d5/d88/default_8c_source.html

#include "ruby/internal/config.h"


#include <signal.h>


#ifndef _WIN32

# include <sys/mman.h>

# include <unistd.h>

# ifdef HAVE_SYS_PRCTL_H

#  include <sys/prctl.h>

# endif

#endif


#if !defined(PAGE_SIZE) && defined(HAVE_SYS_USER_H)

/* LIST_HEAD conflicts with sys/queue.h on macOS */

# include <sys/user.h>

#endif


#ifdef BUILDING_MODULAR_GC

# define nlz_int64(x) (x == 0 ? 64 : (unsigned int)__builtin_clzll((unsigned long long)x))

#else

# include "internal/bits.h"

#endif


#include "ruby/ruby.h"

#include "ruby/atomic.h"

#include "ruby/debug.h"

#include "ruby/thread.h"

#include "ruby/util.h"

#include "ruby/vm.h"

#include "ruby/internal/encoding/string.h"

#include "ccan/list/list.h"

#include "darray.h"

#include "gc/gc.h"

#include "gc/gc_impl.h"


#ifndef BUILDING_MODULAR_GC

# include "probes.h"

#endif


#ifdef BUILDING_MODULAR_GC

# define RB_DEBUG_COUNTER_INC(_name) ((void)0)

# define RB_DEBUG_COUNTER_INC_IF(_name, cond) (!!(cond))

#else

# include "debug_counter.h"

#endif


#ifdef BUILDING_MODULAR_GC

# define rb_asan_poison_object(obj) ((void)(obj))

# define rb_asan_unpoison_object(obj, newobj_p) ((void)(obj), (void)(newobj_p))

# define asan_unpoisoning_object(obj) if ((obj) || true)

# define asan_poison_memory_region(ptr, size) ((void)(ptr), (void)(size))

# define asan_unpoison_memory_region(ptr, size, malloc_p) ((void)(ptr), (size), (malloc_p))

# define asan_unpoisoning_memory_region(ptr, size) if ((ptr) || (size) || true)


# define VALGRIND_MAKE_MEM_DEFINED(ptr, size) ((void)(ptr), (void)(size))

# define VALGRIND_MAKE_MEM_UNDEFINED(ptr, size) ((void)(ptr), (void)(size))

#else

# include "internal/sanitizers.h"

#endif


/* MALLOC_HEADERS_BEGIN */

#ifndef HAVE_MALLOC_USABLE_SIZE

# ifdef _WIN32

#  define HAVE_MALLOC_USABLE_SIZE

#  define malloc_usable_size(a) _msize(a)

# elif defined HAVE_MALLOC_SIZE

#  define HAVE_MALLOC_USABLE_SIZE

#  define malloc_usable_size(a) malloc_size(a)

# endif

#endif


#ifdef HAVE_MALLOC_USABLE_SIZE

# ifdef RUBY_ALTERNATIVE_MALLOC_HEADER

/* Alternative malloc header is included in ruby/missing.h */

# elif defined(HAVE_MALLOC_H)

#  include <malloc.h>

# elif defined(HAVE_MALLOC_NP_H)

#  include <malloc_np.h>

# elif defined(HAVE_MALLOC_MALLOC_H)

#  include <malloc/malloc.h>

# endif

#endif


#ifdef HAVE_MALLOC_TRIM

# include <malloc.h>


# ifdef __EMSCRIPTEN__

/* malloc_trim is defined in emscripten/emmalloc.h on emscripten. */

#  include <emscripten/emmalloc.h>

# endif

#endif


#ifdef HAVE_MACH_TASK_EXCEPTION_PORTS

# include <mach/task.h>

# include <mach/mach_init.h>

# include <mach/mach_port.h>

#endif


#ifndef VM_CHECK_MODE

# define VM_CHECK_MODE RUBY_DEBUG

#endif


// From ractor_core.h

#ifndef RACTOR_CHECK_MODE

# define RACTOR_CHECK_MODE (VM_CHECK_MODE || RUBY_DEBUG) && (SIZEOF_UINT64_T == SIZEOF_VALUE)

#endif


#ifndef RUBY_DEBUG_LOG

# define RUBY_DEBUG_LOG(...)

#endif


#ifndef GC_HEAP_INIT_BYTES

#define GC_HEAP_INIT_BYTES (2560 * 1024)

#endif

#ifndef GC_HEAP_FREE_SLOTS

#define GC_HEAP_FREE_SLOTS  4096

#endif

#ifndef GC_HEAP_GROWTH_FACTOR

#define GC_HEAP_GROWTH_FACTOR 1.8

#endif

#ifndef GC_HEAP_GROWTH_MAX_BYTES

#define GC_HEAP_GROWTH_MAX_BYTES 0 /* 0 is disable */

#endif

#ifndef GC_HEAP_REMEMBERED_WB_UNPROTECTED_OBJECTS_LIMIT_RATIO

# define GC_HEAP_REMEMBERED_WB_UNPROTECTED_OBJECTS_LIMIT_RATIO 0.01

#endif

#ifndef GC_HEAP_OLDOBJECT_LIMIT_FACTOR

#define GC_HEAP_OLDOBJECT_LIMIT_FACTOR 2.0

#endif


#ifndef GC_HEAP_FREE_SLOTS_MIN_RATIO

#define GC_HEAP_FREE_SLOTS_MIN_RATIO  0.20

#endif

#ifndef GC_HEAP_FREE_SLOTS_GOAL_RATIO

#define GC_HEAP_FREE_SLOTS_GOAL_RATIO 0.40

#endif

#ifndef GC_HEAP_FREE_SLOTS_MAX_RATIO

#define GC_HEAP_FREE_SLOTS_MAX_RATIO  0.65

#endif


#ifndef GC_MALLOC_LIMIT_MIN

#define GC_MALLOC_LIMIT_MIN (16 * 1024 * 1024 /* 16MB */)

#endif

#ifndef GC_MALLOC_LIMIT_MAX

#define GC_MALLOC_LIMIT_MAX (32 * 1024 * 1024 /* 32MB */)

#endif

#ifndef GC_MALLOC_LIMIT_GROWTH_FACTOR

#define GC_MALLOC_LIMIT_GROWTH_FACTOR 1.4

#endif


#ifndef GC_OLDMALLOC_LIMIT_MIN

#define GC_OLDMALLOC_LIMIT_MIN (16 * 1024 * 1024 /* 16MB */)

#endif

#ifndef GC_OLDMALLOC_LIMIT_GROWTH_FACTOR

#define GC_OLDMALLOC_LIMIT_GROWTH_FACTOR 1.2

#endif

#ifndef GC_OLDMALLOC_LIMIT_MAX

#define GC_OLDMALLOC_LIMIT_MAX (128 * 1024 * 1024 /* 128MB */)

#endif


#ifndef GC_MALLOC_INCREASE_LOCAL_THRESHOLD

#define GC_MALLOC_INCREASE_LOCAL_THRESHOLD (8 * 1024 /* 8KB */)

#endif


#ifdef RB_THREAD_LOCAL_SPECIFIER

#define USE_MALLOC_INCREASE_LOCAL 1

static RB_THREAD_LOCAL_SPECIFIER int malloc_increase_local;

#else

#define USE_MALLOC_INCREASE_LOCAL 0

#endif


#ifndef GC_CAN_COMPILE_COMPACTION

#if defined(__wasi__) /* WebAssembly doesn't support signals */

# define GC_CAN_COMPILE_COMPACTION 0

#else

# define GC_CAN_COMPILE_COMPACTION 1

#endif

#endif


#ifndef PRINT_ENTER_EXIT_TICK

# define PRINT_ENTER_EXIT_TICK 0

#endif

#ifndef PRINT_ROOT_TICKS

#define PRINT_ROOT_TICKS 0

#endif


#define USE_TICK_T                 (PRINT_ENTER_EXIT_TICK || PRINT_ROOT_TICKS)


#ifndef HEAP_COUNT

# if SIZEOF_VALUE >= 8

#  define HEAP_COUNT 12

# else

#  define HEAP_COUNT 5

# endif

#endif


/* The reciprocal table and pool_slot_sizes array are both generated from this

 * single definition, so they can never get out of sync. */

#if SIZEOF_VALUE >= 8

# define EACH_POOL_SLOT_SIZE(SLOT) \

    SLOT(32) SLOT(40) SLOT(64) SLOT(80) SLOT(96) SLOT(128) \

    SLOT(160) SLOT(256) SLOT(512) SLOT(640) SLOT(768) SLOT(1024)

#else

# define EACH_POOL_SLOT_SIZE(SLOT) \

    SLOT(32) SLOT(64) SLOT(128) SLOT(256) SLOT(512)

#endif


/* Precomputed reciprocals for fast slot index calculation.

 * For slot size d: reciprocal = ceil(2^48 / d).

 * Then offset / d == (uint32_t)((offset * reciprocal) >> 48)

 * for all offset < HEAP_PAGE_SIZE. */

#define SLOT_RECIPROCAL_SHIFT 48

#define SLOT_RECIPROCAL(size) (((1ULL << SLOT_RECIPROCAL_SHIFT) + (size) - 1) / (size))


static const uint64_t heap_slot_reciprocal_table[HEAP_COUNT] = {

#define SLOT(size) SLOT_RECIPROCAL(size),

    EACH_POOL_SLOT_SIZE(SLOT)

#undef SLOT

};


typedef struct ractor_newobj_heap_cache {

    struct free_slot *freelist;

    struct heap_page *using_page;

    size_t allocated_objects_count;

} rb_ractor_newobj_heap_cache_t;


typedef struct ractor_newobj_cache {

    size_t incremental_mark_step_allocated_slots;

    rb_ractor_newobj_heap_cache_t heap_caches[HEAP_COUNT];

} rb_ractor_newobj_cache_t;


typedef struct {

    size_t heap_init_bytes;

    size_t heap_free_slots;

    double growth_factor;

    size_t growth_max_bytes;


    double heap_free_slots_min_ratio;

    double heap_free_slots_goal_ratio;

    double heap_free_slots_max_ratio;

    double uncollectible_wb_unprotected_objects_limit_ratio;

    double oldobject_limit_factor;


    size_t malloc_limit_min;

    size_t malloc_limit_max;

    double malloc_limit_growth_factor;


    size_t oldmalloc_limit_min;

    size_t oldmalloc_limit_max;

    double oldmalloc_limit_growth_factor;

} ruby_gc_params_t;


static ruby_gc_params_t gc_params = {

    GC_HEAP_INIT_BYTES,

    GC_HEAP_FREE_SLOTS,

    GC_HEAP_GROWTH_FACTOR,

    GC_HEAP_GROWTH_MAX_BYTES,


    GC_HEAP_FREE_SLOTS_MIN_RATIO,

    GC_HEAP_FREE_SLOTS_GOAL_RATIO,

    GC_HEAP_FREE_SLOTS_MAX_RATIO,

    GC_HEAP_REMEMBERED_WB_UNPROTECTED_OBJECTS_LIMIT_RATIO,

    GC_HEAP_OLDOBJECT_LIMIT_FACTOR,


    GC_MALLOC_LIMIT_MIN,

    GC_MALLOC_LIMIT_MAX,

    GC_MALLOC_LIMIT_GROWTH_FACTOR,


    GC_OLDMALLOC_LIMIT_MIN,

    GC_OLDMALLOC_LIMIT_MAX,

    GC_OLDMALLOC_LIMIT_GROWTH_FACTOR,

};


/* GC_DEBUG:

 *  enable to embed GC debugging information.

 */

#ifndef GC_DEBUG

#define GC_DEBUG 0

#endif


/* RGENGC_DEBUG:

 * 1: basic information

 * 2: remember set operation

 * 3: mark

 * 4:

 * 5: sweep

 */

#ifndef RGENGC_DEBUG

#ifdef RUBY_DEVEL

#define RGENGC_DEBUG       -1

#else

#define RGENGC_DEBUG       0

#endif

#endif

#if RGENGC_DEBUG < 0 && !defined(_MSC_VER)

# define RGENGC_DEBUG_ENABLED(level) (-(RGENGC_DEBUG) >= (level) && ruby_rgengc_debug >= (level))

#elif defined(HAVE_VA_ARGS_MACRO)

# define RGENGC_DEBUG_ENABLED(level) ((RGENGC_DEBUG) >= (level))

#else

# define RGENGC_DEBUG_ENABLED(level) 0

#endif

int ruby_rgengc_debug;


/* RGENGC_PROFILE

 * 0: disable RGenGC profiling

 * 1: enable profiling for basic information

 * 2: enable profiling for each types

 */

#ifndef RGENGC_PROFILE

# define RGENGC_PROFILE     0

#endif


/* RGENGC_ESTIMATE_OLDMALLOC

 * Enable/disable to estimate increase size of malloc'ed size by old objects.

 * If estimation exceeds threshold, then will invoke full GC.

 * 0: disable estimation.

 * 1: enable estimation.

 */

#ifndef RGENGC_ESTIMATE_OLDMALLOC

# define RGENGC_ESTIMATE_OLDMALLOC 1

#endif


#ifndef GC_PROFILE_MORE_DETAIL

# define GC_PROFILE_MORE_DETAIL 0

#endif

#ifndef GC_PROFILE_DETAIL_MEMORY

# define GC_PROFILE_DETAIL_MEMORY 0

#endif

#ifndef GC_ENABLE_LAZY_SWEEP

# define GC_ENABLE_LAZY_SWEEP   1

#endif


#ifndef VERIFY_FREE_SIZE

#if RUBY_DEBUG

#define VERIFY_FREE_SIZE 1

#else

#define VERIFY_FREE_SIZE 0

#endif

#endif


#if VERIFY_FREE_SIZE

#undef CALC_EXACT_MALLOC_SIZE

#define CALC_EXACT_MALLOC_SIZE 1

#endif


#ifndef CALC_EXACT_MALLOC_SIZE

# define CALC_EXACT_MALLOC_SIZE 0

#endif


#if defined(HAVE_MALLOC_USABLE_SIZE) || CALC_EXACT_MALLOC_SIZE > 0

# ifndef MALLOC_ALLOCATED_SIZE

#  define MALLOC_ALLOCATED_SIZE 0

# endif

#else

# define MALLOC_ALLOCATED_SIZE 0

#endif

#ifndef MALLOC_ALLOCATED_SIZE_CHECK

# define MALLOC_ALLOCATED_SIZE_CHECK 0

#endif


#ifndef GC_DEBUG_STRESS_TO_CLASS

# define GC_DEBUG_STRESS_TO_CLASS RUBY_DEBUG

#endif


typedef enum {

    GPR_FLAG_NONE               = 0x000,

    /* major reason */

    GPR_FLAG_MAJOR_BY_NOFREE    = 0x001,

    GPR_FLAG_MAJOR_BY_OLDGEN    = 0x002,

    GPR_FLAG_MAJOR_BY_SHADY     = 0x004,

    GPR_FLAG_MAJOR_BY_FORCE     = 0x008,

#if RGENGC_ESTIMATE_OLDMALLOC

    GPR_FLAG_MAJOR_BY_OLDMALLOC = 0x020,

#endif

    GPR_FLAG_MAJOR_MASK         = 0x0ff,


    /* gc reason */

    GPR_FLAG_NEWOBJ             = 0x100,

    GPR_FLAG_MALLOC             = 0x200,

    GPR_FLAG_METHOD             = 0x400,

    GPR_FLAG_CAPI               = 0x800,

    GPR_FLAG_STRESS            = 0x1000,


    /* others */

    GPR_FLAG_IMMEDIATE_SWEEP   = 0x2000,

    GPR_FLAG_HAVE_FINALIZE     = 0x4000,

    GPR_FLAG_IMMEDIATE_MARK    = 0x8000,

    GPR_FLAG_FULL_MARK        = 0x10000,

    GPR_FLAG_COMPACT          = 0x20000,


    GPR_DEFAULT_REASON =

        (GPR_FLAG_FULL_MARK | GPR_FLAG_IMMEDIATE_MARK |

         GPR_FLAG_IMMEDIATE_SWEEP | GPR_FLAG_CAPI),

} gc_profile_record_flag;


typedef struct gc_profile_record {

    unsigned int flags;


    double gc_time;

    double gc_invoke_time;


    size_t heap_total_objects;

    size_t heap_use_size;

    size_t heap_total_size;

    size_t moved_objects;


#if GC_PROFILE_MORE_DETAIL

    double gc_mark_time;

    double gc_sweep_time;


    size_t heap_use_pages;

    size_t heap_live_objects;

    size_t heap_free_objects;


    size_t allocate_increase;

    size_t allocate_limit;


    double prepare_time;

    size_t removing_objects;

    size_t empty_objects;

#if GC_PROFILE_DETAIL_MEMORY

    long maxrss;

    long minflt;

    long majflt;

#endif

#endif

#if MALLOC_ALLOCATED_SIZE

    size_t allocated_size;

#endif


#if RGENGC_PROFILE > 0

    size_t old_objects;

    size_t remembered_normal_objects;

    size_t remembered_shady_objects;

#endif

} gc_profile_record;


struct RMoved {

    VALUE flags;

    VALUE dummy;

    VALUE destination;

    uint32_t original_shape_id;

};


#define RMOVED(obj) ((struct RMoved *)(obj))


typedef uintptr_t bits_t;

enum {

    BITS_SIZE = sizeof(bits_t),

    BITS_BITLENGTH = ( BITS_SIZE * CHAR_BIT )

};


struct heap_page_header {

    struct heap_page *page;

};


struct heap_page_body {

    struct heap_page_header header;

    /* char gap[];      */

    /* RVALUE values[]; */

};


#define STACK_CHUNK_SIZE 500


typedef struct stack_chunk {

    VALUE data[STACK_CHUNK_SIZE];

    struct stack_chunk *next;

} stack_chunk_t;


typedef struct mark_stack {

    stack_chunk_t *chunk;

    stack_chunk_t *cache;

    int index;

    int limit;

    size_t cache_size;

    size_t unused_cache_size;

} mark_stack_t;


typedef int (*gc_compact_compare_func)(const void *l, const void *r, void *d);


typedef struct rb_heap_struct {

    short slot_size;


    /* Basic statistics */

    size_t total_allocated_pages;

    size_t force_major_gc_count;

    size_t force_incremental_marking_finish_count;

    size_t total_allocated_objects;

    size_t total_freed_objects;

    size_t final_slots_count;


    /* Sweeping statistics */

    size_t freed_slots;

    size_t empty_slots;


    struct heap_page *free_pages;

    struct ccan_list_head pages;

    struct heap_page *sweeping_page; /* iterator for .pages */

    struct heap_page *compact_cursor;

    uintptr_t compact_cursor_index;

    struct heap_page *pooled_pages;

    size_t total_pages;      /* total page count in a heap */

    size_t total_slots;      /* total slot count */


} rb_heap_t;


enum {

    gc_stress_no_major,

    gc_stress_no_immediate_sweep,

    gc_stress_full_mark_after_malloc,

    gc_stress_max

};


enum gc_mode {

    gc_mode_none,

    gc_mode_marking,

    gc_mode_sweeping,

    gc_mode_compacting,

};


typedef struct rb_objspace {

    struct {

        size_t increase;

#if RGENGC_ESTIMATE_OLDMALLOC

        size_t oldmalloc_increase;

#endif

    } malloc_counters;


    struct {

        size_t limit;

#if MALLOC_ALLOCATED_SIZE

        size_t allocated_size;

        size_t allocations;

#endif

    } malloc_params;


    struct rb_gc_config {

        bool full_mark;

    } gc_config;


    struct {

        unsigned int mode : 2;

        unsigned int immediate_sweep : 1;

        unsigned int dont_gc : 1;

        unsigned int dont_incremental : 1;

        unsigned int during_gc : 1;

        unsigned int during_compacting : 1;

        unsigned int during_reference_updating : 1;

        unsigned int gc_stressful: 1;

        unsigned int during_minor_gc : 1;

        unsigned int during_incremental_marking : 1;

        unsigned int measure_gc : 1;

    } flags;


    rb_event_flag_t hook_events;


    rb_heap_t heaps[HEAP_COUNT];

    size_t empty_pages_count;

    struct heap_page *empty_pages;


    struct {

        rb_atomic_t finalizing;

    } atomic_flags;


    mark_stack_t mark_stack;

    size_t marked_slots;


    struct {

        rb_darray(struct heap_page *) sorted;


        size_t allocated_pages;

        size_t freed_pages;

        uintptr_t range[2];

        size_t freeable_pages;


        size_t allocatable_bytes;


        /* final */

        VALUE deferred_final;

    } heap_pages;


    st_table *finalizer_table;


    struct {

        int run;

        unsigned int latest_gc_info;

        gc_profile_record *records;

        gc_profile_record *current_record;

        size_t next_index;

        size_t size;


#if GC_PROFILE_MORE_DETAIL

        double prepare_time;

#endif

        double invoke_time;


        size_t minor_gc_count;

        size_t major_gc_count;

        size_t compact_count;

        size_t read_barrier_faults;

#if RGENGC_PROFILE > 0

        size_t total_generated_normal_object_count;

        size_t total_generated_shady_object_count;

        size_t total_shade_operation_count;

        size_t total_promoted_count;

        size_t total_remembered_normal_object_count;

        size_t total_remembered_shady_object_count;


#if RGENGC_PROFILE >= 2

        size_t generated_normal_object_count_types[RUBY_T_MASK];

        size_t generated_shady_object_count_types[RUBY_T_MASK];

        size_t shade_operation_count_types[RUBY_T_MASK];

        size_t promoted_types[RUBY_T_MASK];

        size_t remembered_normal_object_count_types[RUBY_T_MASK];

        size_t remembered_shady_object_count_types[RUBY_T_MASK];

#endif

#endif /* RGENGC_PROFILE */


        /* temporary profiling space */

        double gc_sweep_start_time;

        size_t total_allocated_objects_at_gc_start;

        size_t heap_used_at_gc_start;

        size_t heap_total_slots_at_gc_start;


        /* basic statistics */

        size_t count;

        unsigned long long marking_time_ns;

        struct timespec marking_start_time;

        unsigned long long sweeping_time_ns;

        struct timespec sweeping_start_time;


        /* Weak references */

        size_t weak_references_count;

    } profile;


    VALUE gc_stress_mode;


    struct {

        bool parent_object_old_p;

        VALUE parent_object;


        int need_major_gc;

        size_t last_major_gc;

        size_t uncollectible_wb_unprotected_objects;

        size_t uncollectible_wb_unprotected_objects_limit;

        size_t old_objects;

        size_t old_objects_limit;


#if RGENGC_ESTIMATE_OLDMALLOC

        size_t oldmalloc_increase_limit;

#endif


#if RGENGC_CHECK_MODE >= 2

        struct st_table *allrefs_table;

        size_t error_count;

#endif

    } rgengc;


    struct {

        size_t considered_count_table[T_MASK];

        size_t moved_count_table[T_MASK];

        size_t moved_up_count_table[T_MASK];

        size_t moved_down_count_table[T_MASK];

        size_t total_moved;


        /* This function will be used, if set, to sort the heap prior to compaction */

        gc_compact_compare_func compare_func;

    } rcompactor;


    struct {

        size_t pooled_slots;

        size_t step_slots;

    } rincgc;


#if GC_DEBUG_STRESS_TO_CLASS

    VALUE stress_to_class;

#endif


    rb_darray(VALUE) weak_references;

    rb_postponed_job_handle_t finalize_deferred_pjob;


    unsigned long live_ractor_cache_count;


    int sweeping_heap_count;


    int fork_vm_lock_lev;

} rb_objspace_t;


#ifndef HEAP_PAGE_ALIGN_LOG

/* default tiny heap size: 64KiB */

#define HEAP_PAGE_ALIGN_LOG 16

#endif


#if RACTOR_CHECK_MODE || GC_DEBUG

struct rvalue_overhead {

# if RACTOR_CHECK_MODE

    uint32_t _ractor_belonging_id;

# endif

# if GC_DEBUG

    const char *file;

    int line;

# endif

};


// Make sure that RVALUE_OVERHEAD aligns to sizeof(VALUE)

# define RVALUE_OVERHEAD (sizeof(struct { \

    union { \

        struct rvalue_overhead overhead; \

        VALUE value; \

    }; \

}))

size_t rb_gc_impl_obj_slot_size(VALUE obj);

# define GET_RVALUE_OVERHEAD(obj) ((struct rvalue_overhead *)((uintptr_t)obj + rb_gc_impl_obj_slot_size(obj)))

#else

# ifndef RVALUE_OVERHEAD

#  define RVALUE_OVERHEAD 0

# endif

#endif


#define RVALUE_SLOT_SIZE (sizeof(struct RBasic) + sizeof(VALUE[RBIMPL_RVALUE_EMBED_LEN_MAX]) + RVALUE_OVERHEAD)


static const size_t pool_slot_sizes[HEAP_COUNT] = {

#define SLOT(size) size,

    EACH_POOL_SLOT_SIZE(SLOT)

#undef SLOT

};


#if SIZEOF_VALUE >= 8

static uint8_t size_to_heap_idx[1024 / 8 + 1];

#else

static uint8_t size_to_heap_idx[512 / 8 + 1];

#endif


#ifndef MAX

# define MAX(a, b) (((a) > (b)) ? (a) : (b))

#endif

#ifndef MIN

# define MIN(a, b) (((a) < (b)) ? (a) : (b))

#endif

#define roomof(x, y) (((x) + (y) - 1) / (y))

#define CEILDIV(i, mod) roomof(i, mod)

#define MIN_POOL_SLOT_SIZE 32

enum {

    HEAP_PAGE_ALIGN = (1UL << HEAP_PAGE_ALIGN_LOG),

    HEAP_PAGE_ALIGN_MASK = (~(~0UL << HEAP_PAGE_ALIGN_LOG)),

    HEAP_PAGE_SIZE = HEAP_PAGE_ALIGN,

    HEAP_PAGE_BITMAP_LIMIT = CEILDIV(CEILDIV(HEAP_PAGE_SIZE, MIN_POOL_SLOT_SIZE), BITS_BITLENGTH),

    HEAP_PAGE_BITMAP_SIZE = (BITS_SIZE * HEAP_PAGE_BITMAP_LIMIT),

};

#define HEAP_PAGE_ALIGN (1 << HEAP_PAGE_ALIGN_LOG)

#define HEAP_PAGE_SIZE HEAP_PAGE_ALIGN


#if !defined(INCREMENTAL_MARK_STEP_ALLOCATIONS)

# define INCREMENTAL_MARK_STEP_ALLOCATIONS 500

#endif


#undef INIT_HEAP_PAGE_ALLOC_USE_MMAP

/* Must define either HEAP_PAGE_ALLOC_USE_MMAP or

 * INIT_HEAP_PAGE_ALLOC_USE_MMAP. */


#ifndef HAVE_MMAP

/* We can't use mmap of course, if it is not available. */

static const bool HEAP_PAGE_ALLOC_USE_MMAP = false;


#elif defined(__wasm__)

/* wasmtime does not have proper support for mmap.

 * See https://github.com/bytecodealliance/wasmtime/blob/main/docs/WASI-rationale.md#why-no-mmap-and-friends

 */

static const bool HEAP_PAGE_ALLOC_USE_MMAP = false;


#elif HAVE_CONST_PAGE_SIZE

/* If we have the PAGE_SIZE and it is a constant, then we can directly use it. */

static const bool HEAP_PAGE_ALLOC_USE_MMAP = (PAGE_SIZE <= HEAP_PAGE_SIZE);


#elif defined(PAGE_MAX_SIZE) && (PAGE_MAX_SIZE <= HEAP_PAGE_SIZE)

/* If we can use the maximum page size. */

static const bool HEAP_PAGE_ALLOC_USE_MMAP = true;


#elif defined(PAGE_SIZE)

/* If the PAGE_SIZE macro can be used dynamically. */

# define INIT_HEAP_PAGE_ALLOC_USE_MMAP (PAGE_SIZE <= HEAP_PAGE_SIZE)


#elif defined(HAVE_SYSCONF) && defined(_SC_PAGE_SIZE)

/* If we can use sysconf to determine the page size. */

# define INIT_HEAP_PAGE_ALLOC_USE_MMAP (sysconf(_SC_PAGE_SIZE) <= HEAP_PAGE_SIZE)


#else

/* Otherwise we can't determine the system page size, so don't use mmap. */

static const bool HEAP_PAGE_ALLOC_USE_MMAP = false;

#endif


#ifdef INIT_HEAP_PAGE_ALLOC_USE_MMAP

/* We can determine the system page size at runtime. */

# define HEAP_PAGE_ALLOC_USE_MMAP (heap_page_alloc_use_mmap != false)


static bool heap_page_alloc_use_mmap;

#endif


#define RVALUE_AGE_BIT_COUNT 2

#define RVALUE_AGE_BIT_MASK (((bits_t)1 << RVALUE_AGE_BIT_COUNT) - 1)

#define RVALUE_OLD_AGE   3


struct free_slot {

    VALUE flags;                /* always 0 for freed obj */

    struct free_slot *next;

};


struct heap_page {

    /* Cache line 0: allocation fast path + SLOT_INDEX */

    struct free_slot *freelist;

    uintptr_t start;

    uint64_t slot_size_reciprocal;

    unsigned short slot_size;

    unsigned short total_slots;

    unsigned short free_slots;

    unsigned short final_slots;

    unsigned short pinned_slots;

    struct {

        unsigned int before_sweep : 1;

        unsigned int has_remembered_objects : 1;

        unsigned int has_uncollectible_wb_unprotected_objects : 1;

    } flags;


    rb_heap_t *heap;


    struct heap_page *free_next;

    struct heap_page_body *body;

    struct ccan_list_node page_node;


    bits_t wb_unprotected_bits[HEAP_PAGE_BITMAP_LIMIT];

    /* the following three bitmaps are cleared at the beginning of full GC */

    bits_t mark_bits[HEAP_PAGE_BITMAP_LIMIT];

    bits_t uncollectible_bits[HEAP_PAGE_BITMAP_LIMIT];

    bits_t marking_bits[HEAP_PAGE_BITMAP_LIMIT];


    bits_t remembered_bits[HEAP_PAGE_BITMAP_LIMIT];


    /* If set, the object is not movable */

    bits_t pinned_bits[HEAP_PAGE_BITMAP_LIMIT];

    bits_t age_bits[HEAP_PAGE_BITMAP_LIMIT * RVALUE_AGE_BIT_COUNT];

};


/*

 * When asan is enabled, this will prohibit writing to the freelist until it is unlocked

 */

static void

asan_lock_freelist(struct heap_page *page)

{

    asan_poison_memory_region(&page->freelist, sizeof(struct free_list *));

}


/*

 * When asan is enabled, this will enable the ability to write to the freelist

 */

static void

asan_unlock_freelist(struct heap_page *page)

{

    asan_unpoison_memory_region(&page->freelist, sizeof(struct free_list *), false);

}


static inline bool

heap_page_in_global_empty_pages_pool(rb_objspace_t *objspace, struct heap_page *page)

{

    if (page->total_slots == 0) {

        GC_ASSERT(page->start == 0);

        GC_ASSERT(page->slot_size == 0);

        GC_ASSERT(page->heap == NULL);

        GC_ASSERT(page->free_slots == 0);

        asan_unpoisoning_memory_region(&page->freelist, sizeof(&page->freelist)) {

            GC_ASSERT(page->freelist == NULL);

        }


        return true;

    }

    else {

        GC_ASSERT(page->start != 0);

        GC_ASSERT(page->slot_size != 0);

        GC_ASSERT(page->heap != NULL);


        return false;

    }

}


#define GET_PAGE_BODY(x)   ((struct heap_page_body *)((bits_t)(x) & ~(HEAP_PAGE_ALIGN_MASK)))

#define GET_PAGE_HEADER(x) (&GET_PAGE_BODY(x)->header)

#define GET_HEAP_PAGE(x)   (GET_PAGE_HEADER(x)->page)


static inline size_t

slot_index_for_offset(size_t offset, uint64_t reciprocal)

{

    return (uint32_t)(((uint64_t)offset * reciprocal) >> SLOT_RECIPROCAL_SHIFT);

}


#define SLOT_INDEX(page, p)          slot_index_for_offset((uintptr_t)(p) - (page)->start, (page)->slot_size_reciprocal)

#define SLOT_BITMAP_INDEX(page, p)   (SLOT_INDEX(page, p) / BITS_BITLENGTH)

#define SLOT_BITMAP_OFFSET(page, p)  (SLOT_INDEX(page, p) & (BITS_BITLENGTH - 1))

#define SLOT_BITMAP_BIT(page, p)     ((bits_t)1 << SLOT_BITMAP_OFFSET(page, p))


#define _MARKED_IN_BITMAP(bits, page, p)  ((bits)[SLOT_BITMAP_INDEX(page, p)] & SLOT_BITMAP_BIT(page, p))

#define _MARK_IN_BITMAP(bits, page, p)    ((bits)[SLOT_BITMAP_INDEX(page, p)] |= SLOT_BITMAP_BIT(page, p))

#define _CLEAR_IN_BITMAP(bits, page, p)   ((bits)[SLOT_BITMAP_INDEX(page, p)] &= ~SLOT_BITMAP_BIT(page, p))


#define MARKED_IN_BITMAP(bits, p)    _MARKED_IN_BITMAP(bits, GET_HEAP_PAGE(p), p)

#define MARK_IN_BITMAP(bits, p)      _MARK_IN_BITMAP(bits, GET_HEAP_PAGE(p), p)

#define CLEAR_IN_BITMAP(bits, p)     _CLEAR_IN_BITMAP(bits, GET_HEAP_PAGE(p), p)


#define GET_HEAP_MARK_BITS(x)           (&GET_HEAP_PAGE(x)->mark_bits[0])

#define GET_HEAP_PINNED_BITS(x)         (&GET_HEAP_PAGE(x)->pinned_bits[0])

#define GET_HEAP_UNCOLLECTIBLE_BITS(x)  (&GET_HEAP_PAGE(x)->uncollectible_bits[0])

#define GET_HEAP_WB_UNPROTECTED_BITS(x) (&GET_HEAP_PAGE(x)->wb_unprotected_bits[0])

#define GET_HEAP_MARKING_BITS(x)        (&GET_HEAP_PAGE(x)->marking_bits[0])


static int

RVALUE_AGE_GET(VALUE obj)

{

    struct heap_page *page = GET_HEAP_PAGE(obj);

    bits_t *age_bits = page->age_bits;

    size_t slot_idx = SLOT_INDEX(page, obj);

    size_t idx = (slot_idx / BITS_BITLENGTH) * 2;

    int shift = (int)(slot_idx & (BITS_BITLENGTH - 1));

    int lo = (age_bits[idx] >> shift) & 1;

    int hi = (age_bits[idx + 1] >> shift) & 1;

    return lo | (hi << 1);

}


static void

RVALUE_AGE_SET_BITMAP(VALUE obj, int age)

{

    RUBY_ASSERT(age <= RVALUE_OLD_AGE);

    struct heap_page *page = GET_HEAP_PAGE(obj);

    bits_t *age_bits = page->age_bits;

    size_t slot_idx = SLOT_INDEX(page, obj);

    size_t idx = (slot_idx / BITS_BITLENGTH) * 2;

    int shift = (int)(slot_idx & (BITS_BITLENGTH - 1));

    bits_t mask = (bits_t)1 << shift;


    age_bits[idx]     = (age_bits[idx]     & ~mask) | ((bits_t)(age & 1) << shift);

    age_bits[idx + 1] = (age_bits[idx + 1] & ~mask) | ((bits_t)((age >> 1) & 1) << shift);

}


static void

RVALUE_AGE_SET(VALUE obj, int age)

{

    RVALUE_AGE_SET_BITMAP(obj, age);

    if (age == RVALUE_OLD_AGE) {

        RB_FL_SET_RAW(obj, RUBY_FL_PROMOTED);

    }

    else {

        RB_FL_UNSET_RAW(obj, RUBY_FL_PROMOTED);

    }

}


#define malloc_limit            objspace->malloc_params.limit

#define malloc_increase         objspace->malloc_counters.increase

#define malloc_allocated_size   objspace->malloc_params.allocated_size

#define heap_pages_lomem        objspace->heap_pages.range[0]

#define heap_pages_himem        objspace->heap_pages.range[1]

#define heap_pages_freeable_pages       objspace->heap_pages.freeable_pages

#define heap_pages_deferred_final       objspace->heap_pages.deferred_final

#define heaps              objspace->heaps

#define during_gc               objspace->flags.during_gc

#define finalizing              objspace->atomic_flags.finalizing

#define finalizer_table         objspace->finalizer_table

#define ruby_gc_stressful       objspace->flags.gc_stressful

#define ruby_gc_stress_mode     objspace->gc_stress_mode

#if GC_DEBUG_STRESS_TO_CLASS

#define stress_to_class         objspace->stress_to_class

#define set_stress_to_class(c)  (stress_to_class = (c))

#else

#define stress_to_class         ((void)objspace, 0)

#define set_stress_to_class(c)  ((void)objspace, (c))

#endif


#if 0

#define dont_gc_on()          (fprintf(stderr, "dont_gc_on@%s:%d\n",      __FILE__, __LINE__), objspace->flags.dont_gc = 1)

#define dont_gc_off()         (fprintf(stderr, "dont_gc_off@%s:%d\n",     __FILE__, __LINE__), objspace->flags.dont_gc = 0)

#define dont_gc_set(b)        (fprintf(stderr, "dont_gc_set(%d)@%s:%d\n", __FILE__, __LINE__), objspace->flags.dont_gc = (int)(b))

#define dont_gc_val()         (objspace->flags.dont_gc)

#else

#define dont_gc_on()          (objspace->flags.dont_gc = 1)

#define dont_gc_off()         (objspace->flags.dont_gc = 0)

#define dont_gc_set(b)        (objspace->flags.dont_gc = (int)(b))

#define dont_gc_val()         (objspace->flags.dont_gc)

#endif


#define gc_config_full_mark_set(b) (objspace->gc_config.full_mark = (int)(b))

#define gc_config_full_mark_val    (objspace->gc_config.full_mark)


#ifndef DURING_GC_COULD_MALLOC_REGION_START

# define DURING_GC_COULD_MALLOC_REGION_START() \

    assert(rb_during_gc()); \

    bool _prev_enabled = rb_gc_impl_gc_enabled_p(objspace); \

    rb_gc_impl_gc_disable(objspace, false)

#endif


#ifndef DURING_GC_COULD_MALLOC_REGION_END

# define DURING_GC_COULD_MALLOC_REGION_END() \

    if (_prev_enabled) rb_gc_impl_gc_enable(objspace)

#endif


static inline enum gc_mode

gc_mode_verify(enum gc_mode mode)

{

#if RGENGC_CHECK_MODE > 0

    switch (mode) {

      case gc_mode_none:

      case gc_mode_marking:

      case gc_mode_sweeping:

      case gc_mode_compacting:

        break;

      default:

        rb_bug("gc_mode_verify: unreachable (%d)", (int)mode);

    }

#endif

    return mode;

}


static inline bool

has_sweeping_pages(rb_objspace_t *objspace)

{

    return objspace->sweeping_heap_count != 0;

}


static inline size_t

heap_eden_total_pages(rb_objspace_t *objspace)

{

    size_t count = 0;

    for (int i = 0; i < HEAP_COUNT; i++) {

        count += (&heaps[i])->total_pages;

    }

    return count;

}


static inline size_t

total_allocated_objects(rb_objspace_t *objspace)

{

    size_t count = 0;

    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        count += heap->total_allocated_objects;

    }

    return count;

}


static inline size_t

total_freed_objects(rb_objspace_t *objspace)

{

    size_t count = 0;

    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        count += heap->total_freed_objects;

    }

    return count;

}


static inline size_t

total_final_slots_count(rb_objspace_t *objspace)

{

    size_t count = 0;

    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        count += heap->final_slots_count;

    }

    return count;

}


#define gc_mode(objspace)                gc_mode_verify((enum gc_mode)(objspace)->flags.mode)

#define gc_mode_set(objspace, m)         ((objspace)->flags.mode = (unsigned int)gc_mode_verify(m))

#define gc_needs_major_flags objspace->rgengc.need_major_gc


#define is_marking(objspace)             (gc_mode(objspace) == gc_mode_marking)

#define is_sweeping(objspace)            (gc_mode(objspace) == gc_mode_sweeping)

#define is_full_marking(objspace)        ((objspace)->flags.during_minor_gc == FALSE)

#define is_incremental_marking(objspace) ((objspace)->flags.during_incremental_marking != FALSE)

#define will_be_incremental_marking(objspace) ((objspace)->rgengc.need_major_gc != GPR_FLAG_NONE)

/*

 * Byte budget for incremental sweep steps. Each step sweeps at most

 * this many bytes worth of slots before yielding. The effective slot

 * count per step is GC_INCREMENTAL_SWEEP_BYTES / heap->slot_size,

 * so larger slot pools (which are less heavily used) naturally get

 * fewer slots swept per step.

 *

 * Baseline: 2048 slots * RVALUE_SLOT_SIZE = 2048 * 40 = 81920 bytes,

 * preserving the historical behavior for the smallest heap.

 */

#define GC_INCREMENTAL_SWEEP_BYTES           (2048 * RVALUE_SLOT_SIZE)

#define GC_INCREMENTAL_SWEEP_POOL_BYTES      (1024 * RVALUE_SLOT_SIZE)

#define is_lazy_sweeping(objspace)           (GC_ENABLE_LAZY_SWEEP && has_sweeping_pages(objspace))

/* In lazy sweeping or the previous incremental marking finished and did not yield a free page. */

#define needs_continue_sweeping(objspace, heap) \

    ((heap)->free_pages == NULL && is_lazy_sweeping(objspace))


#if SIZEOF_LONG == SIZEOF_VOIDP

# define obj_id_to_ref(objid) ((objid) ^ FIXNUM_FLAG) /* unset FIXNUM_FLAG */

#elif SIZEOF_LONG_LONG == SIZEOF_VOIDP

# define obj_id_to_ref(objid) (FIXNUM_P(objid) ? \

   ((objid) ^ FIXNUM_FLAG) : (NUM2PTR(objid) << 1))

#else

# error not supported

#endif


struct RZombie {

    VALUE flags;

    VALUE next;

    void (*dfree)(void *);

    void *data;

};


#define RZOMBIE(o) ((struct RZombie *)(o))


static bool ruby_enable_autocompact = false;

#if RGENGC_CHECK_MODE

static gc_compact_compare_func ruby_autocompact_compare_func;

#endif


static void init_mark_stack(mark_stack_t *stack);

static int garbage_collect(rb_objspace_t *, unsigned int reason);


static int  gc_start(rb_objspace_t *objspace, unsigned int reason);

static void gc_rest(rb_objspace_t *objspace);


enum gc_enter_event {

    gc_enter_event_start,

    gc_enter_event_continue,

    gc_enter_event_rest,

    gc_enter_event_finalizer,

};


static inline void gc_enter(rb_objspace_t *objspace, enum gc_enter_event event, unsigned int *lock_lev);

static inline void gc_exit(rb_objspace_t *objspace, enum gc_enter_event event, unsigned int *lock_lev);

static void gc_marking_enter(rb_objspace_t *objspace);

static void gc_marking_exit(rb_objspace_t *objspace);

static void gc_sweeping_enter(rb_objspace_t *objspace);

static void gc_sweeping_exit(rb_objspace_t *objspace);

static bool gc_marks_continue(rb_objspace_t *objspace, rb_heap_t *heap);


static void gc_sweep(rb_objspace_t *objspace);

static void gc_sweep_finish_heap(rb_objspace_t *objspace, rb_heap_t *heap);

static void gc_sweep_continue(rb_objspace_t *objspace, rb_heap_t *heap);


static inline void gc_mark(rb_objspace_t *objspace, VALUE ptr);

static inline void gc_pin(rb_objspace_t *objspace, VALUE ptr);

static inline void gc_mark_and_pin(rb_objspace_t *objspace, VALUE ptr);


static int gc_mark_stacked_objects_incremental(rb_objspace_t *, size_t count);

NO_SANITIZE("memory", static inline bool is_pointer_to_heap(rb_objspace_t *objspace, const void *ptr));


static void gc_verify_internal_consistency(void *objspace_ptr);


static double getrusage_time(void);

static inline void gc_prof_setup_new_record(rb_objspace_t *objspace, unsigned int reason);

static inline void gc_prof_timer_start(rb_objspace_t *);

static inline void gc_prof_timer_stop(rb_objspace_t *);

static inline void gc_prof_mark_timer_start(rb_objspace_t *);

static inline void gc_prof_mark_timer_stop(rb_objspace_t *);

static inline void gc_prof_sweep_timer_start(rb_objspace_t *);

static inline void gc_prof_sweep_timer_stop(rb_objspace_t *);

static inline void gc_prof_set_malloc_info(rb_objspace_t *);

static inline void gc_prof_set_heap_info(rb_objspace_t *);


#define gc_prof_record(objspace) (objspace)->profile.current_record

#define gc_prof_enabled(objspace) ((objspace)->profile.run && (objspace)->profile.current_record)


#ifdef HAVE_VA_ARGS_MACRO

# define gc_report(level, objspace, ...) \

    if (!RGENGC_DEBUG_ENABLED(level)) {} else gc_report_body(level, objspace, __VA_ARGS__)

#else

# define gc_report if (!RGENGC_DEBUG_ENABLED(0)) {} else gc_report_body

#endif

PRINTF_ARGS(static void gc_report_body(int level, rb_objspace_t *objspace, const char *fmt, ...), 3, 4);


static void gc_finalize_deferred(void *dmy);


#if USE_TICK_T


/* the following code is only for internal tuning. */


/* Source code to use RDTSC is quoted and modified from

 * https://www.mcs.anl.gov/~kazutomo/rdtsc.html

 * written by Kazutomo Yoshii <kazutomo@mcs.anl.gov>

 */


#if defined(__GNUC__) && defined(__i386__)

typedef unsigned long long tick_t;

#define PRItick "llu"

static inline tick_t

tick(void)

{

    unsigned long long int x;

    __asm__ __volatile__ ("rdtsc" : "=A" (x));

    return x;

}


#elif defined(__GNUC__) && defined(__x86_64__)

typedef unsigned long long tick_t;

#define PRItick "llu"


static __inline__ tick_t

tick(void)

{

    unsigned long hi, lo;

    __asm__ __volatile__ ("rdtsc" : "=a"(lo), "=d"(hi));

    return ((unsigned long long)lo)|( ((unsigned long long)hi)<<32);

}


#elif defined(__powerpc64__) && (GCC_VERSION_SINCE(4,8,0) || defined(__clang__))

typedef unsigned long long tick_t;

#define PRItick "llu"


static __inline__ tick_t

tick(void)

{

    unsigned long long val = __builtin_ppc_get_timebase();

    return val;

}


#elif defined(__POWERPC__) && defined(__APPLE__)

/* Implementation for macOS PPC by @nobu

 * See: https://github.com/ruby/ruby/pull/5975#discussion_r890045558

 */

typedef unsigned long long tick_t;

#define PRItick "llu"


static __inline__ tick_t

tick(void)

{

    unsigned long int upper, lower, tmp;

    # define mftbu(r) __asm__ volatile("mftbu   %0" : "=r"(r))

    # define mftb(r)  __asm__ volatile("mftb    %0" : "=r"(r))

        do {

            mftbu(upper);

            mftb(lower);

            mftbu(tmp);

        } while (tmp != upper);

    return ((tick_t)upper << 32) | lower;

}


#elif defined(__aarch64__) &&  defined(__GNUC__)

typedef unsigned long tick_t;

#define PRItick "lu"


static __inline__ tick_t

tick(void)

{

    unsigned long val;

    __asm__ __volatile__ ("mrs %0, cntvct_el0" : "=r" (val));

    return val;

}


#elif defined(_WIN32) && defined(_MSC_VER)

#include <intrin.h>

typedef unsigned __int64 tick_t;

#define PRItick "llu"


static inline tick_t

tick(void)

{

    return __rdtsc();

}


#else /* use clock */

typedef clock_t tick_t;

#define PRItick "llu"


static inline tick_t

tick(void)

{

    return clock();

}

#endif /* TSC */

#else /* USE_TICK_T */

#define MEASURE_LINE(expr) expr

#endif /* USE_TICK_T */


static inline VALUE check_rvalue_consistency(rb_objspace_t *objspace, const VALUE obj);


#define RVALUE_MARKED_BITMAP(obj)         MARKED_IN_BITMAP(GET_HEAP_MARK_BITS(obj), (obj))

#define RVALUE_WB_UNPROTECTED_BITMAP(obj) MARKED_IN_BITMAP(GET_HEAP_WB_UNPROTECTED_BITS(obj), (obj))

#define RVALUE_MARKING_BITMAP(obj)        MARKED_IN_BITMAP(GET_HEAP_MARKING_BITS(obj), (obj))

#define RVALUE_UNCOLLECTIBLE_BITMAP(obj)  MARKED_IN_BITMAP(GET_HEAP_UNCOLLECTIBLE_BITS(obj), (obj))

#define RVALUE_PINNED_BITMAP(obj)         MARKED_IN_BITMAP(GET_HEAP_PINNED_BITS(obj), (obj))


static inline int

RVALUE_MARKED(rb_objspace_t *objspace, VALUE obj)

{

    check_rvalue_consistency(objspace, obj);

    return RVALUE_MARKED_BITMAP(obj) != 0;

}


static inline int

RVALUE_PINNED(rb_objspace_t *objspace, VALUE obj)

{

    check_rvalue_consistency(objspace, obj);

    return RVALUE_PINNED_BITMAP(obj) != 0;

}


static inline int

RVALUE_WB_UNPROTECTED(rb_objspace_t *objspace, VALUE obj)

{

    check_rvalue_consistency(objspace, obj);

    return RVALUE_WB_UNPROTECTED_BITMAP(obj) != 0;

}


static inline int

RVALUE_MARKING(rb_objspace_t *objspace, VALUE obj)

{

    check_rvalue_consistency(objspace, obj);

    return RVALUE_MARKING_BITMAP(obj) != 0;

}


static inline int

RVALUE_REMEMBERED(rb_objspace_t *objspace, VALUE obj)

{

    check_rvalue_consistency(objspace, obj);

    return MARKED_IN_BITMAP(GET_HEAP_PAGE(obj)->remembered_bits, obj) != 0;

}


static inline int

RVALUE_UNCOLLECTIBLE(rb_objspace_t *objspace, VALUE obj)

{

    check_rvalue_consistency(objspace, obj);

    return RVALUE_UNCOLLECTIBLE_BITMAP(obj) != 0;

}


#define RVALUE_PAGE_WB_UNPROTECTED(page, obj) MARKED_IN_BITMAP((page)->wb_unprotected_bits, (obj))

#define RVALUE_PAGE_UNCOLLECTIBLE(page, obj)  MARKED_IN_BITMAP((page)->uncollectible_bits, (obj))

#define RVALUE_PAGE_MARKING(page, obj)        MARKED_IN_BITMAP((page)->marking_bits, (obj))


static int rgengc_remember(rb_objspace_t *objspace, VALUE obj);

static void rgengc_mark_and_rememberset_clear(rb_objspace_t *objspace, rb_heap_t *heap);

static void rgengc_rememberset_mark(rb_objspace_t *objspace, rb_heap_t *heap);


static int

check_rvalue_consistency_force(rb_objspace_t *objspace, const VALUE obj, int terminate)

{

    int err = 0;


    int lev = RB_GC_VM_LOCK_NO_BARRIER();

    {

        if (SPECIAL_CONST_P(obj)) {

            fprintf(stderr, "check_rvalue_consistency: %p is a special const.\n", (void *)obj);

            err++;

        }

        else if (!is_pointer_to_heap(objspace, (void *)obj)) {

            struct heap_page *empty_page = objspace->empty_pages;

            while (empty_page) {

                if ((uintptr_t)empty_page->body <= (uintptr_t)obj &&

                        (uintptr_t)obj < (uintptr_t)empty_page->body + HEAP_PAGE_SIZE) {

                    GC_ASSERT(heap_page_in_global_empty_pages_pool(objspace, empty_page));

                    fprintf(stderr, "check_rvalue_consistency: %p is in an empty page (%p).\n",

                            (void *)obj, (void *)empty_page);

                    err++;

                    goto skip;

                }

            }

            fprintf(stderr, "check_rvalue_consistency: %p is not a Ruby object.\n", (void *)obj);

            err++;

          skip:

            ;

        }

        else {

            const int wb_unprotected_bit = RVALUE_WB_UNPROTECTED_BITMAP(obj) != 0;

            const int uncollectible_bit = RVALUE_UNCOLLECTIBLE_BITMAP(obj) != 0;

            const int mark_bit = RVALUE_MARKED_BITMAP(obj) != 0;

            const int marking_bit = RVALUE_MARKING_BITMAP(obj) != 0;

            const int remembered_bit = MARKED_IN_BITMAP(GET_HEAP_PAGE(obj)->remembered_bits, obj) != 0;

            const int age = RVALUE_AGE_GET((VALUE)obj);


            if (heap_page_in_global_empty_pages_pool(objspace, GET_HEAP_PAGE(obj))) {

                fprintf(stderr, "check_rvalue_consistency: %s is in tomb page.\n", rb_obj_info(obj));

                err++;

            }

            if (BUILTIN_TYPE(obj) == T_NONE) {

                fprintf(stderr, "check_rvalue_consistency: %s is T_NONE.\n", rb_obj_info(obj));

                err++;

            }

            if (BUILTIN_TYPE(obj) == T_ZOMBIE) {

                fprintf(stderr, "check_rvalue_consistency: %s is T_ZOMBIE.\n", rb_obj_info(obj));

                err++;

            }


            if (BUILTIN_TYPE(obj) != T_DATA) {

                rb_obj_memsize_of((VALUE)obj);

            }


            /* check generation

             *

             * OLD == age == 3 && old-bitmap && mark-bit (except incremental marking)

             */

            if (age > 0 && wb_unprotected_bit) {

                fprintf(stderr, "check_rvalue_consistency: %s is not WB protected, but age is %d > 0.\n", rb_obj_info(obj), age);

                err++;

            }


            if (!is_marking(objspace) && uncollectible_bit && !mark_bit) {

                fprintf(stderr, "check_rvalue_consistency: %s is uncollectible, but is not marked while !gc.\n", rb_obj_info(obj));

                err++;

            }


            if (!is_full_marking(objspace)) {

                if (uncollectible_bit && age != RVALUE_OLD_AGE && !wb_unprotected_bit) {

                    fprintf(stderr, "check_rvalue_consistency: %s is uncollectible, but not old (age: %d) and not WB unprotected.\n",

                            rb_obj_info(obj), age);

                    err++;

                }

                if (remembered_bit && age != RVALUE_OLD_AGE) {

                    fprintf(stderr, "check_rvalue_consistency: %s is remembered, but not old (age: %d).\n",

                            rb_obj_info(obj), age);

                    err++;

                }

            }


            /*

             * check coloring

             *

             *               marking:false marking:true

             * marked:false  white         *invalid*

             * marked:true   black         grey

             */

            if (is_incremental_marking(objspace) && marking_bit) {

                if (!is_marking(objspace) && !mark_bit) {

                    fprintf(stderr, "check_rvalue_consistency: %s is marking, but not marked.\n", rb_obj_info(obj));

                    err++;

                }

            }

        }

    }

    RB_GC_VM_UNLOCK_NO_BARRIER(lev);


    if (err > 0 && terminate) {

        rb_bug("check_rvalue_consistency_force: there is %d errors.", err);

    }

    return err;

}


#if RGENGC_CHECK_MODE == 0

static inline VALUE

check_rvalue_consistency(rb_objspace_t *objspace, const VALUE obj)

{

    return obj;

}

#else

static VALUE

check_rvalue_consistency(rb_objspace_t *objspace, const VALUE obj)

{

    check_rvalue_consistency_force(objspace, obj, TRUE);

    return obj;

}

#endif


static inline bool

gc_object_moved_p(rb_objspace_t *objspace, VALUE obj)

{


    bool ret;

    asan_unpoisoning_object(obj) {

        ret = BUILTIN_TYPE(obj) == T_MOVED;

    }

    return ret;

}


static inline int

RVALUE_OLD_P(rb_objspace_t *objspace, VALUE obj)

{

    GC_ASSERT(!RB_SPECIAL_CONST_P(obj));

    check_rvalue_consistency(objspace, obj);

    // Because this will only ever be called on GC controlled objects,

    // we can use the faster _RAW function here

    return RB_OBJ_PROMOTED_RAW(obj);

}


static inline void

RVALUE_PAGE_OLD_UNCOLLECTIBLE_SET(rb_objspace_t *objspace, struct heap_page *page, VALUE obj)

{

    MARK_IN_BITMAP(&page->uncollectible_bits[0], obj);

    objspace->rgengc.old_objects++;


#if RGENGC_PROFILE >= 2

    objspace->profile.total_promoted_count++;

    objspace->profile.promoted_types[BUILTIN_TYPE(obj)]++;

#endif

}


static inline void

RVALUE_OLD_UNCOLLECTIBLE_SET(rb_objspace_t *objspace, VALUE obj)

{

    RB_DEBUG_COUNTER_INC(obj_promote);

    RVALUE_PAGE_OLD_UNCOLLECTIBLE_SET(objspace, GET_HEAP_PAGE(obj), obj);

}


/* set age to age+1 */

static inline void

RVALUE_AGE_INC(rb_objspace_t *objspace, VALUE obj)

{

    int age = RVALUE_AGE_GET((VALUE)obj);


    if (RGENGC_CHECK_MODE && age == RVALUE_OLD_AGE) {

        rb_bug("RVALUE_AGE_INC: can not increment age of OLD object %s.", rb_obj_info(obj));

    }


    age++;

    RVALUE_AGE_SET(obj, age);


    if (age == RVALUE_OLD_AGE) {

        RVALUE_OLD_UNCOLLECTIBLE_SET(objspace, obj);

    }


    check_rvalue_consistency(objspace, obj);

}


static inline void

RVALUE_AGE_SET_CANDIDATE(rb_objspace_t *objspace, VALUE obj)

{

    check_rvalue_consistency(objspace, obj);

    GC_ASSERT(!RVALUE_OLD_P(objspace, obj));

    RVALUE_AGE_SET(obj, RVALUE_OLD_AGE - 1);

    check_rvalue_consistency(objspace, obj);

}


static inline void

RVALUE_AGE_RESET(VALUE obj)

{

    RVALUE_AGE_SET(obj, 0);

}


static inline void

RVALUE_DEMOTE(rb_objspace_t *objspace, VALUE obj)

{

    check_rvalue_consistency(objspace, obj);

    GC_ASSERT(RVALUE_OLD_P(objspace, obj));


    if (!is_incremental_marking(objspace) && RVALUE_REMEMBERED(objspace, obj)) {

        CLEAR_IN_BITMAP(GET_HEAP_PAGE(obj)->remembered_bits, obj);

    }


    CLEAR_IN_BITMAP(GET_HEAP_UNCOLLECTIBLE_BITS(obj), obj);

    RVALUE_AGE_RESET(obj);


    if (RVALUE_MARKED(objspace, obj)) {

        objspace->rgengc.old_objects--;

    }


    check_rvalue_consistency(objspace, obj);

}


static inline int

RVALUE_BLACK_P(rb_objspace_t *objspace, VALUE obj)

{

    return RVALUE_MARKED(objspace, obj) && !RVALUE_MARKING(objspace, obj);

}


static inline int

RVALUE_WHITE_P(rb_objspace_t *objspace, VALUE obj)

{

    return !RVALUE_MARKED(objspace, obj);

}


bool

rb_gc_impl_gc_enabled_p(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;

    return !dont_gc_val();

}


void

rb_gc_impl_gc_enable(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    dont_gc_off();

}


void

rb_gc_impl_gc_disable(void *objspace_ptr, bool finish_current_gc)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (finish_current_gc) {

        gc_rest(objspace);

    }


    dont_gc_on();

}


/*

  --------------------------- ObjectSpace -----------------------------

*/


static inline void *

calloc1(size_t n)

{

    return calloc(1, n);

}


void

rb_gc_impl_set_event_hook(void *objspace_ptr, const rb_event_flag_t event)

{

    rb_objspace_t *objspace = objspace_ptr;

    objspace->hook_events = event & RUBY_INTERNAL_EVENT_OBJSPACE_MASK;

}


unsigned long long

rb_gc_impl_get_total_time(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    unsigned long long marking_time = objspace->profile.marking_time_ns;

    unsigned long long sweeping_time = objspace->profile.sweeping_time_ns;


    return marking_time + sweeping_time;

}


void

rb_gc_impl_set_measure_total_time(void *objspace_ptr, VALUE flag)

{

    rb_objspace_t *objspace = objspace_ptr;


    objspace->flags.measure_gc = RTEST(flag) ? TRUE : FALSE;

}


bool

rb_gc_impl_get_measure_total_time(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    return objspace->flags.measure_gc;

}


/* garbage objects will be collected soon. */

bool

rb_gc_impl_garbage_object_p(void *objspace_ptr, VALUE ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    bool dead = false;


    asan_unpoisoning_object(ptr) {

        switch (BUILTIN_TYPE(ptr)) {

          case T_NONE:

          case T_MOVED:

          case T_ZOMBIE:

            dead = true;

            break;

          default:

            break;

        }

    }


    if (dead) return true;

    return is_lazy_sweeping(objspace) && GET_HEAP_PAGE(ptr)->flags.before_sweep &&

        !RVALUE_MARKED(objspace, ptr);

}


static void free_stack_chunks(mark_stack_t *);

static void mark_stack_free_cache(mark_stack_t *);

static void heap_page_free(rb_objspace_t *objspace, struct heap_page *page);


static inline void

heap_page_add_freeobj(rb_objspace_t *objspace, struct heap_page *page, VALUE obj)

{

    rb_asan_unpoison_object(obj, false);


    asan_unlock_freelist(page);


    struct free_slot *slot = (struct free_slot *)obj;

    slot->flags = 0;

    slot->next = page->freelist;

    page->freelist = slot;

    asan_lock_freelist(page);


    // Should have already been reset

    GC_ASSERT(RVALUE_AGE_GET(obj) == 0);


    if (RGENGC_CHECK_MODE &&

        /* obj should belong to page */

        !(page->start <= (uintptr_t)obj &&

          (uintptr_t)obj   <  ((uintptr_t)page->start + (page->total_slots * page->slot_size)) &&

          obj % sizeof(VALUE) == 0)) {

        rb_bug("heap_page_add_freeobj: %p is not rvalue.", (void *)obj);

    }


    rb_asan_poison_object(obj);

    gc_report(3, objspace, "heap_page_add_freeobj: add %p to freelist\n", (void *)obj);

}


static void

heap_allocatable_bytes_expand(rb_objspace_t *objspace,

        rb_heap_t *heap, size_t free_slots, size_t total_slots, size_t slot_size)

{

    double goal_ratio = gc_params.heap_free_slots_goal_ratio;

    size_t target_total_slots;


    if (goal_ratio == 0.0) {

        target_total_slots = (size_t)(total_slots * gc_params.growth_factor);

    }

    else if (total_slots == 0) {

        target_total_slots = gc_params.heap_init_bytes / slot_size;

    }

    else {

        /* Find `f' where free_slots = f * total_slots * goal_ratio

         * => f = (total_slots - free_slots) / ((1 - goal_ratio) * total_slots)

         */

        double f = (double)(total_slots - free_slots) / ((1 - goal_ratio) * total_slots);


        if (f > gc_params.growth_factor) f = gc_params.growth_factor;

        if (f < 1.0) f = 1.1;


        target_total_slots = (size_t)(f * total_slots);


        if (0) {

            fprintf(stderr,

                    "free_slots(%8"PRIuSIZE")/total_slots(%8"PRIuSIZE")=%1.2f,"

                    " G(%1.2f), f(%1.2f),"

                    " total_slots(%8"PRIuSIZE") => target_total_slots(%8"PRIuSIZE")\n",

                    free_slots, total_slots, free_slots/(double)total_slots,

                    goal_ratio, f, total_slots, target_total_slots);

        }

    }


    if (gc_params.growth_max_bytes > 0) {

        size_t max_total_slots = total_slots + gc_params.growth_max_bytes / slot_size;

        if (target_total_slots > max_total_slots) target_total_slots = max_total_slots;

    }


    size_t extend_slot_count = target_total_slots - total_slots;

    /* Extend by at least 1 page. */

    if (extend_slot_count == 0) extend_slot_count = 1;


    objspace->heap_pages.allocatable_bytes += extend_slot_count * slot_size;

}


static inline void

heap_add_freepage(rb_heap_t *heap, struct heap_page *page)

{

    asan_unlock_freelist(page);

    GC_ASSERT(page->free_slots != 0);

    GC_ASSERT(page->freelist != NULL);


    page->free_next = heap->free_pages;

    heap->free_pages = page;


    RUBY_DEBUG_LOG("page:%p freelist:%p", (void *)page, (void *)page->freelist);


    asan_lock_freelist(page);

}


static inline void

heap_add_poolpage(rb_objspace_t *objspace, rb_heap_t *heap, struct heap_page *page)

{

    asan_unlock_freelist(page);

    GC_ASSERT(page->free_slots != 0);

    GC_ASSERT(page->freelist != NULL);


    page->free_next = heap->pooled_pages;

    heap->pooled_pages = page;

    objspace->rincgc.pooled_slots += page->free_slots;


    asan_lock_freelist(page);

}


static void

heap_unlink_page(rb_objspace_t *objspace, rb_heap_t *heap, struct heap_page *page)

{

    ccan_list_del(&page->page_node);

    heap->total_pages--;

    heap->total_slots -= page->total_slots;

}


static void

gc_aligned_free(void *ptr, size_t size)

{

#if defined __MINGW32__

    __mingw_aligned_free(ptr);

#elif defined _WIN32

    _aligned_free(ptr);

#elif defined(HAVE_POSIX_MEMALIGN) || defined(HAVE_MEMALIGN)

    free(ptr);

#else

    free(((void**)ptr)[-1]);

#endif

}


static void

heap_page_body_free(struct heap_page_body *page_body)

{

    GC_ASSERT((uintptr_t)page_body % HEAP_PAGE_ALIGN == 0);


    if (HEAP_PAGE_ALLOC_USE_MMAP) {

#ifdef HAVE_MMAP

        GC_ASSERT(HEAP_PAGE_SIZE % sysconf(_SC_PAGE_SIZE) == 0);

        if (munmap(page_body, HEAP_PAGE_SIZE)) {

            rb_bug("heap_page_body_free: munmap failed");

        }

#endif

    }

    else {

        gc_aligned_free(page_body, HEAP_PAGE_SIZE);

    }

}


static void

heap_page_free(rb_objspace_t *objspace, struct heap_page *page)

{

    objspace->heap_pages.freed_pages++;

    heap_page_body_free(page->body);

    free(page);

}


static void

heap_pages_free_unused_pages(rb_objspace_t *objspace)

{

    if (objspace->empty_pages != NULL && heap_pages_freeable_pages > 0) {

        GC_ASSERT(objspace->empty_pages_count > 0);

        objspace->empty_pages = NULL;

        objspace->empty_pages_count = 0;


        size_t i, j;

        for (i = j = 0; i < rb_darray_size(objspace->heap_pages.sorted); i++) {

            struct heap_page *page = rb_darray_get(objspace->heap_pages.sorted, i);


            if (heap_page_in_global_empty_pages_pool(objspace, page) && heap_pages_freeable_pages > 0) {

                heap_page_free(objspace, page);

                heap_pages_freeable_pages--;

            }

            else {

                if (heap_page_in_global_empty_pages_pool(objspace, page)) {

                    page->free_next = objspace->empty_pages;

                    objspace->empty_pages = page;

                    objspace->empty_pages_count++;

                }


                if (i != j) {

                    rb_darray_set(objspace->heap_pages.sorted, j, page);

                }

                j++;

            }

        }


        rb_darray_pop(objspace->heap_pages.sorted, i - j);

        GC_ASSERT(rb_darray_size(objspace->heap_pages.sorted) == j);


        struct heap_page *hipage = rb_darray_get(objspace->heap_pages.sorted, rb_darray_size(objspace->heap_pages.sorted) - 1);

        uintptr_t himem = (uintptr_t)hipage->body + HEAP_PAGE_SIZE;

        GC_ASSERT(himem <= heap_pages_himem);

        heap_pages_himem = himem;


        struct heap_page *lopage = rb_darray_get(objspace->heap_pages.sorted, 0);

        uintptr_t lomem = (uintptr_t)lopage->body + sizeof(struct heap_page_header);

        GC_ASSERT(lomem >= heap_pages_lomem);

        heap_pages_lomem = lomem;

    }

}


static void *

gc_aligned_malloc(size_t alignment, size_t size)

{

    /* alignment must be a power of 2 */

    GC_ASSERT(((alignment - 1) & alignment) == 0);

    GC_ASSERT(alignment % sizeof(void*) == 0);


    void *res;


#if defined __MINGW32__

    res = __mingw_aligned_malloc(size, alignment);

#elif defined _WIN32

    void *_aligned_malloc(size_t, size_t);

    res = _aligned_malloc(size, alignment);

#elif defined(HAVE_POSIX_MEMALIGN)

    if (posix_memalign(&res, alignment, size) != 0) {

        return NULL;

    }

#elif defined(HAVE_MEMALIGN)

    res = memalign(alignment, size);

#else

    char* aligned;

    res = malloc(alignment + size + sizeof(void*));

    aligned = (char*)res + alignment + sizeof(void*);

    aligned -= ((VALUE)aligned & (alignment - 1));

    ((void**)aligned)[-1] = res;

    res = (void*)aligned;

#endif


    GC_ASSERT((uintptr_t)res % alignment == 0);


    return res;

}


static struct heap_page_body *

heap_page_body_allocate(void)

{

    struct heap_page_body *page_body;


    if (HEAP_PAGE_ALLOC_USE_MMAP) {

#ifdef HAVE_MMAP

        GC_ASSERT(HEAP_PAGE_ALIGN % sysconf(_SC_PAGE_SIZE) == 0);


        size_t mmap_size = HEAP_PAGE_ALIGN + HEAP_PAGE_SIZE;

        char *ptr = mmap(NULL, mmap_size,

                         PROT_READ | PROT_WRITE, MAP_PRIVATE | MAP_ANONYMOUS, -1, 0);

        if (ptr == MAP_FAILED) {

            return NULL;

        }


        // If we are building `default.c` as part of the ruby executable, we

        // may just call `ruby_annotate_mmap`.  But if we are building

        // `default.c` as a shared library, we will not have access to private

        // symbols, and we have to either call prctl directly or make our own

        // wrapper.

#if defined(HAVE_SYS_PRCTL_H) && defined(PR_SET_VMA) && defined(PR_SET_VMA_ANON_NAME)

        prctl(PR_SET_VMA, PR_SET_VMA_ANON_NAME, ptr, mmap_size, "Ruby:GC:default:heap_page_body_allocate");

        errno = 0;

#endif


        char *aligned = ptr + HEAP_PAGE_ALIGN;

        aligned -= ((VALUE)aligned & (HEAP_PAGE_ALIGN - 1));

        GC_ASSERT(aligned > ptr);

        GC_ASSERT(aligned <= ptr + HEAP_PAGE_ALIGN);


        size_t start_out_of_range_size = aligned - ptr;

        GC_ASSERT(start_out_of_range_size % sysconf(_SC_PAGE_SIZE) == 0);

        if (start_out_of_range_size > 0) {

            if (munmap(ptr, start_out_of_range_size)) {

                rb_bug("heap_page_body_allocate: munmap failed for start");

            }

        }


        size_t end_out_of_range_size = HEAP_PAGE_ALIGN - start_out_of_range_size;

        GC_ASSERT(end_out_of_range_size % sysconf(_SC_PAGE_SIZE) == 0);

        if (end_out_of_range_size > 0) {

            if (munmap(aligned + HEAP_PAGE_SIZE, end_out_of_range_size)) {

                rb_bug("heap_page_body_allocate: munmap failed for end");

            }

        }


        page_body = (struct heap_page_body *)aligned;

#endif

    }

    else {

        page_body = gc_aligned_malloc(HEAP_PAGE_ALIGN, HEAP_PAGE_SIZE);

    }


    GC_ASSERT((uintptr_t)page_body % HEAP_PAGE_ALIGN == 0);


    return page_body;

}


static struct heap_page *

heap_page_resurrect(rb_objspace_t *objspace)

{

    struct heap_page *page = NULL;

    if (objspace->empty_pages == NULL) {

        GC_ASSERT(objspace->empty_pages_count == 0);

    }

    else {

        GC_ASSERT(objspace->empty_pages_count > 0);

        objspace->empty_pages_count--;

        page = objspace->empty_pages;

        objspace->empty_pages = page->free_next;

    }


    return page;

}


static struct heap_page *

heap_page_allocate(rb_objspace_t *objspace)

{

    struct heap_page_body *page_body = heap_page_body_allocate();

    if (page_body == 0) {

        rb_memerror();

    }


    struct heap_page *page = calloc1(sizeof(struct heap_page));

    if (page == 0) {

        heap_page_body_free(page_body);

        rb_memerror();

    }


    uintptr_t start = (uintptr_t)page_body + sizeof(struct heap_page_header);

    uintptr_t end = (uintptr_t)page_body + HEAP_PAGE_SIZE;


    size_t lo = 0;

    size_t hi = rb_darray_size(objspace->heap_pages.sorted);

    while (lo < hi) {

        struct heap_page *mid_page;


        size_t mid = (lo + hi) / 2;

        mid_page = rb_darray_get(objspace->heap_pages.sorted, mid);

        if ((uintptr_t)mid_page->start < start) {

            lo = mid + 1;

        }

        else if ((uintptr_t)mid_page->start > start) {

            hi = mid;

        }

        else {

            rb_bug("same heap page is allocated: %p at %"PRIuVALUE, (void *)page_body, (VALUE)mid);

        }

    }


    rb_darray_insert_without_gc(&objspace->heap_pages.sorted, hi, page);


    if (heap_pages_lomem == 0 || heap_pages_lomem > start) heap_pages_lomem = start;

    if (heap_pages_himem < end) heap_pages_himem = end;


    page->body = page_body;

    page_body->header.page = page;


    objspace->heap_pages.allocated_pages++;


    return page;

}


static void

heap_add_page(rb_objspace_t *objspace, rb_heap_t *heap, struct heap_page *page)

{

    /* Adding to eden heap during incremental sweeping is forbidden */

    GC_ASSERT(!heap->sweeping_page);

    GC_ASSERT(heap_page_in_global_empty_pages_pool(objspace, page));


    /* Align start to slot_size boundary */

    uintptr_t start = (uintptr_t)page->body + sizeof(struct heap_page_header);

    uintptr_t rem = start % heap->slot_size;

    if (rem) start += heap->slot_size - rem;


    int slot_count = (int)((HEAP_PAGE_SIZE - (start - (uintptr_t)page->body))/heap->slot_size);


    page->start = start;

    page->total_slots = slot_count;

    page->slot_size = heap->slot_size;

    page->slot_size_reciprocal = heap_slot_reciprocal_table[heap - heaps];

    page->heap = heap;


    memset(&page->wb_unprotected_bits[0], 0, HEAP_PAGE_BITMAP_SIZE);

    memset(&page->age_bits[0], 0, sizeof(page->age_bits));


    asan_unlock_freelist(page);

    page->freelist = NULL;

    asan_unpoison_memory_region(page->body, HEAP_PAGE_SIZE, false);

    for (VALUE p = (VALUE)start; p < start + (slot_count * heap->slot_size); p += heap->slot_size) {

        heap_page_add_freeobj(objspace, page, p);

    }

    asan_lock_freelist(page);


    page->free_slots = slot_count;


    heap->total_allocated_pages++;


    ccan_list_add_tail(&heap->pages, &page->page_node);

    heap->total_pages++;

    heap->total_slots += page->total_slots;

}


static int

heap_page_allocate_and_initialize(rb_objspace_t *objspace, rb_heap_t *heap)

{

    gc_report(1, objspace, "heap_page_allocate_and_initialize: rb_darray_size(objspace->heap_pages.sorted): %"PRIdSIZE", "

                  "allocatable_bytes: %"PRIdSIZE", heap->total_pages: %"PRIdSIZE"\n",

                  rb_darray_size(objspace->heap_pages.sorted), objspace->heap_pages.allocatable_bytes, heap->total_pages);


    bool allocated = false;

    struct heap_page *page = heap_page_resurrect(objspace);


    if (page == NULL && objspace->heap_pages.allocatable_bytes > 0) {

        page = heap_page_allocate(objspace);

        allocated = true;


        GC_ASSERT(page != NULL);

    }


    if (page != NULL) {

        heap_add_page(objspace, heap, page);

        heap_add_freepage(heap, page);


        if (allocated) {

            size_t page_bytes = (size_t)page->total_slots * page->slot_size;

            if (objspace->heap_pages.allocatable_bytes > page_bytes) {

                objspace->heap_pages.allocatable_bytes -= page_bytes;

            }

            else {

                objspace->heap_pages.allocatable_bytes = 0;

            }

        }

    }


    return page != NULL;

}


static void

heap_page_allocate_and_initialize_force(rb_objspace_t *objspace, rb_heap_t *heap)

{

    size_t prev_allocatable_bytes = objspace->heap_pages.allocatable_bytes;

    objspace->heap_pages.allocatable_bytes = HEAP_PAGE_SIZE;

    heap_page_allocate_and_initialize(objspace, heap);

    GC_ASSERT(heap->free_pages != NULL);

    objspace->heap_pages.allocatable_bytes = prev_allocatable_bytes;

}


static void

gc_continue(rb_objspace_t *objspace, rb_heap_t *heap)

{

    unsigned int lock_lev;

    bool needs_gc = is_incremental_marking(objspace) || needs_continue_sweeping(objspace, heap);

    if (!needs_gc) return;


    gc_enter(objspace, gc_enter_event_continue, &lock_lev); // takes vm barrier, try to avoid


    /* Continue marking if in incremental marking. */

    if (is_incremental_marking(objspace)) {

        if (gc_marks_continue(objspace, heap)) {

            gc_sweep(objspace);

        }

    }


    if (needs_continue_sweeping(objspace, heap)) {

        gc_sweep_continue(objspace, heap);

    }


    gc_exit(objspace, gc_enter_event_continue, &lock_lev);

}


static void

heap_prepare(rb_objspace_t *objspace, rb_heap_t *heap)

{

    GC_ASSERT(heap->free_pages == NULL);


    if (heap->total_slots < gc_params.heap_init_bytes / heap->slot_size &&

            heap->sweeping_page == NULL) {

        heap_page_allocate_and_initialize_force(objspace, heap);

        GC_ASSERT(heap->free_pages != NULL);

        return;

    }


    /* Continue incremental marking or lazy sweeping, if in any of those steps. */

    gc_continue(objspace, heap);


    if (heap->free_pages == NULL) {

        heap_page_allocate_and_initialize(objspace, heap);

    }


    /* If we still don't have a free page and not allowed to create a new page,

     * we should start a new GC cycle. */

    if (heap->free_pages == NULL) {

        GC_ASSERT(objspace->empty_pages_count == 0);

        GC_ASSERT(objspace->heap_pages.allocatable_bytes == 0);


        if (gc_start(objspace, GPR_FLAG_NEWOBJ) == FALSE) {

            rb_memerror();

        }

        else {

            if (objspace->heap_pages.allocatable_bytes == 0 && !gc_config_full_mark_val) {

                heap_allocatable_bytes_expand(objspace, heap,

                        heap->freed_slots + heap->empty_slots,

                        heap->total_slots, heap->slot_size);

                GC_ASSERT(objspace->heap_pages.allocatable_bytes > 0);

            }

            /* Do steps of incremental marking or lazy sweeping if the GC run permits. */

            gc_continue(objspace, heap);


            /* If we're not incremental marking (e.g. a minor GC) or finished

             * sweeping and still don't have a free page, then

             * gc_sweep_finish_heap should allow us to create a new page. */

            if (heap->free_pages == NULL && !heap_page_allocate_and_initialize(objspace, heap)) {

                if (gc_needs_major_flags == GPR_FLAG_NONE) {

                    rb_bug("cannot create a new page after GC");

                }

                else { // Major GC is required, which will allow us to create new page

                    if (gc_start(objspace, GPR_FLAG_NEWOBJ) == FALSE) {

                        rb_memerror();

                    }

                    else {

                        /* Do steps of incremental marking or lazy sweeping. */

                        gc_continue(objspace, heap);


                        if (heap->free_pages == NULL &&

                                !heap_page_allocate_and_initialize(objspace, heap)) {

                            rb_bug("cannot create a new page after major GC");

                        }

                    }

                }

            }

        }

    }


    GC_ASSERT(heap->free_pages != NULL);

}


#if GC_DEBUG

static inline const char*

rb_gc_impl_source_location_cstr(int *ptr)

{

    /* We could directly refer `rb_source_location_cstr()` before, but not any

     * longer.  We have to heavy lift using our debugging API. */

    if (! ptr) {

        return NULL;

    }

    else if (! (*ptr = rb_sourceline())) {

        return NULL;

    }

    else {

        return rb_sourcefile();

    }

}

#endif


static inline VALUE

newobj_init(VALUE klass, VALUE flags, int wb_protected, rb_objspace_t *objspace, VALUE obj)

{

    GC_ASSERT(BUILTIN_TYPE(obj) == T_NONE);

    GC_ASSERT((flags & FL_WB_PROTECTED) == 0);

    RBASIC(obj)->flags = flags;

    *((VALUE *)&RBASIC(obj)->klass) = klass;

#if RBASIC_SHAPE_ID_FIELD

    RBASIC(obj)->shape_id = 0;

#endif


#if RACTOR_CHECK_MODE

    void rb_ractor_setup_belonging(VALUE obj);

    rb_ractor_setup_belonging(obj);

#endif


#if RGENGC_CHECK_MODE

    int lev = RB_GC_VM_LOCK_NO_BARRIER();

    {

        check_rvalue_consistency(objspace, obj);


        GC_ASSERT(RVALUE_MARKED(objspace, obj) == FALSE);

        GC_ASSERT(RVALUE_MARKING(objspace, obj) == FALSE);

        GC_ASSERT(RVALUE_OLD_P(objspace, obj) == FALSE);

        GC_ASSERT(RVALUE_WB_UNPROTECTED(objspace, obj) == FALSE);


        if (RVALUE_REMEMBERED(objspace, obj)) rb_bug("newobj: %s is remembered.", rb_obj_info(obj));

    }

    RB_GC_VM_UNLOCK_NO_BARRIER(lev);

#endif


    if (RB_UNLIKELY(wb_protected == FALSE)) {

        MARK_IN_BITMAP(GET_HEAP_WB_UNPROTECTED_BITS(obj), obj);

    }


#if RGENGC_PROFILE

    if (wb_protected) {

        objspace->profile.total_generated_normal_object_count++;

#if RGENGC_PROFILE >= 2

        objspace->profile.generated_normal_object_count_types[BUILTIN_TYPE(obj)]++;

#endif

    }

    else {

        objspace->profile.total_generated_shady_object_count++;

#if RGENGC_PROFILE >= 2

        objspace->profile.generated_shady_object_count_types[BUILTIN_TYPE(obj)]++;

#endif

    }

#endif


#if GC_DEBUG

    GET_RVALUE_OVERHEAD(obj)->file = rb_gc_impl_source_location_cstr(&GET_RVALUE_OVERHEAD(obj)->line);

    GC_ASSERT(!SPECIAL_CONST_P(obj)); /* check alignment */

#endif


    gc_report(5, objspace, "newobj: %s\n", rb_obj_info(obj));


    // RUBY_DEBUG_LOG("obj:%p (%s)", (void *)obj, rb_obj_info(obj));

    return obj;

}


size_t

rb_gc_impl_obj_slot_size(VALUE obj)

{

    return GET_HEAP_PAGE(obj)->slot_size - RVALUE_OVERHEAD;

}


static inline size_t

heap_slot_size(unsigned char pool_id)

{

    GC_ASSERT(pool_id < HEAP_COUNT);


    return pool_slot_sizes[pool_id] - RVALUE_OVERHEAD;

}


bool

rb_gc_impl_size_allocatable_p(size_t size)

{

    return size + RVALUE_OVERHEAD <= pool_slot_sizes[HEAP_COUNT - 1];

}


static const size_t ALLOCATED_COUNT_STEP = 1024;

static void

ractor_cache_flush_count(rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache)

{

    for (int heap_idx = 0; heap_idx < HEAP_COUNT; heap_idx++) {

        rb_ractor_newobj_heap_cache_t *heap_cache = &cache->heap_caches[heap_idx];


        rb_heap_t *heap = &heaps[heap_idx];

        RUBY_ATOMIC_SIZE_ADD(heap->total_allocated_objects, heap_cache->allocated_objects_count);

        heap_cache->allocated_objects_count = 0;

    }

}


static inline VALUE

ractor_cache_allocate_slot(rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache,

                           size_t heap_idx)

{

    rb_ractor_newobj_heap_cache_t *heap_cache = &cache->heap_caches[heap_idx];

    struct free_slot *p = heap_cache->freelist;


    if (RB_UNLIKELY(is_incremental_marking(objspace))) {

        // Not allowed to allocate without running an incremental marking step

        if (cache->incremental_mark_step_allocated_slots >= INCREMENTAL_MARK_STEP_ALLOCATIONS) {

            return Qfalse;

        }


        if (p) {

            cache->incremental_mark_step_allocated_slots++;

        }

    }


    if (RB_LIKELY(p)) {

        VALUE obj = (VALUE)p;

        rb_asan_unpoison_object(obj, true);

        heap_cache->freelist = p->next;


        heap_cache->allocated_objects_count++;

        rb_heap_t *heap = &heaps[heap_idx];

        if (heap_cache->allocated_objects_count >= ALLOCATED_COUNT_STEP) {

            RUBY_ATOMIC_SIZE_ADD(heap->total_allocated_objects, heap_cache->allocated_objects_count);

            heap_cache->allocated_objects_count = 0;

        }


#if RGENGC_CHECK_MODE

        GC_ASSERT(rb_gc_impl_obj_slot_size(obj) == heap_slot_size(heap_idx));

        // zero clear

        MEMZERO((char *)obj, char, heap_slot_size(heap_idx));

#endif

        return obj;

    }

    else {

        return Qfalse;

    }

}


static struct heap_page *

heap_next_free_page(rb_objspace_t *objspace, rb_heap_t *heap)

{

    struct heap_page *page;


    if (heap->free_pages == NULL) {

        heap_prepare(objspace, heap);

    }


    page = heap->free_pages;

    heap->free_pages = page->free_next;


    GC_ASSERT(page->free_slots != 0);


    asan_unlock_freelist(page);


    return page;

}


static inline void

ractor_cache_set_page(rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, size_t heap_idx,

                      struct heap_page *page)

{

    gc_report(3, objspace, "ractor_set_cache: Using page %p\n", (void *)page->body);


    rb_ractor_newobj_heap_cache_t *heap_cache = &cache->heap_caches[heap_idx];


    GC_ASSERT(heap_cache->freelist == NULL);

    GC_ASSERT(page->free_slots != 0);

    GC_ASSERT(page->freelist != NULL);


    heap_cache->using_page = page;

    heap_cache->freelist = page->freelist;

    page->free_slots = 0;

    page->freelist = NULL;


    rb_asan_unpoison_object((VALUE)heap_cache->freelist, false);

    GC_ASSERT(RB_TYPE_P((VALUE)heap_cache->freelist, T_NONE));

    rb_asan_poison_object((VALUE)heap_cache->freelist);

}


static void

init_size_to_heap_idx(void)

{

    for (size_t i = 0; i < sizeof(size_to_heap_idx); i++) {

        size_t effective = i * 8 + RVALUE_OVERHEAD;

        uint8_t idx;

        for (idx = 0; idx < HEAP_COUNT; idx++) {

            if (effective <= pool_slot_sizes[idx]) break;

        }

        size_to_heap_idx[i] = idx;

    }

}


static inline size_t

heap_idx_for_size(size_t size)

{

    size_t compressed = (size + 7) >> 3;

    if (compressed < sizeof(size_to_heap_idx)) {

        size_t heap_idx = size_to_heap_idx[compressed];

        if (RB_LIKELY(heap_idx < HEAP_COUNT)) return heap_idx;

    }


    rb_bug("heap_idx_for_size: allocation size too large "

           "(size=%"PRIuSIZE")", size);

}


size_t

rb_gc_impl_heap_id_for_size(void *objspace_ptr, size_t size)

{

    return heap_idx_for_size(size);

}


static size_t heap_sizes[HEAP_COUNT + 1] = { 0 };


size_t *

rb_gc_impl_heap_sizes(void *objspace_ptr)

{

    if (heap_sizes[0] == 0) {

        for (unsigned char i = 0; i < HEAP_COUNT; i++) {

            heap_sizes[i] = heap_slot_size(i);

        }

    }


    return heap_sizes;

}


NOINLINE(static VALUE newobj_cache_miss(rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, size_t heap_idx, bool vm_locked));


static VALUE

newobj_cache_miss(rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, size_t heap_idx, bool vm_locked)

{

    rb_heap_t *heap = &heaps[heap_idx];

    VALUE obj = Qfalse;


    unsigned int lev = 0;

    bool unlock_vm = false;


    if (!vm_locked) {

        lev = RB_GC_CR_LOCK();

        unlock_vm = true;

    }


    {

        if (is_incremental_marking(objspace)) {

            gc_continue(objspace, heap);

            cache->incremental_mark_step_allocated_slots = 0;


            // Retry allocation after resetting incremental_mark_step_allocated_slots

            obj = ractor_cache_allocate_slot(objspace, cache, heap_idx);

        }


        if (obj == Qfalse) {

            // Get next free page (possibly running GC)

            struct heap_page *page = heap_next_free_page(objspace, heap);

            ractor_cache_set_page(objspace, cache, heap_idx, page);


            // Retry allocation after moving to new page

            obj = ractor_cache_allocate_slot(objspace, cache, heap_idx);

        }

    }


    if (unlock_vm) {

        RB_GC_CR_UNLOCK(lev);

    }


    if (RB_UNLIKELY(obj == Qfalse)) {

        rb_memerror();

    }

    return obj;

}


static VALUE

newobj_alloc(rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, size_t heap_idx, bool vm_locked)

{

    VALUE obj = ractor_cache_allocate_slot(objspace, cache, heap_idx);


    if (RB_UNLIKELY(obj == Qfalse)) {

        obj = newobj_cache_miss(objspace, cache, heap_idx, vm_locked);

    }


    return obj;

}


ALWAYS_INLINE(static VALUE newobj_slowpath(VALUE klass, VALUE flags, rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, int wb_protected, size_t heap_idx));


static inline VALUE

newobj_slowpath(VALUE klass, VALUE flags, rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, int wb_protected, size_t heap_idx)

{

    VALUE obj;

    unsigned int lev;


    lev = RB_GC_CR_LOCK();

    {

        if (RB_UNLIKELY(during_gc || ruby_gc_stressful)) {

            if (during_gc) {

                dont_gc_on();

                during_gc = 0;

                if (rb_memerror_reentered()) {

                    rb_memerror();

                }

                rb_bug("object allocation during garbage collection phase");

            }


            if (ruby_gc_stressful) {

                if (!garbage_collect(objspace, GPR_FLAG_NEWOBJ)) {

                    rb_memerror();

                }

            }

        }


        obj = newobj_alloc(objspace, cache, heap_idx, true);

        newobj_init(klass, flags, wb_protected, objspace, obj);

    }

    RB_GC_CR_UNLOCK(lev);


    return obj;

}


NOINLINE(static VALUE newobj_slowpath_wb_protected(VALUE klass, VALUE flags,

                                                   rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, size_t heap_idx));

NOINLINE(static VALUE newobj_slowpath_wb_unprotected(VALUE klass, VALUE flags,

                                                     rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, size_t heap_idx));


static VALUE

newobj_slowpath_wb_protected(VALUE klass, VALUE flags, rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, size_t heap_idx)

{

    return newobj_slowpath(klass, flags, objspace, cache, TRUE, heap_idx);

}


static VALUE

newobj_slowpath_wb_unprotected(VALUE klass, VALUE flags, rb_objspace_t *objspace, rb_ractor_newobj_cache_t *cache, size_t heap_idx)

{

    return newobj_slowpath(klass, flags, objspace, cache, FALSE, heap_idx);

}


VALUE

rb_gc_impl_new_obj(void *objspace_ptr, void *cache_ptr, VALUE klass, VALUE flags, bool wb_protected, size_t alloc_size)

{

    VALUE obj;

    rb_objspace_t *objspace = objspace_ptr;


    RB_DEBUG_COUNTER_INC(obj_newobj);

    (void)RB_DEBUG_COUNTER_INC_IF(obj_newobj_wb_unprotected, !wb_protected);


    if (RB_UNLIKELY(stress_to_class)) {

        if (rb_hash_lookup2(stress_to_class, klass, Qundef) != Qundef) {

            rb_memerror();

        }

    }


    size_t heap_idx = heap_idx_for_size(alloc_size);


    rb_ractor_newobj_cache_t *cache = (rb_ractor_newobj_cache_t *)cache_ptr;


    if (!RB_UNLIKELY(during_gc || ruby_gc_stressful) &&

            wb_protected) {

        obj = newobj_alloc(objspace, cache, heap_idx, false);

        newobj_init(klass, flags, wb_protected, objspace, obj);

    }

    else {

        RB_DEBUG_COUNTER_INC(obj_newobj_slowpath);


        obj = wb_protected ?

          newobj_slowpath_wb_protected(klass, flags, objspace, cache, heap_idx) :

          newobj_slowpath_wb_unprotected(klass, flags, objspace, cache, heap_idx);

    }


    return obj;

}


static int

ptr_in_page_body_p(const void *ptr, const void *memb)

{

    struct heap_page *page = *(struct heap_page **)memb;

    uintptr_t p_body = (uintptr_t)page->body;


    if ((uintptr_t)ptr >= p_body) {

        return (uintptr_t)ptr < (p_body + HEAP_PAGE_SIZE) ? 0 : 1;

    }

    else {

        return -1;

    }

}


PUREFUNC(static inline struct heap_page *heap_page_for_ptr(rb_objspace_t *objspace, uintptr_t ptr);)

static inline struct heap_page *

heap_page_for_ptr(rb_objspace_t *objspace, uintptr_t ptr)

{

    struct heap_page **res;


    if (ptr < (uintptr_t)heap_pages_lomem ||

            ptr > (uintptr_t)heap_pages_himem) {

        return NULL;

    }


    res = bsearch((void *)ptr, rb_darray_ref(objspace->heap_pages.sorted, 0),

                  rb_darray_size(objspace->heap_pages.sorted), sizeof(struct heap_page *),

                  ptr_in_page_body_p);


    if (res) {

        return *res;

    }

    else {

        return NULL;

    }

}


PUREFUNC(static inline bool is_pointer_to_heap(rb_objspace_t *objspace, const void *ptr);)

static inline bool

is_pointer_to_heap(rb_objspace_t *objspace, const void *ptr)

{

    register uintptr_t p = (uintptr_t)ptr;

    register struct heap_page *page;


    RB_DEBUG_COUNTER_INC(gc_isptr_trial);


    if (p < heap_pages_lomem || p > heap_pages_himem) return FALSE;

    RB_DEBUG_COUNTER_INC(gc_isptr_range);


    if (p % sizeof(VALUE) != 0) return FALSE;

    RB_DEBUG_COUNTER_INC(gc_isptr_align);


    page = heap_page_for_ptr(objspace, (uintptr_t)ptr);

    if (page) {

        RB_DEBUG_COUNTER_INC(gc_isptr_maybe);

        if (heap_page_in_global_empty_pages_pool(objspace, page)) {

            return FALSE;

        }

        else {

            if (p < page->start) return FALSE;

            if (p >= page->start + (page->total_slots * page->slot_size)) return FALSE;

            if ((p - page->start) % page->slot_size != 0) return FALSE;


            return TRUE;

        }

    }

    return FALSE;

}


bool

rb_gc_impl_pointer_to_heap_p(void *objspace_ptr, const void *ptr)

{

    return is_pointer_to_heap(objspace_ptr, ptr);

}


#define ZOMBIE_OBJ_KEPT_FLAGS (FL_FINALIZE)


void

rb_gc_impl_make_zombie(void *objspace_ptr, VALUE obj, void (*dfree)(void *), void *data)

{

    rb_objspace_t *objspace = objspace_ptr;


    struct RZombie *zombie = RZOMBIE(obj);

    zombie->flags = T_ZOMBIE | (zombie->flags & ZOMBIE_OBJ_KEPT_FLAGS);

    zombie->dfree = dfree;

    zombie->data = data;

    VALUE prev, next = heap_pages_deferred_final;

    do {

        zombie->next = prev = next;

        next = RUBY_ATOMIC_VALUE_CAS(heap_pages_deferred_final, prev, obj);

    } while (next != prev);


    struct heap_page *page = GET_HEAP_PAGE(obj);

    page->final_slots++;

    page->heap->final_slots_count++;

}


typedef int each_obj_callback(void *, void *, size_t, void *);

typedef int each_page_callback(struct heap_page *, void *);


struct each_obj_data {

    rb_objspace_t *objspace;

    bool reenable_incremental;


    each_obj_callback *each_obj_callback;

    each_page_callback *each_page_callback;

    void *data;


    struct heap_page **pages[HEAP_COUNT];

    size_t pages_counts[HEAP_COUNT];

};


static VALUE

objspace_each_objects_ensure(VALUE arg)

{

    struct each_obj_data *data = (struct each_obj_data *)arg;

    rb_objspace_t *objspace = data->objspace;


    /* Reenable incremental GC */

    if (data->reenable_incremental) {

        objspace->flags.dont_incremental = FALSE;

    }


    for (int i = 0; i < HEAP_COUNT; i++) {

        struct heap_page **pages = data->pages[i];

        free(pages);

    }


    return Qnil;

}


static VALUE

objspace_each_objects_try(VALUE arg)

{

    struct each_obj_data *data = (struct each_obj_data *)arg;

    rb_objspace_t *objspace = data->objspace;


    /* Copy pages from all heaps to their respective buffers. */

    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        size_t size = heap->total_pages * sizeof(struct heap_page *);


        struct heap_page **pages = malloc(size);

        if (!pages) rb_memerror();


        /* Set up pages buffer by iterating over all pages in the current eden

         * heap. This will be a snapshot of the state of the heap before we

         * call the callback over each page that exists in this buffer. Thus it

         * is safe for the callback to allocate objects without possibly entering

         * an infinite loop. */

        struct heap_page *page = 0;

        size_t pages_count = 0;

        ccan_list_for_each(&heap->pages, page, page_node) {

            pages[pages_count] = page;

            pages_count++;

        }

        data->pages[i] = pages;

        data->pages_counts[i] = pages_count;

        GC_ASSERT(pages_count == heap->total_pages);

    }


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        size_t pages_count = data->pages_counts[i];

        struct heap_page **pages = data->pages[i];


        struct heap_page *page = ccan_list_top(&heap->pages, struct heap_page, page_node);

        for (size_t i = 0; i < pages_count; i++) {

            /* If we have reached the end of the linked list then there are no

             * more pages, so break. */

            if (page == NULL) break;


            /* If this page does not match the one in the buffer, then move to

             * the next page in the buffer. */

            if (pages[i] != page) continue;


            uintptr_t pstart = (uintptr_t)page->start;

            uintptr_t pend = pstart + (page->total_slots * heap->slot_size);


            if (data->each_obj_callback &&

                (*data->each_obj_callback)((void *)pstart, (void *)pend, heap->slot_size, data->data)) {

                break;

            }

            if (data->each_page_callback &&

                (*data->each_page_callback)(page, data->data)) {

                break;

            }


            page = ccan_list_next(&heap->pages, page, page_node);

        }

    }


    return Qnil;

}


static void

objspace_each_exec(bool protected, struct each_obj_data *each_obj_data)

{

    /* Disable incremental GC */

    rb_objspace_t *objspace = each_obj_data->objspace;

    bool reenable_incremental = FALSE;

    if (protected) {

        reenable_incremental = !objspace->flags.dont_incremental;


        gc_rest(objspace);

        objspace->flags.dont_incremental = TRUE;

    }


    each_obj_data->reenable_incremental = reenable_incremental;

    memset(&each_obj_data->pages, 0, sizeof(each_obj_data->pages));

    memset(&each_obj_data->pages_counts, 0, sizeof(each_obj_data->pages_counts));

    rb_ensure(objspace_each_objects_try, (VALUE)each_obj_data,

              objspace_each_objects_ensure, (VALUE)each_obj_data);

}


static void

objspace_each_objects(rb_objspace_t *objspace, each_obj_callback *callback, void *data, bool protected)

{

    struct each_obj_data each_obj_data = {

        .objspace = objspace,

        .each_obj_callback = callback,

        .each_page_callback = NULL,

        .data = data,

    };

    objspace_each_exec(protected, &each_obj_data);

}


void

rb_gc_impl_each_objects(void *objspace_ptr, each_obj_callback *callback, void *data)

{

    objspace_each_objects(objspace_ptr, callback, data, TRUE);

}


#if GC_CAN_COMPILE_COMPACTION

static void

objspace_each_pages(rb_objspace_t *objspace, each_page_callback *callback, void *data, bool protected)

{

    struct each_obj_data each_obj_data = {

        .objspace = objspace,

        .each_obj_callback = NULL,

        .each_page_callback = callback,

        .data = data,

    };

    objspace_each_exec(protected, &each_obj_data);

}

#endif


VALUE

rb_gc_impl_define_finalizer(void *objspace_ptr, VALUE obj, VALUE block)

{

    rb_objspace_t *objspace = objspace_ptr;

    VALUE table;

    st_data_t data;


    GC_ASSERT(!OBJ_FROZEN(obj));


    RBASIC(obj)->flags |= FL_FINALIZE;


    unsigned int lev = RB_GC_VM_LOCK();


    if (st_lookup(finalizer_table, obj, &data)) {

        table = (VALUE)data;

        VALUE dup_table = rb_ary_dup(table);


        RB_GC_VM_UNLOCK(lev);

        /* avoid duplicate block, table is usually small */

        {

            long len = RARRAY_LEN(table);

            long i;


            for (i = 0; i < len; i++) {

                VALUE recv = RARRAY_AREF(dup_table, i);

                if (rb_equal(recv, block)) { // can't be called with VM lock held

                    return recv;

                }

            }

        }

        lev = RB_GC_VM_LOCK();

        RB_GC_GUARD(dup_table);


        rb_ary_push(table, block);

    }

    else {

        table = rb_ary_new3(2, rb_obj_id(obj), block);

        rb_obj_hide(table);

        st_add_direct(finalizer_table, obj, table);

    }


    RB_GC_VM_UNLOCK(lev);


    return block;

}


void

rb_gc_impl_undefine_finalizer(void *objspace_ptr, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;


    GC_ASSERT(!OBJ_FROZEN(obj));


    st_data_t data = obj;


    int lev = RB_GC_VM_LOCK();

    st_delete(finalizer_table, &data, 0);

    RB_GC_VM_UNLOCK(lev);


    FL_UNSET(obj, FL_FINALIZE);

}


void

rb_gc_impl_copy_finalizer(void *objspace_ptr, VALUE dest, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;

    VALUE table;

    st_data_t data;


    if (!FL_TEST(obj, FL_FINALIZE)) return;


    int lev = RB_GC_VM_LOCK();

    if (RB_LIKELY(st_lookup(finalizer_table, obj, &data))) {

        table = rb_ary_dup((VALUE)data);

        RARRAY_ASET(table, 0, rb_obj_id(dest));

        st_insert(finalizer_table, dest, table);

        FL_SET(dest, FL_FINALIZE);

    }

    else {

        rb_bug("rb_gc_copy_finalizer: FL_FINALIZE set but not found in finalizer_table: %s", rb_obj_info(obj));

    }

    RB_GC_VM_UNLOCK(lev);

}


static VALUE

get_final(long i, void *data)

{

    VALUE table = (VALUE)data;


    return RARRAY_AREF(table, i + 1);

}


static unsigned int

run_final(rb_objspace_t *objspace, VALUE zombie, unsigned int lev)

{

    if (RZOMBIE(zombie)->dfree) {

        RZOMBIE(zombie)->dfree(RZOMBIE(zombie)->data);

    }


    st_data_t key = (st_data_t)zombie;

    if (FL_TEST_RAW(zombie, FL_FINALIZE)) {

        FL_UNSET(zombie, FL_FINALIZE);

        st_data_t table;

        if (st_delete(finalizer_table, &key, &table)) {

            RB_GC_VM_UNLOCK(lev);

            rb_gc_run_obj_finalizer(RARRAY_AREF(table, 0), RARRAY_LEN(table) - 1, get_final, (void *)table);

            lev = RB_GC_VM_LOCK();

        }

        else {

            rb_bug("FL_FINALIZE flag is set, but finalizers are not found");

        }

    }

    else {

        GC_ASSERT(!st_lookup(finalizer_table, key, NULL));

    }

    return lev;

}


static void

finalize_list(rb_objspace_t *objspace, VALUE zombie)

{

    while (zombie) {

        VALUE next_zombie;

        struct heap_page *page;

        rb_asan_unpoison_object(zombie, false);

        next_zombie = RZOMBIE(zombie)->next;

        page = GET_HEAP_PAGE(zombie);


        unsigned int lev = RB_GC_VM_LOCK();


        lev = run_final(objspace, zombie, lev);

        {

            GC_ASSERT(BUILTIN_TYPE(zombie) == T_ZOMBIE);

            GC_ASSERT(page->heap->final_slots_count > 0);

            GC_ASSERT(page->final_slots > 0);


            page->heap->final_slots_count--;

            page->final_slots--;

            page->free_slots++;

            RVALUE_AGE_SET_BITMAP(zombie, 0);

            heap_page_add_freeobj(objspace, page, zombie);

            page->heap->total_freed_objects++;

        }

        RB_GC_VM_UNLOCK(lev);


        zombie = next_zombie;

    }

}


static void

finalize_deferred_heap_pages(rb_objspace_t *objspace)

{

    VALUE zombie;

    while ((zombie = RUBY_ATOMIC_VALUE_EXCHANGE(heap_pages_deferred_final, 0)) != 0) {

        finalize_list(objspace, zombie);

    }

}


static void

finalize_deferred(rb_objspace_t *objspace)

{

    rb_gc_set_pending_interrupt();

    finalize_deferred_heap_pages(objspace);

    rb_gc_unset_pending_interrupt();

}


static void

gc_finalize_deferred(void *dmy)

{

    rb_objspace_t *objspace = dmy;

    if (RUBY_ATOMIC_EXCHANGE(finalizing, 1)) return;


    finalize_deferred(objspace);

    RUBY_ATOMIC_SET(finalizing, 0);

}


static void

gc_finalize_deferred_register(rb_objspace_t *objspace)

{

    /* will enqueue a call to gc_finalize_deferred */

    rb_postponed_job_trigger(objspace->finalize_deferred_pjob);

}


static int pop_mark_stack(mark_stack_t *stack, VALUE *data);


static void

gc_abort(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (is_incremental_marking(objspace)) {

        /* Remove all objects from the mark stack. */

        VALUE obj;

        while (pop_mark_stack(&objspace->mark_stack, &obj));


        objspace->flags.during_incremental_marking = FALSE;

    }


    if (is_lazy_sweeping(objspace)) {

        objspace->sweeping_heap_count = 0;

        for (int i = 0; i < HEAP_COUNT; i++) {

            rb_heap_t *heap = &heaps[i];


            heap->sweeping_page = NULL;

            struct heap_page *page = NULL;


            ccan_list_for_each(&heap->pages, page, page_node) {

                page->flags.before_sweep = false;

            }

        }

    }


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        rgengc_mark_and_rememberset_clear(objspace, heap);

    }


    gc_mode_set(objspace, gc_mode_none);

}


void

rb_gc_impl_shutdown_free_objects(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    for (size_t i = 0; i < rb_darray_size(objspace->heap_pages.sorted); i++) {

        struct heap_page *page = rb_darray_get(objspace->heap_pages.sorted, i);

        short stride = page->slot_size;


        uintptr_t p = (uintptr_t)page->start;

        uintptr_t pend = p + page->total_slots * stride;

        for (; p < pend; p += stride) {

            VALUE vp = (VALUE)p;

            asan_unpoisoning_object(vp) {

                if (RB_BUILTIN_TYPE(vp) != T_NONE) {

                    rb_gc_obj_free_vm_weak_references(vp);

                    if (rb_gc_obj_free(objspace, vp)) {

                        RBASIC(vp)->flags = 0;

                    }

                }

            }

        }

    }

}


static int

rb_gc_impl_shutdown_call_finalizer_i(st_data_t key, st_data_t val, st_data_t _data)

{

    VALUE obj = (VALUE)key;

    VALUE table = (VALUE)val;


    GC_ASSERT(RB_FL_TEST(obj, FL_FINALIZE));

    GC_ASSERT(RB_BUILTIN_TYPE(val) == T_ARRAY);


    rb_gc_run_obj_finalizer(RARRAY_AREF(table, 0), RARRAY_LEN(table) - 1, get_final, (void *)table);


    FL_UNSET(obj, FL_FINALIZE);


    return ST_DELETE;

}


void

rb_gc_impl_shutdown_call_finalizer(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


#if RGENGC_CHECK_MODE >= 2

    gc_verify_internal_consistency(objspace);

#endif


    /* prohibit incremental GC */

    objspace->flags.dont_incremental = 1;


    if (RUBY_ATOMIC_EXCHANGE(finalizing, 1)) {

        /* Abort incremental marking and lazy sweeping to speed up shutdown. */

        gc_abort(objspace);

        dont_gc_on();

        return;

    }


    while (finalizer_table->num_entries) {

        st_foreach(finalizer_table, rb_gc_impl_shutdown_call_finalizer_i, 0);

    }


    /* run finalizers */

    finalize_deferred(objspace);

    GC_ASSERT(heap_pages_deferred_final == 0);


    /* Abort incremental marking and lazy sweeping to speed up shutdown. */

    gc_abort(objspace);


    /* prohibit GC because force T_DATA finalizers can break an object graph consistency */

    dont_gc_on();


    /* running data/file finalizers are part of garbage collection */

    unsigned int lock_lev;

    gc_enter(objspace, gc_enter_event_finalizer, &lock_lev);


    /* run data/file object's finalizers */

    for (size_t i = 0; i < rb_darray_size(objspace->heap_pages.sorted); i++) {

        struct heap_page *page = rb_darray_get(objspace->heap_pages.sorted, i);

        short stride = page->slot_size;


        uintptr_t p = (uintptr_t)page->start;

        uintptr_t pend = p + page->total_slots * stride;

        for (; p < pend; p += stride) {

            VALUE vp = (VALUE)p;

            asan_unpoisoning_object(vp) {

                if (rb_gc_shutdown_call_finalizer_p(vp)) {

                    rb_gc_obj_free_vm_weak_references(vp);

                    if (rb_gc_obj_free(objspace, vp)) {

                        RBASIC(vp)->flags = 0;

                    }

                }

            }

        }

    }


    gc_exit(objspace, gc_enter_event_finalizer, &lock_lev);


    finalize_deferred_heap_pages(objspace);


    st_free_table(finalizer_table);

    finalizer_table = 0;

    RUBY_ATOMIC_SET(finalizing, 0);

}


void

rb_gc_impl_each_object(void *objspace_ptr, void (*func)(VALUE obj, void *data), void *data)

{

    rb_objspace_t *objspace = objspace_ptr;


    for (size_t i = 0; i < rb_darray_size(objspace->heap_pages.sorted); i++) {

        struct heap_page *page = rb_darray_get(objspace->heap_pages.sorted, i);

        short stride = page->slot_size;


        uintptr_t p = (uintptr_t)page->start;

        uintptr_t pend = p + page->total_slots * stride;

        for (; p < pend; p += stride) {

            VALUE obj = (VALUE)p;


            asan_unpoisoning_object(obj) {

                func(obj, data);

            }

        }

    }

}


/*

  ------------------------ Garbage Collection ------------------------

*/


/* Sweeping */


static size_t

objspace_available_slots(rb_objspace_t *objspace)

{

    size_t total_slots = 0;

    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        total_slots += heap->total_slots;

    }

    return total_slots;

}


static size_t

objspace_live_slots(rb_objspace_t *objspace)

{

    return total_allocated_objects(objspace) - total_freed_objects(objspace) - total_final_slots_count(objspace);

}


static size_t

objspace_free_slots(rb_objspace_t *objspace)

{

    return objspace_available_slots(objspace) - objspace_live_slots(objspace) - total_final_slots_count(objspace);

}


static void

gc_setup_mark_bits(struct heap_page *page)

{

    /* copy oldgen bitmap to mark bitmap */

    memcpy(&page->mark_bits[0], &page->uncollectible_bits[0], HEAP_PAGE_BITMAP_SIZE);

}


static int gc_is_moveable_obj(rb_objspace_t *objspace, VALUE obj);

static VALUE gc_move(rb_objspace_t *objspace, VALUE scan, VALUE free, size_t src_slot_size, size_t slot_size);


#if defined(_WIN32)

enum {HEAP_PAGE_LOCK = PAGE_NOACCESS, HEAP_PAGE_UNLOCK = PAGE_READWRITE};


static BOOL

protect_page_body(struct heap_page_body *body, DWORD protect)

{

    DWORD old_protect;

    return VirtualProtect(body, HEAP_PAGE_SIZE, protect, &old_protect) != 0;

}

#elif defined(__wasi__)

// wasi-libc's mprotect emulation does not support PROT_NONE

enum {HEAP_PAGE_LOCK, HEAP_PAGE_UNLOCK};

#define protect_page_body(body, protect) 1

#else

enum {HEAP_PAGE_LOCK = PROT_NONE, HEAP_PAGE_UNLOCK = PROT_READ | PROT_WRITE};

#define protect_page_body(body, protect) !mprotect((body), HEAP_PAGE_SIZE, (protect))

#endif


static void

lock_page_body(rb_objspace_t *objspace, struct heap_page_body *body)

{

    if (!protect_page_body(body, HEAP_PAGE_LOCK)) {

        rb_bug("Couldn't protect page %p, errno: %s", (void *)body, strerror(errno));

    }

    else {

        gc_report(5, objspace, "Protecting page in move %p\n", (void *)body);

    }

}


static void

unlock_page_body(rb_objspace_t *objspace, struct heap_page_body *body)

{

    if (!protect_page_body(body, HEAP_PAGE_UNLOCK)) {

        rb_bug("Couldn't unprotect page %p, errno: %s", (void *)body, strerror(errno));

    }

    else {

        gc_report(5, objspace, "Unprotecting page in move %p\n", (void *)body);

    }

}


static bool

try_move(rb_objspace_t *objspace, rb_heap_t *heap, struct heap_page *free_page, VALUE src)

{

    GC_ASSERT(gc_is_moveable_obj(objspace, src));


    struct heap_page *src_page = GET_HEAP_PAGE(src);

    if (!free_page) {

        return false;

    }


    /* We should return true if either src is successfully moved, or src is

     * unmoveable. A false return will cause the sweeping cursor to be

     * incremented to the next page, and src will attempt to move again */

    GC_ASSERT(RVALUE_MARKED(objspace, src));


    asan_unlock_freelist(free_page);

    VALUE dest = (VALUE)free_page->freelist;

    asan_lock_freelist(free_page);

    if (dest) {

        rb_asan_unpoison_object(dest, false);

    }

    else {

        /* if we can't get something from the freelist then the page must be

         * full */

        return false;

    }

    asan_unlock_freelist(free_page);

    free_page->freelist = ((struct free_slot *)dest)->next;

    asan_lock_freelist(free_page);


    GC_ASSERT(RB_BUILTIN_TYPE(dest) == T_NONE);


    if (src_page->slot_size > free_page->slot_size) {

        objspace->rcompactor.moved_down_count_table[BUILTIN_TYPE(src)]++;

    }

    else if (free_page->slot_size > src_page->slot_size) {

        objspace->rcompactor.moved_up_count_table[BUILTIN_TYPE(src)]++;

    }

    objspace->rcompactor.moved_count_table[BUILTIN_TYPE(src)]++;

    objspace->rcompactor.total_moved++;


    gc_move(objspace, src, dest, src_page->slot_size, free_page->slot_size);

    gc_pin(objspace, src);

    free_page->free_slots--;


    return true;

}


static void

gc_unprotect_pages(rb_objspace_t *objspace, rb_heap_t *heap)

{

    struct heap_page *cursor = heap->compact_cursor;


    while (cursor) {

        unlock_page_body(objspace, cursor->body);

        cursor = ccan_list_next(&heap->pages, cursor, page_node);

    }

}


static void gc_update_references(rb_objspace_t *objspace);

#if GC_CAN_COMPILE_COMPACTION

static void invalidate_moved_page(rb_objspace_t *objspace, struct heap_page *page);

#endif


#if defined(__MINGW32__) || defined(_WIN32)

# define GC_COMPACTION_SUPPORTED 1

#else

/* If not MinGW, Windows, or does not have mmap, we cannot use mprotect for

 * the read barrier, so we must disable compaction. */

# define GC_COMPACTION_SUPPORTED (GC_CAN_COMPILE_COMPACTION && HEAP_PAGE_ALLOC_USE_MMAP)

#endif


#if GC_CAN_COMPILE_COMPACTION

static void

read_barrier_handler(uintptr_t address)

{

    rb_objspace_t *objspace = (rb_objspace_t *)rb_gc_get_objspace();


    struct heap_page_body *page_body = GET_PAGE_BODY(address);


    /* If the page_body is NULL, then mprotect cannot handle it and will crash

     * with "Cannot allocate memory". */

    if (page_body == NULL) {

        rb_bug("read_barrier_handler: segmentation fault at %p", (void *)address);

    }


    int lev = RB_GC_VM_LOCK();

    {

        unlock_page_body(objspace, page_body);


        objspace->profile.read_barrier_faults++;


        invalidate_moved_page(objspace, GET_HEAP_PAGE(address));

    }

    RB_GC_VM_UNLOCK(lev);

}

#endif


#if !GC_CAN_COMPILE_COMPACTION

static void

uninstall_handlers(void)

{

    /* no-op */

}


static void

install_handlers(void)

{

    /* no-op */

}

#elif defined(_WIN32)

static LPTOP_LEVEL_EXCEPTION_FILTER old_handler;

typedef void (*signal_handler)(int);

static signal_handler old_sigsegv_handler;


static LONG WINAPI

read_barrier_signal(EXCEPTION_POINTERS *info)

{

    /* EXCEPTION_ACCESS_VIOLATION is what's raised by access to protected pages */

    if (info->ExceptionRecord->ExceptionCode == EXCEPTION_ACCESS_VIOLATION) {

        /* > The second array element specifies the virtual address of the inaccessible data.

         * https://docs.microsoft.com/en-us/windows/win32/api/winnt/ns-winnt-exception_record

         *

         * Use this address to invalidate the page */

        read_barrier_handler((uintptr_t)info->ExceptionRecord->ExceptionInformation[1]);

        return EXCEPTION_CONTINUE_EXECUTION;

    }

    else {

        return EXCEPTION_CONTINUE_SEARCH;

    }

}


static void

uninstall_handlers(void)

{

    signal(SIGSEGV, old_sigsegv_handler);

    SetUnhandledExceptionFilter(old_handler);

}


static void

install_handlers(void)

{

    /* Remove SEGV handler so that the Unhandled Exception Filter handles it */

    old_sigsegv_handler = signal(SIGSEGV, NULL);

    /* Unhandled Exception Filter has access to the violation address similar

     * to si_addr from sigaction */

    old_handler = SetUnhandledExceptionFilter(read_barrier_signal);

}

#else

static struct sigaction old_sigbus_handler;

static struct sigaction old_sigsegv_handler;


#ifdef HAVE_MACH_TASK_EXCEPTION_PORTS

static exception_mask_t old_exception_masks[32];

static mach_port_t old_exception_ports[32];

static exception_behavior_t old_exception_behaviors[32];

static thread_state_flavor_t old_exception_flavors[32];

static mach_msg_type_number_t old_exception_count;


static void

disable_mach_bad_access_exc(void)

{

    old_exception_count = sizeof(old_exception_masks) / sizeof(old_exception_masks[0]);

    task_swap_exception_ports(

        mach_task_self(), EXC_MASK_BAD_ACCESS,

        MACH_PORT_NULL, EXCEPTION_DEFAULT, 0,

        old_exception_masks, &old_exception_count,

        old_exception_ports, old_exception_behaviors, old_exception_flavors

    );

}


static void

restore_mach_bad_access_exc(void)

{

    for (mach_msg_type_number_t i = 0; i < old_exception_count; i++) {

        task_set_exception_ports(

            mach_task_self(),

            old_exception_masks[i], old_exception_ports[i],

            old_exception_behaviors[i], old_exception_flavors[i]

        );

    }

}

#endif


static void

read_barrier_signal(int sig, siginfo_t *info, void *data)

{

    // setup SEGV/BUS handlers for errors

    struct sigaction prev_sigbus, prev_sigsegv;

    sigaction(SIGBUS, &old_sigbus_handler, &prev_sigbus);

    sigaction(SIGSEGV, &old_sigsegv_handler, &prev_sigsegv);


    // enable SIGBUS/SEGV

    sigset_t set, prev_set;

    sigemptyset(&set);

    sigaddset(&set, SIGBUS);

    sigaddset(&set, SIGSEGV);

    sigprocmask(SIG_UNBLOCK, &set, &prev_set);

#ifdef HAVE_MACH_TASK_EXCEPTION_PORTS

    disable_mach_bad_access_exc();

#endif

    // run handler

    read_barrier_handler((uintptr_t)info->si_addr);


    // reset SEGV/BUS handlers

#ifdef HAVE_MACH_TASK_EXCEPTION_PORTS

    restore_mach_bad_access_exc();

#endif

    sigaction(SIGBUS, &prev_sigbus, NULL);

    sigaction(SIGSEGV, &prev_sigsegv, NULL);

    sigprocmask(SIG_SETMASK, &prev_set, NULL);

}


static void

uninstall_handlers(void)

{

#ifdef HAVE_MACH_TASK_EXCEPTION_PORTS

    restore_mach_bad_access_exc();

#endif

    sigaction(SIGBUS, &old_sigbus_handler, NULL);

    sigaction(SIGSEGV, &old_sigsegv_handler, NULL);

}


static void

install_handlers(void)

{

    struct sigaction action;

    memset(&action, 0, sizeof(struct sigaction));

    sigemptyset(&action.sa_mask);

    action.sa_sigaction = read_barrier_signal;

    action.sa_flags = SA_SIGINFO | SA_ONSTACK;


    sigaction(SIGBUS, &action, &old_sigbus_handler);

    sigaction(SIGSEGV, &action, &old_sigsegv_handler);

#ifdef HAVE_MACH_TASK_EXCEPTION_PORTS

    disable_mach_bad_access_exc();

#endif

}

#endif


static void

gc_compact_finish(rb_objspace_t *objspace)

{

    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        gc_unprotect_pages(objspace, heap);

    }


    uninstall_handlers();


    gc_update_references(objspace);

    objspace->profile.compact_count++;


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        heap->compact_cursor = NULL;

        heap->free_pages = NULL;

        heap->compact_cursor_index = 0;

    }


    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);

        record->moved_objects = objspace->rcompactor.total_moved - record->moved_objects;

    }

    objspace->flags.during_compacting = FALSE;

}


struct gc_sweep_context {

    struct heap_page *page;

    int final_slots;

    int freed_slots;

    int empty_slots;

};


static inline void

gc_sweep_plane(rb_objspace_t *objspace, rb_heap_t *heap, uintptr_t p, bits_t bitset, struct gc_sweep_context *ctx)

{

    struct heap_page *sweep_page = ctx->page;

    short slot_size = sweep_page->slot_size;


    do {

        VALUE vp = (VALUE)p;

        GC_ASSERT(vp % sizeof(VALUE) == 0);


        rb_asan_unpoison_object(vp, false);

        if (bitset & 1) {

            switch (BUILTIN_TYPE(vp)) {

              case T_MOVED:

                if (objspace->flags.during_compacting) {

                    /* The sweep cursor shouldn't have made it to any

                     * T_MOVED slots while the compact flag is enabled.

                     * The sweep cursor and compact cursor move in

                     * opposite directions, and when they meet references will

                     * get updated and "during_compacting" should get disabled */

                    rb_bug("T_MOVED shouldn't be seen until compaction is finished");

                }

                gc_report(3, objspace, "page_sweep: %s is added to freelist\n", rb_obj_info(vp));

                ctx->empty_slots++;

                heap_page_add_freeobj(objspace, sweep_page, vp);

                break;

              case T_ZOMBIE:

                /* already counted */

                break;

              case T_NONE:

                ctx->empty_slots++; /* already freed */

                break;


              default:

#if RGENGC_CHECK_MODE

                if (!is_full_marking(objspace)) {

                    if (RVALUE_OLD_P(objspace, vp)) rb_bug("page_sweep: %p - old while minor GC.", (void *)p);

                    if (RVALUE_REMEMBERED(objspace, vp)) rb_bug("page_sweep: %p - remembered.", (void *)p);

                }

#endif


#if RGENGC_CHECK_MODE

#define CHECK(x) if (x(objspace, vp) != FALSE) rb_bug("obj_free: " #x "(%s) != FALSE", rb_obj_info(vp))

                CHECK(RVALUE_WB_UNPROTECTED);

                CHECK(RVALUE_MARKED);

                CHECK(RVALUE_MARKING);

                CHECK(RVALUE_UNCOLLECTIBLE);

#undef CHECK

#endif


                if (!rb_gc_obj_needs_cleanup_p(vp)) {

                    if (RB_UNLIKELY(objspace->hook_events & RUBY_INTERNAL_EVENT_FREEOBJ)) {

                        rb_gc_event_hook(vp, RUBY_INTERNAL_EVENT_FREEOBJ);

                    }


                    (void)VALGRIND_MAKE_MEM_UNDEFINED((void*)p, slot_size);

                    heap_page_add_freeobj(objspace, sweep_page, vp);

                    gc_report(3, objspace, "page_sweep: %s (fast path) added to freelist\n", rb_obj_info(vp));

                    ctx->freed_slots++;

                }

                else {

                    gc_report(2, objspace, "page_sweep: free %p\n", (void *)p);


                    rb_gc_event_hook(vp, RUBY_INTERNAL_EVENT_FREEOBJ);


                    rb_gc_obj_free_vm_weak_references(vp);

                    if (rb_gc_obj_free(objspace, vp)) {

                        (void)VALGRIND_MAKE_MEM_UNDEFINED((void*)p, slot_size);

                        heap_page_add_freeobj(objspace, sweep_page, vp);

                        gc_report(3, objspace, "page_sweep: %s is added to freelist\n", rb_obj_info(vp));

                        ctx->freed_slots++;

                    }

                    else {

                        ctx->final_slots++;

                    }

                }

                break;

            }

        }

        p += slot_size;

        bitset >>= 1;

    } while (bitset);

}


static inline void

gc_sweep_page(rb_objspace_t *objspace, rb_heap_t *heap, struct gc_sweep_context *ctx)

{

    struct heap_page *sweep_page = ctx->page;

    GC_ASSERT(sweep_page->heap == heap);


    uintptr_t p;

    bits_t *bits, bitset;


    gc_report(2, objspace, "page_sweep: start.\n");


#if RGENGC_CHECK_MODE

    if (!objspace->flags.immediate_sweep) {

        GC_ASSERT(sweep_page->flags.before_sweep == TRUE);

    }

#endif

    sweep_page->flags.before_sweep = FALSE;

    sweep_page->free_slots = 0;


    p = (uintptr_t)sweep_page->start;

    bits = sweep_page->mark_bits;

    short slot_size = sweep_page->slot_size;

    int total_slots = sweep_page->total_slots;

    int bitmap_plane_count = CEILDIV(total_slots, BITS_BITLENGTH);


    int out_of_range_bits = total_slots % BITS_BITLENGTH;

    if (out_of_range_bits != 0) {

        bits[bitmap_plane_count - 1] |= ~(((bits_t)1 << out_of_range_bits) - 1);

    }


    // Clear wb_unprotected and age bits for all unmarked slots

    {

        bits_t *wb_unprotected_bits = sweep_page->wb_unprotected_bits;

        bits_t *age_bits = sweep_page->age_bits;

        for (int i = 0; i < bitmap_plane_count; i++) {

            bits_t unmarked = ~bits[i];

            wb_unprotected_bits[i] &= ~unmarked;

            age_bits[i * 2] &= ~unmarked;

            age_bits[i * 2 + 1] &= ~unmarked;

        }

    }


    for (int i = 0; i < bitmap_plane_count; i++) {

        bitset = ~bits[i];

        if (bitset) {

            gc_sweep_plane(objspace, heap, p, bitset, ctx);

        }

        p += BITS_BITLENGTH * slot_size;

    }


    if (!heap->compact_cursor) {

        gc_setup_mark_bits(sweep_page);

    }


#if GC_PROFILE_MORE_DETAIL

    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);

        record->removing_objects += ctx->final_slots + ctx->freed_slots;

        record->empty_objects += ctx->empty_slots;

    }

#endif

    if (0) fprintf(stderr, "gc_sweep_page(%"PRIdSIZE"): total_slots: %d, freed_slots: %d, empty_slots: %d, final_slots: %d\n",

                   rb_gc_count(),

                   sweep_page->total_slots,

                   ctx->freed_slots, ctx->empty_slots, ctx->final_slots);


    sweep_page->free_slots += ctx->freed_slots + ctx->empty_slots;

    sweep_page->heap->total_freed_objects += ctx->freed_slots;


    if (heap_pages_deferred_final && !finalizing) {

        gc_finalize_deferred_register(objspace);

    }


#if RGENGC_CHECK_MODE

    short freelist_len = 0;

    asan_unlock_freelist(sweep_page);

    struct free_slot *ptr = sweep_page->freelist;

    while (ptr) {

        freelist_len++;

        rb_asan_unpoison_object((VALUE)ptr, false);

        struct free_slot *next = ptr->next;

        rb_asan_poison_object((VALUE)ptr);

        ptr = next;

    }

    asan_lock_freelist(sweep_page);

    if (freelist_len != sweep_page->free_slots) {

        rb_bug("inconsistent freelist length: expected %d but was %d", sweep_page->free_slots, freelist_len);

    }

#endif


    gc_report(2, objspace, "page_sweep: end.\n");

}


static const char *

gc_mode_name(enum gc_mode mode)

{

    switch (mode) {

      case gc_mode_none: return "none";

      case gc_mode_marking: return "marking";

      case gc_mode_sweeping: return "sweeping";

      case gc_mode_compacting: return "compacting";

      default: rb_bug("gc_mode_name: unknown mode: %d", (int)mode);

    }

}


static void

gc_mode_transition(rb_objspace_t *objspace, enum gc_mode mode)

{

#if RGENGC_CHECK_MODE

    enum gc_mode prev_mode = gc_mode(objspace);

    switch (prev_mode) {

      case gc_mode_none:     GC_ASSERT(mode == gc_mode_marking); break;

      case gc_mode_marking:  GC_ASSERT(mode == gc_mode_sweeping); break;

      case gc_mode_sweeping: GC_ASSERT(mode == gc_mode_none || mode == gc_mode_compacting); break;

      case gc_mode_compacting: GC_ASSERT(mode == gc_mode_none); break;

    }

#endif

    if (0) fprintf(stderr, "gc_mode_transition: %s->%s\n", gc_mode_name(gc_mode(objspace)), gc_mode_name(mode));

    gc_mode_set(objspace, mode);

}


static void

heap_page_freelist_append(struct heap_page *page, struct free_slot *freelist)

{

    if (freelist) {

        asan_unlock_freelist(page);

        if (page->freelist) {

            struct free_slot *p = page->freelist;

            rb_asan_unpoison_object((VALUE)p, false);

            while (p->next) {

                struct free_slot *prev = p;

                p = p->next;

                rb_asan_poison_object((VALUE)prev);

                rb_asan_unpoison_object((VALUE)p, false);

            }

            p->next = freelist;

            rb_asan_poison_object((VALUE)p);

        }

        else {

            page->freelist = freelist;

        }

        asan_lock_freelist(page);

    }

}


static void

gc_sweep_start_heap(rb_objspace_t *objspace, rb_heap_t *heap)

{

    heap->sweeping_page = ccan_list_top(&heap->pages, struct heap_page, page_node);

    if (heap->sweeping_page) {

        objspace->sweeping_heap_count++;

    }

    heap->free_pages = NULL;

    heap->pooled_pages = NULL;

    if (!objspace->flags.immediate_sweep) {

        struct heap_page *page = NULL;


        ccan_list_for_each(&heap->pages, page, page_node) {

            page->flags.before_sweep = TRUE;

        }

    }

}


#if defined(__GNUC__) && __GNUC__ == 4 && __GNUC_MINOR__ == 4

__attribute__((noinline))

#endif


#if GC_CAN_COMPILE_COMPACTION

static void gc_sort_heap_by_compare_func(rb_objspace_t *objspace, gc_compact_compare_func compare_func);

static int compare_pinned_slots(const void *left, const void *right, void *d);

#endif


static void

gc_ractor_newobj_cache_clear(void *c, void *data)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();

    rb_ractor_newobj_cache_t *newobj_cache = c;


    newobj_cache->incremental_mark_step_allocated_slots = 0;


    for (size_t heap_idx = 0; heap_idx < HEAP_COUNT; heap_idx++) {


        rb_ractor_newobj_heap_cache_t *cache = &newobj_cache->heap_caches[heap_idx];


        rb_heap_t *heap = &heaps[heap_idx];

        RUBY_ATOMIC_SIZE_ADD(heap->total_allocated_objects, cache->allocated_objects_count);

        cache->allocated_objects_count = 0;


        struct heap_page *page = cache->using_page;

        struct free_slot *freelist = cache->freelist;

        RUBY_DEBUG_LOG("ractor using_page:%p freelist:%p", (void *)page, (void *)freelist);


        heap_page_freelist_append(page, freelist);


        cache->using_page = NULL;

        cache->freelist = NULL;

    }

}


static void

gc_sweep_start(rb_objspace_t *objspace)

{

    gc_mode_transition(objspace, gc_mode_sweeping);

    objspace->rincgc.pooled_slots = 0;


#if GC_CAN_COMPILE_COMPACTION

    if (objspace->flags.during_compacting) {

        gc_sort_heap_by_compare_func(

            objspace,

            objspace->rcompactor.compare_func ? objspace->rcompactor.compare_func : compare_pinned_slots

        );

    }

#endif


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        gc_sweep_start_heap(objspace, heap);


        /* We should call gc_sweep_finish_heap for size pools with no pages. */

        if (heap->sweeping_page == NULL) {

            GC_ASSERT(heap->total_pages == 0);

            GC_ASSERT(heap->total_slots == 0);

            gc_sweep_finish_heap(objspace, heap);

        }

    }


    rb_gc_ractor_newobj_cache_foreach(gc_ractor_newobj_cache_clear, NULL);

}


static void

gc_sweep_finish_heap(rb_objspace_t *objspace, rb_heap_t *heap)

{

    size_t total_slots = heap->total_slots;

    size_t swept_slots = heap->freed_slots + heap->empty_slots;


    size_t init_slots = gc_params.heap_init_bytes / heap->slot_size;

    size_t min_free_slots = (size_t)(MAX(total_slots, init_slots) * gc_params.heap_free_slots_min_ratio);


    if (swept_slots < min_free_slots &&

            /* The heap is a growth heap if it freed more slots than had empty slots. */

            ((heap->empty_slots == 0 && total_slots > 0) || heap->freed_slots > heap->empty_slots)) {

        /* If we don't have enough slots and we have pages on the tomb heap, move

        * pages from the tomb heap to the eden heap. This may prevent page

        * creation thrashing (frequently allocating and deallocting pages) and

        * GC thrashing (running GC more frequently than required). */

        struct heap_page *resurrected_page;

        while (swept_slots < min_free_slots &&

                (resurrected_page = heap_page_resurrect(objspace))) {

            heap_add_page(objspace, heap, resurrected_page);

            heap_add_freepage(heap, resurrected_page);


            swept_slots += resurrected_page->free_slots;

        }


        if (swept_slots < min_free_slots) {

            /* Grow this heap if we are in a major GC or if we haven't run at least

             * RVALUE_OLD_AGE minor GC since the last major GC. */

            if (is_full_marking(objspace) ||

                    objspace->profile.count - objspace->rgengc.last_major_gc < RVALUE_OLD_AGE) {

                if (objspace->heap_pages.allocatable_bytes < min_free_slots * heap->slot_size) {

                    heap_allocatable_bytes_expand(objspace, heap, swept_slots, heap->total_slots, heap->slot_size);

                }

            }

            else if (swept_slots < min_free_slots * 7 / 8 &&

                     objspace->heap_pages.allocatable_bytes < (min_free_slots * 7 / 8 - swept_slots) * heap->slot_size) {

                gc_needs_major_flags |= GPR_FLAG_MAJOR_BY_NOFREE;

                heap->force_major_gc_count++;

            }

        }

    }

}


static void

gc_sweep_finish(rb_objspace_t *objspace)

{

    gc_report(1, objspace, "gc_sweep_finish\n");


    gc_prof_set_heap_info(objspace);

    heap_pages_free_unused_pages(objspace);


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];


        heap->freed_slots = 0;

        heap->empty_slots = 0;


        if (!will_be_incremental_marking(objspace)) {

            struct heap_page *end_page = heap->free_pages;

            if (end_page) {

                while (end_page->free_next) end_page = end_page->free_next;

                end_page->free_next = heap->pooled_pages;

            }

            else {

                heap->free_pages = heap->pooled_pages;

            }

            heap->pooled_pages = NULL;

            objspace->rincgc.pooled_slots = 0;

        }

    }


    rb_gc_event_hook(0, RUBY_INTERNAL_EVENT_GC_END_SWEEP);

    gc_mode_transition(objspace, gc_mode_none);


#if RGENGC_CHECK_MODE >= 2

    gc_verify_internal_consistency(objspace);

#endif

}


static int

gc_sweep_step(rb_objspace_t *objspace, rb_heap_t *heap)

{

    struct heap_page *sweep_page = heap->sweeping_page;

    int swept_slots = 0;

    int pooled_slots = 0;

    int sweep_budget = GC_INCREMENTAL_SWEEP_BYTES / heap->slot_size;

    int pool_budget = GC_INCREMENTAL_SWEEP_POOL_BYTES / heap->slot_size;


    if (sweep_page == NULL) return FALSE;


#if GC_ENABLE_LAZY_SWEEP

    gc_prof_sweep_timer_start(objspace);

#endif


    do {

        RUBY_DEBUG_LOG("sweep_page:%p", (void *)sweep_page);


        struct gc_sweep_context ctx = {

            .page = sweep_page,

            .final_slots = 0,

            .freed_slots = 0,

            .empty_slots = 0,

        };

        gc_sweep_page(objspace, heap, &ctx);

        int free_slots = ctx.freed_slots + ctx.empty_slots;


        heap->sweeping_page = ccan_list_next(&heap->pages, sweep_page, page_node);


        if (free_slots == sweep_page->total_slots) {

            /* There are no living objects, so move this page to the global empty pages. */

            heap_unlink_page(objspace, heap, sweep_page);


            sweep_page->start = 0;

            sweep_page->total_slots = 0;

            sweep_page->slot_size = 0;

            sweep_page->heap = NULL;

            sweep_page->free_slots = 0;


            asan_unlock_freelist(sweep_page);

            sweep_page->freelist = NULL;

            asan_lock_freelist(sweep_page);


            asan_poison_memory_region(sweep_page->body, HEAP_PAGE_SIZE);


            objspace->empty_pages_count++;

            sweep_page->free_next = objspace->empty_pages;

            objspace->empty_pages = sweep_page;

        }

        else if (free_slots > 0) {

            heap->freed_slots += ctx.freed_slots;

            heap->empty_slots += ctx.empty_slots;


            if (pooled_slots < pool_budget) {

                heap_add_poolpage(objspace, heap, sweep_page);

                pooled_slots += free_slots;

            }

            else {

                heap_add_freepage(heap, sweep_page);

                swept_slots += free_slots;

                if (swept_slots > sweep_budget) {

                    break;

                }

            }

        }

        else {

            sweep_page->free_next = NULL;

        }

    } while ((sweep_page = heap->sweeping_page));


    if (!heap->sweeping_page) {

        objspace->sweeping_heap_count--;

        GC_ASSERT(objspace->sweeping_heap_count >= 0);

        gc_sweep_finish_heap(objspace, heap);


        if (!has_sweeping_pages(objspace)) {

            gc_sweep_finish(objspace);

        }

    }


#if GC_ENABLE_LAZY_SWEEP

    gc_prof_sweep_timer_stop(objspace);

#endif


    return heap->free_pages != NULL;

}


static void

gc_sweep_rest(rb_objspace_t *objspace)

{

    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];


        while (heap->sweeping_page) {

            gc_sweep_step(objspace, heap);

        }

    }

}


static void

gc_sweep_continue(rb_objspace_t *objspace, rb_heap_t *sweep_heap)

{

    GC_ASSERT(dont_gc_val() == FALSE || objspace->profile.latest_gc_info & GPR_FLAG_METHOD);

    if (!GC_ENABLE_LAZY_SWEEP) return;


    gc_sweeping_enter(objspace);


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        if (gc_sweep_step(objspace, heap)) {

            GC_ASSERT(heap->free_pages != NULL);

        }

        else if (heap == sweep_heap) {

            if (objspace->empty_pages_count > 0 || objspace->heap_pages.allocatable_bytes > 0) {

                /* [Bug #21548]

                 *

                 * If this heap is the heap we want to sweep, but we weren't able

                 * to free any slots, but we also either have empty pages or could

                 * allocate new pages, then we want to preemptively claim a page

                 * because it's possible that sweeping another heap will call

                 * gc_sweep_finish_heap, which may use up all of the

                 * empty/allocatable pages. If other heaps are not finished sweeping

                 * then we do not finish this GC and we will end up triggering a new

                 * GC cycle during this GC phase. */

                heap_page_allocate_and_initialize(objspace, heap);


                GC_ASSERT(heap->free_pages != NULL);

            }

            else {

                /* Not allowed to create a new page so finish sweeping. */

                gc_sweep_rest(objspace);

                GC_ASSERT(gc_mode(objspace) == gc_mode_none);

                break;

            }

        }

    }


    gc_sweeping_exit(objspace);

}


VALUE

rb_gc_impl_location(void *objspace_ptr, VALUE value)

{

    VALUE destination;


    asan_unpoisoning_object(value) {

        if (BUILTIN_TYPE(value) == T_MOVED) {

            destination = (VALUE)RMOVED(value)->destination;

            GC_ASSERT(BUILTIN_TYPE(destination) != T_NONE);

        }

        else {

            destination = value;

        }

    }


    return destination;

}


#if GC_CAN_COMPILE_COMPACTION

static void

invalidate_moved_plane(rb_objspace_t *objspace, struct heap_page *page, uintptr_t p, bits_t bitset)

{

    if (bitset) {

        do {

            if (bitset & 1) {

                VALUE forwarding_object = (VALUE)p;

                VALUE object;


                if (BUILTIN_TYPE(forwarding_object) == T_MOVED) {

                    GC_ASSERT(RVALUE_PINNED(objspace, forwarding_object));

                    GC_ASSERT(!RVALUE_MARKED(objspace, forwarding_object));


                    CLEAR_IN_BITMAP(GET_HEAP_PINNED_BITS(forwarding_object), forwarding_object);


                    object = rb_gc_impl_location(objspace, forwarding_object);


                    uint32_t original_shape_id = 0;

                    if (RB_TYPE_P(object, T_OBJECT)) {

                        original_shape_id = RMOVED(forwarding_object)->original_shape_id;

                    }


                    gc_move(objspace, object, forwarding_object, GET_HEAP_PAGE(object)->slot_size, page->slot_size);

                    /* forwarding_object is now our actual object, and "object"

                     * is the free slot for the original page */


                    if (original_shape_id) {

                        rb_gc_set_shape(forwarding_object, original_shape_id);

                    }


                    struct heap_page *orig_page = GET_HEAP_PAGE(object);

                    orig_page->free_slots++;

                    RVALUE_AGE_SET_BITMAP(object, 0);

                    heap_page_add_freeobj(objspace, orig_page, object);


                    GC_ASSERT(RVALUE_MARKED(objspace, forwarding_object));

                    GC_ASSERT(BUILTIN_TYPE(forwarding_object) != T_MOVED);

                    GC_ASSERT(BUILTIN_TYPE(forwarding_object) != T_NONE);

                }

            }

            p += page->slot_size;

            bitset >>= 1;

        } while (bitset);

    }

}


static void

invalidate_moved_page(rb_objspace_t *objspace, struct heap_page *page)

{

    int i;

    bits_t *mark_bits, *pin_bits;

    bits_t bitset;

    short slot_size = page->slot_size;

    int total_slots = page->total_slots;

    int bitmap_plane_count = CEILDIV(total_slots, BITS_BITLENGTH);


    mark_bits = page->mark_bits;

    pin_bits = page->pinned_bits;


    uintptr_t p = page->start;


    for (i=0; i < bitmap_plane_count; i++) {

        /* Moved objects are pinned but never marked. We reuse the pin bits

         * to indicate there is a moved object in this slot. */

        bitset = pin_bits[i] & ~mark_bits[i];

        invalidate_moved_plane(objspace, page, p, bitset);

        p += BITS_BITLENGTH * slot_size;

    }

}

#endif


static void

gc_compact_start(rb_objspace_t *objspace)

{

    struct heap_page *page = NULL;

    gc_mode_transition(objspace, gc_mode_compacting);


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        ccan_list_for_each(&heap->pages, page, page_node) {

            page->flags.before_sweep = TRUE;

        }


        heap->compact_cursor = ccan_list_tail(&heap->pages, struct heap_page, page_node);

        heap->compact_cursor_index = 0;

    }


    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);

        record->moved_objects = objspace->rcompactor.total_moved;

    }


    memset(objspace->rcompactor.considered_count_table, 0, T_MASK * sizeof(size_t));

    memset(objspace->rcompactor.moved_count_table, 0, T_MASK * sizeof(size_t));

    memset(objspace->rcompactor.moved_up_count_table, 0, T_MASK * sizeof(size_t));

    memset(objspace->rcompactor.moved_down_count_table, 0, T_MASK * sizeof(size_t));


    /* Set up read barrier for pages containing MOVED objects */

    install_handlers();

}


static void gc_sweep_compact(rb_objspace_t *objspace);


static void

gc_sweep(rb_objspace_t *objspace)

{

    gc_sweeping_enter(objspace);


    const unsigned int immediate_sweep = objspace->flags.immediate_sweep;


    gc_report(1, objspace, "gc_sweep: immediate: %d\n", immediate_sweep);


    gc_sweep_start(objspace);

    if (objspace->flags.during_compacting) {

        gc_sweep_compact(objspace);

    }


    if (immediate_sweep) {

#if !GC_ENABLE_LAZY_SWEEP

        gc_prof_sweep_timer_start(objspace);

#endif

        gc_sweep_rest(objspace);

#if !GC_ENABLE_LAZY_SWEEP

        gc_prof_sweep_timer_stop(objspace);

#endif

    }

    else {


        /* Sweep every size pool. */

        for (int i = 0; i < HEAP_COUNT; i++) {

            rb_heap_t *heap = &heaps[i];

            gc_sweep_step(objspace, heap);

        }

    }


    gc_sweeping_exit(objspace);

}


/* Marking - Marking stack */


static stack_chunk_t *

stack_chunk_alloc(void)

{

    stack_chunk_t *res;


    res = malloc(sizeof(stack_chunk_t));

    if (!res)

        rb_memerror();


    return res;

}


static inline int

is_mark_stack_empty(mark_stack_t *stack)

{

    return stack->chunk == NULL;

}


static size_t

mark_stack_size(mark_stack_t *stack)

{

    size_t size = stack->index;

    stack_chunk_t *chunk = stack->chunk ? stack->chunk->next : NULL;


    while (chunk) {

        size += stack->limit;

        chunk = chunk->next;

    }

    return size;

}


static void

add_stack_chunk_cache(mark_stack_t *stack, stack_chunk_t *chunk)

{

    chunk->next = stack->cache;

    stack->cache = chunk;

    stack->cache_size++;

}


static void

shrink_stack_chunk_cache(mark_stack_t *stack)

{

    stack_chunk_t *chunk;


    if (stack->unused_cache_size > (stack->cache_size/2)) {

        chunk = stack->cache;

        stack->cache = stack->cache->next;

        stack->cache_size--;

        free(chunk);

    }

    stack->unused_cache_size = stack->cache_size;

}


static void

push_mark_stack_chunk(mark_stack_t *stack)

{

    stack_chunk_t *next;


    GC_ASSERT(stack->index == stack->limit);


    if (stack->cache_size > 0) {

        next = stack->cache;

        stack->cache = stack->cache->next;

        stack->cache_size--;

        if (stack->unused_cache_size > stack->cache_size)

            stack->unused_cache_size = stack->cache_size;

    }

    else {

        next = stack_chunk_alloc();

    }

    next->next = stack->chunk;

    stack->chunk = next;

    stack->index = 0;

}


static void

pop_mark_stack_chunk(mark_stack_t *stack)

{

    stack_chunk_t *prev;


    prev = stack->chunk->next;

    GC_ASSERT(stack->index == 0);

    add_stack_chunk_cache(stack, stack->chunk);

    stack->chunk = prev;

    stack->index = stack->limit;

}


static void

mark_stack_chunk_list_free(stack_chunk_t *chunk)

{

    stack_chunk_t *next = NULL;


    while (chunk != NULL) {

        next = chunk->next;

        free(chunk);

        chunk = next;

    }

}


static void

free_stack_chunks(mark_stack_t *stack)

{

    mark_stack_chunk_list_free(stack->chunk);

}


static void

mark_stack_free_cache(mark_stack_t *stack)

{

    mark_stack_chunk_list_free(stack->cache);

    stack->cache_size = 0;

    stack->unused_cache_size = 0;

}


static void

push_mark_stack(mark_stack_t *stack, VALUE obj)

{

    switch (BUILTIN_TYPE(obj)) {

      case T_OBJECT:

      case T_CLASS:

      case T_MODULE:

      case T_FLOAT:

      case T_STRING:

      case T_REGEXP:

      case T_ARRAY:

      case T_HASH:

      case T_STRUCT:

      case T_BIGNUM:

      case T_FILE:

      case T_DATA:

      case T_MATCH:

      case T_COMPLEX:

      case T_RATIONAL:

      case T_TRUE:

      case T_FALSE:

      case T_SYMBOL:

      case T_IMEMO:

      case T_ICLASS:

        if (stack->index == stack->limit) {

            push_mark_stack_chunk(stack);

        }

        stack->chunk->data[stack->index++] = obj;

        return;


      case T_NONE:

      case T_NIL:

      case T_FIXNUM:

      case T_MOVED:

      case T_ZOMBIE:

      case T_UNDEF:

      case T_MASK:

        rb_bug("push_mark_stack() called for broken object");

        break;


      case T_NODE:

        rb_bug("push_mark_stack: unexpected T_NODE object");

        break;

    }


    rb_bug("rb_gc_mark(): unknown data type 0x%x(%p) %s",

            BUILTIN_TYPE(obj), (void *)obj,

            is_pointer_to_heap((rb_objspace_t *)rb_gc_get_objspace(), (void *)obj) ? "corrupted object" : "non object");

}


static int

pop_mark_stack(mark_stack_t *stack, VALUE *data)

{

    if (is_mark_stack_empty(stack)) {

        return FALSE;

    }

    if (stack->index == 1) {

        *data = stack->chunk->data[--stack->index];

        pop_mark_stack_chunk(stack);

    }

    else {

        *data = stack->chunk->data[--stack->index];

    }

    return TRUE;

}


static void

init_mark_stack(mark_stack_t *stack)

{

    int i;


    MEMZERO(stack, mark_stack_t, 1);

    stack->index = stack->limit = STACK_CHUNK_SIZE;


    for (i=0; i < 4; i++) {

        add_stack_chunk_cache(stack, stack_chunk_alloc());

    }

    stack->unused_cache_size = stack->cache_size;

}


/* Marking */


static void

rgengc_check_relation(rb_objspace_t *objspace, VALUE obj)

{

    if (objspace->rgengc.parent_object_old_p) {

        if (RVALUE_WB_UNPROTECTED(objspace, obj) || !RVALUE_OLD_P(objspace, obj)) {

            rgengc_remember(objspace, objspace->rgengc.parent_object);

        }

    }

}


static inline int

gc_mark_set(rb_objspace_t *objspace, VALUE obj)

{

    if (RVALUE_MARKED(objspace, obj)) return 0;

    MARK_IN_BITMAP(GET_HEAP_MARK_BITS(obj), obj);

    return 1;

}


static void

gc_aging(rb_objspace_t *objspace, VALUE obj)

{

    /* Disable aging if Major GC's are disabled. This will prevent longish lived

     * objects filling up the heap at the expense of marking many more objects.

     *

     * We should always pre-warm our process when disabling majors, by running

     * GC manually several times so that most objects likely to become oldgen

     * are already oldgen.

     */

    if(!gc_config_full_mark_val)

        return;


    struct heap_page *page = GET_HEAP_PAGE(obj);


    GC_ASSERT(RVALUE_MARKING(objspace, obj) == FALSE);

    check_rvalue_consistency(objspace, obj);


    if (!RVALUE_PAGE_WB_UNPROTECTED(page, obj)) {

        if (!RVALUE_OLD_P(objspace, obj)) {

            int t = BUILTIN_TYPE(obj);

            if (t == T_CLASS || t == T_MODULE || t == T_ICLASS) {

                gc_report(3, objspace, "gc_aging: YOUNG class: %s\n", rb_obj_info(obj));

                RVALUE_AGE_SET(obj, RVALUE_OLD_AGE);

                RVALUE_OLD_UNCOLLECTIBLE_SET(objspace, obj);

            }

            else {

                gc_report(3, objspace, "gc_aging: YOUNG: %s\n", rb_obj_info(obj));

                RVALUE_AGE_INC(objspace, obj);

            }

        }

        else if (is_full_marking(objspace)) {

            GC_ASSERT(RVALUE_PAGE_UNCOLLECTIBLE(page, obj) == FALSE);

            RVALUE_PAGE_OLD_UNCOLLECTIBLE_SET(objspace, page, obj);

        }

    }

    check_rvalue_consistency(objspace, obj);


    objspace->marked_slots++;

}


static void

gc_grey(rb_objspace_t *objspace, VALUE obj)

{

#if RGENGC_CHECK_MODE

    if (RVALUE_MARKED(objspace, obj) == FALSE) rb_bug("gc_grey: %s is not marked.", rb_obj_info(obj));

    if (RVALUE_MARKING(objspace, obj) == TRUE) rb_bug("gc_grey: %s is marking/remembered.", rb_obj_info(obj));

#endif


    if (is_incremental_marking(objspace)) {

        MARK_IN_BITMAP(GET_HEAP_MARKING_BITS(obj), obj);

    }


    if (RB_FL_TEST_RAW(obj, RUBY_FL_WEAK_REFERENCE)) {

        rb_darray_append_without_gc(&objspace->weak_references, obj);

    }


    push_mark_stack(&objspace->mark_stack, obj);

}


static inline void

gc_mark_check_t_none(rb_objspace_t *objspace, VALUE obj)

{

    if (RB_UNLIKELY(BUILTIN_TYPE(obj) == T_NONE)) {

        enum {info_size = 256};

        char obj_info_buf[info_size];

        rb_raw_obj_info(obj_info_buf, info_size, obj);


        char parent_obj_info_buf[info_size];

        rb_raw_obj_info(parent_obj_info_buf, info_size, objspace->rgengc.parent_object);


        rb_bug("try to mark T_NONE object (obj: %s, parent: %s)", obj_info_buf, parent_obj_info_buf);

    }

}


static void

gc_mark(rb_objspace_t *objspace, VALUE obj)

{

    GC_ASSERT(during_gc);

    GC_ASSERT(!objspace->flags.during_reference_updating);


    rgengc_check_relation(objspace, obj);

    if (!gc_mark_set(objspace, obj)) return; /* already marked */


    if (0) { // for debug GC marking miss

        RUBY_DEBUG_LOG("%p (%s) parent:%p (%s)",

                        (void *)obj, obj_type_name(obj),

                        (void *)objspace->rgengc.parent_object, obj_type_name(objspace->rgengc.parent_object));

    }


    gc_mark_check_t_none(objspace, obj);


    gc_aging(objspace, obj);

    gc_grey(objspace, obj);

}


static inline void

gc_pin(rb_objspace_t *objspace, VALUE obj)

{

    GC_ASSERT(!SPECIAL_CONST_P(obj));

    if (RB_UNLIKELY(objspace->flags.during_compacting)) {

        if (RB_LIKELY(during_gc)) {

            if (!RVALUE_PINNED(objspace, obj)) {

                GC_ASSERT(GET_HEAP_PAGE(obj)->pinned_slots <= GET_HEAP_PAGE(obj)->total_slots);

                GET_HEAP_PAGE(obj)->pinned_slots++;

                MARK_IN_BITMAP(GET_HEAP_PINNED_BITS(obj), obj);

            }

        }

    }

}


static inline void

gc_mark_and_pin(rb_objspace_t *objspace, VALUE obj)

{

    gc_pin(objspace, obj);

    gc_mark(objspace, obj);

}


void

rb_gc_impl_mark_and_move(void *objspace_ptr, VALUE *ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (RB_UNLIKELY(objspace->flags.during_reference_updating)) {

        GC_ASSERT(objspace->flags.during_compacting);

        GC_ASSERT(during_gc);


        VALUE destination = rb_gc_impl_location(objspace, *ptr);

        if (destination != *ptr) {

            *ptr = destination;

        }

    }

    else {

        gc_mark(objspace, *ptr);

    }

}


void

rb_gc_impl_mark(void *objspace_ptr, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;


    gc_mark(objspace, obj);

}


void

rb_gc_impl_mark_and_pin(void *objspace_ptr, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;


    gc_mark_and_pin(objspace, obj);

}


void

rb_gc_impl_mark_maybe(void *objspace_ptr, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;


    (void)VALGRIND_MAKE_MEM_DEFINED(&obj, sizeof(obj));


    if (is_pointer_to_heap(objspace, (void *)obj)) {

        asan_unpoisoning_object(obj) {

            /* Garbage can live on the stack, so do not mark or pin */

            switch (BUILTIN_TYPE(obj)) {

              case T_ZOMBIE:

              case T_NONE:

                break;

              default:

                gc_mark_and_pin(objspace, obj);

                break;

            }

        }

    }

}


static int

pin_value(st_data_t key, st_data_t value, st_data_t data)

{

    rb_gc_impl_mark_and_pin((void *)data, (VALUE)value);


    return ST_CONTINUE;

}


static inline void

gc_mark_set_parent_raw(rb_objspace_t *objspace, VALUE obj, bool old_p)

{

    asan_unpoison_memory_region(&objspace->rgengc.parent_object, sizeof(objspace->rgengc.parent_object), false);

    asan_unpoison_memory_region(&objspace->rgengc.parent_object_old_p, sizeof(objspace->rgengc.parent_object_old_p), false);

    objspace->rgengc.parent_object = obj;

    objspace->rgengc.parent_object_old_p = old_p;

}


static inline void

gc_mark_set_parent(rb_objspace_t *objspace, VALUE obj)

{

    gc_mark_set_parent_raw(objspace, obj, RVALUE_OLD_P(objspace, obj));

}


static inline void

gc_mark_set_parent_invalid(rb_objspace_t *objspace)

{

    asan_poison_memory_region(&objspace->rgengc.parent_object, sizeof(objspace->rgengc.parent_object));

    asan_poison_memory_region(&objspace->rgengc.parent_object_old_p, sizeof(objspace->rgengc.parent_object_old_p));

}


static void

mark_roots(rb_objspace_t *objspace, const char **categoryp)

{

#define MARK_CHECKPOINT(category) do { \

    if (categoryp) *categoryp = category; \

} while (0)


    MARK_CHECKPOINT("objspace");

    gc_mark_set_parent_raw(objspace, Qundef, false);


    if (finalizer_table != NULL) {

        st_foreach(finalizer_table, pin_value, (st_data_t)objspace);

    }


    if (stress_to_class) rb_gc_mark(stress_to_class);


    rb_gc_save_machine_context();

    rb_gc_mark_roots(objspace, categoryp);

    gc_mark_set_parent_invalid(objspace);

}


static void

gc_mark_children(rb_objspace_t *objspace, VALUE obj)

{

    gc_mark_set_parent(objspace, obj);

    rb_gc_mark_children(objspace, obj);

    gc_mark_set_parent_invalid(objspace);

}


static inline int

gc_mark_stacked_objects(rb_objspace_t *objspace, int incremental, size_t count)

{

    mark_stack_t *mstack = &objspace->mark_stack;

    VALUE obj;

    size_t marked_slots_at_the_beginning = objspace->marked_slots;

    size_t popped_count = 0;


    while (pop_mark_stack(mstack, &obj)) {

        if (obj == Qundef) continue; /* skip */


        if (RGENGC_CHECK_MODE && !RVALUE_MARKED(objspace, obj)) {

            rb_bug("gc_mark_stacked_objects: %s is not marked.", rb_obj_info(obj));

        }

        gc_mark_children(objspace, obj);


        if (incremental) {

            if (RGENGC_CHECK_MODE && !RVALUE_MARKING(objspace, obj)) {

                rb_bug("gc_mark_stacked_objects: incremental, but marking bit is 0");

            }

            CLEAR_IN_BITMAP(GET_HEAP_MARKING_BITS(obj), obj);

            popped_count++;


            if (popped_count + (objspace->marked_slots - marked_slots_at_the_beginning) > count) {

                break;

            }

        }

        else {

            /* just ignore marking bits */

        }

    }


    if (RGENGC_CHECK_MODE >= 3) gc_verify_internal_consistency(objspace);


    if (is_mark_stack_empty(mstack)) {

        shrink_stack_chunk_cache(mstack);

        return TRUE;

    }

    else {

        return FALSE;

    }

}


static int

gc_mark_stacked_objects_incremental(rb_objspace_t *objspace, size_t count)

{

    return gc_mark_stacked_objects(objspace, TRUE, count);

}


static int

gc_mark_stacked_objects_all(rb_objspace_t *objspace)

{

    return gc_mark_stacked_objects(objspace, FALSE, 0);

}


#if RGENGC_CHECK_MODE >= 4


#define MAKE_ROOTSIG(obj) (((VALUE)(obj) << 1) | 0x01)

#define IS_ROOTSIG(obj)   ((VALUE)(obj) & 0x01)

#define GET_ROOTSIG(obj)  ((const char *)((VALUE)(obj) >> 1))


struct reflist {

    VALUE *list;

    int pos;

    int size;

};


static struct reflist *

reflist_create(VALUE obj)

{

    struct reflist *refs = xmalloc(sizeof(struct reflist));

    refs->size = 1;

    refs->list = ALLOC_N(VALUE, refs->size);

    refs->list[0] = obj;

    refs->pos = 1;

    return refs;

}


static void

reflist_destruct(struct reflist *refs)

{

    xfree(refs->list);

    xfree(refs);

}


static void

reflist_add(struct reflist *refs, VALUE obj)

{

    if (refs->pos == refs->size) {

        refs->size *= 2;

        SIZED_REALLOC_N(refs->list, VALUE, refs->size, refs->size/2);

    }


    refs->list[refs->pos++] = obj;

}


static void

reflist_dump(struct reflist *refs)

{

    int i;

    for (i=0; i<refs->pos; i++) {

        VALUE obj = refs->list[i];

        if (IS_ROOTSIG(obj)) { /* root */

            fprintf(stderr, "<root@%s>", GET_ROOTSIG(obj));

        }

        else {

            fprintf(stderr, "<%s>", rb_obj_info(obj));

        }

        if (i+1 < refs->pos) fprintf(stderr, ", ");

    }

}


static int

reflist_referred_from_machine_context(struct reflist *refs)

{

    int i;

    for (i=0; i<refs->pos; i++) {

        VALUE obj = refs->list[i];

        if (IS_ROOTSIG(obj) && strcmp(GET_ROOTSIG(obj), "machine_context") == 0) return 1;

    }

    return 0;

}


struct allrefs {

    rb_objspace_t *objspace;

    /* a -> obj1

     * b -> obj1

     * c -> obj1

     * c -> obj2

     * d -> obj3

     * #=> {obj1 => [a, b, c], obj2 => [c, d]}

     */

    struct st_table *references;

    const char *category;

    VALUE root_obj;

    mark_stack_t mark_stack;

};


static int

allrefs_add(struct allrefs *data, VALUE obj)

{

    struct reflist *refs;

    st_data_t r;


    if (st_lookup(data->references, obj, &r)) {

        refs = (struct reflist *)r;

        reflist_add(refs, data->root_obj);

        return 0;

    }

    else {

        refs = reflist_create(data->root_obj);

        st_insert(data->references, obj, (st_data_t)refs);

        return 1;

    }

}


static void

allrefs_i(VALUE obj, void *ptr)

{

    struct allrefs *data = (struct allrefs *)ptr;


    if (allrefs_add(data, obj)) {

        push_mark_stack(&data->mark_stack, obj);

    }

}


static void

allrefs_roots_i(VALUE obj, void *ptr)

{

    struct allrefs *data = (struct allrefs *)ptr;

    if (strlen(data->category) == 0) rb_bug("!!!");

    data->root_obj = MAKE_ROOTSIG(data->category);


    if (allrefs_add(data, obj)) {

        push_mark_stack(&data->mark_stack, obj);

    }

}

#define PUSH_MARK_FUNC_DATA(v) do { \

    struct gc_mark_func_data_struct *prev_mark_func_data = GET_VM()->gc.mark_func_data; \

    GET_VM()->gc.mark_func_data = (v);


#define POP_MARK_FUNC_DATA() GET_VM()->gc.mark_func_data = prev_mark_func_data;} while (0)


static st_table *

objspace_allrefs(rb_objspace_t *objspace)

{

    struct allrefs data;

    struct gc_mark_func_data_struct mfd;

    VALUE obj;

    int prev_dont_gc = dont_gc_val();

    dont_gc_on();


    data.objspace = objspace;

    data.references = st_init_numtable();

    init_mark_stack(&data.mark_stack);


    mfd.mark_func = allrefs_roots_i;

    mfd.data = &data;


    /* traverse root objects */

    PUSH_MARK_FUNC_DATA(&mfd);

    GET_VM()->gc.mark_func_data = &mfd;

    mark_roots(objspace, &data.category);

    POP_MARK_FUNC_DATA();


    /* traverse rest objects reachable from root objects */

    while (pop_mark_stack(&data.mark_stack, &obj)) {

        rb_objspace_reachable_objects_from(data.root_obj = obj, allrefs_i, &data);

    }

    free_stack_chunks(&data.mark_stack);


    dont_gc_set(prev_dont_gc);

    return data.references;

}


static int

objspace_allrefs_destruct_i(st_data_t key, st_data_t value, st_data_t ptr)

{

    struct reflist *refs = (struct reflist *)value;

    reflist_destruct(refs);

    return ST_CONTINUE;

}


static void

objspace_allrefs_destruct(struct st_table *refs)

{

    st_foreach(refs, objspace_allrefs_destruct_i, 0);

    st_free_table(refs);

}


#if RGENGC_CHECK_MODE >= 5

static int

allrefs_dump_i(st_data_t k, st_data_t v, st_data_t ptr)

{

    VALUE obj = (VALUE)k;

    struct reflist *refs = (struct reflist *)v;

    fprintf(stderr, "[allrefs_dump_i] %s <- ", rb_obj_info(obj));

    reflist_dump(refs);

    fprintf(stderr, "\n");

    return ST_CONTINUE;

}


static void

allrefs_dump(rb_objspace_t *objspace)

{

    VALUE size = objspace->rgengc.allrefs_table->num_entries;

    fprintf(stderr, "[all refs] (size: %"PRIuVALUE")\n", size);

    st_foreach(objspace->rgengc.allrefs_table, allrefs_dump_i, 0);

}

#endif


static int

gc_check_after_marks_i(st_data_t k, st_data_t v, st_data_t ptr)

{

    VALUE obj = k;

    struct reflist *refs = (struct reflist *)v;

    rb_objspace_t *objspace = (rb_objspace_t *)ptr;


    /* object should be marked or oldgen */

    if (!RVALUE_MARKED(objspace, obj)) {

        fprintf(stderr, "gc_check_after_marks_i: %s is not marked and not oldgen.\n", rb_obj_info(obj));

        fprintf(stderr, "gc_check_after_marks_i: %p is referred from ", (void *)obj);

        reflist_dump(refs);


        if (reflist_referred_from_machine_context(refs)) {

            fprintf(stderr, " (marked from machine stack).\n");

            /* marked from machine context can be false positive */

        }

        else {

            objspace->rgengc.error_count++;

            fprintf(stderr, "\n");

        }

    }

    return ST_CONTINUE;

}


static void

gc_marks_check(rb_objspace_t *objspace, st_foreach_callback_func *checker_func, const char *checker_name)

{

    size_t saved_malloc_increase = objspace->malloc_params.increase;

#if RGENGC_ESTIMATE_OLDMALLOC

    size_t saved_oldmalloc_increase = objspace->malloc_counters.oldmalloc_increase;

#endif

    VALUE already_disabled = rb_objspace_gc_disable(objspace);


    objspace->rgengc.allrefs_table = objspace_allrefs(objspace);


    if (checker_func) {

        st_foreach(objspace->rgengc.allrefs_table, checker_func, (st_data_t)objspace);

    }


    if (objspace->rgengc.error_count > 0) {

#if RGENGC_CHECK_MODE >= 5

        allrefs_dump(objspace);

#endif

        if (checker_name) rb_bug("%s: GC has problem.", checker_name);

    }


    objspace_allrefs_destruct(objspace->rgengc.allrefs_table);

    objspace->rgengc.allrefs_table = 0;


    if (already_disabled == Qfalse) rb_objspace_gc_enable(objspace);

    objspace->malloc_params.increase = saved_malloc_increase;

#if RGENGC_ESTIMATE_OLDMALLOC

    objspace->malloc_counters.oldmalloc_increase = saved_oldmalloc_increase;

#endif

}

#endif /* RGENGC_CHECK_MODE >= 4 */


struct verify_internal_consistency_struct {

    rb_objspace_t *objspace;

    int err_count;

    size_t live_object_count;

    size_t zombie_object_count;


    VALUE parent;

    size_t old_object_count;

    size_t remembered_shady_count;

};


static void

check_generation_i(const VALUE child, void *ptr)

{

    struct verify_internal_consistency_struct *data = (struct verify_internal_consistency_struct *)ptr;

    const VALUE parent = data->parent;


    if (RGENGC_CHECK_MODE) GC_ASSERT(RVALUE_OLD_P(data->objspace, parent));


    if (!RVALUE_OLD_P(data->objspace, child)) {

        if (!RVALUE_REMEMBERED(data->objspace, parent) &&

            !RVALUE_REMEMBERED(data->objspace, child) &&

            !RVALUE_UNCOLLECTIBLE(data->objspace, child)) {

            fprintf(stderr, "verify_internal_consistency_reachable_i: WB miss (O->Y) %s -> %s\n", rb_obj_info(parent), rb_obj_info(child));

            data->err_count++;

        }

    }

}


static void

check_color_i(const VALUE child, void *ptr)

{

    struct verify_internal_consistency_struct *data = (struct verify_internal_consistency_struct *)ptr;

    const VALUE parent = data->parent;


    if (!RVALUE_WB_UNPROTECTED(data->objspace, parent) && RVALUE_WHITE_P(data->objspace, child)) {

        fprintf(stderr, "verify_internal_consistency_reachable_i: WB miss (B->W) - %s -> %s\n",

                rb_obj_info(parent), rb_obj_info(child));

        data->err_count++;

    }

}


static void

check_children_i(const VALUE child, void *ptr)

{

    struct verify_internal_consistency_struct *data = (struct verify_internal_consistency_struct *)ptr;

    if (check_rvalue_consistency_force(data->objspace, child, FALSE) != 0) {

        fprintf(stderr, "check_children_i: %s has error (referenced from %s)",

                rb_obj_info(child), rb_obj_info(data->parent));


        data->err_count++;

    }

}


static int

verify_internal_consistency_i(void *page_start, void *page_end, size_t stride,

                              struct verify_internal_consistency_struct *data)

{

    VALUE obj;

    rb_objspace_t *objspace = data->objspace;


    for (obj = (VALUE)page_start; obj != (VALUE)page_end; obj += stride) {

        asan_unpoisoning_object(obj) {

            if (!rb_gc_impl_garbage_object_p(objspace, obj)) {

                /* count objects */

                data->live_object_count++;

                data->parent = obj;


                /* Normally, we don't expect T_MOVED objects to be in the heap.

                * But they can stay alive on the stack, */

                if (!gc_object_moved_p(objspace, obj)) {

                    /* moved slots don't have children */

                    rb_objspace_reachable_objects_from(obj, check_children_i, (void *)data);

                }


                /* check health of children */

                if (RVALUE_OLD_P(objspace, obj)) data->old_object_count++;

                if (RVALUE_WB_UNPROTECTED(objspace, obj) && RVALUE_UNCOLLECTIBLE(objspace, obj)) data->remembered_shady_count++;


                if (!is_marking(objspace) && RVALUE_OLD_P(objspace, obj)) {

                    /* reachable objects from an oldgen object should be old or (young with remember) */

                    data->parent = obj;

                    rb_objspace_reachable_objects_from(obj, check_generation_i, (void *)data);

                }


                if (!is_marking(objspace) && rb_gc_obj_shareable_p(obj)) {

                    rb_gc_verify_shareable(obj);

                }


                if (is_incremental_marking(objspace)) {

                    if (RVALUE_BLACK_P(objspace, obj)) {

                        /* reachable objects from black objects should be black or grey objects */

                        data->parent = obj;

                        rb_objspace_reachable_objects_from(obj, check_color_i, (void *)data);

                    }

                }

            }

            else {

                if (BUILTIN_TYPE(obj) == T_ZOMBIE) {

                    data->zombie_object_count++;


                    if ((RBASIC(obj)->flags & ~ZOMBIE_OBJ_KEPT_FLAGS) != T_ZOMBIE) {

                        fprintf(stderr, "verify_internal_consistency_i: T_ZOMBIE has extra flags set: %s\n",

                                rb_obj_info(obj));

                        data->err_count++;

                    }


                    if (!!FL_TEST(obj, FL_FINALIZE) != !!st_is_member(finalizer_table, obj)) {

                        fprintf(stderr, "verify_internal_consistency_i: FL_FINALIZE %s but %s finalizer_table: %s\n",

                                FL_TEST(obj, FL_FINALIZE) ? "set" : "not set", st_is_member(finalizer_table, obj) ? "in" : "not in",

                                rb_obj_info(obj));

                        data->err_count++;

                    }

                }

            }

        }

    }


    return 0;

}


static int

gc_verify_heap_page(rb_objspace_t *objspace, struct heap_page *page, VALUE obj)

{

    unsigned int has_remembered_shady = FALSE;

    unsigned int has_remembered_old = FALSE;

    int remembered_old_objects = 0;

    int free_objects = 0;

    int zombie_objects = 0;


    short slot_size = page->slot_size;

    uintptr_t start = (uintptr_t)page->start;

    uintptr_t end = start + page->total_slots * slot_size;


    for (uintptr_t ptr = start; ptr < end; ptr += slot_size) {

        VALUE val = (VALUE)ptr;

        asan_unpoisoning_object(val) {

            enum ruby_value_type type = BUILTIN_TYPE(val);


            if (type == T_NONE) free_objects++;

            if (type == T_ZOMBIE) zombie_objects++;

            if (RVALUE_PAGE_UNCOLLECTIBLE(page, val) && RVALUE_PAGE_WB_UNPROTECTED(page, val)) {

                has_remembered_shady = TRUE;

            }

            if (RVALUE_PAGE_MARKING(page, val)) {

                has_remembered_old = TRUE;

                remembered_old_objects++;

            }

        }

    }


    if (!is_incremental_marking(objspace) &&

        page->flags.has_remembered_objects == FALSE && has_remembered_old == TRUE) {


        for (uintptr_t ptr = start; ptr < end; ptr += slot_size) {

            VALUE val = (VALUE)ptr;

            if (RVALUE_PAGE_MARKING(page, val)) {

                fprintf(stderr, "marking -> %s\n", rb_obj_info(val));

            }

        }

        rb_bug("page %p's has_remembered_objects should be false, but there are remembered old objects (%d). %s",

               (void *)page, remembered_old_objects, obj ? rb_obj_info(obj) : "");

    }


    if (page->flags.has_uncollectible_wb_unprotected_objects == FALSE && has_remembered_shady == TRUE) {

        rb_bug("page %p's has_remembered_shady should be false, but there are remembered shady objects. %s",

               (void *)page, obj ? rb_obj_info(obj) : "");

    }


    if (0) {

        /* free_slots may not equal to free_objects */

        if (page->free_slots != free_objects) {

            rb_bug("page %p's free_slots should be %d, but %d", (void *)page, page->free_slots, free_objects);

        }

    }

    if (page->final_slots != zombie_objects) {

        rb_bug("page %p's final_slots should be %d, but %d", (void *)page, page->final_slots, zombie_objects);

    }


    return remembered_old_objects;

}


static int

gc_verify_heap_pages_(rb_objspace_t *objspace, struct ccan_list_head *head)

{

    int remembered_old_objects = 0;

    struct heap_page *page = 0;


    ccan_list_for_each(head, page, page_node) {

        asan_unlock_freelist(page);

        struct free_slot *p = page->freelist;

        while (p) {

            VALUE vp = (VALUE)p;

            VALUE prev = vp;

            rb_asan_unpoison_object(vp, false);

            if (BUILTIN_TYPE(vp) != T_NONE) {

                fprintf(stderr, "freelist slot expected to be T_NONE but was: %s\n", rb_obj_info(vp));

            }

            p = p->next;

            rb_asan_poison_object(prev);

        }

        asan_lock_freelist(page);


        if (page->flags.has_remembered_objects == FALSE) {

            remembered_old_objects += gc_verify_heap_page(objspace, page, Qfalse);

        }

    }


    return remembered_old_objects;

}


static int

gc_verify_heap_pages(rb_objspace_t *objspace)

{

    int remembered_old_objects = 0;

    for (int i = 0; i < HEAP_COUNT; i++) {

        remembered_old_objects += gc_verify_heap_pages_(objspace, &((&heaps[i])->pages));

    }

    return remembered_old_objects;

}


static void

gc_verify_internal_consistency_(rb_objspace_t *objspace)

{

    struct verify_internal_consistency_struct data = {0};


    data.objspace = objspace;

    gc_report(5, objspace, "gc_verify_internal_consistency: start\n");


    /* check relations */

    for (size_t i = 0; i < rb_darray_size(objspace->heap_pages.sorted); i++) {

        struct heap_page *page = rb_darray_get(objspace->heap_pages.sorted, i);

        short slot_size = page->slot_size;


        uintptr_t start = (uintptr_t)page->start;

        uintptr_t end = start + page->total_slots * slot_size;


        verify_internal_consistency_i((void *)start, (void *)end, slot_size, &data);

    }


    if (data.err_count != 0) {

#if RGENGC_CHECK_MODE >= 5

        objspace->rgengc.error_count = data.err_count;

        gc_marks_check(objspace, NULL, NULL);

        allrefs_dump(objspace);

#endif

        rb_bug("gc_verify_internal_consistency: found internal inconsistency.");

    }


    /* check heap_page status */

    gc_verify_heap_pages(objspace);


    /* check counters */


    ractor_cache_flush_count(objspace, rb_gc_get_ractor_newobj_cache());


    if (!is_lazy_sweeping(objspace) &&

            !finalizing &&

            !rb_gc_multi_ractor_p()) {

        if (objspace_live_slots(objspace) != data.live_object_count) {

            fprintf(stderr, "heap_pages_final_slots: %"PRIdSIZE", total_freed_objects: %"PRIdSIZE"\n",

                    total_final_slots_count(objspace), total_freed_objects(objspace));

            rb_bug("inconsistent live slot number: expect %"PRIuSIZE", but %"PRIuSIZE".",

                   objspace_live_slots(objspace), data.live_object_count);

        }

    }


    if (!is_marking(objspace)) {

        if (objspace->rgengc.old_objects != data.old_object_count) {

            rb_bug("inconsistent old slot number: expect %"PRIuSIZE", but %"PRIuSIZE".",

                   objspace->rgengc.old_objects, data.old_object_count);

        }

        if (objspace->rgengc.uncollectible_wb_unprotected_objects != data.remembered_shady_count) {

            rb_bug("inconsistent number of wb unprotected objects: expect %"PRIuSIZE", but %"PRIuSIZE".",

                   objspace->rgengc.uncollectible_wb_unprotected_objects, data.remembered_shady_count);

        }

    }


    if (!finalizing) {

        size_t list_count = 0;


        {

            VALUE z = heap_pages_deferred_final;

            while (z) {

                list_count++;

                z = RZOMBIE(z)->next;

            }

        }


        if (total_final_slots_count(objspace) != data.zombie_object_count ||

            total_final_slots_count(objspace) != list_count) {


            rb_bug("inconsistent finalizing object count:\n"

                    "  expect %"PRIuSIZE"\n"

                    "  but    %"PRIuSIZE" zombies\n"

                    "  heap_pages_deferred_final list has %"PRIuSIZE" items.",

                    total_final_slots_count(objspace),

                    data.zombie_object_count,

                    list_count);

        }

    }


    gc_report(5, objspace, "gc_verify_internal_consistency: OK\n");

}


static void

gc_verify_internal_consistency(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    unsigned int lev = RB_GC_VM_LOCK();

    {

        rb_gc_vm_barrier(); // stop other ractors


        unsigned int prev_during_gc = during_gc;

        during_gc = FALSE; // stop gc here

        {

            gc_verify_internal_consistency_(objspace);

        }

        during_gc = prev_during_gc;

    }

    RB_GC_VM_UNLOCK(lev);

}


static void

heap_move_pooled_pages_to_free_pages(rb_heap_t *heap)

{

    if (heap->pooled_pages) {

        if (heap->free_pages) {

            struct heap_page *free_pages_tail = heap->free_pages;

            while (free_pages_tail->free_next) {

                free_pages_tail = free_pages_tail->free_next;

            }

            free_pages_tail->free_next = heap->pooled_pages;

        }

        else {

            heap->free_pages = heap->pooled_pages;

        }


        heap->pooled_pages = NULL;

    }

}


static int

gc_remember_unprotected(rb_objspace_t *objspace, VALUE obj)

{

    struct heap_page *page = GET_HEAP_PAGE(obj);

    bits_t *uncollectible_bits = &page->uncollectible_bits[0];


    if (!MARKED_IN_BITMAP(uncollectible_bits, obj)) {

        page->flags.has_uncollectible_wb_unprotected_objects = TRUE;

        MARK_IN_BITMAP(uncollectible_bits, obj);

        objspace->rgengc.uncollectible_wb_unprotected_objects++;


#if RGENGC_PROFILE > 0

        objspace->profile.total_remembered_shady_object_count++;

#if RGENGC_PROFILE >= 2

        objspace->profile.remembered_shady_object_count_types[BUILTIN_TYPE(obj)]++;

#endif

#endif

        return TRUE;

    }

    else {

        return FALSE;

    }

}


static inline void

gc_marks_wb_unprotected_objects_plane(rb_objspace_t *objspace, uintptr_t p, bits_t bits, short slot_size)

{

    if (bits) {

        do {

            if (bits & 1) {

                gc_report(2, objspace, "gc_marks_wb_unprotected_objects: marked shady: %s\n", rb_obj_info((VALUE)p));

                GC_ASSERT(RVALUE_WB_UNPROTECTED(objspace, (VALUE)p));

                GC_ASSERT(RVALUE_MARKED(objspace, (VALUE)p));

                gc_mark_children(objspace, (VALUE)p);

            }

            p += slot_size;

            bits >>= 1;

        } while (bits);

    }

}


static void

gc_marks_wb_unprotected_objects(rb_objspace_t *objspace, rb_heap_t *heap)

{

    struct heap_page *page = 0;


    ccan_list_for_each(&heap->pages, page, page_node) {

        bits_t *mark_bits = page->mark_bits;

        bits_t *wbun_bits = page->wb_unprotected_bits;

        uintptr_t p = page->start;

        short slot_size = page->slot_size;

        int total_slots = page->total_slots;

        int bitmap_plane_count = CEILDIV(total_slots, BITS_BITLENGTH);

        size_t j;


        for (j=0; j<(size_t)bitmap_plane_count; j++) {

            bits_t bits = mark_bits[j] & wbun_bits[j];

            gc_marks_wb_unprotected_objects_plane(objspace, p, bits, slot_size);

            p += BITS_BITLENGTH * slot_size;

        }

    }


    gc_mark_stacked_objects_all(objspace);

}


void

rb_gc_impl_declare_weak_references(void *objspace_ptr, VALUE obj)

{

    FL_SET_RAW(obj, RUBY_FL_WEAK_REFERENCE);

}


bool

rb_gc_impl_handle_weak_references_alive_p(void *objspace_ptr, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;


    bool marked = RVALUE_MARKED(objspace, obj);


    if (marked) {

        rgengc_check_relation(objspace, obj);

    }


    return marked;

}


static void

gc_update_weak_references(rb_objspace_t *objspace)

{

    VALUE *obj_ptr;

    rb_darray_foreach(objspace->weak_references, i, obj_ptr) {

        gc_mark_set_parent(objspace, *obj_ptr);

        rb_gc_handle_weak_references(*obj_ptr);

        gc_mark_set_parent_invalid(objspace);

    }


    size_t capa = rb_darray_capa(objspace->weak_references);

    size_t size = rb_darray_size(objspace->weak_references);


    objspace->profile.weak_references_count = size;


    rb_darray_clear(objspace->weak_references);


    /* If the darray has capacity for more than four times the amount used, we

     * shrink it down to half of that capacity. */

    if (capa > size * 4) {

        rb_darray_resize_capa_without_gc(&objspace->weak_references, size * 2);

    }

}


static void

gc_marks_finish(rb_objspace_t *objspace)

{

    /* finish incremental GC */

    if (is_incremental_marking(objspace)) {

        if (RGENGC_CHECK_MODE && is_mark_stack_empty(&objspace->mark_stack) == 0) {

            rb_bug("gc_marks_finish: mark stack is not empty (%"PRIdSIZE").",

                   mark_stack_size(&objspace->mark_stack));

        }


        mark_roots(objspace, NULL);

        while (gc_mark_stacked_objects_incremental(objspace, INT_MAX) == false);


#if RGENGC_CHECK_MODE >= 2

        if (gc_verify_heap_pages(objspace) != 0) {

            rb_bug("gc_marks_finish (incremental): there are remembered old objects.");

        }

#endif


        objspace->flags.during_incremental_marking = FALSE;

        /* check children of all marked wb-unprotected objects */

        for (int i = 0; i < HEAP_COUNT; i++) {

            gc_marks_wb_unprotected_objects(objspace, &heaps[i]);

        }

    }


    gc_update_weak_references(objspace);


#if RGENGC_CHECK_MODE >= 2

    gc_verify_internal_consistency(objspace);

#endif


#if RGENGC_CHECK_MODE >= 4

    during_gc = FALSE;

    gc_marks_check(objspace, gc_check_after_marks_i, "after_marks");

    during_gc = TRUE;

#endif


    {

        const unsigned long r_mul = objspace->live_ractor_cache_count > 8 ? 8 : objspace->live_ractor_cache_count; // upto 8


        size_t total_slots = objspace_available_slots(objspace);

        size_t sweep_slots = total_slots - objspace->marked_slots; /* will be swept slots */

        size_t max_free_slots = (size_t)(total_slots * gc_params.heap_free_slots_max_ratio);

        size_t min_free_slots = (size_t)(total_slots * gc_params.heap_free_slots_min_ratio);

        if (min_free_slots < gc_params.heap_free_slots * r_mul) {

            min_free_slots = gc_params.heap_free_slots * r_mul;

        }


        int full_marking = is_full_marking(objspace);


        GC_ASSERT(objspace_available_slots(objspace) >= objspace->marked_slots);


        /* Setup freeable slots. */

        size_t total_init_slots = 0;

        for (int i = 0; i < HEAP_COUNT; i++) {

            total_init_slots += (gc_params.heap_init_bytes / heaps[i].slot_size) * r_mul;

        }


        if (max_free_slots < total_init_slots) {

            max_free_slots = total_init_slots;

        }


        /* Approximate freeable pages using the average slots-per-pages across all heaps */

        if (sweep_slots > max_free_slots) {

            size_t excess_slots = sweep_slots - max_free_slots;

            size_t total_heap_pages = heap_eden_total_pages(objspace);

            heap_pages_freeable_pages = total_heap_pages > 0

                ? excess_slots * total_heap_pages / total_slots

                : 0;

        }

        else {

            heap_pages_freeable_pages = 0;

        }


        if (objspace->heap_pages.allocatable_bytes == 0 && sweep_slots < min_free_slots) {

            if (!full_marking && sweep_slots < min_free_slots * 7 / 8) {

                if (objspace->profile.count - objspace->rgengc.last_major_gc < RVALUE_OLD_AGE) {

                    full_marking = TRUE;

                }

                else {

                    gc_report(1, objspace, "gc_marks_finish: next is full GC!!)\n");

                    gc_needs_major_flags |= GPR_FLAG_MAJOR_BY_NOFREE;

                }

            }


            if (full_marking) {

                heap_allocatable_bytes_expand(objspace, NULL, sweep_slots, total_slots, heaps[0].slot_size);

            }

        }


        if (full_marking) {

            /* See the comment about RUBY_GC_HEAP_OLDOBJECT_LIMIT_FACTOR */

            const double r = gc_params.oldobject_limit_factor;

            objspace->rgengc.uncollectible_wb_unprotected_objects_limit = MAX(

                (size_t)(objspace->rgengc.uncollectible_wb_unprotected_objects * r),

                (size_t)(objspace->rgengc.old_objects * gc_params.uncollectible_wb_unprotected_objects_limit_ratio)

            );

            objspace->rgengc.old_objects_limit = (size_t)(objspace->rgengc.old_objects * r);

        }


        if (objspace->rgengc.uncollectible_wb_unprotected_objects > objspace->rgengc.uncollectible_wb_unprotected_objects_limit) {

            gc_needs_major_flags |= GPR_FLAG_MAJOR_BY_SHADY;

        }

        if (objspace->rgengc.old_objects > objspace->rgengc.old_objects_limit) {

            gc_needs_major_flags |= GPR_FLAG_MAJOR_BY_OLDGEN;

        }


        gc_report(1, objspace, "gc_marks_finish (marks %"PRIdSIZE" objects, "

                  "old %"PRIdSIZE" objects, total %"PRIdSIZE" slots, "

                   "sweep %"PRIdSIZE" slots, allocatable %"PRIdSIZE" bytes, next GC: %s)\n",

                  objspace->marked_slots, objspace->rgengc.old_objects, objspace_available_slots(objspace), sweep_slots, objspace->heap_pages.allocatable_bytes,

                  gc_needs_major_flags ? "major" : "minor");

    }


    // TODO: refactor so we don't need to call this

    rb_ractor_finish_marking();


    rb_gc_event_hook(0, RUBY_INTERNAL_EVENT_GC_END_MARK);

}


static bool

gc_compact_heap_cursors_met_p(rb_heap_t *heap)

{

    return heap->sweeping_page == heap->compact_cursor;

}


static rb_heap_t *

gc_compact_destination_pool(rb_objspace_t *objspace, rb_heap_t *src_pool, VALUE obj)

{

    size_t obj_size = rb_gc_obj_optimal_size(obj);

    if (obj_size == 0) {

        return src_pool;

    }


    GC_ASSERT(rb_gc_impl_size_allocatable_p(obj_size));


    size_t idx = heap_idx_for_size(obj_size);


    return &heaps[idx];

}


static bool

gc_compact_move(rb_objspace_t *objspace, rb_heap_t *heap, VALUE src)

{

    GC_ASSERT(BUILTIN_TYPE(src) != T_MOVED);

    GC_ASSERT(gc_is_moveable_obj(objspace, src));


    rb_heap_t *dest_pool = gc_compact_destination_pool(objspace, heap, src);

    uint32_t orig_shape = 0;

    uint32_t new_shape = 0;


    if (gc_compact_heap_cursors_met_p(dest_pool)) {

        return dest_pool != heap;

    }


    if (RB_TYPE_P(src, T_OBJECT)) {

        orig_shape = rb_gc_get_shape(src);


        if (dest_pool != heap) {

            new_shape = rb_gc_rebuild_shape(src, dest_pool - heaps);


            if (new_shape == 0) {

                dest_pool = heap;

            }

        }

    }


    while (!try_move(objspace, dest_pool, dest_pool->free_pages, src)) {

        struct gc_sweep_context ctx = {

            .page = dest_pool->sweeping_page,

            .final_slots = 0,

            .freed_slots = 0,

            .empty_slots = 0,

        };


        /* The page of src could be partially compacted, so it may contain

         * T_MOVED. Sweeping a page may read objects on this page, so we

         * need to lock the page. */

        lock_page_body(objspace, GET_PAGE_BODY(src));

        gc_sweep_page(objspace, dest_pool, &ctx);

        unlock_page_body(objspace, GET_PAGE_BODY(src));


        if (dest_pool->sweeping_page->free_slots > 0) {

            heap_add_freepage(dest_pool, dest_pool->sweeping_page);

        }


        dest_pool->sweeping_page = ccan_list_next(&dest_pool->pages, dest_pool->sweeping_page, page_node);

        if (gc_compact_heap_cursors_met_p(dest_pool)) {

            return dest_pool != heap;

        }

    }


    if (orig_shape != 0) {

        if (new_shape != 0) {

            VALUE dest = rb_gc_impl_location(objspace, src);

            rb_gc_set_shape(dest, new_shape);

        }

        RMOVED(src)->original_shape_id = orig_shape;

    }


    return true;

}


static bool

gc_compact_plane(rb_objspace_t *objspace, rb_heap_t *heap, uintptr_t p, bits_t bitset, struct heap_page *page)

{

    short slot_size = page->slot_size;


    do {

        VALUE vp = (VALUE)p;

        GC_ASSERT(vp % sizeof(VALUE) == 0);


        if (bitset & 1) {

            objspace->rcompactor.considered_count_table[BUILTIN_TYPE(vp)]++;


            if (gc_is_moveable_obj(objspace, vp)) {

                if (!gc_compact_move(objspace, heap, vp)) {

                    //the cursors met. bubble up

                    return false;

                }

            }

        }

        p += slot_size;

        bitset >>= 1;

    } while (bitset);


    return true;

}


// Iterate up all the objects in page, moving them to where they want to go

static bool

gc_compact_page(rb_objspace_t *objspace, rb_heap_t *heap, struct heap_page *page)

{

    GC_ASSERT(page == heap->compact_cursor);


    bits_t *mark_bits, *pin_bits;

    bits_t bitset;

    uintptr_t p = page->start;

    short slot_size = page->slot_size;

    int total_slots = page->total_slots;

    int bitmap_plane_count = CEILDIV(total_slots, BITS_BITLENGTH);


    mark_bits = page->mark_bits;

    pin_bits = page->pinned_bits;


    for (int j = 0; j < bitmap_plane_count; j++) {

        // objects that can be moved are marked and not pinned

        bitset = (mark_bits[j] & ~pin_bits[j]);

        if (bitset) {

            if (!gc_compact_plane(objspace, heap, (uintptr_t)p, bitset, page))

                return false;

        }

        p += BITS_BITLENGTH * slot_size;

    }


    return true;

}


static bool

gc_compact_all_compacted_p(rb_objspace_t *objspace)

{

    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];


        if (heap->total_pages > 0 &&

                !gc_compact_heap_cursors_met_p(heap)) {

            return false;

        }

    }


    return true;

}


static void

gc_sweep_compact(rb_objspace_t *objspace)

{

    gc_compact_start(objspace);

#if RGENGC_CHECK_MODE >= 2

    gc_verify_internal_consistency(objspace);

#endif


    while (!gc_compact_all_compacted_p(objspace)) {

        for (int i = 0; i < HEAP_COUNT; i++) {

            rb_heap_t *heap = &heaps[i];


            if (gc_compact_heap_cursors_met_p(heap)) {

                continue;

            }


            struct heap_page *start_page = heap->compact_cursor;


            if (!gc_compact_page(objspace, heap, start_page)) {

                lock_page_body(objspace, start_page->body);


                continue;

            }


            // If we get here, we've finished moving all objects on the compact_cursor page

            // So we can lock it and move the cursor on to the next one.

            lock_page_body(objspace, start_page->body);

            heap->compact_cursor = ccan_list_prev(&heap->pages, heap->compact_cursor, page_node);

        }

    }


    gc_compact_finish(objspace);


#if RGENGC_CHECK_MODE >= 2

    gc_verify_internal_consistency(objspace);

#endif

}


static void

gc_marks_rest(rb_objspace_t *objspace)

{

    gc_report(1, objspace, "gc_marks_rest\n");


    for (int i = 0; i < HEAP_COUNT; i++) {

        (&heaps[i])->pooled_pages = NULL;

    }


    if (is_incremental_marking(objspace)) {

        while (gc_mark_stacked_objects_incremental(objspace, INT_MAX) == FALSE);

    }

    else {

        gc_mark_stacked_objects_all(objspace);

    }


    gc_marks_finish(objspace);

}


static bool

gc_marks_step(rb_objspace_t *objspace, size_t slots)

{

    bool marking_finished = false;


    GC_ASSERT(is_marking(objspace));

    if (gc_mark_stacked_objects_incremental(objspace, slots)) {

        gc_marks_finish(objspace);


        marking_finished = true;

    }


    return marking_finished;

}


static bool

gc_marks_continue(rb_objspace_t *objspace, rb_heap_t *heap)

{

    GC_ASSERT(dont_gc_val() == FALSE || objspace->profile.latest_gc_info & GPR_FLAG_METHOD);

    bool marking_finished = true;


    gc_marking_enter(objspace);


    if (heap->free_pages) {

        gc_report(2, objspace, "gc_marks_continue: has pooled pages");


        marking_finished = gc_marks_step(objspace, objspace->rincgc.step_slots);

    }

    else {

        gc_report(2, objspace, "gc_marks_continue: no more pooled pages (stack depth: %"PRIdSIZE").\n",

                  mark_stack_size(&objspace->mark_stack));

        heap->force_incremental_marking_finish_count++;

        gc_marks_rest(objspace);

    }


    gc_marking_exit(objspace);


    return marking_finished;

}


static void

gc_marks_start(rb_objspace_t *objspace, int full_mark)

{

    /* start marking */

    gc_report(1, objspace, "gc_marks_start: (%s)\n", full_mark ? "full" : "minor");

    gc_mode_transition(objspace, gc_mode_marking);


    if (full_mark) {

        size_t incremental_marking_steps = (objspace->rincgc.pooled_slots / INCREMENTAL_MARK_STEP_ALLOCATIONS) + 1;

        objspace->rincgc.step_slots = (objspace->marked_slots * 2) / incremental_marking_steps;


        if (0) fprintf(stderr, "objspace->marked_slots: %"PRIdSIZE", "

                       "objspace->rincgc.pooled_page_num: %"PRIdSIZE", "

                       "objspace->rincgc.step_slots: %"PRIdSIZE", \n",

                       objspace->marked_slots, objspace->rincgc.pooled_slots, objspace->rincgc.step_slots);

        objspace->flags.during_minor_gc = FALSE;

        if (ruby_enable_autocompact) {

            objspace->flags.during_compacting |= TRUE;

        }

        objspace->profile.major_gc_count++;

        objspace->rgengc.uncollectible_wb_unprotected_objects = 0;

        objspace->rgengc.old_objects = 0;

        objspace->rgengc.last_major_gc = objspace->profile.count;

        objspace->marked_slots = 0;


        for (int i = 0; i < HEAP_COUNT; i++) {

            rb_heap_t *heap = &heaps[i];

            rgengc_mark_and_rememberset_clear(objspace, heap);

            heap_move_pooled_pages_to_free_pages(heap);


            if (objspace->flags.during_compacting) {

                struct heap_page *page = NULL;


                ccan_list_for_each(&heap->pages, page, page_node) {

                    page->pinned_slots = 0;

                }

            }

        }

    }

    else {

        objspace->flags.during_minor_gc = TRUE;

        objspace->marked_slots =

          objspace->rgengc.old_objects + objspace->rgengc.uncollectible_wb_unprotected_objects; /* uncollectible objects are marked already */

        objspace->profile.minor_gc_count++;


        for (int i = 0; i < HEAP_COUNT; i++) {

            rgengc_rememberset_mark(objspace, &heaps[i]);

        }

    }


    mark_roots(objspace, NULL);


    gc_report(1, objspace, "gc_marks_start: (%s) end, stack in %"PRIdSIZE"\n",

              full_mark ? "full" : "minor", mark_stack_size(&objspace->mark_stack));

}


static bool

gc_marks(rb_objspace_t *objspace, int full_mark)

{

    gc_prof_mark_timer_start(objspace);

    gc_marking_enter(objspace);


    bool marking_finished = false;


    /* setup marking */


    gc_marks_start(objspace, full_mark);

    if (!is_incremental_marking(objspace)) {

        gc_marks_rest(objspace);

        marking_finished = true;

    }


#if RGENGC_PROFILE > 0

    if (gc_prof_record(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);

        record->old_objects = objspace->rgengc.old_objects;

    }

#endif


    gc_marking_exit(objspace);

    gc_prof_mark_timer_stop(objspace);


    return marking_finished;

}


/* RGENGC */


static void

gc_report_body(int level, rb_objspace_t *objspace, const char *fmt, ...)

{

    if (level <= RGENGC_DEBUG) {

        char buf[1024];

        FILE *out = stderr;

        va_list args;

        const char *status = " ";


        if (during_gc) {

            status = is_full_marking(objspace) ? "+" : "-";

        }

        else {

            if (is_lazy_sweeping(objspace)) {

                status = "S";

            }

            if (is_incremental_marking(objspace)) {

                status = "M";

            }

        }


        va_start(args, fmt);

        vsnprintf(buf, 1024, fmt, args);

        va_end(args);


        fprintf(out, "%s|", status);

        fputs(buf, out);

    }

}


/* bit operations */


static int

rgengc_remembersetbits_set(rb_objspace_t *objspace, VALUE obj)

{

    struct heap_page *page = GET_HEAP_PAGE(obj);

    bits_t *bits = &page->remembered_bits[0];


    if (MARKED_IN_BITMAP(bits, obj)) {

        return FALSE;

    }

    else {

        page->flags.has_remembered_objects = TRUE;

        MARK_IN_BITMAP(bits, obj);

        return TRUE;

    }

}


/* wb, etc */


/* return FALSE if already remembered */

static int

rgengc_remember(rb_objspace_t *objspace, VALUE obj)

{

    gc_report(6, objspace, "rgengc_remember: %s %s\n", rb_obj_info(obj),

              RVALUE_REMEMBERED(objspace, obj) ? "was already remembered" : "is remembered now");


    check_rvalue_consistency(objspace, obj);


    if (RGENGC_CHECK_MODE) {

        if (RVALUE_WB_UNPROTECTED(objspace, obj)) rb_bug("rgengc_remember: %s is not wb protected.", rb_obj_info(obj));

    }


#if RGENGC_PROFILE > 0

    if (!RVALUE_REMEMBERED(objspace, obj)) {

        if (RVALUE_WB_UNPROTECTED(objspace, obj) == 0) {

            objspace->profile.total_remembered_normal_object_count++;

#if RGENGC_PROFILE >= 2

            objspace->profile.remembered_normal_object_count_types[BUILTIN_TYPE(obj)]++;

#endif

        }

    }

#endif /* RGENGC_PROFILE > 0 */


    return rgengc_remembersetbits_set(objspace, obj);

}


#ifndef PROFILE_REMEMBERSET_MARK

#define PROFILE_REMEMBERSET_MARK 0

#endif


static inline void

rgengc_rememberset_mark_plane(rb_objspace_t *objspace, uintptr_t p, bits_t bitset, short slot_size)

{

    if (bitset) {

        do {

            if (bitset & 1) {

                VALUE obj = (VALUE)p;

                gc_report(2, objspace, "rgengc_rememberset_mark: mark %s\n", rb_obj_info(obj));

                GC_ASSERT(RVALUE_UNCOLLECTIBLE(objspace, obj));

                GC_ASSERT(RVALUE_OLD_P(objspace, obj) || RVALUE_WB_UNPROTECTED(objspace, obj));


                gc_mark_children(objspace, obj);


                if (RB_FL_TEST_RAW(obj, RUBY_FL_WEAK_REFERENCE)) {

                    rb_darray_append_without_gc(&objspace->weak_references, obj);

                }

            }

            p += slot_size;

            bitset >>= 1;

        } while (bitset);

    }

}


static void

rgengc_rememberset_mark(rb_objspace_t *objspace, rb_heap_t *heap)

{

    size_t j;

    struct heap_page *page = 0;

#if PROFILE_REMEMBERSET_MARK

    int has_old = 0, has_shady = 0, has_both = 0, skip = 0;

#endif

    gc_report(1, objspace, "rgengc_rememberset_mark: start\n");


    ccan_list_for_each(&heap->pages, page, page_node) {

        if (page->flags.has_remembered_objects | page->flags.has_uncollectible_wb_unprotected_objects) {

            uintptr_t p = page->start;

            short slot_size = page->slot_size;

            int total_slots = page->total_slots;

            int bitmap_plane_count = CEILDIV(total_slots, BITS_BITLENGTH);

            bits_t bitset, bits[HEAP_PAGE_BITMAP_LIMIT];

            bits_t *remembered_bits = page->remembered_bits;

            bits_t *uncollectible_bits = page->uncollectible_bits;

            bits_t *wb_unprotected_bits = page->wb_unprotected_bits;

#if PROFILE_REMEMBERSET_MARK

            if (page->flags.has_remembered_objects && page->flags.has_uncollectible_wb_unprotected_objects) has_both++;

            else if (page->flags.has_remembered_objects) has_old++;

            else if (page->flags.has_uncollectible_wb_unprotected_objects) has_shady++;

#endif

            for (j=0; j < (size_t)bitmap_plane_count; j++) {

                bits[j] = remembered_bits[j] | (uncollectible_bits[j] & wb_unprotected_bits[j]);

                remembered_bits[j] = 0;

            }

            page->flags.has_remembered_objects = FALSE;


            for (j=0; j < (size_t)bitmap_plane_count; j++) {

                bitset = bits[j];

                rgengc_rememberset_mark_plane(objspace, p, bitset, slot_size);

                p += BITS_BITLENGTH * slot_size;

            }

        }

#if PROFILE_REMEMBERSET_MARK

        else {

            skip++;

        }

#endif

    }


#if PROFILE_REMEMBERSET_MARK

    fprintf(stderr, "%d\t%d\t%d\t%d\n", has_both, has_old, has_shady, skip);

#endif

    gc_report(1, objspace, "rgengc_rememberset_mark: finished\n");

}


static void

rgengc_mark_and_rememberset_clear(rb_objspace_t *objspace, rb_heap_t *heap)

{

    struct heap_page *page = 0;


    ccan_list_for_each(&heap->pages, page, page_node) {

        memset(&page->mark_bits[0],       0, HEAP_PAGE_BITMAP_SIZE);

        memset(&page->uncollectible_bits[0], 0, HEAP_PAGE_BITMAP_SIZE);

        memset(&page->marking_bits[0],    0, HEAP_PAGE_BITMAP_SIZE);

        memset(&page->remembered_bits[0], 0, HEAP_PAGE_BITMAP_SIZE);

        memset(&page->pinned_bits[0],     0, HEAP_PAGE_BITMAP_SIZE);

        page->flags.has_uncollectible_wb_unprotected_objects = FALSE;

        page->flags.has_remembered_objects = FALSE;

    }

}


/* RGENGC: APIs */


NOINLINE(static void gc_writebarrier_generational(VALUE a, VALUE b, rb_objspace_t *objspace));


static void

gc_writebarrier_generational(VALUE a, VALUE b, rb_objspace_t *objspace)

{

    if (RGENGC_CHECK_MODE) {

        if (!RVALUE_OLD_P(objspace, a)) rb_bug("gc_writebarrier_generational: %s is not an old object.", rb_obj_info(a));

        if ( RVALUE_OLD_P(objspace, b)) rb_bug("gc_writebarrier_generational: %s is an old object.", rb_obj_info(b));

        if (is_incremental_marking(objspace)) rb_bug("gc_writebarrier_generational: called while incremental marking: %s -> %s", rb_obj_info(a), rb_obj_info(b));

    }


    /* mark `a' and remember (default behavior) */

    if (!RVALUE_REMEMBERED(objspace, a)) {

        int lev = RB_GC_VM_LOCK_NO_BARRIER();

        {

            rgengc_remember(objspace, a);

        }

        RB_GC_VM_UNLOCK_NO_BARRIER(lev);


        gc_report(1, objspace, "gc_writebarrier_generational: %s (remembered) -> %s\n", rb_obj_info(a), rb_obj_info(b));

    }


    check_rvalue_consistency(objspace, a);

    check_rvalue_consistency(objspace, b);

}


static void

gc_mark_from(rb_objspace_t *objspace, VALUE obj, VALUE parent)

{

    gc_mark_set_parent(objspace, parent);

    rgengc_check_relation(objspace, obj);

    if (gc_mark_set(objspace, obj) != FALSE) {

        gc_aging(objspace, obj);

        gc_grey(objspace, obj);

    }

    gc_mark_set_parent_invalid(objspace);

}


NOINLINE(static void gc_writebarrier_incremental(VALUE a, VALUE b, rb_objspace_t *objspace));


static void

gc_writebarrier_incremental(VALUE a, VALUE b, rb_objspace_t *objspace)

{

    gc_report(2, objspace, "gc_writebarrier_incremental: [LG] %p -> %s\n", (void *)a, rb_obj_info(b));


    if (RVALUE_BLACK_P(objspace, a)) {

        if (RVALUE_WHITE_P(objspace, b)) {

            if (!RVALUE_WB_UNPROTECTED(objspace, a)) {

                gc_report(2, objspace, "gc_writebarrier_incremental: [IN] %p -> %s\n", (void *)a, rb_obj_info(b));

                gc_mark_from(objspace, b, a);

            }

        }

        else if (RVALUE_OLD_P(objspace, a) && !RVALUE_OLD_P(objspace, b)) {

            rgengc_remember(objspace, a);

        }


        if (RB_UNLIKELY(objspace->flags.during_compacting)) {

            MARK_IN_BITMAP(GET_HEAP_PINNED_BITS(b), b);

        }

    }

}


void

rb_gc_impl_writebarrier(void *objspace_ptr, VALUE a, VALUE b)

{

    rb_objspace_t *objspace = objspace_ptr;


#if RGENGC_CHECK_MODE

    if (SPECIAL_CONST_P(a)) rb_bug("rb_gc_writebarrier: a is special const: %"PRIxVALUE, a);

    if (SPECIAL_CONST_P(b)) rb_bug("rb_gc_writebarrier: b is special const: %"PRIxVALUE, b);

#else

    RBIMPL_ASSERT_OR_ASSUME(!SPECIAL_CONST_P(a));

    RBIMPL_ASSERT_OR_ASSUME(!SPECIAL_CONST_P(b));

#endif


    GC_ASSERT(!during_gc);

    GC_ASSERT(RB_BUILTIN_TYPE(a) != T_NONE);

    GC_ASSERT(RB_BUILTIN_TYPE(a) != T_MOVED);

    GC_ASSERT(RB_BUILTIN_TYPE(a) != T_ZOMBIE);

    GC_ASSERT(RB_BUILTIN_TYPE(b) != T_NONE);

    GC_ASSERT(RB_BUILTIN_TYPE(b) != T_MOVED);

    GC_ASSERT(RB_BUILTIN_TYPE(b) != T_ZOMBIE);


  retry:

    if (!is_incremental_marking(objspace)) {

        if (!RVALUE_OLD_P(objspace, a) || RVALUE_OLD_P(objspace, b)) {

            // do nothing

        }

        else {

            gc_writebarrier_generational(a, b, objspace);

        }

    }

    else {

        bool retry = false;

        /* slow path */

        int lev = RB_GC_VM_LOCK_NO_BARRIER();

        {

            if (is_incremental_marking(objspace)) {

                gc_writebarrier_incremental(a, b, objspace);

            }

            else {

                retry = true;

            }

        }

        RB_GC_VM_UNLOCK_NO_BARRIER(lev);


        if (retry) goto retry;

    }

    return;

}


void

rb_gc_impl_writebarrier_unprotect(void *objspace_ptr, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (RVALUE_WB_UNPROTECTED(objspace, obj)) {

        return;

    }

    else {

        gc_report(2, objspace, "rb_gc_writebarrier_unprotect: %s %s\n", rb_obj_info(obj),

                  RVALUE_REMEMBERED(objspace, obj) ? " (already remembered)" : "");


        unsigned int lev = RB_GC_VM_LOCK_NO_BARRIER();

        {

            if (RVALUE_OLD_P(objspace, obj)) {

                gc_report(1, objspace, "rb_gc_writebarrier_unprotect: %s\n", rb_obj_info(obj));

                RVALUE_DEMOTE(objspace, obj);

                gc_mark_set(objspace, obj);

                gc_remember_unprotected(objspace, obj);


#if RGENGC_PROFILE

                objspace->profile.total_shade_operation_count++;

#if RGENGC_PROFILE >= 2

                objspace->profile.shade_operation_count_types[BUILTIN_TYPE(obj)]++;

#endif /* RGENGC_PROFILE >= 2 */

#endif /* RGENGC_PROFILE */

            }

            else {

                RVALUE_AGE_RESET(obj);

            }


            RB_DEBUG_COUNTER_INC(obj_wb_unprotect);

            MARK_IN_BITMAP(GET_HEAP_WB_UNPROTECTED_BITS(obj), obj);

        }

        RB_GC_VM_UNLOCK_NO_BARRIER(lev);

    }

}


void

rb_gc_impl_copy_attributes(void *objspace_ptr, VALUE dest, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (RVALUE_WB_UNPROTECTED(objspace, obj)) {

        rb_gc_impl_writebarrier_unprotect(objspace, dest);

    }

    rb_gc_impl_copy_finalizer(objspace, dest, obj);

}


const char *

rb_gc_impl_active_gc_name(void)

{

    return "default";

}


void

rb_gc_impl_writebarrier_remember(void *objspace_ptr, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;


    gc_report(1, objspace, "rb_gc_writebarrier_remember: %s\n", rb_obj_info(obj));


    if (is_incremental_marking(objspace) || RVALUE_OLD_P(objspace, obj)) {

        int lev = RB_GC_VM_LOCK_NO_BARRIER();

        {

            if (is_incremental_marking(objspace)) {

                if (RVALUE_BLACK_P(objspace, obj)) {

                    gc_grey(objspace, obj);

                }

            }

            else if (RVALUE_OLD_P(objspace, obj)) {

                rgengc_remember(objspace, obj);

            }

        }

        RB_GC_VM_UNLOCK_NO_BARRIER(lev);

    }

}


struct rb_gc_object_metadata_names {

    // Must be ID only

    ID ID_wb_protected, ID_age, ID_old, ID_uncollectible, ID_marking,

        ID_marked, ID_pinned, ID_remembered, ID_object_id, ID_shareable;

};


#define RB_GC_OBJECT_METADATA_ENTRY_COUNT (sizeof(struct rb_gc_object_metadata_names) / sizeof(ID))

static struct rb_gc_object_metadata_entry object_metadata_entries[RB_GC_OBJECT_METADATA_ENTRY_COUNT + 1];


struct rb_gc_object_metadata_entry *

rb_gc_impl_object_metadata(void *objspace_ptr, VALUE obj)

{

    rb_objspace_t *objspace = objspace_ptr;

    size_t n = 0;

    static struct rb_gc_object_metadata_names names;


    if (!names.ID_marked) {

#define I(s) names.ID_##s = rb_intern(#s)

        I(wb_protected);

        I(age);

        I(old);

        I(uncollectible);

        I(marking);

        I(marked);

        I(pinned);

        I(remembered);

        I(object_id);

        I(shareable);

#undef I

    }


#define SET_ENTRY(na, v) do { \

    GC_ASSERT(n <= RB_GC_OBJECT_METADATA_ENTRY_COUNT); \

    object_metadata_entries[n].name = names.ID_##na; \

    object_metadata_entries[n].val = v; \

    n++; \

} while (0)


    if (!RVALUE_WB_UNPROTECTED(objspace, obj)) SET_ENTRY(wb_protected, Qtrue);

    SET_ENTRY(age, INT2FIX(RVALUE_AGE_GET(obj)));

    if (RVALUE_OLD_P(objspace, obj)) SET_ENTRY(old, Qtrue);

    if (RVALUE_UNCOLLECTIBLE(objspace, obj)) SET_ENTRY(uncollectible, Qtrue);

    if (RVALUE_MARKING(objspace, obj)) SET_ENTRY(marking, Qtrue);

    if (RVALUE_MARKED(objspace, obj)) SET_ENTRY(marked, Qtrue);

    if (RVALUE_PINNED(objspace, obj)) SET_ENTRY(pinned, Qtrue);

    if (RVALUE_REMEMBERED(objspace, obj)) SET_ENTRY(remembered, Qtrue);

    if (rb_obj_id_p(obj)) SET_ENTRY(object_id, rb_obj_id(obj));

    if (FL_TEST(obj, FL_SHAREABLE)) SET_ENTRY(shareable, Qtrue);


    object_metadata_entries[n].name = 0;

    object_metadata_entries[n].val = 0;

#undef SET_ENTRY


    return object_metadata_entries;

}


void *

rb_gc_impl_ractor_cache_alloc(void *objspace_ptr, void *ractor)

{

    rb_objspace_t *objspace = objspace_ptr;


    objspace->live_ractor_cache_count++;


    return calloc1(sizeof(rb_ractor_newobj_cache_t));

}


void

rb_gc_impl_ractor_cache_free(void *objspace_ptr, void *cache)

{

    rb_objspace_t *objspace = objspace_ptr;


    objspace->live_ractor_cache_count--;

    gc_ractor_newobj_cache_clear(cache, NULL);

    free(cache);

}


static void

heap_ready_to_gc(rb_objspace_t *objspace, rb_heap_t *heap)

{

    if (!heap->free_pages) {

        if (!heap_page_allocate_and_initialize(objspace, heap)) {

            objspace->heap_pages.allocatable_bytes = HEAP_PAGE_SIZE;

            heap_page_allocate_and_initialize(objspace, heap);

        }

    }

}


static int

ready_to_gc(rb_objspace_t *objspace)

{

    if (dont_gc_val() || during_gc) {

        for (int i = 0; i < HEAP_COUNT; i++) {

            rb_heap_t *heap = &heaps[i];

            heap_ready_to_gc(objspace, heap);

        }

        return FALSE;

    }

    else {

        return TRUE;

    }

}


static void

gc_reset_malloc_info(rb_objspace_t *objspace, bool full_mark)

{

    gc_prof_set_malloc_info(objspace);

    {

        size_t inc = RUBY_ATOMIC_SIZE_EXCHANGE(malloc_increase, 0);

        size_t old_limit = malloc_limit;


        if (inc > malloc_limit) {

            malloc_limit = (size_t)(inc * gc_params.malloc_limit_growth_factor);

            if (malloc_limit > gc_params.malloc_limit_max) {

                malloc_limit = gc_params.malloc_limit_max;

            }

        }

        else {

            malloc_limit = (size_t)(malloc_limit * 0.98); /* magic number */

            if (malloc_limit < gc_params.malloc_limit_min) {

                malloc_limit = gc_params.malloc_limit_min;

            }

        }


        if (0) {

            if (old_limit != malloc_limit) {

                fprintf(stderr, "[%"PRIuSIZE"] malloc_limit: %"PRIuSIZE" -> %"PRIuSIZE"\n",

                        rb_gc_count(), old_limit, malloc_limit);

            }

            else {

                fprintf(stderr, "[%"PRIuSIZE"] malloc_limit: not changed (%"PRIuSIZE")\n",

                        rb_gc_count(), malloc_limit);

            }

        }

    }


    /* reset oldmalloc info */

#if RGENGC_ESTIMATE_OLDMALLOC

    if (!full_mark) {

        if (objspace->malloc_counters.oldmalloc_increase > objspace->rgengc.oldmalloc_increase_limit) {

            gc_needs_major_flags |= GPR_FLAG_MAJOR_BY_OLDMALLOC;

            objspace->rgengc.oldmalloc_increase_limit =

              (size_t)(objspace->rgengc.oldmalloc_increase_limit * gc_params.oldmalloc_limit_growth_factor);


            if (objspace->rgengc.oldmalloc_increase_limit > gc_params.oldmalloc_limit_max) {

                objspace->rgengc.oldmalloc_increase_limit = gc_params.oldmalloc_limit_max;

            }

        }


        if (0) fprintf(stderr, "%"PRIdSIZE"\t%d\t%"PRIuSIZE"\t%"PRIuSIZE"\t%"PRIdSIZE"\n",

                       rb_gc_count(),

                       gc_needs_major_flags,

                       objspace->malloc_counters.oldmalloc_increase,

                       objspace->rgengc.oldmalloc_increase_limit,

                       gc_params.oldmalloc_limit_max);

    }

    else {

        /* major GC */

        objspace->malloc_counters.oldmalloc_increase = 0;


        if ((objspace->profile.latest_gc_info & GPR_FLAG_MAJOR_BY_OLDMALLOC) == 0) {

            objspace->rgengc.oldmalloc_increase_limit =

              (size_t)(objspace->rgengc.oldmalloc_increase_limit / ((gc_params.oldmalloc_limit_growth_factor - 1)/10 + 1));

            if (objspace->rgengc.oldmalloc_increase_limit < gc_params.oldmalloc_limit_min) {

                objspace->rgengc.oldmalloc_increase_limit = gc_params.oldmalloc_limit_min;

            }

        }

    }

#endif

}


static int

garbage_collect(rb_objspace_t *objspace, unsigned int reason)

{

    int ret;


    int lev = RB_GC_VM_LOCK();

    {

#if GC_PROFILE_MORE_DETAIL

        objspace->profile.prepare_time = getrusage_time();

#endif


        gc_rest(objspace);


#if GC_PROFILE_MORE_DETAIL

        objspace->profile.prepare_time = getrusage_time() - objspace->profile.prepare_time;

#endif


        ret = gc_start(objspace, reason);

    }

    RB_GC_VM_UNLOCK(lev);


    return ret;

}


static int

gc_start(rb_objspace_t *objspace, unsigned int reason)

{

    unsigned int do_full_mark = !!(reason & GPR_FLAG_FULL_MARK);


    if (!rb_darray_size(objspace->heap_pages.sorted)) return TRUE; /* heap is not ready */

    if (!(reason & GPR_FLAG_METHOD) && !ready_to_gc(objspace)) return TRUE; /* GC is not allowed */


    GC_ASSERT(gc_mode(objspace) == gc_mode_none, "gc_mode is %s\n", gc_mode_name(gc_mode(objspace)));

    GC_ASSERT(!is_lazy_sweeping(objspace));

    GC_ASSERT(!is_incremental_marking(objspace));


    unsigned int lock_lev;

    gc_enter(objspace, gc_enter_event_start, &lock_lev);


    /* reason may be clobbered, later, so keep set immediate_sweep here */

    objspace->flags.immediate_sweep = !!(reason & GPR_FLAG_IMMEDIATE_SWEEP);


#if RGENGC_CHECK_MODE >= 2

    gc_verify_internal_consistency(objspace);

#endif


    if (ruby_gc_stressful) {

        int flag = FIXNUM_P(ruby_gc_stress_mode) ? FIX2INT(ruby_gc_stress_mode) : 0;


        if ((flag & (1 << gc_stress_no_major)) == 0) {

            do_full_mark = TRUE;

        }


        objspace->flags.immediate_sweep = !(flag & (1<<gc_stress_no_immediate_sweep));

    }


    if (gc_needs_major_flags) {

        reason |= gc_needs_major_flags;

        do_full_mark = TRUE;

    }


    /* if major gc has been disabled, never do a full mark */

    if (!gc_config_full_mark_val) {

        do_full_mark = FALSE;

    }

    gc_needs_major_flags = GPR_FLAG_NONE;


    if (do_full_mark && (reason & GPR_FLAG_MAJOR_MASK) == 0) {

        reason |= GPR_FLAG_MAJOR_BY_FORCE; /* GC by CAPI, METHOD, and so on. */

    }


    if (objspace->flags.dont_incremental ||

            reason & GPR_FLAG_IMMEDIATE_MARK ||

            ruby_gc_stressful) {

        objspace->flags.during_incremental_marking = FALSE;

    }

    else {

        objspace->flags.during_incremental_marking = do_full_mark;

    }


    /* Explicitly enable compaction (GC.compact) */

    if (do_full_mark && ruby_enable_autocompact) {

        objspace->flags.during_compacting = TRUE;

#if RGENGC_CHECK_MODE

        objspace->rcompactor.compare_func = ruby_autocompact_compare_func;

#endif

    }

    else {

        objspace->flags.during_compacting = !!(reason & GPR_FLAG_COMPACT);

    }


    if (!GC_ENABLE_LAZY_SWEEP || objspace->flags.dont_incremental) {

        objspace->flags.immediate_sweep = TRUE;

    }


    if (objspace->flags.immediate_sweep) reason |= GPR_FLAG_IMMEDIATE_SWEEP;


    gc_report(1, objspace, "gc_start(reason: %x) => %u, %d, %d\n",

              reason,

              do_full_mark, !is_incremental_marking(objspace), objspace->flags.immediate_sweep);


    RB_DEBUG_COUNTER_INC(gc_count);


    if (reason & GPR_FLAG_MAJOR_MASK) {

        (void)RB_DEBUG_COUNTER_INC_IF(gc_major_nofree, reason & GPR_FLAG_MAJOR_BY_NOFREE);

        (void)RB_DEBUG_COUNTER_INC_IF(gc_major_oldgen, reason & GPR_FLAG_MAJOR_BY_OLDGEN);

        (void)RB_DEBUG_COUNTER_INC_IF(gc_major_shady,  reason & GPR_FLAG_MAJOR_BY_SHADY);

        (void)RB_DEBUG_COUNTER_INC_IF(gc_major_force,  reason & GPR_FLAG_MAJOR_BY_FORCE);

#if RGENGC_ESTIMATE_OLDMALLOC

        (void)RB_DEBUG_COUNTER_INC_IF(gc_major_oldmalloc, reason & GPR_FLAG_MAJOR_BY_OLDMALLOC);

#endif

    }

    else {

        (void)RB_DEBUG_COUNTER_INC_IF(gc_minor_newobj, reason & GPR_FLAG_NEWOBJ);

        (void)RB_DEBUG_COUNTER_INC_IF(gc_minor_malloc, reason & GPR_FLAG_MALLOC);

        (void)RB_DEBUG_COUNTER_INC_IF(gc_minor_method, reason & GPR_FLAG_METHOD);

        (void)RB_DEBUG_COUNTER_INC_IF(gc_minor_capi,   reason & GPR_FLAG_CAPI);

        (void)RB_DEBUG_COUNTER_INC_IF(gc_minor_stress, reason & GPR_FLAG_STRESS);

    }


    objspace->profile.count++;

    objspace->profile.latest_gc_info = reason;

    objspace->profile.total_allocated_objects_at_gc_start = total_allocated_objects(objspace);

    objspace->profile.heap_used_at_gc_start = rb_darray_size(objspace->heap_pages.sorted);

    objspace->profile.heap_total_slots_at_gc_start = objspace_available_slots(objspace);

    objspace->profile.weak_references_count = 0;

    gc_prof_setup_new_record(objspace, reason);

    gc_reset_malloc_info(objspace, do_full_mark);


    rb_gc_event_hook(0, RUBY_INTERNAL_EVENT_GC_START);


    GC_ASSERT(during_gc);


    gc_prof_timer_start(objspace);

    {

        if (gc_marks(objspace, do_full_mark)) {

            gc_sweep(objspace);

        }

    }

    gc_prof_timer_stop(objspace);


    gc_exit(objspace, gc_enter_event_start, &lock_lev);

    return TRUE;

}


static void

gc_rest(rb_objspace_t *objspace)

{

    if (is_incremental_marking(objspace) || is_lazy_sweeping(objspace)) {

        unsigned int lock_lev;

        gc_enter(objspace, gc_enter_event_rest, &lock_lev);


        if (RGENGC_CHECK_MODE >= 2) gc_verify_internal_consistency(objspace);


        if (is_incremental_marking(objspace)) {

            gc_marking_enter(objspace);

            gc_marks_rest(objspace);

            gc_marking_exit(objspace);


            gc_sweep(objspace);

        }


        if (is_lazy_sweeping(objspace)) {

            gc_sweeping_enter(objspace);

            gc_sweep_rest(objspace);

            gc_sweeping_exit(objspace);

        }


        gc_exit(objspace, gc_enter_event_rest, &lock_lev);

    }

}


struct objspace_and_reason {

    rb_objspace_t *objspace;

    unsigned int reason;

};


static void

gc_current_status_fill(rb_objspace_t *objspace, char *buff)

{

    int i = 0;

    if (is_marking(objspace)) {

        buff[i++] = 'M';

        if (is_full_marking(objspace))        buff[i++] = 'F';

        if (is_incremental_marking(objspace)) buff[i++] = 'I';

    }

    else if (is_sweeping(objspace)) {

        buff[i++] = 'S';

        if (is_lazy_sweeping(objspace))      buff[i++] = 'L';

    }

    else {

        buff[i++] = 'N';

    }

    buff[i] = '\0';

}


static const char *

gc_current_status(rb_objspace_t *objspace)

{

    static char buff[0x10];

    gc_current_status_fill(objspace, buff);

    return buff;

}


#if PRINT_ENTER_EXIT_TICK


static tick_t last_exit_tick;

static tick_t enter_tick;

static int enter_count = 0;

static char last_gc_status[0x10];


static inline void

gc_record(rb_objspace_t *objspace, int direction, const char *event)

{

    if (direction == 0) { /* enter */

        enter_count++;

        enter_tick = tick();

        gc_current_status_fill(objspace, last_gc_status);

    }

    else { /* exit */

        tick_t exit_tick = tick();

        char current_gc_status[0x10];

        gc_current_status_fill(objspace, current_gc_status);

#if 1

        /* [last mutator time] [gc time] [event] */

        fprintf(stderr, "%"PRItick"\t%"PRItick"\t%s\t[%s->%s|%c]\n",

                enter_tick - last_exit_tick,

                exit_tick - enter_tick,

                event,

                last_gc_status, current_gc_status,

                (objspace->profile.latest_gc_info & GPR_FLAG_MAJOR_MASK) ? '+' : '-');

        last_exit_tick = exit_tick;

#else

        /* [enter_tick] [gc time] [event] */

        fprintf(stderr, "%"PRItick"\t%"PRItick"\t%s\t[%s->%s|%c]\n",

                enter_tick,

                exit_tick - enter_tick,

                event,

                last_gc_status, current_gc_status,

                (objspace->profile.latest_gc_info & GPR_FLAG_MAJOR_MASK) ? '+' : '-');

#endif

    }

}

#else /* PRINT_ENTER_EXIT_TICK */

static inline void

gc_record(rb_objspace_t *objspace, int direction, const char *event)

{

    /* null */

}

#endif /* PRINT_ENTER_EXIT_TICK */


static const char *

gc_enter_event_cstr(enum gc_enter_event event)

{

    switch (event) {

      case gc_enter_event_start: return "start";

      case gc_enter_event_continue: return "continue";

      case gc_enter_event_rest: return "rest";

      case gc_enter_event_finalizer: return "finalizer";

    }

    return NULL;

}


static void

gc_enter_count(enum gc_enter_event event)

{

    switch (event) {

      case gc_enter_event_start:          RB_DEBUG_COUNTER_INC(gc_enter_start); break;

      case gc_enter_event_continue:       RB_DEBUG_COUNTER_INC(gc_enter_continue); break;

      case gc_enter_event_rest:           RB_DEBUG_COUNTER_INC(gc_enter_rest); break;

      case gc_enter_event_finalizer:      RB_DEBUG_COUNTER_INC(gc_enter_finalizer); break;

    }

}


static bool current_process_time(struct timespec *ts);


static void

gc_clock_start(struct timespec *ts)

{

    if (!current_process_time(ts)) {

        ts->tv_sec = 0;

        ts->tv_nsec = 0;

    }

}


static unsigned long long

gc_clock_end(struct timespec *ts)

{

    struct timespec end_time;


    if ((ts->tv_sec > 0 || ts->tv_nsec > 0) &&

            current_process_time(&end_time) &&

            end_time.tv_sec >= ts->tv_sec) {

        return (unsigned long long)(end_time.tv_sec - ts->tv_sec) * (1000 * 1000 * 1000) +

                    (end_time.tv_nsec - ts->tv_nsec);

    }


    return 0;

}


static inline void

gc_enter(rb_objspace_t *objspace, enum gc_enter_event event, unsigned int *lock_lev)

{

    *lock_lev = RB_GC_VM_LOCK();


    switch (event) {

      case gc_enter_event_rest:

      case gc_enter_event_start:

      case gc_enter_event_continue:

        // stop other ractors

        rb_gc_vm_barrier();

        break;

      default:

        break;

    }


    gc_enter_count(event);

    if (RB_UNLIKELY(during_gc != 0)) rb_bug("during_gc != 0");

    if (RGENGC_CHECK_MODE >= 3) gc_verify_internal_consistency(objspace);


    during_gc = TRUE;

    RUBY_DEBUG_LOG("%s (%s)",gc_enter_event_cstr(event), gc_current_status(objspace));

    gc_report(1, objspace, "gc_enter: %s [%s]\n", gc_enter_event_cstr(event), gc_current_status(objspace));

    gc_record(objspace, 0, gc_enter_event_cstr(event));


    rb_gc_event_hook(0, RUBY_INTERNAL_EVENT_GC_ENTER);

}


static inline void

gc_exit(rb_objspace_t *objspace, enum gc_enter_event event, unsigned int *lock_lev)

{

    GC_ASSERT(during_gc != 0);


    rb_gc_event_hook(0, RUBY_INTERNAL_EVENT_GC_EXIT);


    gc_record(objspace, 1, gc_enter_event_cstr(event));

    RUBY_DEBUG_LOG("%s (%s)", gc_enter_event_cstr(event), gc_current_status(objspace));

    gc_report(1, objspace, "gc_exit: %s [%s]\n", gc_enter_event_cstr(event), gc_current_status(objspace));

    during_gc = FALSE;


    RB_GC_VM_UNLOCK(*lock_lev);

}


#ifndef MEASURE_GC

#define MEASURE_GC (objspace->flags.measure_gc)

#endif


static void

gc_marking_enter(rb_objspace_t *objspace)

{

    GC_ASSERT(during_gc != 0);


    if (MEASURE_GC) {

        gc_clock_start(&objspace->profile.marking_start_time);

    }

}


static void

gc_marking_exit(rb_objspace_t *objspace)

{

    GC_ASSERT(during_gc != 0);


    if (MEASURE_GC) {

        objspace->profile.marking_time_ns += gc_clock_end(&objspace->profile.marking_start_time);

    }

}


static void

gc_sweeping_enter(rb_objspace_t *objspace)

{

    GC_ASSERT(during_gc != 0);


    if (MEASURE_GC) {

        gc_clock_start(&objspace->profile.sweeping_start_time);

    }

}


static void

gc_sweeping_exit(rb_objspace_t *objspace)

{

    GC_ASSERT(during_gc != 0);


    if (MEASURE_GC) {

        objspace->profile.sweeping_time_ns += gc_clock_end(&objspace->profile.sweeping_start_time);

    }

}


static void *

gc_with_gvl(void *ptr)

{

    struct objspace_and_reason *oar = (struct objspace_and_reason *)ptr;

    return (void *)(VALUE)garbage_collect(oar->objspace, oar->reason);

}


int ruby_thread_has_gvl_p(void);


static int

garbage_collect_with_gvl(rb_objspace_t *objspace, unsigned int reason)

{

    if (dont_gc_val()) {

        return TRUE;

    }

    else if (!ruby_native_thread_p()) {

        return TRUE;

    }

    else if (!ruby_thread_has_gvl_p()) {

        void *ret;

        struct objspace_and_reason oar;

        oar.objspace = objspace;

        oar.reason = reason;

        ret = rb_thread_call_with_gvl(gc_with_gvl, (void *)&oar);


        return !!ret;

    }

    else {

        return garbage_collect(objspace, reason);

    }

}


static int

gc_set_candidate_object_i(void *vstart, void *vend, size_t stride, void *data)

{

    rb_objspace_t *objspace = (rb_objspace_t *)data;


    VALUE v = (VALUE)vstart;

    for (; v != (VALUE)vend; v += stride) {

        asan_unpoisoning_object(v) {

            switch (BUILTIN_TYPE(v)) {

              case T_NONE:

              case T_ZOMBIE:

                break;

              default:

                rb_gc_prepare_heap_process_object(v);

                if (!RVALUE_OLD_P(objspace, v) && !RVALUE_WB_UNPROTECTED(objspace, v)) {

                    RVALUE_AGE_SET_CANDIDATE(objspace, v);

                }

            }

        }

    }


    return 0;

}


void

rb_gc_impl_start(void *objspace_ptr, bool full_mark, bool immediate_mark, bool immediate_sweep, bool compact)

{

    rb_objspace_t *objspace = objspace_ptr;

    unsigned int reason = (GPR_FLAG_FULL_MARK |

                           GPR_FLAG_IMMEDIATE_MARK |

                           GPR_FLAG_IMMEDIATE_SWEEP |

                           GPR_FLAG_METHOD);


    int full_marking_p = gc_config_full_mark_val;

    gc_config_full_mark_set(TRUE);


    /* For now, compact implies full mark / sweep, so ignore other flags */

    if (compact) {

        GC_ASSERT(GC_COMPACTION_SUPPORTED);


        reason |= GPR_FLAG_COMPACT;

    }

    else {

        if (!full_mark)       reason &= ~GPR_FLAG_FULL_MARK;

        if (!immediate_mark)  reason &= ~GPR_FLAG_IMMEDIATE_MARK;

        if (!immediate_sweep) reason &= ~GPR_FLAG_IMMEDIATE_SWEEP;

    }


    garbage_collect(objspace, reason);

    gc_finalize_deferred(objspace);


    gc_config_full_mark_set(full_marking_p);

}


void

rb_gc_impl_prepare_heap(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    size_t orig_total_slots = objspace_available_slots(objspace);

    size_t orig_allocatable_bytes = objspace->heap_pages.allocatable_bytes;


    rb_gc_impl_each_objects(objspace, gc_set_candidate_object_i, objspace_ptr);


    double orig_max_free_slots = gc_params.heap_free_slots_max_ratio;

    /* Ensure that all empty pages are moved onto empty_pages. */

    gc_params.heap_free_slots_max_ratio = 0.0;

    rb_gc_impl_start(objspace, true, true, true, true);

    gc_params.heap_free_slots_max_ratio = orig_max_free_slots;


    objspace->heap_pages.allocatable_bytes = 0;

    heap_pages_freeable_pages = objspace->empty_pages_count;

    heap_pages_free_unused_pages(objspace_ptr);

    GC_ASSERT(heap_pages_freeable_pages == 0);

    GC_ASSERT(objspace->empty_pages_count == 0);

    objspace->heap_pages.allocatable_bytes = orig_allocatable_bytes;


    size_t total_slots = objspace_available_slots(objspace);

    if (orig_total_slots > total_slots) {

        objspace->heap_pages.allocatable_bytes += (orig_total_slots - total_slots) * heaps[0].slot_size;

    }


#if defined(HAVE_MALLOC_TRIM) && !defined(RUBY_ALTERNATIVE_MALLOC_HEADER)

    malloc_trim(0);

#endif

}


static int

gc_is_moveable_obj(rb_objspace_t *objspace, VALUE obj)

{

    GC_ASSERT(!SPECIAL_CONST_P(obj));


    switch (BUILTIN_TYPE(obj)) {

      case T_NONE:

      case T_MOVED:

      case T_ZOMBIE:

        return FALSE;

      case T_SYMBOL:

      case T_STRING:

      case T_OBJECT:

      case T_FLOAT:

      case T_IMEMO:

      case T_ARRAY:

      case T_BIGNUM:

      case T_ICLASS:

      case T_MODULE:

      case T_REGEXP:

      case T_DATA:

      case T_MATCH:

      case T_STRUCT:

      case T_HASH:

      case T_FILE:

      case T_COMPLEX:

      case T_RATIONAL:

      case T_NODE:

      case T_CLASS:

        if (FL_TEST_RAW(obj, FL_FINALIZE)) {

            /* The finalizer table is a numtable. It looks up objects by address.

             * We can't mark the keys in the finalizer table because that would

             * prevent the objects from being collected.  This check prevents

             * objects that are keys in the finalizer table from being moved

             * without directly pinning them. */

            GC_ASSERT(st_is_member(finalizer_table, obj));


            return FALSE;

        }

        GC_ASSERT(RVALUE_MARKED(objspace, obj));

        GC_ASSERT(!RVALUE_PINNED(objspace, obj));


        return TRUE;


      default:

        rb_bug("gc_is_moveable_obj: unreachable (%d)", (int)BUILTIN_TYPE(obj));

        break;

    }


    return FALSE;

}


void rb_mv_generic_ivar(VALUE src, VALUE dst);


static VALUE

gc_move(rb_objspace_t *objspace, VALUE src, VALUE dest, size_t src_slot_size, size_t slot_size)

{

    int marked;

    int wb_unprotected;

    int uncollectible;

    int age;


    gc_report(4, objspace, "Moving object: %p -> %p\n", (void *)src, (void *)dest);


    GC_ASSERT(BUILTIN_TYPE(src) != T_NONE);

    GC_ASSERT(!MARKED_IN_BITMAP(GET_HEAP_MARK_BITS(dest), dest));


    GC_ASSERT(!RVALUE_MARKING(objspace, src));


    /* Save off bits for current object. */

    marked = RVALUE_MARKED(objspace, src);

    wb_unprotected = RVALUE_WB_UNPROTECTED(objspace, src);

    uncollectible = RVALUE_UNCOLLECTIBLE(objspace, src);

    bool remembered = RVALUE_REMEMBERED(objspace, src);

    age = RVALUE_AGE_GET(src);


    /* Clear bits for eventual T_MOVED */

    CLEAR_IN_BITMAP(GET_HEAP_MARK_BITS(src), src);

    CLEAR_IN_BITMAP(GET_HEAP_WB_UNPROTECTED_BITS(src), src);

    CLEAR_IN_BITMAP(GET_HEAP_UNCOLLECTIBLE_BITS(src), src);

    CLEAR_IN_BITMAP(GET_HEAP_PAGE(src)->remembered_bits, src);


    /* Move the object */

    memcpy((void *)dest, (void *)src, MIN(src_slot_size, slot_size));


    if (RVALUE_OVERHEAD > 0) {

        void *dest_overhead = (void *)(((uintptr_t)dest) + slot_size - RVALUE_OVERHEAD);

        void *src_overhead = (void *)(((uintptr_t)src) + src_slot_size - RVALUE_OVERHEAD);


        memcpy(dest_overhead, src_overhead, RVALUE_OVERHEAD);

    }


    memset((void *)src, 0, src_slot_size);

    RVALUE_AGE_SET_BITMAP(src, 0);


    /* Set bits for object in new location */

    if (remembered) {

        MARK_IN_BITMAP(GET_HEAP_PAGE(dest)->remembered_bits, dest);

    }

    else {

        CLEAR_IN_BITMAP(GET_HEAP_PAGE(dest)->remembered_bits, dest);

    }


    if (marked) {

        MARK_IN_BITMAP(GET_HEAP_MARK_BITS(dest), dest);

    }

    else {

        CLEAR_IN_BITMAP(GET_HEAP_MARK_BITS(dest), dest);

    }


    if (wb_unprotected) {

        MARK_IN_BITMAP(GET_HEAP_WB_UNPROTECTED_BITS(dest), dest);

    }

    else {

        CLEAR_IN_BITMAP(GET_HEAP_WB_UNPROTECTED_BITS(dest), dest);

    }


    if (uncollectible) {

        MARK_IN_BITMAP(GET_HEAP_UNCOLLECTIBLE_BITS(dest), dest);

    }

    else {

        CLEAR_IN_BITMAP(GET_HEAP_UNCOLLECTIBLE_BITS(dest), dest);

    }


    RVALUE_AGE_SET(dest, age);

    /* Assign forwarding address */

    RMOVED(src)->flags = T_MOVED;

    RMOVED(src)->dummy = Qundef;

    RMOVED(src)->destination = dest;

    GC_ASSERT(BUILTIN_TYPE(dest) != T_NONE);


    GET_HEAP_PAGE(src)->heap->total_freed_objects++;

    GET_HEAP_PAGE(dest)->heap->total_allocated_objects++;


    return src;

}


#if GC_CAN_COMPILE_COMPACTION

static int

compare_pinned_slots(const void *left, const void *right, void *dummy)

{

    struct heap_page *left_page;

    struct heap_page *right_page;


    left_page = *(struct heap_page * const *)left;

    right_page = *(struct heap_page * const *)right;


    return left_page->pinned_slots - right_page->pinned_slots;

}


static int

compare_free_slots(const void *left, const void *right, void *dummy)

{

    struct heap_page *left_page;

    struct heap_page *right_page;


    left_page = *(struct heap_page * const *)left;

    right_page = *(struct heap_page * const *)right;


    return left_page->free_slots - right_page->free_slots;

}


static void

gc_sort_heap_by_compare_func(rb_objspace_t *objspace, gc_compact_compare_func compare_func)

{

    for (int j = 0; j < HEAP_COUNT; j++) {

        rb_heap_t *heap = &heaps[j];


        size_t total_pages = heap->total_pages;

        size_t size = rb_size_mul_or_raise(total_pages, sizeof(struct heap_page *), rb_eRuntimeError);

        struct heap_page *page = 0, **page_list = malloc(size);

        size_t i = 0;


        heap->free_pages = NULL;

        ccan_list_for_each(&heap->pages, page, page_node) {

            page_list[i++] = page;

            GC_ASSERT(page);

        }


        GC_ASSERT((size_t)i == total_pages);


        /* Sort the heap so "filled pages" are first. `heap_add_page` adds to the

         * head of the list, so empty pages will end up at the start of the heap */

        ruby_qsort(page_list, total_pages, sizeof(struct heap_page *), compare_func, NULL);


        /* Reset the eden heap */

        ccan_list_head_init(&heap->pages);


        for (i = 0; i < total_pages; i++) {

            ccan_list_add(&heap->pages, &page_list[i]->page_node);

            if (page_list[i]->free_slots != 0) {

                heap_add_freepage(heap, page_list[i]);

            }

        }


        free(page_list);

    }

}

#endif


void

rb_gc_impl_register_pinning_obj(void *objspace_ptr, VALUE obj)

{

    /* no-op */

}


bool

rb_gc_impl_object_moved_p(void *objspace_ptr, VALUE obj)

{

    return gc_object_moved_p(objspace_ptr, obj);

}


static int

gc_ref_update(void *vstart, void *vend, size_t stride, rb_objspace_t *objspace, struct heap_page *page)

{

    VALUE v = (VALUE)vstart;


    page->flags.has_uncollectible_wb_unprotected_objects = FALSE;

    page->flags.has_remembered_objects = FALSE;


    /* For each object on the page */

    for (; v != (VALUE)vend; v += stride) {

        asan_unpoisoning_object(v) {

            switch (BUILTIN_TYPE(v)) {

              case T_NONE:

              case T_MOVED:

              case T_ZOMBIE:

                break;

              default:

                if (RVALUE_WB_UNPROTECTED(objspace, v)) {

                    page->flags.has_uncollectible_wb_unprotected_objects = TRUE;

                }

                if (RVALUE_REMEMBERED(objspace, v)) {

                    page->flags.has_remembered_objects = TRUE;

                }

                if (page->flags.before_sweep) {

                    if (RVALUE_MARKED(objspace, v)) {

                        rb_gc_update_object_references(objspace, v);

                    }

                }

                else {

                    rb_gc_update_object_references(objspace, v);

                }

            }

        }

    }


    return 0;

}


static int

gc_update_references_weak_table_i(VALUE obj, void *data)

{

    int ret;

    asan_unpoisoning_object(obj) {

        ret = BUILTIN_TYPE(obj) == T_MOVED ? ST_REPLACE : ST_CONTINUE;

    }

    return ret;

}


static int

gc_update_references_weak_table_replace_i(VALUE *obj, void *data)

{

    *obj = rb_gc_location(*obj);


    return ST_CONTINUE;

}


static void

gc_update_references(rb_objspace_t *objspace)

{

    objspace->flags.during_reference_updating = true;


    rb_gc_before_updating_jit_code();


    struct heap_page *page = NULL;


    for (int i = 0; i < HEAP_COUNT; i++) {

        bool should_set_mark_bits = TRUE;

        rb_heap_t *heap = &heaps[i];


        ccan_list_for_each(&heap->pages, page, page_node) {

            uintptr_t start = (uintptr_t)page->start;

            uintptr_t end = start + (page->total_slots * heap->slot_size);


            gc_ref_update((void *)start, (void *)end, heap->slot_size, objspace, page);

            if (page == heap->sweeping_page) {

                should_set_mark_bits = FALSE;

            }

            if (should_set_mark_bits) {

                gc_setup_mark_bits(page);

            }

        }

    }


    gc_update_table_refs(finalizer_table);


    rb_gc_update_vm_references((void *)objspace);


    for (int table = 0; table < RB_GC_VM_WEAK_TABLE_COUNT; table++) {

        rb_gc_vm_weak_table_foreach(

            gc_update_references_weak_table_i,

            gc_update_references_weak_table_replace_i,

            NULL,

            false,

            table

        );

    }


    rb_gc_after_updating_jit_code();


    objspace->flags.during_reference_updating = false;

}


#if GC_CAN_COMPILE_COMPACTION

static void

root_obj_check_moved_i(const char *category, VALUE obj, void *data)

{

    rb_objspace_t *objspace = data;


    if (gc_object_moved_p(objspace, obj)) {

        rb_bug("ROOT %s points to MOVED: %p -> %s", category, (void *)obj, rb_obj_info(rb_gc_impl_location(objspace, obj)));

    }

}


static void

reachable_object_check_moved_i(VALUE ref, void *data)

{

    VALUE parent = (VALUE)data;

    if (gc_object_moved_p(rb_gc_get_objspace(), ref)) {

        rb_bug("Object %s points to MOVED: %p -> %s", rb_obj_info(parent), (void *)ref, rb_obj_info(rb_gc_impl_location(rb_gc_get_objspace(), ref)));

    }

}


static int

heap_check_moved_i(void *vstart, void *vend, size_t stride, void *data)

{

    rb_objspace_t *objspace = data;


    VALUE v = (VALUE)vstart;

    for (; v != (VALUE)vend; v += stride) {

        if (gc_object_moved_p(objspace, v)) {

            /* Moved object still on the heap, something may have a reference. */

        }

        else {

            asan_unpoisoning_object(v) {

                switch (BUILTIN_TYPE(v)) {

                  case T_NONE:

                  case T_ZOMBIE:

                    break;

                  default:

                    if (!rb_gc_impl_garbage_object_p(objspace, v)) {

                        rb_objspace_reachable_objects_from(v, reachable_object_check_moved_i, (void *)v);

                    }

                }

            }

        }

    }


    return 0;

}

#endif


bool

rb_gc_impl_during_gc_p(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    return during_gc;

}


#if RGENGC_PROFILE >= 2


static const char*

type_name(int type, VALUE obj)

{

    switch ((enum ruby_value_type)type) {

      case RUBY_T_NONE:     return "T_NONE";

      case RUBY_T_OBJECT:   return "T_OBJECT";

      case RUBY_T_CLASS:    return "T_CLASS";

      case RUBY_T_MODULE:   return "T_MODULE";

      case RUBY_T_FLOAT:    return "T_FLOAT";

      case RUBY_T_STRING:   return "T_STRING";

      case RUBY_T_REGEXP:   return "T_REGEXP";

      case RUBY_T_ARRAY:    return "T_ARRAY";

      case RUBY_T_HASH:     return "T_HASH";

      case RUBY_T_STRUCT:   return "T_STRUCT";

      case RUBY_T_BIGNUM:   return "T_BIGNUM";

      case RUBY_T_FILE:     return "T_FILE";

      case RUBY_T_DATA:     return "T_DATA";

      case RUBY_T_MATCH:    return "T_MATCH";

      case RUBY_T_COMPLEX:  return "T_COMPLEX";

      case RUBY_T_RATIONAL: return "T_RATIONAL";

      case RUBY_T_NIL:      return "T_NIL";

      case RUBY_T_TRUE:     return "T_TRUE";

      case RUBY_T_FALSE:    return "T_FALSE";

      case RUBY_T_SYMBOL:   return "T_SYMBOL";

      case RUBY_T_FIXNUM:   return "T_FIXNUM";

      case RUBY_T_UNDEF:    return "T_UNDEF";

      case RUBY_T_IMEMO:    return "T_IMEMO";

      case RUBY_T_NODE:     return "T_NODE";

      case RUBY_T_ICLASS:   return "T_ICLASS";

      case RUBY_T_ZOMBIE:   return "T_ZOMBIE";

      case RUBY_T_MOVED:    return "T_MOVED";

      default:              return "unknown";

    }

}


static void

gc_count_add_each_types(VALUE hash, const char *name, const size_t *types)

{

    VALUE result = rb_hash_new_with_size(T_MASK);

    int i;

    for (i=0; i<T_MASK; i++) {

        const char *type = type_name(i, 0);

        rb_hash_aset(result, ID2SYM(rb_intern(type)), SIZET2NUM(types[i]));

    }

    rb_hash_aset(hash, ID2SYM(rb_intern(name)), result);

}

#endif


size_t

rb_gc_impl_gc_count(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    return objspace->profile.count;

}


static VALUE

gc_info_decode(rb_objspace_t *objspace, const VALUE hash_or_key, const unsigned int orig_flags)

{

    static VALUE sym_major_by = Qnil, sym_gc_by, sym_immediate_sweep, sym_have_finalizer, sym_state, sym_need_major_by;

    static VALUE sym_nofree, sym_oldgen, sym_shady, sym_force, sym_stress;

#if RGENGC_ESTIMATE_OLDMALLOC

    static VALUE sym_oldmalloc;

#endif

    static VALUE sym_newobj, sym_malloc, sym_method, sym_capi;

    static VALUE sym_none, sym_marking, sym_sweeping;

    static VALUE sym_weak_references_count;

    VALUE hash = Qnil, key = Qnil;

    VALUE major_by, need_major_by;

    unsigned int flags = orig_flags ? orig_flags : objspace->profile.latest_gc_info;


    if (SYMBOL_P(hash_or_key)) {

        key = hash_or_key;

    }

    else if (RB_TYPE_P(hash_or_key, T_HASH)) {

        hash = hash_or_key;

    }

    else {

        rb_bug("gc_info_decode: non-hash or symbol given");

    }


    if (NIL_P(sym_major_by)) {

#define S(s) sym_##s = ID2SYM(rb_intern_const(#s))

        S(major_by);

        S(gc_by);

        S(immediate_sweep);

        S(have_finalizer);

        S(state);

        S(need_major_by);


        S(stress);

        S(nofree);

        S(oldgen);

        S(shady);

        S(force);

#if RGENGC_ESTIMATE_OLDMALLOC

        S(oldmalloc);

#endif

        S(newobj);

        S(malloc);

        S(method);

        S(capi);


        S(none);

        S(marking);

        S(sweeping);


        S(weak_references_count);

#undef S

    }


#define SET(name, attr) \

    if (key == sym_##name) \

        return (attr); \

    else if (hash != Qnil) \

        rb_hash_aset(hash, sym_##name, (attr));


    major_by =

      (flags & GPR_FLAG_MAJOR_BY_NOFREE) ? sym_nofree :

      (flags & GPR_FLAG_MAJOR_BY_OLDGEN) ? sym_oldgen :

      (flags & GPR_FLAG_MAJOR_BY_SHADY)  ? sym_shady :

      (flags & GPR_FLAG_MAJOR_BY_FORCE)  ? sym_force :

#if RGENGC_ESTIMATE_OLDMALLOC

      (flags & GPR_FLAG_MAJOR_BY_OLDMALLOC) ? sym_oldmalloc :

#endif

      Qnil;

    SET(major_by, major_by);


    if (orig_flags == 0) { /* set need_major_by only if flags not set explicitly */

        unsigned int need_major_flags = gc_needs_major_flags;

        need_major_by =

            (need_major_flags & GPR_FLAG_MAJOR_BY_NOFREE) ? sym_nofree :

            (need_major_flags & GPR_FLAG_MAJOR_BY_OLDGEN) ? sym_oldgen :

            (need_major_flags & GPR_FLAG_MAJOR_BY_SHADY)  ? sym_shady :

            (need_major_flags & GPR_FLAG_MAJOR_BY_FORCE)  ? sym_force :

#if RGENGC_ESTIMATE_OLDMALLOC

            (need_major_flags & GPR_FLAG_MAJOR_BY_OLDMALLOC) ? sym_oldmalloc :

#endif

            Qnil;

        SET(need_major_by, need_major_by);

    }


    SET(gc_by,

        (flags & GPR_FLAG_NEWOBJ) ? sym_newobj :

        (flags & GPR_FLAG_MALLOC) ? sym_malloc :

        (flags & GPR_FLAG_METHOD) ? sym_method :

        (flags & GPR_FLAG_CAPI)   ? sym_capi :

        (flags & GPR_FLAG_STRESS) ? sym_stress :

        Qnil

    );


    SET(have_finalizer, (flags & GPR_FLAG_HAVE_FINALIZE) ? Qtrue : Qfalse);

    SET(immediate_sweep, (flags & GPR_FLAG_IMMEDIATE_SWEEP) ? Qtrue : Qfalse);


    if (orig_flags == 0) {

        SET(state, gc_mode(objspace) == gc_mode_none ? sym_none :

                   gc_mode(objspace) == gc_mode_marking ? sym_marking : sym_sweeping);

    }


    SET(weak_references_count, LONG2FIX(objspace->profile.weak_references_count));

#undef SET


    if (!NIL_P(key)) {

        // Matched key should return above

        return Qundef;

    }


    return hash;

}


VALUE

rb_gc_impl_latest_gc_info(void *objspace_ptr, VALUE key)

{

    rb_objspace_t *objspace = objspace_ptr;


    return gc_info_decode(objspace, key, 0);

}


enum gc_stat_sym {

    gc_stat_sym_count,

    gc_stat_sym_time,

    gc_stat_sym_marking_time,

    gc_stat_sym_sweeping_time,

    gc_stat_sym_heap_allocated_pages,

    gc_stat_sym_heap_empty_pages,

    gc_stat_sym_heap_allocatable_bytes,

    gc_stat_sym_heap_available_slots,

    gc_stat_sym_heap_live_slots,

    gc_stat_sym_heap_free_slots,

    gc_stat_sym_heap_final_slots,

    gc_stat_sym_heap_marked_slots,

    gc_stat_sym_heap_eden_pages,

    gc_stat_sym_total_allocated_pages,

    gc_stat_sym_total_freed_pages,

    gc_stat_sym_total_allocated_objects,

    gc_stat_sym_total_freed_objects,

    gc_stat_sym_malloc_increase_bytes,

    gc_stat_sym_malloc_increase_bytes_limit,

    gc_stat_sym_minor_gc_count,

    gc_stat_sym_major_gc_count,

    gc_stat_sym_compact_count,

    gc_stat_sym_read_barrier_faults,

    gc_stat_sym_total_moved_objects,

    gc_stat_sym_remembered_wb_unprotected_objects,

    gc_stat_sym_remembered_wb_unprotected_objects_limit,

    gc_stat_sym_old_objects,

    gc_stat_sym_old_objects_limit,

#if RGENGC_ESTIMATE_OLDMALLOC

    gc_stat_sym_oldmalloc_increase_bytes,

    gc_stat_sym_oldmalloc_increase_bytes_limit,

#endif

#if RGENGC_PROFILE

    gc_stat_sym_total_generated_normal_object_count,

    gc_stat_sym_total_generated_shady_object_count,

    gc_stat_sym_total_shade_operation_count,

    gc_stat_sym_total_promoted_count,

    gc_stat_sym_total_remembered_normal_object_count,

    gc_stat_sym_total_remembered_shady_object_count,

#endif

    gc_stat_sym_last

};


static VALUE gc_stat_symbols[gc_stat_sym_last];


static void

setup_gc_stat_symbols(void)

{

    if (gc_stat_symbols[0] == 0) {

#define S(s) gc_stat_symbols[gc_stat_sym_##s] = ID2SYM(rb_intern_const(#s))

        S(count);

        S(time);

        S(marking_time),

        S(sweeping_time),

        S(heap_allocated_pages);

        S(heap_empty_pages);

        S(heap_allocatable_bytes);

        S(heap_available_slots);

        S(heap_live_slots);

        S(heap_free_slots);

        S(heap_final_slots);

        S(heap_marked_slots);

        S(heap_eden_pages);

        S(total_allocated_pages);

        S(total_freed_pages);

        S(total_allocated_objects);

        S(total_freed_objects);

        S(malloc_increase_bytes);

        S(malloc_increase_bytes_limit);

        S(minor_gc_count);

        S(major_gc_count);

        S(compact_count);

        S(read_barrier_faults);

        S(total_moved_objects);

        S(remembered_wb_unprotected_objects);

        S(remembered_wb_unprotected_objects_limit);

        S(old_objects);

        S(old_objects_limit);

#if RGENGC_ESTIMATE_OLDMALLOC

        S(oldmalloc_increase_bytes);

        S(oldmalloc_increase_bytes_limit);

#endif

#if RGENGC_PROFILE

        S(total_generated_normal_object_count);

        S(total_generated_shady_object_count);

        S(total_shade_operation_count);

        S(total_promoted_count);

        S(total_remembered_normal_object_count);

        S(total_remembered_shady_object_count);

#endif /* RGENGC_PROFILE */

#undef S

    }

}


static uint64_t

ns_to_ms(uint64_t ns)

{

    return ns / (1000 * 1000);

}


static void malloc_increase_local_flush(rb_objspace_t *objspace);


VALUE

rb_gc_impl_stat(void *objspace_ptr, VALUE hash_or_sym)

{

    rb_objspace_t *objspace = objspace_ptr;

    VALUE hash = Qnil, key = Qnil;


    setup_gc_stat_symbols();


    ractor_cache_flush_count(objspace, rb_gc_get_ractor_newobj_cache());

    malloc_increase_local_flush(objspace);


    if (RB_TYPE_P(hash_or_sym, T_HASH)) {

        hash = hash_or_sym;

    }

    else if (SYMBOL_P(hash_or_sym)) {

        key = hash_or_sym;

    }

    else {

        rb_bug("non-hash or symbol given");

    }


#define SET(name, attr) \

    if (key == gc_stat_symbols[gc_stat_sym_##name]) \

        return SIZET2NUM(attr); \

    else if (hash != Qnil) \

        rb_hash_aset(hash, gc_stat_symbols[gc_stat_sym_##name], SIZET2NUM(attr));


    SET(count, objspace->profile.count);

    SET(time, (size_t)ns_to_ms(objspace->profile.marking_time_ns + objspace->profile.sweeping_time_ns)); // TODO: UINT64T2NUM

    SET(marking_time, (size_t)ns_to_ms(objspace->profile.marking_time_ns));

    SET(sweeping_time, (size_t)ns_to_ms(objspace->profile.sweeping_time_ns));


    /* implementation dependent counters */

    SET(heap_allocated_pages, rb_darray_size(objspace->heap_pages.sorted));

    SET(heap_empty_pages, objspace->empty_pages_count)

    SET(heap_allocatable_bytes, objspace->heap_pages.allocatable_bytes);

    SET(heap_available_slots, objspace_available_slots(objspace));

    SET(heap_live_slots, objspace_live_slots(objspace));

    SET(heap_free_slots, objspace_free_slots(objspace));

    SET(heap_final_slots, total_final_slots_count(objspace));

    SET(heap_marked_slots, objspace->marked_slots);

    SET(heap_eden_pages, heap_eden_total_pages(objspace));

    SET(total_allocated_pages, objspace->heap_pages.allocated_pages);

    SET(total_freed_pages, objspace->heap_pages.freed_pages);

    SET(total_allocated_objects, total_allocated_objects(objspace));

    SET(total_freed_objects, total_freed_objects(objspace));

    SET(malloc_increase_bytes, malloc_increase);

    SET(malloc_increase_bytes_limit, malloc_limit);

    SET(minor_gc_count, objspace->profile.minor_gc_count);

    SET(major_gc_count, objspace->profile.major_gc_count);

    SET(compact_count, objspace->profile.compact_count);

    SET(read_barrier_faults, objspace->profile.read_barrier_faults);

    SET(total_moved_objects, objspace->rcompactor.total_moved);

    SET(remembered_wb_unprotected_objects, objspace->rgengc.uncollectible_wb_unprotected_objects);

    SET(remembered_wb_unprotected_objects_limit, objspace->rgengc.uncollectible_wb_unprotected_objects_limit);

    SET(old_objects, objspace->rgengc.old_objects);

    SET(old_objects_limit, objspace->rgengc.old_objects_limit);

#if RGENGC_ESTIMATE_OLDMALLOC

    SET(oldmalloc_increase_bytes, objspace->malloc_counters.oldmalloc_increase);

    SET(oldmalloc_increase_bytes_limit, objspace->rgengc.oldmalloc_increase_limit);

#endif


#if RGENGC_PROFILE

    SET(total_generated_normal_object_count, objspace->profile.total_generated_normal_object_count);

    SET(total_generated_shady_object_count, objspace->profile.total_generated_shady_object_count);

    SET(total_shade_operation_count, objspace->profile.total_shade_operation_count);

    SET(total_promoted_count, objspace->profile.total_promoted_count);

    SET(total_remembered_normal_object_count, objspace->profile.total_remembered_normal_object_count);

    SET(total_remembered_shady_object_count, objspace->profile.total_remembered_shady_object_count);

#endif /* RGENGC_PROFILE */

#undef SET


    if (!NIL_P(key)) {

        // Matched key should return above

        return Qundef;

    }


#if defined(RGENGC_PROFILE) && RGENGC_PROFILE >= 2

    if (hash != Qnil) {

        gc_count_add_each_types(hash, "generated_normal_object_count_types", objspace->profile.generated_normal_object_count_types);

        gc_count_add_each_types(hash, "generated_shady_object_count_types", objspace->profile.generated_shady_object_count_types);

        gc_count_add_each_types(hash, "shade_operation_count_types", objspace->profile.shade_operation_count_types);

        gc_count_add_each_types(hash, "promoted_types", objspace->profile.promoted_types);

        gc_count_add_each_types(hash, "remembered_normal_object_count_types", objspace->profile.remembered_normal_object_count_types);

        gc_count_add_each_types(hash, "remembered_shady_object_count_types", objspace->profile.remembered_shady_object_count_types);

    }

#endif


    return hash;

}


enum gc_stat_heap_sym {

    gc_stat_heap_sym_slot_size,

    gc_stat_heap_sym_heap_live_slots,

    gc_stat_heap_sym_heap_free_slots,

    gc_stat_heap_sym_heap_final_slots,

    gc_stat_heap_sym_heap_eden_pages,

    gc_stat_heap_sym_heap_eden_slots,

    gc_stat_heap_sym_total_allocated_pages,

    gc_stat_heap_sym_force_major_gc_count,

    gc_stat_heap_sym_force_incremental_marking_finish_count,

    gc_stat_heap_sym_heap_allocatable_slots,

    gc_stat_heap_sym_total_allocated_objects,

    gc_stat_heap_sym_total_freed_objects,

    gc_stat_heap_sym_last

};


static VALUE gc_stat_heap_symbols[gc_stat_heap_sym_last];


static void

setup_gc_stat_heap_symbols(void)

{

    if (gc_stat_heap_symbols[0] == 0) {

#define S(s) gc_stat_heap_symbols[gc_stat_heap_sym_##s] = ID2SYM(rb_intern_const(#s))

        S(slot_size);

        S(heap_live_slots);

        S(heap_free_slots);

        S(heap_final_slots);

        S(heap_eden_pages);

        S(heap_eden_slots);

        S(heap_allocatable_slots);

        S(total_allocated_pages);

        S(force_major_gc_count);

        S(force_incremental_marking_finish_count);

        S(total_allocated_objects);

        S(total_freed_objects);

#undef S

    }

}


static VALUE

stat_one_heap(rb_objspace_t *objspace, rb_heap_t *heap, VALUE hash, VALUE key)

{

#define SET(name, attr) \

    if (key == gc_stat_heap_symbols[gc_stat_heap_sym_##name]) \

        return SIZET2NUM(attr); \

    else if (hash != Qnil) \

        rb_hash_aset(hash, gc_stat_heap_symbols[gc_stat_heap_sym_##name], SIZET2NUM(attr));


    SET(slot_size, heap->slot_size);

    SET(heap_live_slots, heap->total_allocated_objects - heap->total_freed_objects - heap->final_slots_count);

    SET(heap_free_slots, heap->total_slots - (heap->total_allocated_objects - heap->total_freed_objects));

    SET(heap_final_slots, heap->final_slots_count);

    SET(heap_eden_pages, heap->total_pages);

    SET(heap_eden_slots, heap->total_slots);

    SET(heap_allocatable_slots, objspace->heap_pages.allocatable_bytes / heap->slot_size);

    SET(total_allocated_pages, heap->total_allocated_pages);

    SET(force_major_gc_count, heap->force_major_gc_count);

    SET(force_incremental_marking_finish_count, heap->force_incremental_marking_finish_count);

    SET(total_allocated_objects, heap->total_allocated_objects);

    SET(total_freed_objects, heap->total_freed_objects);

#undef SET


    if (!NIL_P(key)) {

        // Matched key should return above

        return Qundef;

    }


    return hash;

}


VALUE

rb_gc_impl_stat_heap(void *objspace_ptr, VALUE heap_name, VALUE hash_or_sym)

{

    rb_objspace_t *objspace = objspace_ptr;


    ractor_cache_flush_count(objspace, rb_gc_get_ractor_newobj_cache());


    setup_gc_stat_heap_symbols();


    if (NIL_P(heap_name)) {

        if (!RB_TYPE_P(hash_or_sym, T_HASH)) {

            rb_bug("non-hash given");

        }


        for (int i = 0; i < HEAP_COUNT; i++) {

            VALUE hash = rb_hash_aref(hash_or_sym, INT2FIX(i));

            if (NIL_P(hash)) {

                hash = rb_hash_new();

                rb_hash_aset(hash_or_sym, INT2FIX(i), hash);

            }


            stat_one_heap(objspace, &heaps[i], hash, Qnil);

        }

    }

    else if (FIXNUM_P(heap_name)) {

        int heap_idx = FIX2INT(heap_name);


        if (heap_idx < 0 || heap_idx >= HEAP_COUNT) {

            rb_raise(rb_eArgError, "size pool index out of range");

        }


        if (SYMBOL_P(hash_or_sym)) {

            return stat_one_heap(objspace, &heaps[heap_idx], Qnil, hash_or_sym);

        }

        else if (RB_TYPE_P(hash_or_sym, T_HASH)) {

            return stat_one_heap(objspace, &heaps[heap_idx], hash_or_sym, Qnil);

        }

        else {

            rb_bug("non-hash or symbol given");

        }

    }

    else {

        rb_bug("heap_name must be nil or an Integer");

    }


    return hash_or_sym;

}


/* I could include internal.h for this, but doing so undefines some Array macros

 * necessary for initialising objects, and I don't want to include all the array

 * headers to get them back

 * TODO: Investigate why RARRAY_AREF gets undefined in internal.h

 */

#ifndef RBOOL

#define RBOOL(v) (v ? Qtrue : Qfalse)

#endif


VALUE

rb_gc_impl_config_get(void *objspace_ptr)

{

#define sym(name) ID2SYM(rb_intern_const(name))

    rb_objspace_t *objspace = objspace_ptr;

    VALUE hash = rb_hash_new();


    rb_hash_aset(hash, sym("rgengc_allow_full_mark"), RBOOL(gc_config_full_mark_val));


    return hash;

}


static int

gc_config_set_key(VALUE key, VALUE value, VALUE data)

{

    rb_objspace_t *objspace = (rb_objspace_t *)data;

    if (rb_sym2id(key) == rb_intern("rgengc_allow_full_mark")) {

        gc_rest(objspace);

        gc_config_full_mark_set(RTEST(value));

    }

    return ST_CONTINUE;

}


void

rb_gc_impl_config_set(void *objspace_ptr, VALUE hash)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (!RB_TYPE_P(hash, T_HASH)) {

        rb_raise(rb_eArgError, "expected keyword arguments");

    }


    rb_hash_foreach(hash, gc_config_set_key, (st_data_t)objspace);

}


VALUE

rb_gc_impl_stress_get(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;

    return ruby_gc_stress_mode;

}


void

rb_gc_impl_stress_set(void *objspace_ptr, VALUE flag)

{

    rb_objspace_t *objspace = objspace_ptr;


    objspace->flags.gc_stressful = RTEST(flag);

    objspace->gc_stress_mode = flag;

}


static int

get_envparam_size(const char *name, size_t *default_value, size_t lower_bound)

{

    const char *ptr = getenv(name);

    ssize_t val;


    if (ptr != NULL && *ptr) {

        size_t unit = 0;

        char *end;

#if SIZEOF_SIZE_T == SIZEOF_LONG_LONG

        val = strtoll(ptr, &end, 0);

#else

        val = strtol(ptr, &end, 0);

#endif

        switch (*end) {

          case 'k': case 'K':

            unit = 1024;

            ++end;

            break;

          case 'm': case 'M':

            unit = 1024*1024;

            ++end;

            break;

          case 'g': case 'G':

            unit = 1024*1024*1024;

            ++end;

            break;

        }

        while (*end && isspace((unsigned char)*end)) end++;

        if (*end) {

            if (RTEST(ruby_verbose)) fprintf(stderr, "invalid string for %s: %s\n", name, ptr);

            return 0;

        }

        if (unit > 0) {

            if (val < -(ssize_t)(SIZE_MAX / 2 / unit) || (ssize_t)(SIZE_MAX / 2 / unit) < val) {

                if (RTEST(ruby_verbose)) fprintf(stderr, "%s=%s is ignored because it overflows\n", name, ptr);

                return 0;

            }

            val *= unit;

        }

        if (val > 0 && (size_t)val > lower_bound) {

            if (RTEST(ruby_verbose)) {

                fprintf(stderr, "%s=%"PRIdSIZE" (default value: %"PRIuSIZE")\n", name, val, *default_value);

            }

            *default_value = (size_t)val;

            return 1;

        }

        else {

            if (RTEST(ruby_verbose)) {

                fprintf(stderr, "%s=%"PRIdSIZE" (default value: %"PRIuSIZE") is ignored because it must be greater than %"PRIuSIZE".\n",

                        name, val, *default_value, lower_bound);

            }

            return 0;

        }

    }

    return 0;

}


static int

get_envparam_double(const char *name, double *default_value, double lower_bound, double upper_bound, int accept_zero)

{

    const char *ptr = getenv(name);

    double val;


    if (ptr != NULL && *ptr) {

        char *end;

        val = strtod(ptr, &end);

        if (!*ptr || *end) {

            if (RTEST(ruby_verbose)) fprintf(stderr, "invalid string for %s: %s\n", name, ptr);

            return 0;

        }


        if (accept_zero && val == 0.0) {

            goto accept;

        }

        else if (val <= lower_bound) {

            if (RTEST(ruby_verbose)) {

                fprintf(stderr, "%s=%f (default value: %f) is ignored because it must be greater than %f.\n",

                        name, val, *default_value, lower_bound);

            }

        }

        else if (upper_bound != 0.0 && /* ignore upper_bound if it is 0.0 */

                 val > upper_bound) {

            if (RTEST(ruby_verbose)) {

                fprintf(stderr, "%s=%f (default value: %f) is ignored because it must be lower than %f.\n",

                        name, val, *default_value, upper_bound);

            }

        }

        else {

            goto accept;

        }

    }

    return 0;


  accept:

    if (RTEST(ruby_verbose)) fprintf(stderr, "%s=%f (default value: %f)\n", name, val, *default_value);

    *default_value = val;

    return 1;

}


/*

 * GC tuning environment variables

 *

 * * RUBY_GC_HEAP_FREE_SLOTS

 *   - Prepare at least this amount of slots after GC.

 *   - Allocate slots if there are not enough slots.

 * * RUBY_GC_HEAP_GROWTH_FACTOR (new from 2.1)

 *   - Allocate slots by this factor.

 *   - (next slots number) = (current slots number) * (this factor)

 * * RUBY_GC_HEAP_GROWTH_MAX_BYTES (was RUBY_GC_HEAP_GROWTH_MAX_SLOTS)

 *   - Allocation rate is limited to this number of bytes.

 * * RUBY_GC_HEAP_FREE_SLOTS_MIN_RATIO (new from 2.4)

 *   - Allocate additional pages when the number of free slots is

 *     lower than the value (total_slots * (this ratio)).

 * * RUBY_GC_HEAP_FREE_SLOTS_GOAL_RATIO (new from 2.4)

 *   - Allocate slots to satisfy this formula:

 *       free_slots = total_slots * goal_ratio

 *   - In other words, prepare (total_slots * goal_ratio) free slots.

 *   - if this value is 0.0, then use RUBY_GC_HEAP_GROWTH_FACTOR directly.

 * * RUBY_GC_HEAP_FREE_SLOTS_MAX_RATIO (new from 2.4)

 *   - Allow to free pages when the number of free slots is

 *     greater than the value (total_slots * (this ratio)).

 * * RUBY_GC_HEAP_OLDOBJECT_LIMIT_FACTOR (new from 2.1.1)

 *   - Do full GC when the number of old objects is more than R * N

 *     where R is this factor and

 *           N is the number of old objects just after last full GC.

 *

 *  * obsolete

 *    * RUBY_FREE_MIN       -> RUBY_GC_HEAP_FREE_SLOTS (from 2.1)

 *    * RUBY_HEAP_MIN_SLOTS -> RUBY_GC_HEAP_INIT_SLOTS (from 2.1) -> RUBY_GC_HEAP_INIT_BYTES

 *

 * * RUBY_GC_MALLOC_LIMIT

 * * RUBY_GC_MALLOC_LIMIT_MAX (new from 2.1)

 * * RUBY_GC_MALLOC_LIMIT_GROWTH_FACTOR (new from 2.1)

 *

 * * RUBY_GC_OLDMALLOC_LIMIT (new from 2.1)

 * * RUBY_GC_OLDMALLOC_LIMIT_MAX (new from 2.1)

 * * RUBY_GC_OLDMALLOC_LIMIT_GROWTH_FACTOR (new from 2.1)

 */


void

rb_gc_impl_set_params(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;

    /* RUBY_GC_HEAP_FREE_SLOTS */

    if (get_envparam_size("RUBY_GC_HEAP_FREE_SLOTS", &gc_params.heap_free_slots, 0)) {

        /* ok */

    }


    get_envparam_size("RUBY_GC_HEAP_INIT_BYTES", &gc_params.heap_init_bytes, 0);


    get_envparam_double("RUBY_GC_HEAP_GROWTH_FACTOR", &gc_params.growth_factor, 1.0, 0.0, FALSE);

    get_envparam_size  ("RUBY_GC_HEAP_GROWTH_MAX_BYTES", &gc_params.growth_max_bytes, 0);

    get_envparam_double("RUBY_GC_HEAP_FREE_SLOTS_MIN_RATIO", &gc_params.heap_free_slots_min_ratio,

                        0.0, 1.0, FALSE);

    get_envparam_double("RUBY_GC_HEAP_FREE_SLOTS_MAX_RATIO", &gc_params.heap_free_slots_max_ratio,

                        gc_params.heap_free_slots_min_ratio, 1.0, FALSE);

    get_envparam_double("RUBY_GC_HEAP_FREE_SLOTS_GOAL_RATIO", &gc_params.heap_free_slots_goal_ratio,

                        gc_params.heap_free_slots_min_ratio, gc_params.heap_free_slots_max_ratio, TRUE);

    get_envparam_double("RUBY_GC_HEAP_OLDOBJECT_LIMIT_FACTOR", &gc_params.oldobject_limit_factor, 0.0, 0.0, TRUE);

    get_envparam_double("RUBY_GC_HEAP_REMEMBERED_WB_UNPROTECTED_OBJECTS_LIMIT_RATIO", &gc_params.uncollectible_wb_unprotected_objects_limit_ratio, 0.0, 0.0, TRUE);


    if (get_envparam_size("RUBY_GC_MALLOC_LIMIT", &gc_params.malloc_limit_min, 0)) {

        malloc_limit = gc_params.malloc_limit_min;

    }

    get_envparam_size  ("RUBY_GC_MALLOC_LIMIT_MAX", &gc_params.malloc_limit_max, 0);

    if (!gc_params.malloc_limit_max) { /* ignore max-check if 0 */

        gc_params.malloc_limit_max = SIZE_MAX;

    }

    get_envparam_double("RUBY_GC_MALLOC_LIMIT_GROWTH_FACTOR", &gc_params.malloc_limit_growth_factor, 1.0, 0.0, FALSE);


#if RGENGC_ESTIMATE_OLDMALLOC

    if (get_envparam_size("RUBY_GC_OLDMALLOC_LIMIT", &gc_params.oldmalloc_limit_min, 0)) {

        objspace->rgengc.oldmalloc_increase_limit = gc_params.oldmalloc_limit_min;

    }

    get_envparam_size  ("RUBY_GC_OLDMALLOC_LIMIT_MAX", &gc_params.oldmalloc_limit_max, 0);

    get_envparam_double("RUBY_GC_OLDMALLOC_LIMIT_GROWTH_FACTOR", &gc_params.oldmalloc_limit_growth_factor, 1.0, 0.0, FALSE);

#endif

}


static inline size_t

objspace_malloc_size(rb_objspace_t *objspace, void *ptr, size_t hint)

{

#ifdef HAVE_MALLOC_USABLE_SIZE

    if (!hint) {

        hint = malloc_usable_size(ptr);

    }

#endif

    return hint;

}


enum memop_type {

    MEMOP_TYPE_MALLOC  = 0,

    MEMOP_TYPE_FREE,

    MEMOP_TYPE_REALLOC

};


static inline void

atomic_sub_nounderflow(size_t *var, size_t sub)

{

    if (sub == 0) return;


    while (1) {

        size_t val = *var;

        if (val < sub) sub = val;

        if (RUBY_ATOMIC_SIZE_CAS(*var, val, val-sub) == val) break;

    }

}


#define gc_stress_full_mark_after_malloc_p() \

    (FIXNUM_P(ruby_gc_stress_mode) && (FIX2LONG(ruby_gc_stress_mode) & (1<<gc_stress_full_mark_after_malloc)))


static void

objspace_malloc_gc_stress(rb_objspace_t *objspace)

{

    if (ruby_gc_stressful && ruby_native_thread_p()) {

        unsigned int reason = (GPR_FLAG_IMMEDIATE_MARK | GPR_FLAG_IMMEDIATE_SWEEP |

                               GPR_FLAG_STRESS | GPR_FLAG_MALLOC);


        if (gc_stress_full_mark_after_malloc_p()) {

            reason |= GPR_FLAG_FULL_MARK;

        }

        garbage_collect_with_gvl(objspace, reason);

    }

}


static void

malloc_increase_commit(rb_objspace_t *objspace, size_t new_size, size_t old_size)

{

    if (new_size > old_size) {

        RUBY_ATOMIC_SIZE_ADD(malloc_increase, new_size - old_size);

#if RGENGC_ESTIMATE_OLDMALLOC

        RUBY_ATOMIC_SIZE_ADD(objspace->malloc_counters.oldmalloc_increase, new_size - old_size);

#endif

    }

    else {

        atomic_sub_nounderflow(&malloc_increase, old_size - new_size);

#if RGENGC_ESTIMATE_OLDMALLOC

        atomic_sub_nounderflow(&objspace->malloc_counters.oldmalloc_increase, old_size - new_size);

#endif

    }

}


#if USE_MALLOC_INCREASE_LOCAL

static void

malloc_increase_local_flush(rb_objspace_t *objspace)

{

    int delta = malloc_increase_local;

    if (delta == 0) return;


    malloc_increase_local = 0;

    if (delta > 0) {

        malloc_increase_commit(objspace, (size_t)delta, 0);

    }

    else {

        malloc_increase_commit(objspace, 0, (size_t)(-delta));

    }

}

#else

static void

malloc_increase_local_flush(rb_objspace_t *objspace)

{

}

#endif


static inline bool

objspace_malloc_increase_report(rb_objspace_t *objspace, void *mem, size_t new_size, size_t old_size, enum memop_type type, bool gc_allowed)

{

    if (0) fprintf(stderr, "increase - ptr: %p, type: %s, new_size: %"PRIdSIZE", old_size: %"PRIdSIZE"\n",

                   mem,

                   type == MEMOP_TYPE_MALLOC  ? "malloc" :

                   type == MEMOP_TYPE_FREE    ? "free  " :

                   type == MEMOP_TYPE_REALLOC ? "realloc": "error",

                   new_size, old_size);

    return false;

}


static bool

objspace_malloc_increase_body(rb_objspace_t *objspace, void *mem, size_t new_size, size_t old_size, enum memop_type type, bool gc_allowed)

{

#if USE_MALLOC_INCREASE_LOCAL

    if (new_size < GC_MALLOC_INCREASE_LOCAL_THRESHOLD &&

        old_size < GC_MALLOC_INCREASE_LOCAL_THRESHOLD) {

        malloc_increase_local += (int)new_size - (int)old_size;


        if (malloc_increase_local >= GC_MALLOC_INCREASE_LOCAL_THRESHOLD ||

            malloc_increase_local <= -GC_MALLOC_INCREASE_LOCAL_THRESHOLD) {

            malloc_increase_local_flush(objspace);

        }

    }

    else {

        malloc_increase_local_flush(objspace);

        malloc_increase_commit(objspace, new_size, old_size);

    }

#else

    malloc_increase_commit(objspace, new_size, old_size);

#endif


    if (type == MEMOP_TYPE_MALLOC && gc_allowed) {

      retry:

        if (malloc_increase > malloc_limit && ruby_native_thread_p() && !dont_gc_val()) {

            if (ruby_thread_has_gvl_p() && is_lazy_sweeping(objspace)) {

                gc_rest(objspace); /* gc_rest can reduce malloc_increase */

                goto retry;

            }

            garbage_collect_with_gvl(objspace, GPR_FLAG_MALLOC);

        }

    }


#if MALLOC_ALLOCATED_SIZE

    if (new_size >= old_size) {

        RUBY_ATOMIC_SIZE_ADD(objspace->malloc_params.allocated_size, new_size - old_size);

    }

    else {

        size_t dec_size = old_size - new_size;


#if MALLOC_ALLOCATED_SIZE_CHECK

        size_t allocated_size = objspace->malloc_params.allocated_size;

        if (allocated_size < dec_size) {

            rb_bug("objspace_malloc_increase: underflow malloc_params.allocated_size.");

        }

#endif

        atomic_sub_nounderflow(&objspace->malloc_params.allocated_size, dec_size);

    }


    switch (type) {

      case MEMOP_TYPE_MALLOC:

        RUBY_ATOMIC_SIZE_INC(objspace->malloc_params.allocations);

        break;

      case MEMOP_TYPE_FREE:

        {

            size_t allocations = objspace->malloc_params.allocations;

            if (allocations > 0) {

                atomic_sub_nounderflow(&objspace->malloc_params.allocations, 1);

            }

#if MALLOC_ALLOCATED_SIZE_CHECK

            else {

                GC_ASSERT(objspace->malloc_params.allocations > 0);

            }

#endif

        }

        break;

      case MEMOP_TYPE_REALLOC: /* ignore */ break;

    }

#endif

    return true;

}


#define objspace_malloc_increase(...) \

    for (bool malloc_increase_done = objspace_malloc_increase_report(__VA_ARGS__); \

         !malloc_increase_done; \

         malloc_increase_done = objspace_malloc_increase_body(__VA_ARGS__))


struct malloc_obj_info { /* 4 words */

    size_t size;

};


static inline size_t

objspace_malloc_prepare(rb_objspace_t *objspace, size_t size)

{

    if (size == 0) size = 1;


#if CALC_EXACT_MALLOC_SIZE

    size += sizeof(struct malloc_obj_info);

#endif


    return size;

}


static bool

malloc_during_gc_p(rb_objspace_t *objspace)

{

    /* malloc is not allowed during GC when we're not using multiple ractors

     * (since ractors can run while another thread is sweeping) and when we

     * have the GVL (since if we don't have the GVL, we'll try to acquire the

     * GVL which will block and ensure the other thread finishes GC). */

    return during_gc && !dont_gc_val() && !rb_gc_multi_ractor_p() && ruby_thread_has_gvl_p();

}


static inline void *

objspace_malloc_fixup(rb_objspace_t *objspace, void *mem, size_t size, bool gc_allowed)

{

    size = objspace_malloc_size(objspace, mem, size);

    objspace_malloc_increase(objspace, mem, size, 0, MEMOP_TYPE_MALLOC, gc_allowed) {}


#if CALC_EXACT_MALLOC_SIZE

    {

        struct malloc_obj_info *info = mem;

        info->size = size;

        mem = info + 1;

    }

#endif


    return mem;

}


#if defined(__GNUC__) && RUBY_DEBUG

#define RB_BUG_INSTEAD_OF_RB_MEMERROR 1

#endif


#ifndef RB_BUG_INSTEAD_OF_RB_MEMERROR

# define RB_BUG_INSTEAD_OF_RB_MEMERROR 0

#endif


#define GC_MEMERROR(...) \

    ((RB_BUG_INSTEAD_OF_RB_MEMERROR+0) ? rb_bug("" __VA_ARGS__) : (void)0)


#define TRY_WITH_GC(siz, expr) do {                          \

        const gc_profile_record_flag gpr =                   \

            GPR_FLAG_FULL_MARK           |                   \

            GPR_FLAG_IMMEDIATE_MARK      |                   \

            GPR_FLAG_IMMEDIATE_SWEEP     |                   \

            GPR_FLAG_MALLOC;                                 \

        objspace_malloc_gc_stress(objspace);                 \

                                                             \

        if (RB_LIKELY((expr))) {                             \

            /* Success on 1st try */                         \

        }                                                    \

        else if (gc_allowed && !garbage_collect_with_gvl(objspace, gpr)) { \

            /* @shyouhei thinks this doesn't happen */       \

            GC_MEMERROR("TRY_WITH_GC: could not GC");        \

        }                                                    \

        else if ((expr)) {                                   \

            /* Success on 2nd try */                         \

        }                                                    \

        else {                                               \

            GC_MEMERROR("TRY_WITH_GC: could not allocate:"   \

                        "%"PRIdSIZE" bytes for %s",          \

                        siz, # expr);                        \

        }                                                    \

    } while (0)


static void

check_malloc_not_in_gc(rb_objspace_t *objspace, const char *msg)

{

    if (RB_UNLIKELY(malloc_during_gc_p(objspace))) {

        dont_gc_on();

        during_gc = false;

        rb_bug("Cannot %s during GC", msg);

    }

}


void

rb_gc_impl_free(void *objspace_ptr, void *ptr, size_t old_size)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (!ptr) {

        /*

         * ISO/IEC 9899 says "If ptr is a null pointer, no action occurs" since

         * its first version.  We would better follow.

         */

        return;

    }

#if CALC_EXACT_MALLOC_SIZE

    struct malloc_obj_info *info = (struct malloc_obj_info *)ptr - 1;

#if VERIFY_FREE_SIZE

    if (!info->size) {

        rb_bug("buffer %p has no recorded size. Was it allocated with ruby_mimalloc? If so it should be freed with ruby_mimfree", ptr);

    }


    if (old_size && (old_size + sizeof(struct malloc_obj_info)) != info->size) {

        rb_bug("buffer %p freed with old_size=%zu, but was allocated with size=%zu", ptr, old_size, info->size - sizeof(struct malloc_obj_info));

    }

#endif

    ptr = info;

    old_size = info->size;

#endif

    old_size = objspace_malloc_size(objspace, ptr, old_size);


    objspace_malloc_increase(objspace, ptr, 0, old_size, MEMOP_TYPE_FREE, true) {

        free(ptr);

        ptr = NULL;

        RB_DEBUG_COUNTER_INC(heap_xfree);

    }

}


void *

rb_gc_impl_malloc(void *objspace_ptr, size_t size, bool gc_allowed)

{

    rb_objspace_t *objspace = objspace_ptr;

    check_malloc_not_in_gc(objspace, "malloc");


    void *mem;


    size = objspace_malloc_prepare(objspace, size);

    TRY_WITH_GC(size, mem = malloc(size));

    RB_DEBUG_COUNTER_INC(heap_xmalloc);

    if (!mem) return mem;

    return objspace_malloc_fixup(objspace, mem, size, gc_allowed);

}


void *

rb_gc_impl_calloc(void *objspace_ptr, size_t size, bool gc_allowed)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (RB_UNLIKELY(malloc_during_gc_p(objspace))) {

        rb_warn("calloc during GC detected, this could cause crashes if it triggers another GC");

#if RGENGC_CHECK_MODE || RUBY_DEBUG

        rb_bug("Cannot calloc during GC");

#endif

    }


    void *mem;


    size = objspace_malloc_prepare(objspace, size);

    TRY_WITH_GC(size, mem = calloc1(size));

    if (!mem) return mem;

    return objspace_malloc_fixup(objspace, mem, size, gc_allowed);

}


void *

rb_gc_impl_realloc(void *objspace_ptr, void *ptr, size_t new_size, size_t old_size, bool gc_allowed)

{

    rb_objspace_t *objspace = objspace_ptr;


    check_malloc_not_in_gc(objspace, "realloc");


    void *mem;


    if (!ptr) return rb_gc_impl_malloc(objspace, new_size, gc_allowed);


    /*

     * The behavior of realloc(ptr, 0) is implementation defined.

     * Therefore we don't use realloc(ptr, 0) for portability reason.

     * see http://www.open-std.org/jtc1/sc22/wg14/www/docs/dr_400.htm

     */

    if (new_size == 0) {

        if ((mem = rb_gc_impl_malloc(objspace, 0, gc_allowed)) != NULL) {

            /*

             * - OpenBSD's malloc(3) man page says that when 0 is passed, it

             *   returns a non-NULL pointer to an access-protected memory page.

             *   The returned pointer cannot be read / written at all, but

             *   still be a valid argument of free().

             *

             *   https://man.openbsd.org/malloc.3

             *

             * - Linux's malloc(3) man page says that it _might_ perhaps return

             *   a non-NULL pointer when its argument is 0.  That return value

             *   is safe (and is expected) to be passed to free().

             *

             *   https://man7.org/linux/man-pages/man3/malloc.3.html

             *

             * - As I read the implementation jemalloc's malloc() returns fully

             *   normal 16 bytes memory region when its argument is 0.

             *

             * - As I read the implementation musl libc's malloc() returns

             *   fully normal 32 bytes memory region when its argument is 0.

             *

             * - Other malloc implementations can also return non-NULL.

             */

            rb_gc_impl_free(objspace, ptr, old_size);

            return mem;

        }

        else {

            /*

             * It is dangerous to return NULL here, because that could lead to

             * RCE.  Fallback to 1 byte instead of zero.

             *

             * https://cve.mitre.org/cgi-bin/cvename.cgi?name=CVE-2019-11932

             */

            new_size = 1;

        }

    }


#if CALC_EXACT_MALLOC_SIZE

    {

        struct malloc_obj_info *info = (struct malloc_obj_info *)ptr - 1;

        new_size += sizeof(struct malloc_obj_info);

        ptr = info;

#if VERIFY_FREE_SIZE

        if (old_size && (old_size + sizeof(struct malloc_obj_info)) != info->size) {

            rb_bug("buffer %p realloced with old_size=%zu, but was allocated with size=%zu", ptr, old_size, info->size - sizeof(struct malloc_obj_info));

        }

#endif

        old_size = info->size;

    }

#endif


    old_size = objspace_malloc_size(objspace, ptr, old_size);

    TRY_WITH_GC(new_size, mem = RB_GNUC_EXTENSION_BLOCK(realloc(ptr, new_size)));

    if (!mem) return mem;

    new_size = objspace_malloc_size(objspace, mem, new_size);


#if CALC_EXACT_MALLOC_SIZE

    {

        struct malloc_obj_info *info = mem;

        info->size = new_size;

        mem = info + 1;

    }

#endif


    objspace_malloc_increase(objspace, mem, new_size, old_size, MEMOP_TYPE_REALLOC, gc_allowed);


    RB_DEBUG_COUNTER_INC(heap_xrealloc);

    return mem;

}


void

rb_gc_impl_adjust_memory_usage(void *objspace_ptr, ssize_t diff)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (diff > 0) {

        objspace_malloc_increase(objspace, 0, diff, 0, MEMOP_TYPE_REALLOC, true);

    }

    else if (diff < 0) {

        objspace_malloc_increase(objspace, 0, 0, -diff, MEMOP_TYPE_REALLOC, true);

    }

}


// TODO: move GC profiler stuff back into gc.c

/*

  ------------------------------ GC profiler ------------------------------

*/


#define GC_PROFILE_RECORD_DEFAULT_SIZE 100


static bool

current_process_time(struct timespec *ts)

{

#if defined(HAVE_CLOCK_GETTIME) && defined(CLOCK_PROCESS_CPUTIME_ID)

    {

        static int try_clock_gettime = 1;

        if (try_clock_gettime && clock_gettime(CLOCK_PROCESS_CPUTIME_ID, ts) == 0) {

            return true;

        }

        else {

            try_clock_gettime = 0;

        }

    }

#endif


#ifdef RUSAGE_SELF

    {

        struct rusage usage;

        struct timeval time;

        if (getrusage(RUSAGE_SELF, &usage) == 0) {

            time = usage.ru_utime;

            ts->tv_sec = time.tv_sec;

            ts->tv_nsec = (int32_t)time.tv_usec * 1000;

            return true;

        }

    }

#endif


#ifdef _WIN32

    {

        FILETIME creation_time, exit_time, kernel_time, user_time;

        ULARGE_INTEGER ui;


        if (GetProcessTimes(GetCurrentProcess(),

                            &creation_time, &exit_time, &kernel_time, &user_time) != 0) {

            memcpy(&ui, &user_time, sizeof(FILETIME));

#define PER100NSEC (uint64_t)(1000 * 1000 * 10)

            ts->tv_nsec = (long)(ui.QuadPart % PER100NSEC);

            ts->tv_sec  = (time_t)(ui.QuadPart / PER100NSEC);

            return true;

        }

    }

#endif


    return false;

}


static double

getrusage_time(void)

{

    struct timespec ts;

    if (current_process_time(&ts)) {

        return ts.tv_sec + ts.tv_nsec * 1e-9;

    }

    else {

        return 0.0;

    }

}


static inline void

gc_prof_setup_new_record(rb_objspace_t *objspace, unsigned int reason)

{

    if (objspace->profile.run) {

        size_t index = objspace->profile.next_index;

        gc_profile_record *record;


        /* create new record */

        objspace->profile.next_index++;


        if (!objspace->profile.records) {

            objspace->profile.size = GC_PROFILE_RECORD_DEFAULT_SIZE;

            objspace->profile.records = malloc(xmalloc2_size(sizeof(gc_profile_record), objspace->profile.size));

        }

        if (index >= objspace->profile.size) {

            void *ptr;

            objspace->profile.size += 1000;

            ptr = realloc(objspace->profile.records, xmalloc2_size(sizeof(gc_profile_record), objspace->profile.size));

            if (!ptr) rb_memerror();

            objspace->profile.records = ptr;

        }

        if (!objspace->profile.records) {

            rb_bug("gc_profile malloc or realloc miss");

        }

        record = objspace->profile.current_record = &objspace->profile.records[objspace->profile.next_index - 1];

        MEMZERO(record, gc_profile_record, 1);


        /* setup before-GC parameter */

        record->flags = reason | (ruby_gc_stressful ? GPR_FLAG_STRESS : 0);

#if MALLOC_ALLOCATED_SIZE

        record->allocated_size = malloc_allocated_size;

#endif

#if GC_PROFILE_MORE_DETAIL && GC_PROFILE_DETAIL_MEMORY

#ifdef RUSAGE_SELF

        {

            struct rusage usage;

            if (getrusage(RUSAGE_SELF, &usage) == 0) {

                record->maxrss = usage.ru_maxrss;

                record->minflt = usage.ru_minflt;

                record->majflt = usage.ru_majflt;

            }

        }

#endif

#endif

    }

}


static inline void

gc_prof_timer_start(rb_objspace_t *objspace)

{

    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);

#if GC_PROFILE_MORE_DETAIL

        record->prepare_time = objspace->profile.prepare_time;

#endif

        record->gc_time = 0;

        record->gc_invoke_time = getrusage_time();

    }

}


static double

elapsed_time_from(double time)

{

    double now = getrusage_time();

    if (now > time) {

        return now - time;

    }

    else {

        return 0;

    }

}


static inline void

gc_prof_timer_stop(rb_objspace_t *objspace)

{

    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);

        record->gc_time = elapsed_time_from(record->gc_invoke_time);

        record->gc_invoke_time -= objspace->profile.invoke_time;

    }

}


#ifdef BUILDING_MODULAR_GC

# define RUBY_DTRACE_GC_HOOK(name)

#else

# define RUBY_DTRACE_GC_HOOK(name) \

    do {if (RUBY_DTRACE_GC_##name##_ENABLED()) RUBY_DTRACE_GC_##name();} while (0)

#endif


static inline void

gc_prof_mark_timer_start(rb_objspace_t *objspace)

{

    RUBY_DTRACE_GC_HOOK(MARK_BEGIN);

#if GC_PROFILE_MORE_DETAIL

    if (gc_prof_enabled(objspace)) {

        gc_prof_record(objspace)->gc_mark_time = getrusage_time();

    }

#endif

}


static inline void

gc_prof_mark_timer_stop(rb_objspace_t *objspace)

{

    RUBY_DTRACE_GC_HOOK(MARK_END);

#if GC_PROFILE_MORE_DETAIL

    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);

        record->gc_mark_time = elapsed_time_from(record->gc_mark_time);

    }

#endif

}


static inline void

gc_prof_sweep_timer_start(rb_objspace_t *objspace)

{

    RUBY_DTRACE_GC_HOOK(SWEEP_BEGIN);

    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);


        if (record->gc_time > 0 || GC_PROFILE_MORE_DETAIL) {

            objspace->profile.gc_sweep_start_time = getrusage_time();

        }

    }

}


static inline void

gc_prof_sweep_timer_stop(rb_objspace_t *objspace)

{

    RUBY_DTRACE_GC_HOOK(SWEEP_END);


    if (gc_prof_enabled(objspace)) {

        double sweep_time;

        gc_profile_record *record = gc_prof_record(objspace);


        if (record->gc_time > 0) {

            sweep_time = elapsed_time_from(objspace->profile.gc_sweep_start_time);

            /* need to accumulate GC time for lazy sweep after gc() */

            record->gc_time += sweep_time;

        }

        else if (GC_PROFILE_MORE_DETAIL) {

            sweep_time = elapsed_time_from(objspace->profile.gc_sweep_start_time);

        }


#if GC_PROFILE_MORE_DETAIL

        record->gc_sweep_time += sweep_time;

        if (heap_pages_deferred_final) record->flags |= GPR_FLAG_HAVE_FINALIZE;

#endif

        if (heap_pages_deferred_final) objspace->profile.latest_gc_info |= GPR_FLAG_HAVE_FINALIZE;

    }

}


static inline void

gc_prof_set_malloc_info(rb_objspace_t *objspace)

{

#if GC_PROFILE_MORE_DETAIL

    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);

        record->allocate_increase = malloc_increase;

        record->allocate_limit = malloc_limit;

    }

#endif

}


static inline void

gc_prof_set_heap_info(rb_objspace_t *objspace)

{

    if (gc_prof_enabled(objspace)) {

        gc_profile_record *record = gc_prof_record(objspace);


        /* Sum across all size pools since each has a different slot size. */

        size_t total = 0;

        size_t use_size = 0;

        size_t total_size = 0;

        for (int i = 0; i < HEAP_COUNT; i++) {

            rb_heap_t *heap = &heaps[i];

            size_t heap_live = heap->total_allocated_objects - heap->total_freed_objects - heap->final_slots_count;

            total += heap->total_slots;

            use_size += heap_live * heap->slot_size;

            total_size += heap->total_slots * heap->slot_size;

        }


#if GC_PROFILE_MORE_DETAIL

        size_t live = objspace->profile.total_allocated_objects_at_gc_start - total_freed_objects(objspace);

        record->heap_use_pages = objspace->profile.heap_used_at_gc_start;

        record->heap_live_objects = live;

        record->heap_free_objects = total - live;

#endif


        record->heap_total_objects = total;

        record->heap_use_size = use_size;

        record->heap_total_size = total_size;

    }

}


/*

 *  call-seq:

 *    GC::Profiler.clear          -> nil

 *

 *  Clears the \GC profiler data.

 *

 */


static VALUE

gc_profile_clear(VALUE _)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();

    void *p = objspace->profile.records;

    objspace->profile.records = NULL;

    objspace->profile.size = 0;

    objspace->profile.next_index = 0;

    objspace->profile.current_record = 0;

    free(p);

    return Qnil;

}


/*

 *  call-seq:

 *     GC::Profiler.raw_data    -> [Hash, ...]

 *

 *  Returns an Array of individual raw profile data Hashes ordered

 *  from earliest to latest by +:GC_INVOKE_TIME+.

 *

 *  For example:

 *

 *    [

 *      {

 *         :GC_TIME=>1.3000000000000858e-05,

 *         :GC_INVOKE_TIME=>0.010634999999999999,

 *         :HEAP_USE_SIZE=>289640,

 *         :HEAP_TOTAL_SIZE=>588960,

 *         :HEAP_TOTAL_OBJECTS=>14724,

 *         :GC_IS_MARKED=>false

 *      },

 *      # ...

 *    ]

 *

 *  The keys mean:

 *

 *  +:GC_TIME+::

 *      Time elapsed in seconds for this GC run

 *  +:GC_INVOKE_TIME+::

 *      Time elapsed in seconds from startup to when the GC was invoked

 *  +:HEAP_USE_SIZE+::

 *      Total bytes of heap used

 *  +:HEAP_TOTAL_SIZE+::

 *      Total size of heap in bytes

 *  +:HEAP_TOTAL_OBJECTS+::

 *      Total number of objects

 *  +:GC_IS_MARKED+::

 *      Returns +true+ if the GC is in mark phase

 *

 *  If ruby was built with +GC_PROFILE_MORE_DETAIL+, you will also have access

 *  to the following hash keys:

 *

 *  +:GC_MARK_TIME+::

 *  +:GC_SWEEP_TIME+::

 *  +:ALLOCATE_INCREASE+::

 *  +:ALLOCATE_LIMIT+::

 *  +:HEAP_USE_PAGES+::

 *  +:HEAP_LIVE_OBJECTS+::

 *  +:HEAP_FREE_OBJECTS+::

 *  +:HAVE_FINALIZE+::

 *

 */


static VALUE

gc_profile_record_get(VALUE _)

{

    VALUE prof;

    VALUE gc_profile = rb_ary_new();

    size_t i;

    rb_objspace_t *objspace = rb_gc_get_objspace();


    if (!objspace->profile.run) {

        return Qnil;

    }


    for (i =0; i < objspace->profile.next_index; i++) {

        gc_profile_record *record = &objspace->profile.records[i];


        prof = rb_hash_new();

        rb_hash_aset(prof, ID2SYM(rb_intern("GC_FLAGS")), gc_info_decode(objspace, rb_hash_new(), record->flags));

        rb_hash_aset(prof, ID2SYM(rb_intern("GC_TIME")), DBL2NUM(record->gc_time));

        rb_hash_aset(prof, ID2SYM(rb_intern("GC_INVOKE_TIME")), DBL2NUM(record->gc_invoke_time));

        rb_hash_aset(prof, ID2SYM(rb_intern("HEAP_USE_SIZE")), SIZET2NUM(record->heap_use_size));

        rb_hash_aset(prof, ID2SYM(rb_intern("HEAP_TOTAL_SIZE")), SIZET2NUM(record->heap_total_size));

        rb_hash_aset(prof, ID2SYM(rb_intern("HEAP_TOTAL_OBJECTS")), SIZET2NUM(record->heap_total_objects));

        rb_hash_aset(prof, ID2SYM(rb_intern("MOVED_OBJECTS")), SIZET2NUM(record->moved_objects));

        rb_hash_aset(prof, ID2SYM(rb_intern("GC_IS_MARKED")), Qtrue);

#if GC_PROFILE_MORE_DETAIL

        rb_hash_aset(prof, ID2SYM(rb_intern("GC_MARK_TIME")), DBL2NUM(record->gc_mark_time));

        rb_hash_aset(prof, ID2SYM(rb_intern("GC_SWEEP_TIME")), DBL2NUM(record->gc_sweep_time));

        rb_hash_aset(prof, ID2SYM(rb_intern("ALLOCATE_INCREASE")), SIZET2NUM(record->allocate_increase));

        rb_hash_aset(prof, ID2SYM(rb_intern("ALLOCATE_LIMIT")), SIZET2NUM(record->allocate_limit));

        rb_hash_aset(prof, ID2SYM(rb_intern("HEAP_USE_PAGES")), SIZET2NUM(record->heap_use_pages));

        rb_hash_aset(prof, ID2SYM(rb_intern("HEAP_LIVE_OBJECTS")), SIZET2NUM(record->heap_live_objects));

        rb_hash_aset(prof, ID2SYM(rb_intern("HEAP_FREE_OBJECTS")), SIZET2NUM(record->heap_free_objects));


        rb_hash_aset(prof, ID2SYM(rb_intern("REMOVING_OBJECTS")), SIZET2NUM(record->removing_objects));

        rb_hash_aset(prof, ID2SYM(rb_intern("EMPTY_OBJECTS")), SIZET2NUM(record->empty_objects));


        rb_hash_aset(prof, ID2SYM(rb_intern("HAVE_FINALIZE")), (record->flags & GPR_FLAG_HAVE_FINALIZE) ? Qtrue : Qfalse);

#endif


#if RGENGC_PROFILE > 0

        rb_hash_aset(prof, ID2SYM(rb_intern("OLD_OBJECTS")), SIZET2NUM(record->old_objects));

        rb_hash_aset(prof, ID2SYM(rb_intern("REMEMBERED_NORMAL_OBJECTS")), SIZET2NUM(record->remembered_normal_objects));

        rb_hash_aset(prof, ID2SYM(rb_intern("REMEMBERED_SHADY_OBJECTS")), SIZET2NUM(record->remembered_shady_objects));

#endif

        rb_ary_push(gc_profile, prof);

    }


    return gc_profile;

}


#if GC_PROFILE_MORE_DETAIL

#define MAJOR_REASON_MAX 0x10


static char *

gc_profile_dump_major_reason(unsigned int flags, char *buff)

{

    unsigned int reason = flags & GPR_FLAG_MAJOR_MASK;

    int i = 0;


    if (reason == GPR_FLAG_NONE) {

        buff[0] = '-';

        buff[1] = 0;

    }

    else {

#define C(x, s) \

  if (reason & GPR_FLAG_MAJOR_BY_##x) { \

      buff[i++] = #x[0]; \

      if (i >= MAJOR_REASON_MAX) rb_bug("gc_profile_dump_major_reason: overflow"); \

      buff[i] = 0; \

  }

        C(NOFREE, N);

        C(OLDGEN, O);

        C(SHADY,  S);

#if RGENGC_ESTIMATE_OLDMALLOC

        C(OLDMALLOC, M);

#endif

#undef C

    }

    return buff;

}

#endif


static void

gc_profile_dump_on(VALUE out, VALUE (*append)(VALUE, VALUE))

{

    rb_objspace_t *objspace = rb_gc_get_objspace();

    size_t count = objspace->profile.next_index;

#ifdef MAJOR_REASON_MAX

    char reason_str[MAJOR_REASON_MAX];

#endif


    if (objspace->profile.run && count /* > 1 */) {

        size_t i;

        const gc_profile_record *record;


        append(out, rb_sprintf("GC %"PRIuSIZE" invokes.\n", objspace->profile.count));

        append(out, rb_str_new_cstr("Index    Invoke Time(sec)       Use Size(byte)     Total Size(byte)         Total Object                    GC Time(ms)\n"));


        for (i = 0; i < count; i++) {

            record = &objspace->profile.records[i];

            append(out, rb_sprintf("%5"PRIuSIZE" %19.3f %20"PRIuSIZE" %20"PRIuSIZE" %20"PRIuSIZE" %30.20f\n",

                                   i+1, record->gc_invoke_time, record->heap_use_size,

                                   record->heap_total_size, record->heap_total_objects, record->gc_time*1000));

        }


#if GC_PROFILE_MORE_DETAIL

        const char *str = "\n\n" \

                                    "More detail.\n" \

                                    "Prepare Time = Previously GC's rest sweep time\n"

                                    "Index Flags          Allocate Inc.  Allocate Limit"

#if CALC_EXACT_MALLOC_SIZE

                                    "  Allocated Size"

#endif

                                    "  Use Page     Mark Time(ms)    Sweep Time(ms)  Prepare Time(ms)  LivingObj    FreeObj RemovedObj   EmptyObj"

#if RGENGC_PROFILE

                                    " OldgenObj RemNormObj RemShadObj"

#endif

#if GC_PROFILE_DETAIL_MEMORY

                                    " MaxRSS(KB) MinorFLT MajorFLT"

#endif

                                    "\n";

        append(out, rb_str_new_cstr(str));


        for (i = 0; i < count; i++) {

            record = &objspace->profile.records[i];

            append(out, rb_sprintf("%5"PRIuSIZE" %4s/%c/%6s%c %13"PRIuSIZE" %15"PRIuSIZE

#if CALC_EXACT_MALLOC_SIZE

                                   " %15"PRIuSIZE

#endif

                                   " %9"PRIuSIZE" %17.12f %17.12f %17.12f %10"PRIuSIZE" %10"PRIuSIZE" %10"PRIuSIZE" %10"PRIuSIZE

#if RGENGC_PROFILE

                                   "%10"PRIuSIZE" %10"PRIuSIZE" %10"PRIuSIZE

#endif

#if GC_PROFILE_DETAIL_MEMORY

                                   "%11ld %8ld %8ld"

#endif


                                   "\n",

                                   i+1,

                                   gc_profile_dump_major_reason(record->flags, reason_str),

                                   (record->flags & GPR_FLAG_HAVE_FINALIZE) ? 'F' : '.',

                                   (record->flags & GPR_FLAG_NEWOBJ) ? "NEWOBJ" :

                                   (record->flags & GPR_FLAG_MALLOC) ? "MALLOC" :

                                   (record->flags & GPR_FLAG_METHOD) ? "METHOD" :

                                   (record->flags & GPR_FLAG_CAPI)   ? "CAPI__" : "??????",

                                   (record->flags & GPR_FLAG_STRESS) ? '!' : ' ',

                                   record->allocate_increase, record->allocate_limit,

#if CALC_EXACT_MALLOC_SIZE

                                   record->allocated_size,

#endif

                                   record->heap_use_pages,

                                   record->gc_mark_time*1000,

                                   record->gc_sweep_time*1000,

                                   record->prepare_time*1000,


                                   record->heap_live_objects,

                                   record->heap_free_objects,

                                   record->removing_objects,

                                   record->empty_objects

#if RGENGC_PROFILE

                                   ,

                                   record->old_objects,

                                   record->remembered_normal_objects,

                                   record->remembered_shady_objects

#endif

#if GC_PROFILE_DETAIL_MEMORY

                                   ,

                                   record->maxrss / 1024,

                                   record->minflt,

                                   record->majflt

#endif


                       ));

        }

#endif

    }

}


/*

 *  call-seq:

 *     GC::Profiler.result  -> String

 *

 *  Returns a profile data report such as:

 *

 *    GC 1 invokes.

 *    Index    Invoke Time(sec)       Use Size(byte)     Total Size(byte)         Total Object                    GC time(ms)

 *        1               0.012               159240               212940                10647         0.00000000000001530000

 */


static VALUE

gc_profile_result(VALUE _)

{

    VALUE str = rb_str_buf_new(0);

    gc_profile_dump_on(str, rb_str_buf_append);

    return str;

}


/*

 *  call-seq:

 *     GC::Profiler.report

 *     GC::Profiler.report(io)

 *

 *  Writes the GC::Profiler.result to <tt>$stdout</tt> or the given IO object.

 *

 */


static VALUE

gc_profile_report(int argc, VALUE *argv, VALUE self)

{

    VALUE out;


    out = (!rb_check_arity(argc, 0, 1) ? rb_stdout : argv[0]);

    gc_profile_dump_on(out, rb_io_write);


    return Qnil;

}


/*

 *  call-seq:

 *     GC::Profiler.total_time  -> float

 *

 *  The total time used for garbage collection in seconds

 */


static VALUE

gc_profile_total_time(VALUE self)

{

    double time = 0;

    rb_objspace_t *objspace = rb_gc_get_objspace();


    if (objspace->profile.run && objspace->profile.next_index > 0) {

        size_t i;

        size_t count = objspace->profile.next_index;


        for (i = 0; i < count; i++) {

            time += objspace->profile.records[i].gc_time;

        }

    }

    return DBL2NUM(time);

}


/*

 *  call-seq:

 *    GC::Profiler.enabled?     -> true or false

 *

 *  The current status of \GC profile mode.

 */


static VALUE

gc_profile_enable_get(VALUE self)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();

    return objspace->profile.run ? Qtrue : Qfalse;

}


/*

 *  call-seq:

 *    GC::Profiler.enable       -> nil

 *

 *  Starts the \GC profiler.

 *

 */


static VALUE

gc_profile_enable(VALUE _)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();

    objspace->profile.run = TRUE;

    objspace->profile.current_record = 0;

    return Qnil;

}


/*

 *  call-seq:

 *    GC::Profiler.disable      -> nil

 *

 *  Stops the \GC profiler.

 *

 */


static VALUE

gc_profile_disable(VALUE _)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();


    objspace->profile.run = FALSE;

    objspace->profile.current_record = 0;

    return Qnil;

}


void

rb_gc_verify_internal_consistency(void)

{

    gc_verify_internal_consistency(rb_gc_get_objspace());

}


/*

 *  call-seq:

 *     GC.verify_internal_consistency                  -> nil

 *

 *  Verify internal consistency.

 *

 *  This method is implementation specific.

 *  Now this method checks generational consistency

 *  if RGenGC is supported.

 */

static VALUE

gc_verify_internal_consistency_m(VALUE dummy)

{

    rb_gc_verify_internal_consistency();

    return Qnil;

}


#if GC_CAN_COMPILE_COMPACTION

/*

 *  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.

 */

static VALUE

gc_set_auto_compact(VALUE _, VALUE v)

{

    GC_ASSERT(GC_COMPACTION_SUPPORTED);


    ruby_enable_autocompact = RTEST(v);


#if RGENGC_CHECK_MODE

    ruby_autocompact_compare_func = NULL;


    if (SYMBOL_P(v)) {

        ID id = RB_SYM2ID(v);

        if (id == rb_intern("empty")) {

            ruby_autocompact_compare_func = compare_free_slots;

        }

    }

#endif


    return v;

}

#else

#  define gc_set_auto_compact rb_f_notimplement

#endif


#if GC_CAN_COMPILE_COMPACTION

/*

 *  call-seq:

 *     GC.auto_compact    -> true or false

 *

 *  Returns whether or not automatic compaction has been enabled.

 */

static VALUE

gc_get_auto_compact(VALUE _)

{

    return ruby_enable_autocompact ? Qtrue : Qfalse;

}

#else

#  define gc_get_auto_compact rb_f_notimplement

#endif


#if GC_CAN_COMPILE_COMPACTION

/*

 *  call-seq:

 *     GC.latest_compact_info -> hash

 *

 * Returns information about object moved in the most recent \GC compaction.

 *

 * The returned +hash+ contains the following keys:

 *

 * [considered]

 *   Hash containing the type of the object as the key and the number of

 *   objects of that type that were considered for movement.

 * [moved]

 *   Hash containing the type of the object as the key and the number of

 *   objects of that type that were actually moved.

 * [moved_up]

 *   Hash containing the type of the object as the key and the number of

 *   objects of that type that were increased in size.

 * [moved_down]

 *   Hash containing the type of the object as the key and the number of

 *   objects of that type that were decreased in size.

 *

 * Some objects can't be moved (due to pinning) so these numbers can be used to

 * calculate compaction efficiency.

 */

static VALUE

gc_compact_stats(VALUE self)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();

    VALUE h = rb_hash_new();

    VALUE considered = rb_hash_new();

    VALUE moved = rb_hash_new();

    VALUE moved_up = rb_hash_new();

    VALUE moved_down = rb_hash_new();


    for (size_t i = 0; i < T_MASK; i++) {

        if (objspace->rcompactor.considered_count_table[i]) {

            rb_hash_aset(considered, type_sym(i), SIZET2NUM(objspace->rcompactor.considered_count_table[i]));

        }


        if (objspace->rcompactor.moved_count_table[i]) {

            rb_hash_aset(moved, type_sym(i), SIZET2NUM(objspace->rcompactor.moved_count_table[i]));

        }


        if (objspace->rcompactor.moved_up_count_table[i]) {

            rb_hash_aset(moved_up, type_sym(i), SIZET2NUM(objspace->rcompactor.moved_up_count_table[i]));

        }


        if (objspace->rcompactor.moved_down_count_table[i]) {

            rb_hash_aset(moved_down, type_sym(i), SIZET2NUM(objspace->rcompactor.moved_down_count_table[i]));

        }

    }


    rb_hash_aset(h, ID2SYM(rb_intern("considered")), considered);

    rb_hash_aset(h, ID2SYM(rb_intern("moved")), moved);

    rb_hash_aset(h, ID2SYM(rb_intern("moved_up")), moved_up);

    rb_hash_aset(h, ID2SYM(rb_intern("moved_down")), moved_down);


    return h;

}

#else

#  define gc_compact_stats rb_f_notimplement

#endif


#if GC_CAN_COMPILE_COMPACTION

/*

 *  call-seq:

 *     GC.compact -> hash

 *

 * 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.

 *

 * The returned +hash+ contains statistics about the objects that were moved;

 * see GC.latest_compact_info.

 *

 * This method is only expected to work on CRuby.

 *

 * To test whether \GC compaction is supported, use the idiom:

 *

 *   GC.respond_to?(:compact)

 */

static VALUE

gc_compact(VALUE self)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();

    int full_marking_p = gc_config_full_mark_val;

    gc_config_full_mark_set(TRUE);


    /* Run GC with compaction enabled */

    rb_gc_impl_start(rb_gc_get_objspace(), true, true, true, true);

    gc_config_full_mark_set(full_marking_p);


    return gc_compact_stats(self);

}

#else

#  define gc_compact rb_f_notimplement

#endif


#if GC_CAN_COMPILE_COMPACTION

struct desired_compaction_pages_i_data {

    rb_objspace_t *objspace;

    size_t required_slots[HEAP_COUNT];

};


static int

desired_compaction_pages_i(struct heap_page *page, void *data)

{

    struct desired_compaction_pages_i_data *tdata = data;

    rb_objspace_t *objspace = tdata->objspace;

    VALUE vstart = (VALUE)page->start;

    VALUE vend = vstart + (VALUE)(page->total_slots * page->heap->slot_size);


    for (VALUE v = vstart; v != vend; v += page->heap->slot_size) {

        asan_unpoisoning_object(v) {

            /* skip T_NONEs; they won't be moved */

            if (BUILTIN_TYPE(v) != T_NONE) {

                rb_heap_t *dest_pool = gc_compact_destination_pool(objspace, page->heap, v);

                size_t dest_pool_idx = dest_pool - heaps;

                tdata->required_slots[dest_pool_idx]++;

            }

        }

    }


    return 0;

}


/* 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 expands 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.

 */

static VALUE

gc_verify_compaction_references(int argc, VALUE* argv, VALUE self)

{

    static ID keywords[3] = {0};

    if (!keywords[0]) {

        keywords[0] = rb_intern("toward");

        keywords[1] = rb_intern("double_heap");

        keywords[2] = rb_intern("expand_heap");

    }


    VALUE options;

    rb_scan_args_kw(rb_keyword_given_p(), argc, argv, ":", &options);


    VALUE arguments[3] = { Qnil, Qfalse, Qfalse };

    int kwarg_count = rb_get_kwargs(options, keywords, 0, 3, arguments);

    bool toward_empty = kwarg_count > 0 && SYMBOL_P(arguments[0]) && SYM2ID(arguments[0]) == rb_intern("empty");

    bool expand_heap = (kwarg_count > 1 && RTEST(arguments[1])) || (kwarg_count > 2 && RTEST(arguments[2]));


    rb_objspace_t *objspace = rb_gc_get_objspace();


    /* Clear the heap. */

    rb_gc_impl_start(objspace, true, true, true, false);


    unsigned int lev = RB_GC_VM_LOCK();

    {

        gc_rest(objspace);


        /* if both double_heap and expand_heap are set, expand_heap takes precedence */

        if (expand_heap) {

            struct desired_compaction_pages_i_data desired_compaction = {

                .objspace = objspace,

                .required_slots = {0},

            };

            /* Work out how many objects want to be in each size pool, taking account of moves */

            objspace_each_pages(objspace, desired_compaction_pages_i, &desired_compaction, TRUE);


            /* Find out which pool has the most pages */

            size_t max_existing_pages = 0;

            for (int i = 0; i < HEAP_COUNT; i++) {

                rb_heap_t *heap = &heaps[i];

                max_existing_pages = MAX(max_existing_pages, heap->total_pages);

            }


            /* Add pages to each size pool so that compaction is guaranteed to move every object */

            for (int i = 0; i < HEAP_COUNT; i++) {

                rb_heap_t *heap = &heaps[i];


                size_t pages_to_add = 0;

                /*

                 * Step 1: Make sure every pool has the same number of pages, by adding empty pages

                 * to smaller pools. This is required to make sure the compact cursor can advance

                 * through all of the pools in `gc_sweep_compact` without hitting the "sweep &

                 * compact cursors met" condition on some pools before fully compacting others

                 */

                pages_to_add += max_existing_pages - heap->total_pages;

                /*

                 * Step 2: Now add additional free pages to each size pool sufficient to hold all objects

                 * that want to be in that size pool, whether moved into it or moved within it

                 */

                objspace->heap_pages.allocatable_bytes = desired_compaction.required_slots[i] * heap->slot_size;

                while (objspace->heap_pages.allocatable_bytes > 0) {

                    heap_page_allocate_and_initialize(objspace, heap);

                }

                /*

                 * Step 3: Add two more pages so that the compact & sweep cursors will meet _after_ all objects

                 * have been moved, and not on the last iteration of the `gc_sweep_compact` loop

                 */

                pages_to_add += 2;


                for (; pages_to_add > 0; pages_to_add--) {

                    heap_page_allocate_and_initialize_force(objspace, heap);

                }

            }

        }


        if (toward_empty) {

            objspace->rcompactor.compare_func = compare_free_slots;

        }

    }

    RB_GC_VM_UNLOCK(lev);


    rb_gc_impl_start(rb_gc_get_objspace(), true, true, true, true);


    rb_objspace_reachable_objects_from_root(root_obj_check_moved_i, objspace);

    objspace_each_objects(objspace, heap_check_moved_i, objspace, TRUE);


    objspace->rcompactor.compare_func = NULL;


    return gc_compact_stats(self);

}

#else

# define gc_verify_compaction_references rb_f_notimplement

#endif


void

rb_gc_impl_objspace_free(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    if (is_lazy_sweeping(objspace))

        rb_bug("lazy sweeping underway when freeing object space");


    free(objspace->profile.records);

    objspace->profile.records = NULL;


    for (size_t i = 0; i < rb_darray_size(objspace->heap_pages.sorted); i++) {

        heap_page_free(objspace, rb_darray_get(objspace->heap_pages.sorted, i));

    }

    rb_darray_free_without_gc(objspace->heap_pages.sorted);

    heap_pages_lomem = 0;

    heap_pages_himem = 0;


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];

        heap->total_pages = 0;

        heap->total_slots = 0;

    }


    free_stack_chunks(&objspace->mark_stack);

    mark_stack_free_cache(&objspace->mark_stack);


    rb_darray_free_without_gc(objspace->weak_references);


    free(objspace);

}


#if MALLOC_ALLOCATED_SIZE

/*

 *  call-seq:

 *     GC.malloc_allocated_size -> Integer

 *

 *  Returns the size of memory allocated by malloc().

 *

 *  Only available if ruby was built with +CALC_EXACT_MALLOC_SIZE+.

 */


static VALUE

gc_malloc_allocated_size(VALUE self)

{

    rb_objspace_t *objspace = (rb_objspace_t *)rb_gc_get_objspace();

    return ULL2NUM(objspace->malloc_params.allocated_size);

}


/*

 *  call-seq:

 *     GC.malloc_allocations -> Integer

 *

 *  Returns the number of malloc() allocations.

 *

 *  Only available if ruby was built with +CALC_EXACT_MALLOC_SIZE+.

 */


static VALUE

gc_malloc_allocations(VALUE self)

{

    rb_objspace_t *objspace = (rb_objspace_t *)rb_gc_get_objspace();

    return ULL2NUM(objspace->malloc_params.allocations);

}

#endif


void

rb_gc_impl_before_fork(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    objspace->fork_vm_lock_lev = RB_GC_VM_LOCK();

    rb_gc_vm_barrier();

}


void

rb_gc_impl_after_fork(void *objspace_ptr, rb_pid_t pid)

{

    rb_objspace_t *objspace = objspace_ptr;


    RB_GC_VM_UNLOCK(objspace->fork_vm_lock_lev);

    objspace->fork_vm_lock_lev = 0;


    if (pid == 0) { /* child process */

        rb_gc_ractor_newobj_cache_foreach(gc_ractor_newobj_cache_clear, NULL);

    }

}


VALUE rb_ident_hash_new_with_size(st_index_t size);


#if GC_DEBUG_STRESS_TO_CLASS

/*

 *  call-seq:

 *    GC.add_stress_to_class(class[, ...])

 *

 *  Raises NoMemoryError when allocating an instance of the given classes.

 *

 */

static VALUE

rb_gcdebug_add_stress_to_class(int argc, VALUE *argv, VALUE self)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();


    if (!stress_to_class) {

        set_stress_to_class(rb_ident_hash_new_with_size(argc));

    }


    for (int i = 0; i < argc; i++) {

        VALUE klass = argv[i];

        rb_hash_aset(stress_to_class, klass, Qtrue);

    }


    return self;

}


/*

 *  call-seq:

 *    GC.remove_stress_to_class(class[, ...])

 *

 *  No longer raises NoMemoryError when allocating an instance of the

 *  given classes.

 *

 */

static VALUE

rb_gcdebug_remove_stress_to_class(int argc, VALUE *argv, VALUE self)

{

    rb_objspace_t *objspace = rb_gc_get_objspace();


    if (stress_to_class) {

        for (int i = 0; i < argc; ++i) {

            rb_hash_delete(stress_to_class, argv[i]);

        }


        if (rb_hash_size(stress_to_class) == 0) {

            stress_to_class = 0;

        }

    }


    return Qnil;

}

#endif


void *

rb_gc_impl_objspace_alloc(void)

{

    rb_objspace_t *objspace = calloc1(sizeof(rb_objspace_t));


    return objspace;

}


void

rb_gc_impl_objspace_init(void *objspace_ptr)

{

    rb_objspace_t *objspace = objspace_ptr;


    gc_config_full_mark_set(TRUE);


    objspace->flags.measure_gc = true;

    malloc_limit = gc_params.malloc_limit_min;

    objspace->finalize_deferred_pjob = rb_postponed_job_preregister(0, gc_finalize_deferred, objspace);

    if (objspace->finalize_deferred_pjob == POSTPONED_JOB_HANDLE_INVALID) {

        rb_bug("Could not preregister postponed job for GC");

    }


    /* A standard RVALUE (RBasic + embedded VALUEs + debug overhead) must fit

     * in at least one pool.  In debug builds RVALUE_OVERHEAD can push this

     * beyond the 48-byte pool into the 64-byte pool, which is fine. */

    GC_ASSERT(rb_gc_impl_size_allocatable_p(sizeof(struct RBasic) + sizeof(VALUE[RBIMPL_RVALUE_EMBED_LEN_MAX])));


    for (int i = 0; i < HEAP_COUNT; i++) {

        rb_heap_t *heap = &heaps[i];


        heap->slot_size = pool_slot_sizes[i];


        ccan_list_head_init(&heap->pages);

    }


    init_size_to_heap_idx();


    rb_darray_make_without_gc(&objspace->heap_pages.sorted, 0);

    rb_darray_make_without_gc(&objspace->weak_references, 0);


#if defined(INIT_HEAP_PAGE_ALLOC_USE_MMAP)

    /* Need to determine if we can use mmap at runtime. */

    heap_page_alloc_use_mmap = INIT_HEAP_PAGE_ALLOC_USE_MMAP;

#endif

#if RGENGC_ESTIMATE_OLDMALLOC

    objspace->rgengc.oldmalloc_increase_limit = gc_params.oldmalloc_limit_min;

#endif

    gc_params.heap_init_bytes = GC_HEAP_INIT_BYTES;


    init_mark_stack(&objspace->mark_stack);


    objspace->profile.invoke_time = getrusage_time();

    finalizer_table = st_init_numtable();

}


void

rb_gc_impl_init(void)

{

    VALUE gc_constants = rb_hash_new();

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("DEBUG")), GC_DEBUG ? Qtrue : Qfalse);

    /* Minimum slot size that fits a standard RVALUE */

    size_t rvalue_pool = 0;

    for (size_t i = 0; i < HEAP_COUNT; i++) {

        if (pool_slot_sizes[i] >= RVALUE_SLOT_SIZE) { rvalue_pool = pool_slot_sizes[i]; break; }

    }

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("RVALUE_SIZE")), SIZET2NUM(rvalue_pool - RVALUE_OVERHEAD));

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("RBASIC_SIZE")), SIZET2NUM(sizeof(struct RBasic)));

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("RVALUE_OVERHEAD")), SIZET2NUM(RVALUE_OVERHEAD));

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("HEAP_PAGE_BITMAP_SIZE")), SIZET2NUM(HEAP_PAGE_BITMAP_SIZE));

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("HEAP_PAGE_SIZE")), SIZET2NUM(HEAP_PAGE_SIZE));

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("HEAP_COUNT")), LONG2FIX(HEAP_COUNT));

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("RVARGC_MAX_ALLOCATE_SIZE")), LONG2FIX(heap_slot_size(HEAP_COUNT - 1)));

    rb_hash_aset(gc_constants, ID2SYM(rb_intern("RVALUE_OLD_AGE")), LONG2FIX(RVALUE_OLD_AGE));

    if (RB_BUG_INSTEAD_OF_RB_MEMERROR+0) {

        rb_hash_aset(gc_constants, ID2SYM(rb_intern("RB_BUG_INSTEAD_OF_RB_MEMERROR")), Qtrue);

    }

    OBJ_FREEZE(gc_constants);

    /* Internal constants in the garbage collector. */

    rb_define_const(rb_mGC, "INTERNAL_CONSTANTS", gc_constants);


    if (GC_COMPACTION_SUPPORTED) {

        rb_define_singleton_method(rb_mGC, "compact", gc_compact, 0);

        rb_define_singleton_method(rb_mGC, "auto_compact", gc_get_auto_compact, 0);

        rb_define_singleton_method(rb_mGC, "auto_compact=", gc_set_auto_compact, 1);

        rb_define_singleton_method(rb_mGC, "latest_compact_info", gc_compact_stats, 0);

        rb_define_singleton_method(rb_mGC, "verify_compaction_references", gc_verify_compaction_references, -1);

    }

    else {

        rb_define_singleton_method(rb_mGC, "compact", rb_f_notimplement, 0);

        rb_define_singleton_method(rb_mGC, "auto_compact", rb_f_notimplement, 0);

        rb_define_singleton_method(rb_mGC, "auto_compact=", rb_f_notimplement, 1);

        rb_define_singleton_method(rb_mGC, "latest_compact_info", rb_f_notimplement, 0);

        rb_define_singleton_method(rb_mGC, "verify_compaction_references", rb_f_notimplement, -1);

    }


#if GC_DEBUG_STRESS_TO_CLASS

    rb_define_singleton_method(rb_mGC, "add_stress_to_class", rb_gcdebug_add_stress_to_class, -1);

    rb_define_singleton_method(rb_mGC, "remove_stress_to_class", rb_gcdebug_remove_stress_to_class, -1);

#endif


    /* internal methods */

    rb_define_singleton_method(rb_mGC, "verify_internal_consistency", gc_verify_internal_consistency_m, 0);


#if MALLOC_ALLOCATED_SIZE

    rb_define_singleton_method(rb_mGC, "malloc_allocated_size", gc_malloc_allocated_size, 0);

    rb_define_singleton_method(rb_mGC, "malloc_allocations", gc_malloc_allocations, 0);

#endif


    VALUE rb_mProfiler = rb_define_module_under(rb_mGC, "Profiler");

    rb_define_singleton_method(rb_mProfiler, "enabled?", gc_profile_enable_get, 0);

    rb_define_singleton_method(rb_mProfiler, "enable", gc_profile_enable, 0);

    rb_define_singleton_method(rb_mProfiler, "raw_data", gc_profile_record_get, 0);

    rb_define_singleton_method(rb_mProfiler, "disable", gc_profile_disable, 0);

    rb_define_singleton_method(rb_mProfiler, "clear", gc_profile_clear, 0);

    rb_define_singleton_method(rb_mProfiler, "result", gc_profile_result, 0);

    rb_define_singleton_method(rb_mProfiler, "report", gc_profile_report, -1);

    rb_define_singleton_method(rb_mProfiler, "total_time", gc_profile_total_time, 0);


    {

        VALUE opts;

        /* \GC build options */

        rb_define_const(rb_mGC, "OPTS", opts = rb_ary_new());

#define OPT(o) if (o) rb_ary_push(opts, rb_interned_str(#o, sizeof(#o) - 1))

        OPT(GC_DEBUG);

        OPT(USE_RGENGC);

        OPT(RGENGC_DEBUG);

        OPT(RGENGC_CHECK_MODE);

        OPT(RGENGC_PROFILE);

        OPT(RGENGC_ESTIMATE_OLDMALLOC);

        OPT(GC_PROFILE_MORE_DETAIL);

        OPT(GC_ENABLE_LAZY_SWEEP);

        OPT(CALC_EXACT_MALLOC_SIZE);

        OPT(MALLOC_ALLOCATED_SIZE);

        OPT(MALLOC_ALLOCATED_SIZE_CHECK);

        OPT(GC_PROFILE_DETAIL_MEMORY);

        OPT(GC_COMPACTION_SUPPORTED);

#undef OPT

        OBJ_FREEZE(opts);

    }

}

RBIMPL_ASSERT_OR_ASSUME
#define RBIMPL_ASSERT_OR_ASSUME(...)
This is either RUBY_ASSERT or RBIMPL_ASSUME, depending on RUBY_DEBUG.
Definition assert.h:311

RUBY_ASSERT
#define RUBY_ASSERT(...)
Asserts that the given expression is truthy if and only if RUBY_DEBUG is truthy.
Definition assert.h:219

atomic.h
Atomic operations.

RUBY_ATOMIC_VALUE_CAS
#define RUBY_ATOMIC_VALUE_CAS(var, oldval, newval)
Identical to RUBY_ATOMIC_CAS, except it expects its arguments are VALUE.
Definition atomic.h:406

RUBY_ATOMIC_SIZE_EXCHANGE
#define RUBY_ATOMIC_SIZE_EXCHANGE(var, val)
Identical to RUBY_ATOMIC_EXCHANGE, except it expects its arguments are size_t.
Definition atomic.h:270

RUBY_ATOMIC_SIZE_INC
#define RUBY_ATOMIC_SIZE_INC(var)
Identical to RUBY_ATOMIC_INC, except it expects its argument is size_t.
Definition atomic.h:246

RUBY_ATOMIC_SIZE_CAS
#define RUBY_ATOMIC_SIZE_CAS(var, oldval, newval)
Identical to RUBY_ATOMIC_CAS, except it expects its arguments are size_t.
Definition atomic.h:284

rb_atomic_t
std::atomic< unsigned > rb_atomic_t
Type that is eligible for atomic operations.
Definition atomic.h:69

RUBY_ATOMIC_SIZE_ADD
#define RUBY_ATOMIC_SIZE_ADD(var, val)
Identical to RUBY_ATOMIC_ADD, except it expects its arguments are size_t.
Definition atomic.h:297

RUBY_ATOMIC_VALUE_EXCHANGE
#define RUBY_ATOMIC_VALUE_EXCHANGE(var, val)
Identical to RUBY_ATOMIC_EXCHANGE, except it expects its arguments are VALUE.
Definition atomic.h:392

RUBY_ATOMIC_SET
#define RUBY_ATOMIC_SET(var, val)
Identical to RUBY_ATOMIC_EXCHANGE, except for the return type.
Definition atomic.h:185

RUBY_ATOMIC_EXCHANGE
#define RUBY_ATOMIC_EXCHANGE(var, val)
Atomically replaces the value pointed by var with val.
Definition atomic.h:152

rb_define_singleton_method
#define rb_define_singleton_method(klass, mid, func, arity)
Defines klass.mid.
Definition cxxanyargs.hpp:656

debug.h

rb_postponed_job_handle_t
unsigned int rb_postponed_job_handle_t
The type of a handle returned from rb_postponed_job_preregister and passed to rb_postponed_job_trigge...
Definition debug.h:703

rb_postponed_job_trigger
void rb_postponed_job_trigger(rb_postponed_job_handle_t h)
Triggers a pre-registered job registered with rb_postponed_job_preregister, scheduling it for executi...
Definition vm_trace.c:1916

rb_postponed_job_preregister
rb_postponed_job_handle_t rb_postponed_job_preregister(unsigned int flags, rb_postponed_job_func_t func, void *data)
Pre-registers a func in Ruby's postponed job preregistration table, returning an opaque handle which ...
Definition vm_trace.c:1882

RB_GNUC_EXTENSION_BLOCK
#define RB_GNUC_EXTENSION_BLOCK(x)
This is expanded to the passed token for non-GCC compilers.
Definition defines.h:91

RUBY_INTERNAL_EVENT_GC_EXIT
#define RUBY_INTERNAL_EVENT_GC_EXIT
gc_exit() is called.
Definition event.h:99

RUBY_INTERNAL_EVENT_GC_ENTER
#define RUBY_INTERNAL_EVENT_GC_ENTER
gc_enter() is called.
Definition event.h:98

RUBY_INTERNAL_EVENT_GC_END_SWEEP
#define RUBY_INTERNAL_EVENT_GC_END_SWEEP
GC ended sweep phase.
Definition event.h:97

RUBY_INTERNAL_EVENT_GC_END_MARK
#define RUBY_INTERNAL_EVENT_GC_END_MARK
GC ended mark phase.
Definition event.h:96

RUBY_INTERNAL_EVENT_OBJSPACE_MASK
#define RUBY_INTERNAL_EVENT_OBJSPACE_MASK
Bitmask of GC events.
Definition event.h:100

RUBY_INTERNAL_EVENT_FREEOBJ
#define RUBY_INTERNAL_EVENT_FREEOBJ
Object swept.
Definition event.h:94

RUBY_INTERNAL_EVENT_GC_START
#define RUBY_INTERNAL_EVENT_GC_START
GC started.
Definition event.h:95

rb_event_flag_t
uint32_t rb_event_flag_t
Represents event(s).
Definition event.h:108

RB_FL_TEST
static VALUE RB_FL_TEST(VALUE obj, VALUE flags)
Tests if the given flag(s) are set or not.
Definition fl_type.h:430

RB_FL_TEST_RAW
static VALUE RB_FL_TEST_RAW(VALUE obj, VALUE flags)
This is an implementation detail of RB_FL_TEST().
Definition fl_type.h:404

RB_FL_SET_RAW
static void RB_FL_SET_RAW(VALUE obj, VALUE flags)
This is an implementation detail of RB_FL_SET().
Definition fl_type.h:541

RB_FL_UNSET_RAW
static void RB_FL_UNSET_RAW(VALUE obj, VALUE flags)
This is an implementation detail of RB_FL_UNSET().
Definition fl_type.h:601

RUBY_FL_PROMOTED
@ RUBY_FL_PROMOTED
Ruby objects are "generational".
Definition fl_type.h:205

RUBY_FL_WEAK_REFERENCE
@ RUBY_FL_WEAK_REFERENCE
This object weakly refers to other objects.
Definition fl_type.h:260

rb_define_module_under
VALUE rb_define_module_under(VALUE outer, const char *name)
Defines a module under the namespace of outer.
Definition class.c:1662

rb_scan_args_kw
int rb_scan_args_kw(int kw_flag, int argc, const VALUE *argv, const char *fmt,...)
Identical to rb_scan_args(), except it also accepts kw_splat.
Definition class.c:3196

rb_keyword_given_p
int rb_keyword_given_p(void)
Determines if the current method is given a keyword argument.
Definition eval.c:1031

rb_get_kwargs
int rb_get_kwargs(VALUE keyword_hash, const ID *table, int required, int optional, VALUE *values)
Keyword argument deconstructor.
Definition class.c:2972

T_COMPLEX
#define T_COMPLEX
Old name of RUBY_T_COMPLEX.
Definition value_type.h:59

T_FILE
#define T_FILE
Old name of RUBY_T_FILE.
Definition value_type.h:62

T_STRING
#define T_STRING
Old name of RUBY_T_STRING.
Definition value_type.h:78

xfree
#define xfree
Old name of ruby_xfree.
Definition xmalloc.h:58

T_MASK
#define T_MASK
Old name of RUBY_T_MASK.
Definition value_type.h:68

Qundef
#define Qundef
Old name of RUBY_Qundef.
Definition special_consts.h:62

INT2FIX
#define INT2FIX
Old name of RB_INT2FIX.
Definition long.h:48

OBJ_FROZEN
#define OBJ_FROZEN
Old name of RB_OBJ_FROZEN.
Definition fl_type.h:133

T_NIL
#define T_NIL
Old name of RUBY_T_NIL.
Definition value_type.h:72

T_FLOAT
#define T_FLOAT
Old name of RUBY_T_FLOAT.
Definition value_type.h:64

T_IMEMO
#define T_IMEMO
Old name of RUBY_T_IMEMO.
Definition value_type.h:67

ID2SYM
#define ID2SYM
Old name of RB_ID2SYM.
Definition symbol.h:44

T_BIGNUM
#define T_BIGNUM
Old name of RUBY_T_BIGNUM.
Definition value_type.h:57

SPECIAL_CONST_P
#define SPECIAL_CONST_P
Old name of RB_SPECIAL_CONST_P.
Definition special_consts.h:56

T_STRUCT
#define T_STRUCT
Old name of RUBY_T_STRUCT.
Definition value_type.h:79

OBJ_FREEZE
#define OBJ_FREEZE
Old name of RB_OBJ_FREEZE.
Definition fl_type.h:131

T_FIXNUM
#define T_FIXNUM
Old name of RUBY_T_FIXNUM.
Definition value_type.h:63

SYM2ID
#define SYM2ID
Old name of RB_SYM2ID.
Definition symbol.h:45

T_DATA
#define T_DATA
Old name of RUBY_T_DATA.
Definition value_type.h:60

FL_SHAREABLE
#define FL_SHAREABLE
Old name of RUBY_FL_SHAREABLE.
Definition fl_type.h:62

T_NONE
#define T_NONE
Old name of RUBY_T_NONE.
Definition value_type.h:74

T_NODE
#define T_NODE
Old name of RUBY_T_NODE.
Definition value_type.h:73

SIZET2NUM
#define SIZET2NUM
Old name of RB_SIZE2NUM.
Definition size_t.h:62

xmalloc
#define xmalloc
Old name of ruby_xmalloc.
Definition xmalloc.h:53

LONG2FIX
#define LONG2FIX
Old name of RB_INT2FIX.
Definition long.h:49

FIX2INT
#define FIX2INT
Old name of RB_FIX2INT.
Definition int.h:41

FL_FINALIZE
#define FL_FINALIZE
Old name of RUBY_FL_FINALIZE.
Definition fl_type.h:61

T_MODULE
#define T_MODULE
Old name of RUBY_T_MODULE.
Definition value_type.h:70

T_TRUE
#define T_TRUE
Old name of RUBY_T_TRUE.
Definition value_type.h:81

T_RATIONAL
#define T_RATIONAL
Old name of RUBY_T_RATIONAL.
Definition value_type.h:76

T_ICLASS
#define T_ICLASS
Old name of RUBY_T_ICLASS.
Definition value_type.h:66

T_HASH
#define T_HASH
Old name of RUBY_T_HASH.
Definition value_type.h:65

ALLOC_N
#define ALLOC_N
Old name of RB_ALLOC_N.
Definition memory.h:399

FL_TEST_RAW
#define FL_TEST_RAW
Old name of RB_FL_TEST_RAW.
Definition fl_type.h:128

FL_SET
#define FL_SET
Old name of RB_FL_SET.
Definition fl_type.h:125

rb_ary_new3
#define rb_ary_new3
Old name of rb_ary_new_from_args.
Definition array.h:658

T_FALSE
#define T_FALSE
Old name of RUBY_T_FALSE.
Definition value_type.h:61

ULL2NUM
#define ULL2NUM
Old name of RB_ULL2NUM.
Definition long_long.h:31

T_UNDEF
#define T_UNDEF
Old name of RUBY_T_UNDEF.
Definition value_type.h:82

Qtrue
#define Qtrue
Old name of RUBY_Qtrue.
Definition special_consts.h:61

T_ZOMBIE
#define T_ZOMBIE
Old name of RUBY_T_ZOMBIE.
Definition value_type.h:83

Qnil
#define Qnil
Old name of RUBY_Qnil.
Definition special_consts.h:60

Qfalse
#define Qfalse
Old name of RUBY_Qfalse.
Definition special_consts.h:59

T_ARRAY
#define T_ARRAY
Old name of RUBY_T_ARRAY.
Definition value_type.h:56

T_OBJECT
#define T_OBJECT
Old name of RUBY_T_OBJECT.
Definition value_type.h:75

NIL_P
#define NIL_P
Old name of RB_NIL_P.
Definition special_consts.h:55

FL_WB_PROTECTED
#define FL_WB_PROTECTED
Old name of RUBY_FL_WB_PROTECTED.
Definition fl_type.h:59

T_SYMBOL
#define T_SYMBOL
Old name of RUBY_T_SYMBOL.
Definition value_type.h:80

DBL2NUM
#define DBL2NUM
Old name of rb_float_new.
Definition double.h:29

T_MATCH
#define T_MATCH
Old name of RUBY_T_MATCH.
Definition value_type.h:69

T_CLASS
#define T_CLASS
Old name of RUBY_T_CLASS.
Definition value_type.h:58

BUILTIN_TYPE
#define BUILTIN_TYPE
Old name of RB_BUILTIN_TYPE.
Definition value_type.h:85

T_MOVED
#define T_MOVED
Old name of RUBY_T_MOVED.
Definition value_type.h:71

FL_TEST
#define FL_TEST
Old name of RB_FL_TEST.
Definition fl_type.h:127

FL_UNSET
#define FL_UNSET
Old name of RB_FL_UNSET.
Definition fl_type.h:129

FIXNUM_P
#define FIXNUM_P
Old name of RB_FIXNUM_P.
Definition special_consts.h:53

FL_SET_RAW
#define FL_SET_RAW
Old name of RB_FL_SET_RAW.
Definition fl_type.h:126

SYMBOL_P
#define SYMBOL_P
Old name of RB_SYMBOL_P.
Definition value_type.h:88

T_REGEXP
#define T_REGEXP
Old name of RUBY_T_REGEXP.
Definition value_type.h:77

ruby_verbose
#define ruby_verbose
This variable controls whether the interpreter is in debug mode.
Definition error.h:476

rb_eRuntimeError
VALUE rb_eRuntimeError
RuntimeError exception.
Definition error.c:1425

rb_warn
void rb_warn(const char *fmt,...)
Identical to rb_warning(), except it reports unless $VERBOSE is nil.
Definition error.c:467

rb_obj_hide
VALUE rb_obj_hide(VALUE obj)
Make the object invisible from Ruby code.
Definition object.c:95

rb_mGC
VALUE rb_mGC
GC module.
Definition gc.c:429

rb_equal
VALUE rb_equal(VALUE lhs, VALUE rhs)
This function is an optimised version of calling #==.
Definition object.c:141

rb_stdout
VALUE rb_stdout
STDOUT constant.
Definition io.c:201

string.h
Routines to manipulate encodings of strings.

RB_OBJ_PROMOTED_RAW
static bool RB_OBJ_PROMOTED_RAW(VALUE obj)
This is the implementation of RB_OBJ_PROMOTED().
Definition gc.h:706

USE_RGENGC
#define USE_RGENGC
Definition gc.h:428

rb_ary_dup
VALUE rb_ary_dup(VALUE ary)
Duplicates an array.

rb_ary_new
VALUE rb_ary_new(void)
Allocates a new, empty array.

rb_ary_push
VALUE rb_ary_push(VALUE ary, VALUE elem)
Special case of rb_ary_cat() that it adds only one element.

rb_check_arity
static int rb_check_arity(int argc, int min, int max)
Ensures that the passed integer is in the passed range.
Definition error.h:284

rb_str_buf_append
VALUE rb_str_buf_append(VALUE dst, VALUE src)
Identical to rb_str_cat_cstr(), except it takes Ruby's string instead of C's.
Definition string.c:3800

rb_str_buf_new
VALUE rb_str_buf_new(long capa)
Allocates a "string  buffer".
Definition string.c:1716

rb_str_new_cstr
#define rb_str_new_cstr(str)
Identical to rb_str_new, except it assumes the passed pointer is a pointer to a C string.
Definition string.h:1515

rb_sourcefile
const char * rb_sourcefile(void)
Resembles __FILE__.
Definition vm.c:2079

rb_f_notimplement
VALUE rb_f_notimplement(int argc, const VALUE *argv, VALUE obj, VALUE marker)
Raises rb_eNotImpError.
Definition vm_method.c:859

rb_sourceline
int rb_sourceline(void)
Resembles __LINE__.
Definition vm.c:2093

RB_SYM2ID
#define RB_SYM2ID
Just another name of rb_sym2id.
Definition symbol.h:43

rb_sym2id
ID rb_sym2id(VALUE obj)
Converts an instance of rb_cSymbol into an ID.
Definition symbol.c:974

capa
int capa
Designed capacity of the buffer.
Definition io.h:11

len
int len
Length of the buffer.
Definition io.h:8

thread.h

rb_thread_call_with_gvl
void * rb_thread_call_with_gvl(void *(*func)(void *), void *data1)
(Re-)acquires the GVL.
Definition thread.c:2063

util.h

strtod
#define strtod(s, e)
Just another name of ruby_strtod.
Definition util.h:223

ruby_qsort
void ruby_qsort(void *, const size_t, const size_t, int(*)(const void *, const void *, void *), void *)
Reentrant implementation of quick sort.

vm.h

MEMZERO
#define MEMZERO(p, type, n)
Handy macro to erase a region of memory.
Definition memory.h:360

RB_GC_GUARD
#define RB_GC_GUARD(v)
Prevents premature destruction of local objects.
Definition memory.h:167

ruby::backward::cxxanyargs::type
VALUE type(ANYARGS)
ANYARGS-ed function type.
Definition cxxanyargs.hpp:56

ruby::backward::cxxanyargs::rb_hash_foreach
void rb_hash_foreach(VALUE q, int_type *w, VALUE e)
Iteration over the given hash.
Definition cxxanyargs.hpp:455

ruby::backward::cxxanyargs::rb_ensure
VALUE rb_ensure(type *q, VALUE w, type *e, VALUE r)
An equivalent of ensure clause.
Definition cxxanyargs.hpp:283

RARRAY_LEN
#define RARRAY_LEN
Just another name of rb_array_len.
Definition rarray.h:51

RARRAY_ASET
static void RARRAY_ASET(VALUE ary, long i, VALUE v)
Assigns an object in an array.
Definition rarray.h:386

RARRAY_AREF
#define RARRAY_AREF(a, i)
Definition rarray.h:403

RBASIC
#define RBASIC(obj)
Convenient casting macro.
Definition rbasic.h:40

ruby.h

errno
#define errno
Ractor-aware version of errno.
Definition ruby.h:388

ruby_native_thread_p
int ruby_native_thread_p(void)
Queries if the thread which calls this function is a ruby's thread.
Definition thread.c:5815

RB_SPECIAL_CONST_P
static bool RB_SPECIAL_CONST_P(VALUE obj)
Checks if the given object is of enum ruby_special_consts.
Definition special_consts.h:327

RTEST
#define RTEST
This is an old name of RB_TEST.
Definition special_consts.h:51

_
#define _(args)
This was a transition path from K&R to ANSI.
Definition stdarg.h:35

__sFILE
Definition vsnprintf.c:160

RBasic
Ruby object's base components.
Definition rbasic.h:69

RMoved
Definition default.c:437

RZombie
Definition default.c:1102

each_obj_data
Definition default.c:2674

free_slot
Definition default.c:803

gc_profile_record
Definition default.c:395

gc_sweep_context
Definition default.c:3515

heap_page_body
Definition default.c:456

heap_page_header
Definition default.c:452

heap_page
Definition default.c:808

malloc_obj_info
Definition default.c:8198

mark_stack
Definition default.c:469

objspace_and_reason
Definition default.c:6587

objspace
Definition mmtk.c:19

ractor_newobj_cache
Definition default.c:226

ractor_newobj_heap_cache
Definition default.c:220

rb_gc_object_metadata_entry
Definition gc_impl.h:15

rb_gc_object_metadata_names
Definition default.c:6245

rb_heap_struct
Definition default.c:480

rb_objspace::rb_gc_config
Definition default.c:536

rb_objspace
Definition default.c:520

ruby_gc_params_t
Definition default.c:231

st_table
Definition st.h:79

stack_chunk
Definition default.c:464

timespec
Definition missing.h:74

timeval
Definition missing.h:63

verify_internal_consistency_struct
Definition default.c:4973

__attribute__
Definition vm_insnhelper.c:2404

ID
uintptr_t ID
Type that represents a Ruby identifier such as a variable name.
Definition value.h:52

VALUE
uintptr_t VALUE
Type that represents a Ruby object.
Definition value.h:40

RB_BUILTIN_TYPE
static enum ruby_value_type RB_BUILTIN_TYPE(VALUE obj)
Queries the type of the object.
Definition value_type.h:182

RB_TYPE_P
static bool RB_TYPE_P(VALUE obj, enum ruby_value_type t)
Queries if the given object is of given type.
Definition value_type.h:376

ruby_value_type
ruby_value_type
C-level type of an object.
Definition value_type.h:113

RUBY_T_SYMBOL
@ RUBY_T_SYMBOL
Definition value_type.h:135

RUBY_T_MATCH
@ RUBY_T_MATCH
Definition value_type.h:128

RUBY_T_MODULE
@ RUBY_T_MODULE
Definition value_type.h:118

RUBY_T_ICLASS
@ RUBY_T_ICLASS
Hidden classes known as IClasses.
Definition value_type.h:141

RUBY_T_MOVED
@ RUBY_T_MOVED
Definition value_type.h:143

RUBY_T_FIXNUM
@ RUBY_T_FIXNUM
Integers formerly known as Fixnums.
Definition value_type.h:136

RUBY_T_IMEMO
@ RUBY_T_IMEMO
Definition value_type.h:139

RUBY_T_NODE
@ RUBY_T_NODE
Definition value_type.h:140

RUBY_T_OBJECT
@ RUBY_T_OBJECT
Definition value_type.h:116

RUBY_T_DATA
@ RUBY_T_DATA
Definition value_type.h:127

RUBY_T_FALSE
@ RUBY_T_FALSE
Definition value_type.h:134

RUBY_T_UNDEF
@ RUBY_T_UNDEF
Definition value_type.h:137

RUBY_T_COMPLEX
@ RUBY_T_COMPLEX
Definition value_type.h:129

RUBY_T_STRING
@ RUBY_T_STRING
Definition value_type.h:120

RUBY_T_HASH
@ RUBY_T_HASH
Definition value_type.h:123

RUBY_T_NIL
@ RUBY_T_NIL
Definition value_type.h:132

RUBY_T_CLASS
@ RUBY_T_CLASS
Definition value_type.h:117

RUBY_T_ARRAY
@ RUBY_T_ARRAY
Definition value_type.h:122

RUBY_T_MASK
@ RUBY_T_MASK
Bitmask of ruby_value_type.
Definition value_type.h:145

RUBY_T_RATIONAL
@ RUBY_T_RATIONAL
Definition value_type.h:130

RUBY_T_ZOMBIE
@ RUBY_T_ZOMBIE
Definition value_type.h:142

RUBY_T_BIGNUM
@ RUBY_T_BIGNUM
Definition value_type.h:125

RUBY_T_TRUE
@ RUBY_T_TRUE
Definition value_type.h:133

RUBY_T_FLOAT
@ RUBY_T_FLOAT
Definition value_type.h:119

RUBY_T_STRUCT
@ RUBY_T_STRUCT
Definition value_type.h:124

RUBY_T_NONE
@ RUBY_T_NONE
Non-object (swept etc.)
Definition value_type.h:114

RUBY_T_REGEXP
@ RUBY_T_REGEXP
Definition value_type.h:121

RUBY_T_FILE
@ RUBY_T_FILE
Definition value_type.h:126