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ruby--ruby/gc.rb
Peter Zhu b0bbcaedc7 Revert "Add GC.stat_size_pool to get stats for a size pool"
This reverts commit 6157619bb6.

We'll wait for comments in the open ticket: https://bugs.ruby-lang.org/issues/18364
2021-11-25 11:01:50 -05:00

312 lines
10 KiB
Ruby

# for gc.c
# The GC module provides an interface to Ruby's mark and
# sweep garbage collection mechanism.
#
# Some of the underlying methods are also available via the ObjectSpace
# module.
#
# You may obtain information about the operation of the GC through
# GC::Profiler.
module GC
# call-seq:
# GC.start -> nil
# ObjectSpace.garbage_collect -> nil
# include GC; garbage_collect -> nil
# GC.start(full_mark: true, immediate_sweep: true) -> nil
# ObjectSpace.garbage_collect(full_mark: true, immediate_sweep: true) -> nil
# include GC; garbage_collect(full_mark: true, immediate_sweep: true) -> nil
#
# Initiates garbage collection, even if manually disabled.
#
# This method is defined with keyword arguments that default to true:
#
# def GC.start(full_mark: true, immediate_sweep: true); end
#
# Use full_mark: false to perform a minor GC.
# Use immediate_sweep: false to defer sweeping (use lazy sweep).
#
# Note: These keyword arguments are implementation and version dependent. They
# are not guaranteed to be future-compatible, and may be ignored if the
# underlying implementation does not support them.
def self.start full_mark: true, immediate_mark: true, immediate_sweep: true
Primitive.gc_start_internal full_mark, immediate_mark, immediate_sweep, false
end
def garbage_collect full_mark: true, immediate_mark: true, immediate_sweep: true
Primitive.gc_start_internal full_mark, immediate_mark, immediate_sweep, false
end
# call-seq:
# GC.auto_compact -> true or false
#
# Returns whether or not automatic compaction has been enabled.
#
def self.auto_compact
Primitive.gc_get_auto_compact
end
# call-seq:
# GC.auto_compact = flag
#
# Updates automatic compaction mode.
#
# When enabled, the compactor will execute on every major collection.
#
# Enabling compaction will degrade performance on major collections.
def self.auto_compact=(flag)
Primitive.gc_set_auto_compact(flag)
end
# call-seq:
# GC.enable -> true or false
#
# Enables garbage collection, returning +true+ if garbage
# collection was previously disabled.
#
# GC.disable #=> false
# GC.enable #=> true
# GC.enable #=> false
#
def self.enable
Primitive.gc_enable
end
# call-seq:
# GC.disable -> true or false
#
# Disables garbage collection, returning +true+ if garbage
# collection was already disabled.
#
# GC.disable #=> false
# GC.disable #=> true
def self.disable
Primitive.gc_disable
end
# call-seq:
# GC.stress -> integer, true or false
#
# Returns current status of GC stress mode.
def self.stress
Primitive.gc_stress_get
end
# call-seq:
# GC.stress = flag -> flag
#
# Updates the GC stress mode.
#
# When stress mode is enabled, the GC is invoked at every GC opportunity:
# all memory and object allocations.
#
# Enabling stress mode will degrade performance, it is only for debugging.
#
# flag can be true, false, or an integer bit-ORed following flags.
# 0x01:: no major GC
# 0x02:: no immediate sweep
# 0x04:: full mark after malloc/calloc/realloc
def self.stress=(flag)
Primitive.gc_stress_set_m flag
end
# call-seq:
# GC.count -> Integer
#
# The number of times GC occurred.
#
# It returns the number of times GC occurred since the process started.
def self.count
Primitive.gc_count
end
# call-seq:
# GC.stat -> Hash
# GC.stat(hash) -> hash
# GC.stat(:key) -> Numeric
#
# Returns a Hash containing information about the GC.
#
# The contents of the hash are implementation specific and may be changed in
# the future.
#
# The hash includes information about internal statistics about GC such as:
#
# [count]
# The total number of garbage collections ran since application start
# (count includes both minor and major garbage collections)
# [heap_allocated_pages]
# The total number of `:heap_eden_pages` + `:heap_tomb_pages`
# [heap_sorted_length]
# The number of pages that can fit into the buffer that holds references to
# all pages
# [heap_allocatable_pages]
# The total number of pages the application could allocate without additional GC
# [heap_available_slots]
# The total number of slots in all `:heap_allocated_pages`
# [heap_live_slots]
# The total number of slots which contain live objects
# [heap_free_slots]
# The total number of slots which do not contain live objects
# [heap_final_slots]
# The total number of slots with pending finalizers to be run
# [heap_marked_slots]
# The total number of objects marked in the last GC
# [heap_eden_pages]
# The total number of pages which contain at least one live slot
# [heap_tomb_pages]
# The total number of pages which do not contain any live slots
# [total_allocated_pages]
# The cumulative number of pages allocated since application start
# [total_freed_pages]
# The cumulative number of pages freed since application start
# [total_allocated_objects]
# The cumulative number of objects allocated since application start
# [total_freed_objects]
# The cumulative number of objects freed since application start
# [malloc_increase_bytes]
# Amount of memory allocated on the heap for objects. Decreased by any GC
# [malloc_increase_bytes_limit]
# When `:malloc_increase_bytes` crosses this limit, GC is triggered
# [minor_gc_count]
# The total number of minor garbage collections run since process start
# [major_gc_count]
# The total number of major garbage collections run since process start
# [remembered_wb_unprotected_objects]
# The total number of objects without write barriers
# [remembered_wb_unprotected_objects_limit]
# When `:remembered_wb_unprotected_objects` crosses this limit,
# major GC is triggered
# [old_objects]
# Number of live, old objects which have survived at least 3 garbage collections
# [old_objects_limit]
# When `:old_objects` crosses this limit, major GC is triggered
# [oldmalloc_increase_bytes]
# Amount of memory allocated on the heap for objects. Decreased by major GC
# [oldmalloc_increase_bytes_limit]
# When `:old_malloc_increase_bytes` crosses this limit, major GC is triggered
#
# If the optional argument, hash, is given,
# it is overwritten and returned.
# This is intended to avoid probe effect.
#
# This method is only expected to work on C Ruby.
def self.stat hash_or_key = nil
Primitive.gc_stat hash_or_key
end
# call-seq:
# GC.latest_gc_info -> {:gc_by=>:newobj}
# GC.latest_gc_info(hash) -> hash
# GC.latest_gc_info(:major_by) -> :malloc
#
# Returns information about the most recent garbage collection.
#
# If the optional argument, hash, is given,
# it is overwritten and returned.
# This is intended to avoid probe effect.
def self.latest_gc_info hash_or_key = nil
Primitive.gc_latest_gc_info hash_or_key
end
# call-seq:
# GC.latest_compact_info -> {:considered=>{:T_CLASS=>11}, :moved=>{:T_CLASS=>11}}
#
# Returns information about object moved in the most recent GC compaction.
#
# The returned hash has two keys :considered and :moved. The hash for
# :considered lists the number of objects that were considered for movement
# by the compactor, and the :moved hash lists the number of objects that
# were actually moved. Some objects can't be moved (maybe they were pinned)
# so these numbers can be used to calculate compaction efficiency.
def self.latest_compact_info
Primitive.gc_compact_stats
end
# call-seq:
# GC.compact
#
# This function compacts objects together in Ruby's heap. It eliminates
# unused space (or fragmentation) in the heap by moving objects in to that
# unused space. This function returns a hash which contains statistics about
# which objects were moved. See `GC.latest_gc_info` for details about
# compaction statistics.
#
# This method is implementation specific and not expected to be implemented
# in any implementation besides MRI.
def self.compact
Primitive.gc_compact
end
# call-seq:
# GC.verify_compaction_references(toward: nil, double_heap: false) -> hash
#
# Verify compaction reference consistency.
#
# This method is implementation specific. During compaction, objects that
# were moved are replaced with T_MOVED objects. No object should have a
# reference to a T_MOVED object after compaction.
#
# This function doubles the heap to ensure room to move all objects,
# compacts the heap to make sure everything moves, updates all references,
# then performs a full GC. If any object contains a reference to a T_MOVED
# object, that object should be pushed on the mark stack, and will
# make a SEGV.
def self.verify_compaction_references(toward: nil, double_heap: false)
Primitive.gc_verify_compaction_references(double_heap, toward == :empty)
end
# :nodoc:
# call-seq:
# GC.using_rvargc? -> true or false
#
# Returns true if using experimental feature Variable Width Allocation, false
# otherwise.
def self.using_rvargc?
GC::INTERNAL_CONSTANTS[:SIZE_POOL_COUNT] > 1
end
# call-seq:
# GC.measure_total_time = true/false
#
# Enable to measure GC time.
# You can get the result with `GC.stat(:time)`.
# Note that the GC time measurement can introduce the performance regression.
def self.measure_total_time=(flag)
Primitive.cstmt! %{
rb_objspace.flags.measure_gc = RTEST(flag) ? TRUE : FALSE;
return flag;
}
end
# call-seq:
# GC.measure_total_time -> true/false
#
# Return measure_total_time flag (default: true).
# Note that measurement can affect the application performance.
def self.measure_total_time
Primitive.cexpr! %{
RBOOL(rb_objspace.flags.measure_gc)
}
end
# call-seq:
# GC.total_time -> int
#
# Return measured GC total time in nano seconds.
def self.total_time
Primitive.cexpr! %{
ULL2NUM(rb_objspace.profile.total_time_ns)
}
end
end
module ObjectSpace
def garbage_collect full_mark: true, immediate_mark: true, immediate_sweep: true
Primitive.gc_start_internal full_mark, immediate_mark, immediate_sweep, false
end
module_function :garbage_collect
end