delegatee`. In this case, it will memcopy self, 1, and 2 to the stack before calling `delegatee`. It knows how much memory to copy from the caller because `CI1` contains stack size information (argc: 2). Before executing the `send` instruction, we push `...` on the stack. The `send` instruction pops `...`, and because it is tagged with `FORWARDING`, it knows to memcopy (using the information in the CI it just popped): ``` == disasm: #<ISeq:delegator@-e:1 (1,0)-(1,39)> local table (size: 1, argc: 0 [opts: 0, rest: -1, post: 0, block: -1, kw: -1@-1, kwrest: -1]) [ 1] "..."@0 0000 putself ( 1)[LiCa] 0001 getlocal_WC_0 "..."@0 0003 send <calldata!mid:delegatee, argc:0, FCALL|FORWARDING>, nil 0006 leave [Re] ``` Instruction 001 puts the caller's CI on the stack. `send` is tagged with FORWARDING, so it reads the CI and _copies_ the callers stack to this stack: ``` Executing Line | Code | Stack ---------------+---------------------------------------+-------- 1| def delegatee(a, b) = a + b | self 2| | 1 3| def delegator(...) | 2 4| # | CI1 (argc: 2) -> 5| delegatee(...) # CI2 (FORWARDING) | cref_or_me 6| end | specval 7| | type 8| def caller | self 9| delegator(1, 2) # CI1 (argc: 2) | 1 10| end | 2 ``` The "FORWARDING" call site combines information from CI1 with CI2 in order to support passing other values in addition to the `...` value, as well as perfectly forward splat args, kwargs, etc. Since we're able to copy the stack from `caller` in to `delegator`'s stack, we can avoid allocating objects. I want to do this to eliminate object allocations for delegate methods. My long term goal is to implement `Class#new` in Ruby and it uses `...`. I was able to implement `Class#new` in Ruby [here](https://github.com/ruby/ruby/pull/9289). If we adopt the technique in this patch, then we can optimize allocating objects that take keyword parameters for `initialize`. For example, this code will allocate 2 objects: one for `SomeObject`, and one for the kwargs: ```ruby SomeObject.new(foo: 1) ``` If we combine this technique, plus implement `Class#new` in Ruby, then we can reduce allocations for this common operation. Co-Authored-By: John Hawthorn <john@hawthorn.email> Co-Authored-By: Alan Wu <XrXr@users.noreply.github.com> 
This patch optimizes forwarding callers and callees. It only optimizes methods that only take `...` as their parameter, and then pass `...` to other calls.

Calls it optimizes look like this:

```ruby
def bar(a) = a
def foo(...) = bar(...) # optimized
foo(123)
```

```ruby
def bar(a) = a
def foo(...) = bar(1, 2, ...) # optimized
foo(123)
```

```ruby
def bar(*a) = a

def foo(...)
  list = [1, 2]
  bar(*list, ...) # optimized
end
foo(123)
```

All variants of the above but using `super` are also optimized, including a bare super like this:

```ruby
def foo(...)
  super
end
```

This patch eliminates intermediate allocations made when calling methods that accept `...`.
We can observe allocation elimination like this:

```ruby
def m
  x = GC.stat(:total_allocated_objects)
  yield
  GC.stat(:total_allocated_objects) - x
end

def bar(a) = a
def foo(...) = bar(...)

def test
  m { foo(123) }
end

test
p test # allocates 1 object on master, but 0 objects with this patch
```

```ruby
def bar(a, b:) = a + b
def foo(...) = bar(...)

def test
  m { foo(1, b: 2) }
end

test
p test # allocates 2 objects on master, but 0 objects with this patch
```

How does it work?
-----------------

This patch works by using a dynamic stack size when passing forwarded parameters to callees.
The caller's info object (known as the "CI") contains the stack size of the
parameters, so we pass the CI object itself as a parameter to the callee.
When forwarding parameters, the forwarding ISeq uses the caller's CI to determine how much stack to copy, then copies the caller's stack before calling the callee.
The CI at the forwarded call site is adjusted using information from the caller's CI.

I think this description is kind of confusing, so let's walk through an example with code.

```ruby
def delegatee(a, b) = a + b

def delegator(...)
  delegatee(...)  # CI2 (FORWARDING)
end

def caller
  delegator(1, 2) # CI1 (argc: 2)
end
```

Before we call the delegator method, the stack looks like this:

```
Executing Line | Code                                  | Stack
---------------+---------------------------------------+--------
              1| def delegatee(a, b) = a + b           | self
              2|                                       | 1
              3| def delegator(...)                    | 2
              4|   #                                   |
              5|   delegatee(...)  # CI2 (FORWARDING)  |
              6| end                                   |
              7|                                       |
              8| def caller                            |
          ->  9|   delegator(1, 2) # CI1 (argc: 2)     |
             10| end                                   |
```

The ISeq for `delegator` is tagged as "forwardable", so when `caller` calls in
to `delegator`, it writes `CI1` on to the stack as a local variable for the
`delegator` method.  The `delegator` method has a special local called `...`
that holds the caller's CI object.

Here is the ISeq disasm fo `delegator`:

```
== disasm: #<ISeq:delegator@-e:1 (1,0)-(1,39)>
local table (size: 1, argc: 0 [opts: 0, rest: -1, post: 0, block: -1, kw: -1@-1, kwrest: -1])
[ 1] "..."@0
0000 putself                                                          (   1)[LiCa]
0001 getlocal_WC_0                          "..."@0
0003 send                                   <calldata!mid:delegatee, argc:0, FCALL|FORWARDING>, nil
0006 leave                                  [Re]
```

The local called `...` will contain the caller's CI: CI1.

Here is the stack when we enter `delegator`:

```
Executing Line | Code                                  | Stack
---------------+---------------------------------------+--------
              1| def delegatee(a, b) = a + b           | self
              2|                                       | 1
              3| def delegator(...)                    | 2
           -> 4|   #                                   | CI1 (argc: 2)
              5|   delegatee(...)  # CI2 (FORWARDING)  | cref_or_me
              6| end                                   | specval
              7|                                       | type
              8| def caller                            |
              9|   delegator(1, 2) # CI1 (argc: 2)     |
             10| end                                   |
```

The CI at `delegatee` on line 5 is tagged as "FORWARDING", so it knows to
memcopy the caller's stack before calling `delegatee`.  In this case, it will
memcopy self, 1, and 2 to the stack before calling `delegatee`.  It knows how much
memory to copy from the caller because `CI1` contains stack size information
(argc: 2).

Before executing the `send` instruction, we push `...` on the stack.  The
`send` instruction pops `...`, and because it is tagged with `FORWARDING`, it
knows to memcopy (using the information in the CI it just popped):

```
== disasm: #<ISeq:delegator@-e:1 (1,0)-(1,39)>
local table (size: 1, argc: 0 [opts: 0, rest: -1, post: 0, block: -1, kw: -1@-1, kwrest: -1])
[ 1] "..."@0
0000 putself                                                          (   1)[LiCa]
0001 getlocal_WC_0                          "..."@0
0003 send                                   <calldata!mid:delegatee, argc:0, FCALL|FORWARDING>, nil
0006 leave                                  [Re]
```

Instruction 001 puts the caller's CI on the stack.  `send` is tagged with
FORWARDING, so it reads the CI and _copies_ the callers stack to this stack:

```
Executing Line | Code                                  | Stack
---------------+---------------------------------------+--------
              1| def delegatee(a, b) = a + b           | self
              2|                                       | 1
              3| def delegator(...)                    | 2
              4|   #                                   | CI1 (argc: 2)
           -> 5|   delegatee(...)  # CI2 (FORWARDING)  | cref_or_me
              6| end                                   | specval
              7|                                       | type
              8| def caller                            | self
              9|   delegator(1, 2) # CI1 (argc: 2)     | 1
             10| end                                   | 2
```

The "FORWARDING" call site combines information from CI1 with CI2 in order
to support passing other values in addition to the `...` value, as well as
perfectly forward splat args, kwargs, etc.

Since we're able to copy the stack from `caller` in to `delegator`'s stack, we
can avoid allocating objects.

I want to do this to eliminate object allocations for delegate methods.
My long term goal is to implement `Class#new` in Ruby and it uses `...`.

I was able to implement `Class#new` in Ruby
[here](https://github.com/ruby/ruby/pull/9289).
If we adopt the technique in this patch, then we can optimize allocating
objects that take keyword parameters for `initialize`.

For example, this code will allocate 2 objects: one for `SomeObject`, and one
for the kwargs:

```ruby
SomeObject.new(foo: 1)
```

If we combine this technique, plus implement `Class#new` in Ruby, then we can
reduce allocations for this common operation.

Co-Authored-By: John Hawthorn <john@hawthorn.email>
Co-Authored-By: Alan Wu <XrXr@users.noreply.github.com>
Stop exposing `rb_str_chilled_p` 2024-06-02T11:53:35+00:00 Jean Boussier jean.boussier@gmail.com 2024-05-30T12:55:32+00:00 730e3b2ce01915c4a98b79bb281b2c38a9ff1131 [Feature #20205] Now that chilled strings no longer appear as frozen, there is no need to offer an API to check for chilled strings. We however need to change `rb_check_frozen_internal` to no longer be a macro, as it needs to check for chilled strings. 
[Feature #20205]

Now that chilled strings no longer appear as frozen, there is no
need to offer an API to check for chilled strings.

We however need to change `rb_check_frozen_internal` to no
longer be a macro, as it needs to check for chilled strings.
Introduce a specialize instruction for Array#pack 2024-05-23T19:11:50+00:00 Nobuyoshi Nakada nobu@ruby-lang.org 2024-05-23T18:23:26+00:00 49fcd33e136ee2fe8720183b63a41bb6ef8d615c Instructions for this code: ```ruby # frozen_string_literal: true [a].pack("C") ``` Before this commit: ``` == disasm: #<ISeq:<main>@test.rb:1 (1,0)-(3,13)> 0000 putself ( 3)[Li] 0001 opt_send_without_block <calldata!mid:a, argc:0, FCALL|VCALL|ARGS_SIMPLE> 0003 newarray 1 0005 putobject "C" 0007 opt_send_without_block <calldata!mid:pack, argc:1, ARGS_SIMPLE> 0009 leave ``` After this commit: ``` == disasm: #<ISeq:<main>@test.rb:1 (1,0)-(3,13)> 0000 putself ( 3)[Li] 0001 opt_send_without_block <calldata!mid:a, argc:0, FCALL|VCALL|ARGS_SIMPLE> 0003 putobject "C" 0005 opt_newarray_send 2, :pack 0008 leave ``` Co-authored-by: Maxime Chevalier-Boisvert <maxime.chevalierboisvert@shopify.com> Co-authored-by: Aaron Patterson <tenderlove@ruby-lang.org> 
Instructions for this code:

```ruby
  # frozen_string_literal: true

[a].pack("C")
```

Before this commit:

```
== disasm: #<ISeq:<main>@test.rb:1 (1,0)-(3,13)>
0000 putself                                                          (   3)[Li]
0001 opt_send_without_block                 <calldata!mid:a, argc:0, FCALL|VCALL|ARGS_SIMPLE>
0003 newarray                               1
0005 putobject                              "C"
0007 opt_send_without_block                 <calldata!mid:pack, argc:1, ARGS_SIMPLE>
0009 leave
```

After this commit:

```
== disasm: #<ISeq:<main>@test.rb:1 (1,0)-(3,13)>
0000 putself                                                          (   3)[Li]
0001 opt_send_without_block                 <calldata!mid:a, argc:0, FCALL|VCALL|ARGS_SIMPLE>
0003 putobject                              "C"
0005 opt_newarray_send                      2, :pack
0008 leave
```

Co-authored-by: Maxime Chevalier-Boisvert <maxime.chevalierboisvert@shopify.com>
Co-authored-by: Aaron Patterson <tenderlove@ruby-lang.org>