ruby.git/vm_callinfo.h, branch v3_4_9 The Ruby Programming Language vm_cc_new: don't assume `cme` is present. (#15322) 2025-12-01T17:44:46+00:00 Jean Boussier jean.boussier@gmail.com 2025-12-01T17:44:46+00:00 3b09e559da73e63ff25156fcb9e892948c7b2afb [Bug #21694] `vm_search_super_method` explictly calls `vm_cc_new` with `cme=NULL` when there is no super class. 
[Bug #21694]

`vm_search_super_method` explictly calls `vm_cc_new` with `cme=NULL`
when there is no super class.
 Only set shape id for CCs on attr_set + ivar 2024-07-31T23:23:28+00:00 Aaron Patterson tenderlove@ruby-lang.org 2024-06-07T00:38:25+00:00 bbeebc9258f11db188c34a9a24e64f03448667c3 Only ivar reader and writer methods should need the shape ID set on the inline cache. We shouldn't accidentally overwrite parts of the CC union when it's not necessary. 
Only ivar reader and writer methods should need the shape ID set on the
inline cache.  We shouldn't accidentally overwrite parts of the CC union
when it's not necessary.
Fix comment for VM_CALL_ARGS_SIMPLE (#11067) 2024-06-28T14:11:35+00:00 Gabriel Lacroix lacroixgabriel@gmail.com 2024-06-28T14:11:35+00:00 1652c194c849468659baa566a2422a308d6eac0c * Set VM_CALL_KWARG flag first and reuse it to avoid checking kw_arg twice * Fix comment for VM_CALL_ARGS_SIMPLE * Make VM_CALL_ARGS_SIMPLE set-site match its comment 
* Set VM_CALL_KWARG flag first and reuse it to avoid checking kw_arg twice

* Fix comment for VM_CALL_ARGS_SIMPLE

* Make VM_CALL_ARGS_SIMPLE set-site match its comment
 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>
We don't need to check if the ci is markable anymore 2024-04-24T22:09:06+00:00 Aaron Patterson tenderlove@ruby-lang.org 2024-04-24T20:39:39+00:00 0434dfb76bdbd0c11f4da244a54357c95bb2fb8c It doesn't matter if CI's are stack allocated or not. 
It doesn't matter if CI's are stack allocated or not.
Implement equality for CI comparison when CC searching 2024-04-18T16:06:33+00:00 Aaron Patterson tenderlove@ruby-lang.org 2024-04-17T23:30:41+00:00 147ca9585ede559fd68e162cbbbaba84f009c9a1 When we're searching for CCs, compare the argc and flags for CI rather than comparing pointers. This means we don't need to store a reference to the CI, and it also naturally "de-duplicates" CC objects. We can observe the effect with the following code: ```ruby require "objspace" hash = {} p ObjectSpace.memsize_of(Hash) eval ("a".."zzz").map { |key| "hash.merge(:#{key} => 1)" }.join("; ") p ObjectSpace.memsize_of(Hash) ``` On master: ``` $ ruby -v test.rb ruby 3.4.0dev (2024-04-15T16:21:41Z master d019b3baec) [arm64-darwin23] test.rb:3: warning: assigned but unused variable - hash 3424 527736 ``` On this branch: ``` $ make runruby compiling vm.c linking miniruby builtin_binary.inc updated compiling builtin.c linking static-library libruby.3.4-static.a ln -sf ../../rbconfig.rb .ext/arm64-darwin23/rbconfig.rb linking ruby ld: warning: ignoring duplicate libraries: '-ldl', '-lobjc', '-lpthread' RUBY_ON_BUG='gdb -x ./.gdbinit -p' ./miniruby -I./lib -I. -I.ext/common ./tool/runruby.rb --extout=.ext -- --disable-gems ./test.rb 2240 2368 ``` Co-authored-by: John Hawthorn <jhawthorn@github.com> 
When we're searching for CCs, compare the argc and flags for CI rather
than comparing pointers.  This means we don't need to store a reference
to the CI, and it also naturally "de-duplicates" CC objects.

We can observe the effect with the following code:

```ruby
require "objspace"

hash = {}

p ObjectSpace.memsize_of(Hash)

eval ("a".."zzz").map { |key|
  "hash.merge(:#{key} => 1)"
}.join("; ")

p ObjectSpace.memsize_of(Hash)
```

On master:

```
$ ruby -v test.rb
ruby 3.4.0dev (2024-04-15T16:21:41Z master d019b3baec) [arm64-darwin23]
test.rb:3: warning: assigned but unused variable - hash
3424
527736
```

On this branch:

```
$ make runruby
compiling vm.c
linking miniruby
builtin_binary.inc updated
compiling builtin.c
linking static-library libruby.3.4-static.a
ln -sf ../../rbconfig.rb .ext/arm64-darwin23/rbconfig.rb
linking ruby
ld: warning: ignoring duplicate libraries: '-ldl', '-lobjc', '-lpthread'
RUBY_ON_BUG='gdb -x ./.gdbinit -p' ./miniruby -I./lib -I. -I.ext/common  ./tool/runruby.rb --extout=.ext  -- --disable-gems  ./test.rb
2240
2368
```

Co-authored-by: John Hawthorn <jhawthorn@github.com>
Add IMEMO_NEW 2024-02-21T16:33:05+00:00 Peter Zhu peter@peterzhu.ca 2024-02-20T20:58:10+00:00 330830dd1a44b6e497250a14d93efae6fa363f82 Rather than exposing that an imemo has a flag and four fields, this changes the implementation to only expose one field (the klass) and fills the rest with 0. The type will have to fill in the values themselves. 
Rather than exposing that an imemo has a flag and four fields, this
changes the implementation to only expose one field (the klass) and
fills the rest with 0. The type will have to fill in the values themselves.
De-dup identical callinfo objects 2024-02-21T02:55:00+00:00 John Hawthorn john@hawthorn.email 2024-02-12T05:43:38+00:00 1c97abaabae6844c861705fd07f532292dcffa74 Previously every call to vm_ci_new (when the CI was not packable) would result in a different callinfo being returned this meant that every kwarg callsite had its own CI. When calling, different CIs result in different CCs. These CIs and CCs both end up persisted on the T_CLASS inside cc_tbl. So in an eval loop this resulted in a memory leak of both types of object. This also likely resulted in extra memory used, and extra time searching, in non-eval cases. For simplicity in this commit I always allocate a CI object inside rb_vm_ci_lookup, but ideally we would lazily allocate it only when needed. I hope to do that as a follow up in the future. 
Previously every call to vm_ci_new (when the CI was not packable) would
result in a different callinfo being returned this meant that every
kwarg callsite had its own CI.

When calling, different CIs result in different CCs. These CIs and CCs
both end up persisted on the T_CLASS inside cc_tbl. So in an eval loop
this resulted in a memory leak of both types of object. This also likely
resulted in extra memory used, and extra time searching, in non-eval
cases.

For simplicity in this commit I always allocate a CI object inside
rb_vm_ci_lookup, but ideally we would lazily allocate it only when
needed. I hope to do that as a follow up in the future.
Add VM_CALL_ARGS_SPLAT_MUT callinfo flag 2024-01-25T02:25:55+00:00 Jeremy Evans code@jeremyevans.net 2023-11-23T18:47:24+00:00 22e488464a412afa58f201c49e54773aa8011320 This flag is set when the caller has already created a new array to handle a splat, such as for `f(*a, b)` and `f(*a, *b)`. Previously, if `f` was defined as `def f(*a)`, these calls would create an extra array on the callee side, instead of using the new array created by the caller. This modifies `setup_args_core` to set the flag whenver it would add a `splatarray true` instruction. However, when `splatarray true` is changed to `splatarray false` in the peephole optimizer, to avoid unnecessary allocations on the caller side, the flag must be removed. Add `optimize_args_splat_no_copy` and have the peephole optimizer call that. This significantly simplifies the related peephole optimizer code. On the callee side, in `setup_parameters_complex`, set `args->rest_dupped` to true if the flag is set. This takes a similar approach for optimizing regular splats that was previiously used for keyword splats in d2c41b1bff1f3102544bb0d03d4e82356d034d33 (via VM_CALL_KW_SPLAT_MUT). 
This flag is set when the caller has already created a new array to
handle a splat, such as for `f(*a, b)` and `f(*a, *b)`.  Previously,
if `f` was defined as `def f(*a)`, these calls would create an extra
array on the callee side, instead of using the new array created
by the caller.

This modifies `setup_args_core` to set the flag whenver it would add
a `splatarray true` instruction.  However, when `splatarray true` is
changed to `splatarray false` in the peephole optimizer, to avoid
unnecessary allocations on the caller side, the flag must be removed.
Add `optimize_args_splat_no_copy` and have the peephole optimizer call
that.  This significantly simplifies the related peephole optimizer
code.

On the callee side, in `setup_parameters_complex`, set
`args->rest_dupped` to true if the flag is set.

This takes a similar approach for optimizing regular splats that was
previiously used for keyword splats in
d2c41b1bff1f3102544bb0d03d4e82356d034d33 (via VM_CALL_KW_SPLAT_MUT).
Support tracing of struct member accessor methods 2023-12-07T18:29:33+00:00 Jeremy Evans code@jeremyevans.net 2023-10-27T00:03:17+00:00 3081c83169c55ef7eead6222e49248e09232c22c This follows the same approach used for attr_reader/attr_writer in 2d98593bf54a37397c6e4886ccc7e3654c2eaf85, skipping the checking for tracing after the first call using the call cache, and clearing the call cache when tracing is turned on/off. Fixes [Bug #18886] 
This follows the same approach used for attr_reader/attr_writer in
2d98593bf54a37397c6e4886ccc7e3654c2eaf85, skipping the checking for
tracing after the first call using the call cache, and clearing the
call cache when tracing is turned on/off.

Fixes [Bug #18886]