ruby/ractor.c

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// Ractor implementation
#include "ruby/ruby.h"
#include "ruby/thread.h"
#include "ruby/ractor.h"
#include "ruby/thread_native.h"
#include "vm_core.h"
#include "eval_intern.h"
#include "vm_sync.h"
#include "ractor_core.h"
#include "internal/complex.h"
#include "internal/error.h"
#include "internal/gc.h"
#include "internal/hash.h"
#include "internal/rational.h"
#include "internal/struct.h"
#include "internal/thread.h"
#include "variable.h"
#include "yjit.h"
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#include "rjit.h"
VALUE rb_cRactor;
static VALUE rb_cRactorSelector;
VALUE rb_eRactorUnsafeError;
VALUE rb_eRactorIsolationError;
static VALUE rb_eRactorError;
static VALUE rb_eRactorRemoteError;
static VALUE rb_eRactorMovedError;
static VALUE rb_eRactorClosedError;
static VALUE rb_cRactorMovedObject;
static void vm_ractor_blocking_cnt_inc(rb_vm_t *vm, rb_ractor_t *r, const char *file, int line);
// Ractor locking
static void
ASSERT_ractor_unlocking(rb_ractor_t *r)
{
#if RACTOR_CHECK_MODE > 0
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// GET_EC is NULL in an RJIT worker
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if (rb_current_execution_context(false) != NULL && r->sync.locked_by == rb_ractor_self(GET_RACTOR())) {
rb_bug("recursive ractor locking");
}
#endif
}
static void
ASSERT_ractor_locking(rb_ractor_t *r)
{
#if RACTOR_CHECK_MODE > 0
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// GET_EC is NULL in an RJIT worker
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if (rb_current_execution_context(false) != NULL && r->sync.locked_by != rb_ractor_self(GET_RACTOR())) {
rp(r->sync.locked_by);
rb_bug("ractor lock is not acquired.");
}
#endif
}
static void
ractor_lock(rb_ractor_t *r, const char *file, int line)
{
RUBY_DEBUG_LOG2(file, line, "locking r:%u%s", r->pub.id, rb_current_ractor_raw(false) == r ? " (self)" : "");
ASSERT_ractor_unlocking(r);
rb_native_mutex_lock(&r->sync.lock);
#if RACTOR_CHECK_MODE > 0
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if (rb_current_execution_context(false) != NULL) { // GET_EC is NULL in an RJIT worker
rb_ractor_t *cr = rb_current_ractor_raw(false);
r->sync.locked_by = cr ? rb_ractor_self(cr) : Qundef;
}
#endif
RUBY_DEBUG_LOG2(file, line, "locked r:%u%s", r->pub.id, rb_current_ractor_raw(false) == r ? " (self)" : "");
}
static void
ractor_lock_self(rb_ractor_t *cr, const char *file, int line)
{
VM_ASSERT(cr == GET_RACTOR());
#if RACTOR_CHECK_MODE > 0
VM_ASSERT(cr->sync.locked_by != cr->pub.self);
#endif
ractor_lock(cr, file, line);
}
static void
ractor_unlock(rb_ractor_t *r, const char *file, int line)
{
ASSERT_ractor_locking(r);
#if RACTOR_CHECK_MODE > 0
r->sync.locked_by = Qnil;
#endif
rb_native_mutex_unlock(&r->sync.lock);
RUBY_DEBUG_LOG2(file, line, "r:%u%s", r->pub.id, rb_current_ractor_raw(false) == r ? " (self)" : "");
}
static void
ractor_unlock_self(rb_ractor_t *cr, const char *file, int line)
{
VM_ASSERT(cr == GET_RACTOR());
#if RACTOR_CHECK_MODE > 0
VM_ASSERT(cr->sync.locked_by == cr->pub.self);
#endif
ractor_unlock(cr, file, line);
}
#define RACTOR_LOCK(r) ractor_lock(r, __FILE__, __LINE__)
#define RACTOR_UNLOCK(r) ractor_unlock(r, __FILE__, __LINE__)
#define RACTOR_LOCK_SELF(r) ractor_lock_self(r, __FILE__, __LINE__)
#define RACTOR_UNLOCK_SELF(r) ractor_unlock_self(r, __FILE__, __LINE__)
void
rb_ractor_lock_self(rb_ractor_t *r)
{
RACTOR_LOCK_SELF(r);
}
void
rb_ractor_unlock_self(rb_ractor_t *r)
{
RACTOR_UNLOCK_SELF(r);
}
// Ractor status
static const char *
ractor_status_str(enum ractor_status status)
{
switch (status) {
case ractor_created: return "created";
case ractor_running: return "running";
case ractor_blocking: return "blocking";
case ractor_terminated: return "terminated";
}
rb_bug("unreachable");
}
static void
ractor_status_set(rb_ractor_t *r, enum ractor_status status)
{
RUBY_DEBUG_LOG("r:%u [%s]->[%s]", r->pub.id, ractor_status_str(r->status_), ractor_status_str(status));
// check 1
if (r->status_ != ractor_created) {
VM_ASSERT(r == GET_RACTOR()); // only self-modification is allowed.
ASSERT_vm_locking();
}
// check2: transition check. assume it will be vanished on non-debug build.
switch (r->status_) {
case ractor_created:
VM_ASSERT(status == ractor_blocking);
break;
case ractor_running:
VM_ASSERT(status == ractor_blocking||
status == ractor_terminated);
break;
case ractor_blocking:
VM_ASSERT(status == ractor_running);
break;
case ractor_terminated:
rb_bug("unreachable");
break;
}
r->status_ = status;
}
static bool
ractor_status_p(rb_ractor_t *r, enum ractor_status status)
{
return rb_ractor_status_p(r, status);
}
// Ractor data/mark/free
static struct rb_ractor_basket *ractor_queue_at(rb_ractor_t *r, struct rb_ractor_queue *rq, int i);
static void ractor_local_storage_mark(rb_ractor_t *r);
static void ractor_local_storage_free(rb_ractor_t *r);
static void
ractor_queue_mark(struct rb_ractor_queue *rq)
{
for (int i=0; i<rq->cnt; i++) {
struct rb_ractor_basket *b = ractor_queue_at(NULL, rq, i);
rb_gc_mark(b->sender);
switch (b->type.e) {
case basket_type_yielding:
case basket_type_take_basket:
case basket_type_deleted:
case basket_type_reserved:
// ignore
break;
default:
rb_gc_mark(b->p.send.v);
}
}
}
static void
ractor_mark(void *ptr)
{
rb_ractor_t *r = (rb_ractor_t *)ptr;
ractor_queue_mark(&r->sync.recv_queue);
ractor_queue_mark(&r->sync.takers_queue);
rb_gc_mark(r->receiving_mutex);
rb_gc_mark(r->loc);
rb_gc_mark(r->name);
rb_gc_mark(r->r_stdin);
rb_gc_mark(r->r_stdout);
rb_gc_mark(r->r_stderr);
rb_hook_list_mark(&r->pub.hooks);
if (r->threads.cnt > 0) {
rb_thread_t *th = 0;
ccan_list_for_each(&r->threads.set, th, lt_node) {
VM_ASSERT(th != NULL);
rb_gc_mark(th->self);
}
}
ractor_local_storage_mark(r);
}
static void
ractor_queue_free(struct rb_ractor_queue *rq)
{
free(rq->baskets);
}
static void
ractor_free(void *ptr)
{
rb_ractor_t *r = (rb_ractor_t *)ptr;
RUBY_DEBUG_LOG("free r:%d", rb_ractor_id(r));
rb_native_mutex_destroy(&r->sync.lock);
#ifdef RUBY_THREAD_WIN32_H
rb_native_cond_destroy(&r->sync.cond);
#endif
ractor_queue_free(&r->sync.recv_queue);
ractor_queue_free(&r->sync.takers_queue);
ractor_local_storage_free(r);
rb_hook_list_free(&r->pub.hooks);
ruby_xfree(r);
}
static size_t
ractor_queue_memsize(const struct rb_ractor_queue *rq)
{
return sizeof(struct rb_ractor_basket) * rq->size;
}
static size_t
ractor_memsize(const void *ptr)
{
rb_ractor_t *r = (rb_ractor_t *)ptr;
// TODO: more correct?
return sizeof(rb_ractor_t) +
ractor_queue_memsize(&r->sync.recv_queue) +
ractor_queue_memsize(&r->sync.takers_queue);
}
static const rb_data_type_t ractor_data_type = {
"ractor",
{
ractor_mark,
ractor_free,
ractor_memsize,
NULL, // update
},
0, 0, RUBY_TYPED_FREE_IMMEDIATELY /* | RUBY_TYPED_WB_PROTECTED */
};
bool
rb_ractor_p(VALUE gv)
{
if (rb_typeddata_is_kind_of(gv, &ractor_data_type)) {
return true;
}
else {
return false;
}
}
static inline rb_ractor_t *
RACTOR_PTR(VALUE self)
{
VM_ASSERT(rb_ractor_p(self));
rb_ractor_t *r = DATA_PTR(self);
return r;
}
static rb_atomic_t ractor_last_id;
#if RACTOR_CHECK_MODE > 0
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uint32_t
rb_ractor_current_id(void)
{
if (GET_THREAD()->ractor == NULL) {
return 1; // main ractor
}
else {
return rb_ractor_id(GET_RACTOR());
}
}
#endif
// Ractor queue
static void
ractor_queue_setup(struct rb_ractor_queue *rq)
{
rq->size = 2;
rq->cnt = 0;
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rq->start = 0;
rq->baskets = malloc(sizeof(struct rb_ractor_basket) * rq->size);
}
static struct rb_ractor_basket *
ractor_queue_head(rb_ractor_t *r, struct rb_ractor_queue *rq)
{
if (r != NULL) ASSERT_ractor_locking(r);
return &rq->baskets[rq->start];
}
static struct rb_ractor_basket *
ractor_queue_at(rb_ractor_t *r, struct rb_ractor_queue *rq, int i)
{
if (r != NULL) ASSERT_ractor_locking(r);
return &rq->baskets[(rq->start + i) % rq->size];
}
static void
ractor_queue_advance(rb_ractor_t *r, struct rb_ractor_queue *rq)
{
ASSERT_ractor_locking(r);
if (rq->reserved_cnt == 0) {
rq->cnt--;
rq->start = (rq->start + 1) % rq->size;
rq->serial++;
}
else {
ractor_queue_at(r, rq, 0)->type.e = basket_type_deleted;
}
}
static bool
ractor_queue_skip_p(rb_ractor_t *r, struct rb_ractor_queue *rq, int i)
{
struct rb_ractor_basket *b = ractor_queue_at(r, rq, i);
return basket_type_p(b, basket_type_deleted) ||
basket_type_p(b, basket_type_reserved);
}
static void
ractor_queue_compact(rb_ractor_t *r, struct rb_ractor_queue *rq)
{
ASSERT_ractor_locking(r);
while (rq->cnt > 0 && basket_type_p(ractor_queue_at(r, rq, 0), basket_type_deleted)) {
ractor_queue_advance(r, rq);
}
}
static bool
ractor_queue_empty_p(rb_ractor_t *r, struct rb_ractor_queue *rq)
{
ASSERT_ractor_locking(r);
if (rq->cnt == 0) {
return true;
}
ractor_queue_compact(r, rq);
for (int i=0; i<rq->cnt; i++) {
if (!ractor_queue_skip_p(r, rq, i)) {
return false;
}
}
return true;
}
static bool
ractor_queue_deq(rb_ractor_t *r, struct rb_ractor_queue *rq, struct rb_ractor_basket *basket)
{
ASSERT_ractor_locking(r);
for (int i=0; i<rq->cnt; i++) {
if (!ractor_queue_skip_p(r, rq, i)) {
struct rb_ractor_basket *b = ractor_queue_at(r, rq, i);
*basket = *b;
// remove from queue
b->type.e = basket_type_deleted;
ractor_queue_compact(r, rq);
return true;
}
}
return false;
}
static void
ractor_queue_enq(rb_ractor_t *r, struct rb_ractor_queue *rq, struct rb_ractor_basket *basket)
{
ASSERT_ractor_locking(r);
if (rq->size <= rq->cnt) {
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rq->baskets = realloc(rq->baskets, sizeof(struct rb_ractor_basket) * rq->size * 2);
for (int i=rq->size - rq->start; i<rq->cnt; i++) {
rq->baskets[i + rq->start] = rq->baskets[i + rq->start - rq->size];
}
rq->size *= 2;
}
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rq->baskets[(rq->start + rq->cnt++) % rq->size] = *basket;
// fprintf(stderr, "%s %p->cnt:%d\n", RUBY_FUNCTION_NAME_STRING, (void *)rq, rq->cnt);
}
static void
ractor_queue_delete(rb_ractor_t *r, struct rb_ractor_queue *rq, struct rb_ractor_basket *basket)
{
basket->type.e = basket_type_deleted;
}
// Ractor basket
static VALUE ractor_reset_belonging(VALUE obj); // in this file
static VALUE
ractor_basket_value(struct rb_ractor_basket *b)
{
switch (b->type.e) {
case basket_type_ref:
break;
case basket_type_copy:
case basket_type_move:
case basket_type_will:
b->type.e = basket_type_ref;
b->p.send.v = ractor_reset_belonging(b->p.send.v);
break;
default:
rb_bug("unreachable");
}
return b->p.send.v;
}
static VALUE
ractor_basket_accept(struct rb_ractor_basket *b)
{
VALUE v = ractor_basket_value(b);
if (b->p.send.exception) {
VALUE cause = v;
VALUE err = rb_exc_new_cstr(rb_eRactorRemoteError, "thrown by remote Ractor.");
rb_ivar_set(err, rb_intern("@ractor"), b->sender);
rb_ec_setup_exception(NULL, err, cause);
rb_exc_raise(err);
}
return v;
}
// Ractor synchronizations
#if USE_RUBY_DEBUG_LOG
static const char *
wait_status_str(enum rb_ractor_wait_status wait_status)
{
switch ((int)wait_status) {
case wait_none: return "none";
case wait_receiving: return "receiving";
case wait_taking: return "taking";
case wait_yielding: return "yielding";
case wait_receiving|wait_taking: return "receiving|taking";
case wait_receiving|wait_yielding: return "receiving|yielding";
case wait_taking|wait_yielding: return "taking|yielding";
case wait_receiving|wait_taking|wait_yielding: return "receiving|taking|yielding";
}
rb_bug("unreachable");
}
static const char *
wakeup_status_str(enum rb_ractor_wakeup_status wakeup_status)
{
switch (wakeup_status) {
case wakeup_none: return "none";
case wakeup_by_send: return "by_send";
case wakeup_by_yield: return "by_yield";
case wakeup_by_take: return "by_take";
case wakeup_by_close: return "by_close";
case wakeup_by_interrupt: return "by_interrupt";
case wakeup_by_retry: return "by_retry";
}
rb_bug("unreachable");
}
static const char *
basket_type_name(enum rb_ractor_basket_type type)
{
switch (type) {
case basket_type_none: return "none";
case basket_type_ref: return "ref";
case basket_type_copy: return "copy";
case basket_type_move: return "move";
case basket_type_will: return "will";
case basket_type_deleted: return "deleted";
case basket_type_reserved: return "reserved";
case basket_type_take_basket: return "take_basket";
case basket_type_yielding: return "yielding";
}
VM_ASSERT(0);
return NULL;
}
#endif // USE_RUBY_DEBUG_LOG
static bool
ractor_sleeping_by(const rb_ractor_t *r, enum rb_ractor_wait_status wait_status)
{
return (r->sync.wait.status & wait_status) && r->sync.wait.wakeup_status == wakeup_none;
}
#ifdef RUBY_THREAD_PTHREAD_H
// thread_*.c
void rb_ractor_sched_wakeup(rb_ractor_t *r);
#else
static void
rb_ractor_sched_wakeup(rb_ractor_t *r)
{
rb_native_cond_broadcast(&r->sync.cond);
}
#endif
static bool
ractor_wakeup(rb_ractor_t *r, enum rb_ractor_wait_status wait_status, enum rb_ractor_wakeup_status wakeup_status)
{
ASSERT_ractor_locking(r);
RUBY_DEBUG_LOG("r:%u wait_by:%s -> wait:%s wakeup:%s",
rb_ractor_id(r),
wait_status_str(r->sync.wait.status),
wait_status_str(wait_status),
wakeup_status_str(wakeup_status));
if (ractor_sleeping_by(r, wait_status)) {
r->sync.wait.wakeup_status = wakeup_status;
rb_ractor_sched_wakeup(r);
return true;
}
else {
return false;
}
}
static void
ractor_sleep_interrupt(void *ptr)
{
rb_ractor_t *r = ptr;
RACTOR_LOCK(r);
{
ractor_wakeup(r, wait_receiving | wait_taking | wait_yielding, wakeup_by_interrupt);
}
RACTOR_UNLOCK(r);
}
typedef void (*ractor_sleep_cleanup_function)(rb_ractor_t *cr, void *p);
static void
ractor_check_ints(rb_execution_context_t *ec, rb_ractor_t *cr, ractor_sleep_cleanup_function cf_func, void *cf_data)
{
if (cr->sync.wait.status != wait_none) {
enum rb_ractor_wait_status prev_wait_status = cr->sync.wait.status;
cr->sync.wait.status = wait_none;
cr->sync.wait.wakeup_status = wakeup_by_interrupt;
RACTOR_UNLOCK(cr);
{
if (cf_func) {
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enum ruby_tag_type state;
EC_PUSH_TAG(ec);
if ((state = EC_EXEC_TAG()) == TAG_NONE) {
rb_thread_check_ints();
}
EC_POP_TAG();
if (state) {
(*cf_func)(cr, cf_data);
EC_JUMP_TAG(ec, state);
}
}
else {
rb_thread_check_ints();
}
}
// reachable?
RACTOR_LOCK(cr);
cr->sync.wait.status = prev_wait_status;
}
}
#ifdef RUBY_THREAD_PTHREAD_H
void rb_ractor_sched_sleep(rb_execution_context_t *ec, rb_ractor_t *cr, rb_unblock_function_t *ubf);
#else
// win32
static void
ractor_cond_wait(rb_ractor_t *r)
{
#if RACTOR_CHECK_MODE > 0
VALUE locked_by = r->sync.locked_by;
r->sync.locked_by = Qnil;
#endif
rb_native_cond_wait(&r->sync.cond, &r->sync.lock);
#if RACTOR_CHECK_MODE > 0
r->sync.locked_by = locked_by;
#endif
}
static void *
ractor_sleep_wo_gvl(void *ptr)
{
rb_ractor_t *cr = ptr;
RACTOR_LOCK_SELF(cr);
{
VM_ASSERT(cr->sync.wait.status != wait_none);
if (cr->sync.wait.wakeup_status == wakeup_none) {
ractor_cond_wait(cr);
}
cr->sync.wait.status = wait_none;
}
RACTOR_UNLOCK_SELF(cr);
return NULL;
}
static void
rb_ractor_sched_sleep(rb_execution_context_t *ec, rb_ractor_t *cr, rb_unblock_function_t *ubf)
{
RACTOR_UNLOCK(cr);
{
rb_nogvl(ractor_sleep_wo_gvl, cr,
ubf, cr,
RB_NOGVL_UBF_ASYNC_SAFE | RB_NOGVL_INTR_FAIL);
}
RACTOR_LOCK(cr);
}
#endif
static enum rb_ractor_wakeup_status
ractor_sleep_with_cleanup(rb_execution_context_t *ec, rb_ractor_t *cr, enum rb_ractor_wait_status wait_status,
ractor_sleep_cleanup_function cf_func, void *cf_data)
{
enum rb_ractor_wakeup_status wakeup_status;
VM_ASSERT(GET_RACTOR() == cr);
// TODO: multi-threads
VM_ASSERT(cr->sync.wait.status == wait_none);
VM_ASSERT(wait_status != wait_none);
cr->sync.wait.status = wait_status;
cr->sync.wait.wakeup_status = wakeup_none;
// fprintf(stderr, "%s r:%p status:%s, wakeup_status:%s\n", RUBY_FUNCTION_NAME_STRING, (void *)cr,
// wait_status_str(cr->sync.wait.status), wakeup_status_str(cr->sync.wait.wakeup_status));
RUBY_DEBUG_LOG("sleep by %s", wait_status_str(wait_status));
while (cr->sync.wait.wakeup_status == wakeup_none) {
rb_ractor_sched_sleep(ec, cr, ractor_sleep_interrupt);
ractor_check_ints(ec, cr, cf_func, cf_data);
}
cr->sync.wait.status = wait_none;
// TODO: multi-thread
wakeup_status = cr->sync.wait.wakeup_status;
cr->sync.wait.wakeup_status = wakeup_none;
RUBY_DEBUG_LOG("wakeup %s", wakeup_status_str(wakeup_status));
return wakeup_status;
}
static enum rb_ractor_wakeup_status
ractor_sleep(rb_execution_context_t *ec, rb_ractor_t *cr, enum rb_ractor_wait_status wait_status)
{
return ractor_sleep_with_cleanup(ec, cr, wait_status, 0, NULL);
}
// Ractor.receive
static void
ractor_recursive_receive_if(rb_ractor_t *r)
{
if (r->receiving_mutex && rb_mutex_owned_p(r->receiving_mutex)) {
rb_raise(rb_eRactorError, "can not call receive/receive_if recursively");
}
}
static VALUE
ractor_try_receive(rb_execution_context_t *ec, rb_ractor_t *cr, struct rb_ractor_queue *rq)
{
struct rb_ractor_basket basket;
ractor_recursive_receive_if(cr);
bool received = false;
RACTOR_LOCK_SELF(cr);
{
RUBY_DEBUG_LOG("rq->cnt:%d", rq->cnt);
received = ractor_queue_deq(cr, rq, &basket);
}
RACTOR_UNLOCK_SELF(cr);
if (!received) {
if (cr->sync.incoming_port_closed) {
rb_raise(rb_eRactorClosedError, "The incoming port is already closed");
}
return Qundef;
}
else {
return ractor_basket_accept(&basket);
}
}
static void
ractor_wait_receive(rb_execution_context_t *ec, rb_ractor_t *cr, struct rb_ractor_queue *rq)
{
VM_ASSERT(cr == rb_ec_ractor_ptr(ec));
ractor_recursive_receive_if(cr);
RACTOR_LOCK(cr);
{
while (ractor_queue_empty_p(cr, rq)) {
ractor_sleep(ec, cr, wait_receiving);
}
}
RACTOR_UNLOCK(cr);
}
static VALUE
ractor_receive(rb_execution_context_t *ec, rb_ractor_t *cr)
{
VM_ASSERT(cr == rb_ec_ractor_ptr(ec));
VALUE v;
struct rb_ractor_queue *rq = &cr->sync.recv_queue;
while (UNDEF_P(v = ractor_try_receive(ec, cr, rq))) {
ractor_wait_receive(ec, cr, rq);
}
return v;
}
#if 0
static void
rq_dump(struct rb_ractor_queue *rq)
{
bool bug = false;
for (int i=0; i<rq->cnt; i++) {
struct rb_ractor_basket *b = ractor_queue_at(NULL, rq, i);
fprintf(stderr, "%d (start:%d) type:%s %p %s\n", i, rq->start, basket_type_name(b->type),
(void *)b, RSTRING_PTR(RARRAY_AREF(b->v, 1)));
if (basket_type_p(b, basket_type_reserved) bug = true;
}
if (bug) rb_bug("!!");
}
#endif
struct receive_block_data {
rb_ractor_t *cr;
struct rb_ractor_queue *rq;
VALUE v;
int index;
bool success;
};
static void
ractor_receive_if_lock(rb_ractor_t *cr)
{
VALUE m = cr->receiving_mutex;
if (m == Qfalse) {
m = cr->receiving_mutex = rb_mutex_new();
}
rb_mutex_lock(m);
}
static VALUE
receive_if_body(VALUE ptr)
{
struct receive_block_data *data = (struct receive_block_data *)ptr;
ractor_receive_if_lock(data->cr);
VALUE block_result = rb_yield(data->v);
rb_ractor_t *cr = data->cr;
RACTOR_LOCK_SELF(cr);
{
struct rb_ractor_basket *b = ractor_queue_at(cr, data->rq, data->index);
VM_ASSERT(basket_type_p(b, basket_type_reserved));
data->rq->reserved_cnt--;
if (RTEST(block_result)) {
ractor_queue_delete(cr, data->rq, b);
ractor_queue_compact(cr, data->rq);
}
else {
b->type.e = basket_type_ref;
}
}
RACTOR_UNLOCK_SELF(cr);
data->success = true;
if (RTEST(block_result)) {
return data->v;
}
else {
return Qundef;
}
}
static VALUE
receive_if_ensure(VALUE v)
{
struct receive_block_data *data = (struct receive_block_data *)v;
rb_ractor_t *cr = data->cr;
if (!data->success) {
RACTOR_LOCK_SELF(cr);
{
struct rb_ractor_basket *b = ractor_queue_at(cr, data->rq, data->index);
VM_ASSERT(basket_type_p(b, basket_type_reserved));
b->type.e = basket_type_deleted;
data->rq->reserved_cnt--;
}
RACTOR_UNLOCK_SELF(cr);
}
rb_mutex_unlock(cr->receiving_mutex);
return Qnil;
}
static VALUE
ractor_receive_if(rb_execution_context_t *ec, VALUE crv, VALUE b)
{
if (!RTEST(b)) rb_raise(rb_eArgError, "no block given");
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
unsigned int serial = (unsigned int)-1;
int index = 0;
struct rb_ractor_queue *rq = &cr->sync.recv_queue;
while (1) {
VALUE v = Qundef;
ractor_wait_receive(ec, cr, rq);
RACTOR_LOCK_SELF(cr);
{
if (serial != rq->serial) {
serial = rq->serial;
index = 0;
}
// check newer version
for (int i=index; i<rq->cnt; i++) {
if (!ractor_queue_skip_p(cr, rq, i)) {
struct rb_ractor_basket *b = ractor_queue_at(cr, rq, i);
v = ractor_basket_value(b);
b->type.e = basket_type_reserved;
rq->reserved_cnt++;
index = i;
break;
}
}
}
RACTOR_UNLOCK_SELF(cr);
2022-11-15 07:24:08 +03:00
if (!UNDEF_P(v)) {
struct receive_block_data data = {
.cr = cr,
.rq = rq,
.v = v,
.index = index,
.success = false,
};
VALUE result = rb_ensure(receive_if_body, (VALUE)&data,
receive_if_ensure, (VALUE)&data);
if (!UNDEF_P(result)) return result;
index++;
}
RUBY_VM_CHECK_INTS(ec);
}
}
static void
ractor_send_basket(rb_execution_context_t *ec, rb_ractor_t *r, struct rb_ractor_basket *b)
{
bool closed = false;
RACTOR_LOCK(r);
{
if (r->sync.incoming_port_closed) {
closed = true;
}
else {
ractor_queue_enq(r, &r->sync.recv_queue, b);
ractor_wakeup(r, wait_receiving, wakeup_by_send);
}
}
RACTOR_UNLOCK(r);
if (closed) {
rb_raise(rb_eRactorClosedError, "The incoming-port is already closed");
}
}
// Ractor#send
static VALUE ractor_move(VALUE obj); // in this file
static VALUE ractor_copy(VALUE obj); // in this file
static void
ractor_basket_prepare_contents(VALUE obj, VALUE move, volatile VALUE *pobj, enum rb_ractor_basket_type *ptype)
{
VALUE v;
enum rb_ractor_basket_type type;
if (rb_ractor_shareable_p(obj)) {
type = basket_type_ref;
v = obj;
}
else if (!RTEST(move)) {
v = ractor_copy(obj);
type = basket_type_copy;
}
else {
type = basket_type_move;
v = ractor_move(obj);
}
*pobj = v;
*ptype = type;
}
static void
ractor_basket_fill_(rb_ractor_t *cr, struct rb_ractor_basket *basket, VALUE obj, bool exc)
{
VM_ASSERT(cr == GET_RACTOR());
basket->sender = cr->pub.self;
basket->p.send.exception = exc;
basket->p.send.v = obj;
}
static void
ractor_basket_fill(rb_ractor_t *cr, struct rb_ractor_basket *basket, VALUE obj, VALUE move, bool exc)
{
VALUE v;
enum rb_ractor_basket_type type;
ractor_basket_prepare_contents(obj, move, &v, &type);
ractor_basket_fill_(cr, basket, v, exc);
basket->type.e = type;
}
static void
ractor_basket_fill_will(rb_ractor_t *cr, struct rb_ractor_basket *basket, VALUE obj, bool exc)
{
ractor_basket_fill_(cr, basket, obj, exc);
basket->type.e = basket_type_will;
}
static VALUE
ractor_send(rb_execution_context_t *ec, rb_ractor_t *r, VALUE obj, VALUE move)
{
struct rb_ractor_basket basket;
// TODO: Ractor local GC
ractor_basket_fill(rb_ec_ractor_ptr(ec), &basket, obj, move, false);
ractor_send_basket(ec, r, &basket);
return r->pub.self;
}
// Ractor#take
static bool
ractor_take_has_will(rb_ractor_t *r)
{
ASSERT_ractor_locking(r);
return basket_type_p(&r->sync.will_basket, basket_type_will);
}
static bool
ractor_take_will(rb_ractor_t *r, struct rb_ractor_basket *b)
{
ASSERT_ractor_locking(r);
if (ractor_take_has_will(r)) {
*b = r->sync.will_basket;
r->sync.will_basket.type.e = basket_type_none;
return true;
}
else {
VM_ASSERT(basket_type_p(&r->sync.will_basket, basket_type_none));
return false;
}
}
static bool
ractor_take_will_lock(rb_ractor_t *r, struct rb_ractor_basket *b)
{
ASSERT_ractor_unlocking(r);
bool taken;
RACTOR_LOCK(r);
{
taken = ractor_take_will(r, b);
}
RACTOR_UNLOCK(r);
return taken;
}
static bool
ractor_register_take(rb_ractor_t *cr, rb_ractor_t *r, struct rb_ractor_basket *take_basket,
bool is_take, struct rb_ractor_selector_take_config *config, bool ignore_error)
{
struct rb_ractor_basket b = {
.type.e = basket_type_take_basket,
.sender = cr->pub.self,
.p = {
.take = {
.basket = take_basket,
.config = config,
},
},
};
bool closed = false;
RACTOR_LOCK(r);
{
if (is_take && ractor_take_will(r, take_basket)) {
RUBY_DEBUG_LOG("take over a will of r:%d", rb_ractor_id(r));
}
else if (!is_take && ractor_take_has_will(r)) {
RUBY_DEBUG_LOG("has_will");
VM_ASSERT(config != NULL);
config->closed = true;
}
else if (r->sync.outgoing_port_closed) {
closed = true;
}
else {
RUBY_DEBUG_LOG("register in r:%d", rb_ractor_id(r));
ractor_queue_enq(r, &r->sync.takers_queue, &b);
if (basket_none_p(take_basket)) {
ractor_wakeup(r, wait_yielding, wakeup_by_take);
}
}
}
RACTOR_UNLOCK(r);
if (closed) {
if (!ignore_error) rb_raise(rb_eRactorClosedError, "The outgoing-port is already closed");
return false;
}
else {
return true;
}
}
static bool
ractor_deregister_take(rb_ractor_t *r, struct rb_ractor_basket *take_basket)
{
struct rb_ractor_queue *ts = &r->sync.takers_queue;
bool deleted = false;
RACTOR_LOCK(r);
{
if (r->sync.outgoing_port_closed) {
// ok
}
else {
for (int i=0; i<ts->cnt; i++) {
struct rb_ractor_basket *b = ractor_queue_at(r, ts, i);
if (basket_type_p(b, basket_type_take_basket) && b->p.take.basket == take_basket) {
ractor_queue_delete(r, ts, b);
deleted = true;
}
}
if (deleted) {
ractor_queue_compact(r, ts);
}
}
}
RACTOR_UNLOCK(r);
return deleted;
}
static VALUE
ractor_try_take(rb_ractor_t *cr, rb_ractor_t *r, struct rb_ractor_basket *take_basket)
{
bool taken;
RACTOR_LOCK_SELF(cr);
{
if (basket_none_p(take_basket) || basket_type_p(take_basket, basket_type_yielding)) {
taken = false;
}
else {
taken = true;
}
}
RACTOR_UNLOCK_SELF(cr);
if (taken) {
RUBY_DEBUG_LOG("taken");
if (basket_type_p(take_basket, basket_type_deleted)) {
VM_ASSERT(r->sync.outgoing_port_closed);
rb_raise(rb_eRactorClosedError, "The outgoing-port is already closed");
}
return ractor_basket_accept(take_basket);
}
else {
RUBY_DEBUG_LOG("not taken");
return Qundef;
}
}
#if VM_CHECK_MODE > 0
static bool
ractor_check_specific_take_basket_lock(rb_ractor_t *r, struct rb_ractor_basket *tb)
{
bool ret = false;
struct rb_ractor_queue *ts = &r->sync.takers_queue;
RACTOR_LOCK(r);
{
for (int i=0; i<ts->cnt; i++) {
struct rb_ractor_basket *b = ractor_queue_at(r, ts, i);
if (basket_type_p(b, basket_type_take_basket) && b->p.take.basket == tb) {
ret = true;
break;
}
}
}
RACTOR_UNLOCK(r);
return ret;
}
#endif
static void
ractor_take_cleanup(rb_ractor_t *cr, rb_ractor_t *r, struct rb_ractor_basket *tb)
{
retry:
if (basket_none_p(tb)) { // not yielded yet
if (!ractor_deregister_take(r, tb)) {
// not in r's takers queue
rb_thread_sleep(0);
goto retry;
}
}
else {
VM_ASSERT(!ractor_check_specific_take_basket_lock(r, tb));
}
}
struct take_wait_take_cleanup_data {
rb_ractor_t *r;
struct rb_ractor_basket *tb;
};
static void
ractor_wait_take_cleanup(rb_ractor_t *cr, void *ptr)
{
struct take_wait_take_cleanup_data *data = (struct take_wait_take_cleanup_data *)ptr;
ractor_take_cleanup(cr, data->r, data->tb);
}
static void
ractor_wait_take(rb_execution_context_t *ec, rb_ractor_t *cr, rb_ractor_t *r, struct rb_ractor_basket *take_basket)
{
struct take_wait_take_cleanup_data data = {
.r = r,
.tb = take_basket,
};
RACTOR_LOCK_SELF(cr);
{
if (basket_none_p(take_basket) || basket_type_p(take_basket, basket_type_yielding)) {
ractor_sleep_with_cleanup(ec, cr, wait_taking, ractor_wait_take_cleanup, &data);
}
}
RACTOR_UNLOCK_SELF(cr);
}
static VALUE
ractor_take(rb_execution_context_t *ec, rb_ractor_t *r)
{
RUBY_DEBUG_LOG("from r:%u", rb_ractor_id(r));
VALUE v;
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
struct rb_ractor_basket take_basket = {
.type.e = basket_type_none,
.sender = 0,
};
ractor_register_take(cr, r, &take_basket, true, NULL, false);
while (UNDEF_P(v = ractor_try_take(cr, r, &take_basket))) {
ractor_wait_take(ec, cr, r, &take_basket);
}
VM_ASSERT(!basket_none_p(&take_basket));
VM_ASSERT(!ractor_check_specific_take_basket_lock(r, &take_basket));
return v;
}
// Ractor.yield
static bool
ractor_check_take_basket(rb_ractor_t *cr, struct rb_ractor_queue *rs)
{
ASSERT_ractor_locking(cr);
for (int i=0; i<rs->cnt; i++) {
struct rb_ractor_basket *b = ractor_queue_at(cr, rs, i);
if (basket_type_p(b, basket_type_take_basket) &&
basket_none_p(b->p.take.basket)) {
return true;
}
}
return false;
}
static bool
ractor_deq_take_basket(rb_ractor_t *cr, struct rb_ractor_queue *rs, struct rb_ractor_basket *b)
{
ASSERT_ractor_unlocking(cr);
struct rb_ractor_basket *first_tb = NULL;
bool found = false;
RACTOR_LOCK_SELF(cr);
{
while (ractor_queue_deq(cr, rs, b)) {
if (basket_type_p(b, basket_type_take_basket)) {
struct rb_ractor_basket *tb = b->p.take.basket;
if (RUBY_ATOMIC_CAS(tb->type.atomic, basket_type_none, basket_type_yielding) == basket_type_none) {
found = true;
break;
}
else {
ractor_queue_enq(cr, rs, b);
if (first_tb == NULL) first_tb = tb;
struct rb_ractor_basket *head = ractor_queue_head(cr, rs);
VM_ASSERT(head != NULL);
if (basket_type_p(head, basket_type_take_basket) && head->p.take.basket == first_tb) {
break; // loop detected
}
}
}
else {
VM_ASSERT(basket_none_p(b));
}
}
if (found && b->p.take.config && !b->p.take.config->oneshot) {
ractor_queue_enq(cr, rs, b);
}
}
RACTOR_UNLOCK_SELF(cr);
return found;
}
static bool
ractor_try_yield(rb_execution_context_t *ec, rb_ractor_t *cr, struct rb_ractor_queue *ts, volatile VALUE obj, VALUE move, bool exc, bool is_will)
{
ASSERT_ractor_unlocking(cr);
struct rb_ractor_basket b;
if (ractor_deq_take_basket(cr, ts, &b)) {
VM_ASSERT(basket_type_p(&b, basket_type_take_basket));
VM_ASSERT(basket_type_p(b.p.take.basket, basket_type_yielding));
rb_ractor_t *tr = RACTOR_PTR(b.sender);
struct rb_ractor_basket *tb = b.p.take.basket;
enum rb_ractor_basket_type type;
RUBY_DEBUG_LOG("basket from r:%u", rb_ractor_id(tr));
if (is_will) {
type = basket_type_will;
}
else {
2023-08-07 18:32:45 +03:00
enum ruby_tag_type state;
// begin
EC_PUSH_TAG(ec);
if ((state = EC_EXEC_TAG()) == TAG_NONE) {
// TODO: Ractor local GC
ractor_basket_prepare_contents(obj, move, &obj, &type);
}
EC_POP_TAG();
// rescue
if (state) {
RACTOR_LOCK_SELF(cr);
{
b.p.take.basket->type.e = basket_type_none;
ractor_queue_enq(cr, ts, &b);
}
RACTOR_UNLOCK_SELF(cr);
EC_JUMP_TAG(ec, state);
}
}
RACTOR_LOCK(tr);
{
VM_ASSERT(basket_type_p(tb, basket_type_yielding));
// fill atomic
RUBY_DEBUG_LOG("fill %sbasket from r:%u", is_will ? "will " : "", rb_ractor_id(tr));
ractor_basket_fill_(cr, tb, obj, exc);
if (RUBY_ATOMIC_CAS(tb->type.atomic, basket_type_yielding, type) != basket_type_yielding) {
rb_bug("unreachable");
}
ractor_wakeup(tr, wait_taking, wakeup_by_yield);
}
RACTOR_UNLOCK(tr);
return true;
}
else {
RUBY_DEBUG_LOG("no take basket");
return false;
}
}
static void
ractor_wait_yield(rb_execution_context_t *ec, rb_ractor_t *cr, struct rb_ractor_queue *ts)
{
RACTOR_LOCK_SELF(cr);
{
while (!ractor_check_take_basket(cr, ts)) {
ractor_sleep(ec, cr, wait_yielding);
}
}
RACTOR_UNLOCK_SELF(cr);
}
static VALUE
ractor_yield(rb_execution_context_t *ec, rb_ractor_t *cr, VALUE obj, VALUE move)
{
struct rb_ractor_queue *ts = &cr->sync.takers_queue;
while (!ractor_try_yield(ec, cr, ts, obj, move, false, false)) {
ractor_wait_yield(ec, cr, ts);
}
return Qnil;
}
// Ractor::Selector
Fix Ractor.receive_if + rb_vm_barrier() deadlock I have this scripts that deadlocks after about 5 minutes if I repeatedly run it with a shell loop: ```ruby $VERBOSE = nil lamb = ->(main, gc) do gc.verify_internal_consistency gc.verify_internal_consistency main << 1 gc.verify_internal_consistency gc.verify_internal_consistency main << 2 gc.verify_internal_consistency gc.verify_internal_consistency main << 3 gc.verify_internal_consistency gc.verify_internal_consistency end lamb[[], GC] lamb[[], GC] r = Ractor.new Ractor.current, GC, &lamb a = [] a << Ractor.receive_if{|msg| msg == 2} a << Ractor.receive_if{|msg| msg == 3} a << Ractor.receive_if{|msg| msg == 1} ``` Shell loop: ```shell while ./miniruby deadlock.rb; do date; done ``` Once it locks up, CTRL-C doesn't interrupt the process which led me to infer `receive_if` is looping in `ractor_receive_if()` without checking for interrupts. This can be confirmed by attaching a debugger to the deadlocked miniruby. The deadlock has one thread looping in `receive_if` and another waiting in `rb_vm_barrier()`. The barrier relies on interrupt checking to finish. Theoretically speaking the `rb_vm_barrier()` could come from one thread naturally starting GC. We found this while developing YJIT but it dead locks running with YJIT disabled. YJIT currently relies on `rb_vm_barrier()` to synchronize before changing memory protection. This diff adds an interrupt check in the loop in `Ractor#receive_if` which seems to fix the deadlock. In addition, this commit allows interrupting the following single ractor script with CTRL-C. ```shell ruby -e 'Ractor.current.send(3); Ractor.receive_if { false }' ```
2022-03-29 00:00:45 +03:00
struct rb_ractor_selector {
rb_ractor_t *r;
struct rb_ractor_basket take_basket;
st_table *take_ractors; // rb_ractor_t * => (struct rb_ractor_selector_take_config *)
};
static int
ractor_selector_mark_ractors_i(st_data_t key, st_data_t value, st_data_t data)
{
const rb_ractor_t *r = (rb_ractor_t *)key;
rb_gc_mark(r->pub.self);
return ST_CONTINUE;
}
static void
ractor_selector_mark(void *ptr)
{
struct rb_ractor_selector *s = ptr;
if (s->take_ractors) {
st_foreach(s->take_ractors, ractor_selector_mark_ractors_i, 0);
}
switch (s->take_basket.type.e) {
case basket_type_ref:
case basket_type_copy:
case basket_type_move:
case basket_type_will:
rb_gc_mark(s->take_basket.sender);
rb_gc_mark(s->take_basket.p.send.v);
break;
default:
break;
}
}
static int
ractor_selector_release_i(st_data_t key, st_data_t val, st_data_t data)
{
struct rb_ractor_selector *s = (struct rb_ractor_selector *)data;
struct rb_ractor_selector_take_config *config = (struct rb_ractor_selector_take_config *)val;
if (!config->closed) {
ractor_deregister_take((rb_ractor_t *)key, &s->take_basket);
}
free(config);
return ST_CONTINUE;
}
static void
ractor_selector_free(void *ptr)
{
struct rb_ractor_selector *s = ptr;
st_foreach(s->take_ractors, ractor_selector_release_i, (st_data_t)s);
st_free_table(s->take_ractors);
ruby_xfree(ptr);
}
static size_t
ractor_selector_memsize(const void *ptr)
{
const struct rb_ractor_selector *s = ptr;
return sizeof(struct rb_ractor_selector) +
st_memsize(s->take_ractors) +
s->take_ractors->num_entries * sizeof(struct rb_ractor_selector_take_config);
}
static const rb_data_type_t ractor_selector_data_type = {
"ractor/selector",
{
ractor_selector_mark,
ractor_selector_free,
ractor_selector_memsize,
NULL, // update
},
0, 0, RUBY_TYPED_FREE_IMMEDIATELY,
};
static struct rb_ractor_selector *
RACTOR_SELECTOR_PTR(VALUE selv)
{
VM_ASSERT(rb_typeddata_is_kind_of(selv, &ractor_selector_data_type));
return (struct rb_ractor_selector *)DATA_PTR(selv);
}
// Ractor::Selector.new
static VALUE
ractor_selector_create(VALUE klass)
{
struct rb_ractor_selector *s;
VALUE selv = TypedData_Make_Struct(klass, struct rb_ractor_selector, &ractor_selector_data_type, s);
s->take_basket.type.e = basket_type_reserved;
s->take_ractors = st_init_numtable(); // ractor (ptr) -> take_config
return selv;
}
// Ractor::Selector#add(r)
static VALUE
ractor_selector_add(VALUE selv, VALUE rv)
{
if (!rb_ractor_p(rv)) {
rb_raise(rb_eArgError, "Not a ractor object");
}
rb_ractor_t *r = RACTOR_PTR(rv);
struct rb_ractor_selector *s = RACTOR_SELECTOR_PTR(selv);
if (st_lookup(s->take_ractors, (st_data_t)r, NULL)) {
rb_raise(rb_eArgError, "already added");
}
struct rb_ractor_selector_take_config *config = malloc(sizeof(struct rb_ractor_selector_take_config));
VM_ASSERT(config != NULL);
config->closed = false;
config->oneshot = false;
if (ractor_register_take(GET_RACTOR(), r, &s->take_basket, false, config, true)) {
st_insert(s->take_ractors, (st_data_t)r, (st_data_t)config);
}
return rv;
}
// Ractor::Selector#remove(r)
static VALUE
ractor_selector_remove(VALUE selv, VALUE rv)
{
if (!rb_ractor_p(rv)) {
rb_raise(rb_eArgError, "Not a ractor object");
}
rb_ractor_t *r = RACTOR_PTR(rv);
struct rb_ractor_selector *s = RACTOR_SELECTOR_PTR(selv);
RUBY_DEBUG_LOG("r:%u", rb_ractor_id(r));
if (!st_lookup(s->take_ractors, (st_data_t)r, NULL)) {
rb_raise(rb_eArgError, "not added yet");
}
ractor_deregister_take(r, &s->take_basket);
struct rb_ractor_selector_take_config *config;
st_delete(s->take_ractors, (st_data_t *)&r, (st_data_t *)&config);
free(config);
return rv;
}
// Ractor::Selector#clear
struct ractor_selector_clear_data {
VALUE selv;
rb_execution_context_t *ec;
};
static int
ractor_selector_clear_i(st_data_t key, st_data_t val, st_data_t data)
{
VALUE selv = (VALUE)data;
rb_ractor_t *r = (rb_ractor_t *)key;
ractor_selector_remove(selv, r->pub.self);
return ST_CONTINUE;
}
static VALUE
ractor_selector_clear(VALUE selv)
{
struct rb_ractor_selector *s = RACTOR_SELECTOR_PTR(selv);
st_foreach(s->take_ractors, ractor_selector_clear_i, (st_data_t)selv);
st_clear(s->take_ractors);
return selv;
}
static VALUE
ractor_selector_empty_p(VALUE selv)
{
struct rb_ractor_selector *s = RACTOR_SELECTOR_PTR(selv);
return s->take_ractors->num_entries == 0 ? Qtrue : Qfalse;
}
static int
ractor_selector_wait_i(st_data_t key, st_data_t val, st_data_t dat)
{
rb_ractor_t *r = (rb_ractor_t *)key;
struct rb_ractor_basket *tb = (struct rb_ractor_basket *)dat;
int ret;
if (!basket_none_p(tb)) {
RUBY_DEBUG_LOG("already taken:%s", basket_type_name(tb->type.e));
return ST_STOP;
}
RACTOR_LOCK(r);
{
if (basket_type_p(&r->sync.will_basket, basket_type_will)) {
RUBY_DEBUG_LOG("r:%u has will", rb_ractor_id(r));
if (RUBY_ATOMIC_CAS(tb->type.atomic, basket_type_none, basket_type_will) == basket_type_none) {
ractor_take_will(r, tb);
ret = ST_STOP;
}
else {
RUBY_DEBUG_LOG("has will, but already taken (%s)", basket_type_name(tb->type.e));
ret = ST_CONTINUE;
}
}
else if (r->sync.outgoing_port_closed) {
RUBY_DEBUG_LOG("r:%u is closed", rb_ractor_id(r));
if (RUBY_ATOMIC_CAS(tb->type.atomic, basket_type_none, basket_type_deleted) == basket_type_none) {
tb->sender = r->pub.self;
ret = ST_STOP;
}
else {
RUBY_DEBUG_LOG("closed, but already taken (%s)", basket_type_name(tb->type.e));
ret = ST_CONTINUE;
}
}
else {
RUBY_DEBUG_LOG("wakeup r:%u", rb_ractor_id(r));
ractor_wakeup(r, wait_yielding, wakeup_by_take);
ret = ST_CONTINUE;
}
}
RACTOR_UNLOCK(r);
return ret;
}
// Ractor::Selector#wait
static void
ractor_selector_wait_cleaup(rb_ractor_t *cr, void *ptr)
{
struct rb_ractor_basket *tb = (struct rb_ractor_basket *)ptr;
RACTOR_LOCK_SELF(cr);
{
while (basket_type_p(tb, basket_type_yielding)) rb_thread_sleep(0);
// if tb->type is not none, taking is succeeded, but interruption ignore it unfortunately.
tb->type.e = basket_type_reserved;
}
RACTOR_UNLOCK_SELF(cr);
}
static VALUE
ractor_selector__wait(VALUE selv, VALUE do_receivev, VALUE do_yieldv, VALUE yield_value, VALUE move)
{
rb_execution_context_t *ec = GET_EC();
struct rb_ractor_selector *s = RACTOR_SELECTOR_PTR(selv);
struct rb_ractor_basket *tb = &s->take_basket;
struct rb_ractor_basket taken_basket;
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
bool do_receive = !!RTEST(do_receivev);
bool do_yield = !!RTEST(do_yieldv);
VALUE ret_v, ret_r;
enum rb_ractor_wait_status wait_status;
struct rb_ractor_queue *rq = &cr->sync.recv_queue;
struct rb_ractor_queue *ts = &cr->sync.takers_queue;
RUBY_DEBUG_LOG("start");
retry:
RUBY_DEBUG_LOG("takers:%ld", s->take_ractors->num_entries);
// setup wait_status
wait_status = wait_none;
if (s->take_ractors->num_entries > 0) wait_status |= wait_taking;
if (do_receive) wait_status |= wait_receiving;
if (do_yield) wait_status |= wait_yielding;
RUBY_DEBUG_LOG("wait:%s", wait_status_str(wait_status));
if (wait_status == wait_none) {
rb_raise(rb_eRactorError, "no taking ractors");
}
// check recv_queue
2024-01-30 08:48:59 +03:00
if (do_receive && !UNDEF_P(ret_v = ractor_try_receive(ec, cr, rq))) {
ret_r = ID2SYM(rb_intern("receive"));
goto success;
}
// check takers
if (do_yield && ractor_try_yield(ec, cr, ts, yield_value, move, false, false)) {
ret_v = Qnil;
ret_r = ID2SYM(rb_intern("yield"));
goto success;
}
// check take_basket
VM_ASSERT(basket_type_p(&s->take_basket, basket_type_reserved));
s->take_basket.type.e = basket_type_none;
// kick all take target ractors
st_foreach(s->take_ractors, ractor_selector_wait_i, (st_data_t)tb);
RACTOR_LOCK_SELF(cr);
{
retry_waiting:
while (1) {
if (!basket_none_p(tb)) {
RUBY_DEBUG_LOG("taken:%s from r:%u", basket_type_name(tb->type.e),
tb->sender ? rb_ractor_id(RACTOR_PTR(tb->sender)) : 0);
break;
}
if (do_receive && !ractor_queue_empty_p(cr, rq)) {
RUBY_DEBUG_LOG("can receive (%d)", rq->cnt);
break;
}
if (do_yield && ractor_check_take_basket(cr, ts)) {
RUBY_DEBUG_LOG("can yield");
break;
}
ractor_sleep_with_cleanup(ec, cr, wait_status, ractor_selector_wait_cleaup, tb);
}
taken_basket = *tb;
// ensure
// tb->type.e = basket_type_reserved # do it atomic in the following code
if (taken_basket.type.e == basket_type_yielding ||
RUBY_ATOMIC_CAS(tb->type.atomic, taken_basket.type.e, basket_type_reserved) != taken_basket.type.e) {
if (basket_type_p(tb, basket_type_yielding)) {
RACTOR_UNLOCK_SELF(cr);
{
rb_thread_sleep(0);
}
RACTOR_LOCK_SELF(cr);
}
goto retry_waiting;
}
}
RACTOR_UNLOCK_SELF(cr);
// check the taken resutl
switch (taken_basket.type.e) {
case basket_type_none:
VM_ASSERT(do_receive || do_yield);
goto retry;
case basket_type_yielding:
rb_bug("unreachable");
case basket_type_deleted: {
ractor_selector_remove(selv, taken_basket.sender);
rb_ractor_t *r = RACTOR_PTR(taken_basket.sender);
if (ractor_take_will_lock(r, &taken_basket)) {
RUBY_DEBUG_LOG("has_will");
}
else {
RUBY_DEBUG_LOG("no will");
// rb_raise(rb_eRactorClosedError, "The outgoing-port is already closed");
// remove and retry wait
goto retry;
}
break;
}
case basket_type_will:
// no more messages
ractor_selector_remove(selv, taken_basket.sender);
break;
default:
break;
}
RUBY_DEBUG_LOG("taken_basket:%s", basket_type_name(taken_basket.type.e));
ret_v = ractor_basket_accept(&taken_basket);
ret_r = taken_basket.sender;
success:
return rb_ary_new_from_args(2, ret_r, ret_v);
}
static VALUE
ractor_selector_wait(int argc, VALUE *argv, VALUE selector)
{
VALUE options;
ID keywords[3];
VALUE values[3];
keywords[0] = rb_intern("receive");
keywords[1] = rb_intern("yield_value");
keywords[2] = rb_intern("move");
rb_scan_args(argc, argv, "0:", &options);
rb_get_kwargs(options, keywords, 0, numberof(values), values);
return ractor_selector__wait(selector,
values[0] == Qundef ? Qfalse : RTEST(values[0]),
values[1] != Qundef, values[1], values[2]);
}
static VALUE
ractor_selector_new(int argc, VALUE *ractors, VALUE klass)
{
VALUE selector = ractor_selector_create(klass);
for (int i=0; i<argc; i++) {
ractor_selector_add(selector, ractors[i]);
}
return selector;
}
static VALUE
ractor_select_internal(rb_execution_context_t *ec, VALUE self, VALUE ractors, VALUE do_receive, VALUE do_yield, VALUE yield_value, VALUE move)
{
VALUE selector = ractor_selector_new(RARRAY_LENINT(ractors), (VALUE *)RARRAY_CONST_PTR(ractors), rb_cRactorSelector);
VALUE result;
int state;
EC_PUSH_TAG(ec);
if ((state = EC_EXEC_TAG() == TAG_NONE)) {
result = ractor_selector__wait(selector, do_receive, do_yield, yield_value, move);
}
else {
// ensure
ractor_selector_clear(selector);
// jump
EC_JUMP_TAG(ec, state);
}
EC_POP_TAG();
RB_GC_GUARD(ractors);
return result;
}
// Ractor#close_incoming
static VALUE
ractor_close_incoming(rb_execution_context_t *ec, rb_ractor_t *r)
{
VALUE prev;
RACTOR_LOCK(r);
{
if (!r->sync.incoming_port_closed) {
prev = Qfalse;
r->sync.incoming_port_closed = true;
if (ractor_wakeup(r, wait_receiving, wakeup_by_close)) {
VM_ASSERT(ractor_queue_empty_p(r, &r->sync.recv_queue));
RUBY_DEBUG_LOG("cancel receiving");
}
}
else {
prev = Qtrue;
}
}
RACTOR_UNLOCK(r);
return prev;
}
// Ractor#close_outgoing
static VALUE
ractor_close_outgoing(rb_execution_context_t *ec, rb_ractor_t *r)
{
VALUE prev;
RACTOR_LOCK(r);
{
struct rb_ractor_queue *ts = &r->sync.takers_queue;
rb_ractor_t *tr;
struct rb_ractor_basket b;
if (!r->sync.outgoing_port_closed) {
prev = Qfalse;
r->sync.outgoing_port_closed = true;
}
else {
VM_ASSERT(ractor_queue_empty_p(r, ts));
prev = Qtrue;
}
// wakeup all taking ractors
while (ractor_queue_deq(r, ts, &b)) {
if (basket_type_p(&b, basket_type_take_basket)) {
tr = RACTOR_PTR(b.sender);
struct rb_ractor_basket *tb = b.p.take.basket;
if (RUBY_ATOMIC_CAS(tb->type.atomic, basket_type_none, basket_type_yielding) == basket_type_none) {
b.p.take.basket->sender = r->pub.self;
if (RUBY_ATOMIC_CAS(tb->type.atomic, basket_type_yielding, basket_type_deleted) != basket_type_yielding) {
rb_bug("unreachable");
}
RUBY_DEBUG_LOG("set delete for r:%u", rb_ractor_id(RACTOR_PTR(b.sender)));
}
if (b.p.take.config) {
b.p.take.config->closed = true;
}
// TODO: deadlock-able?
RACTOR_LOCK(tr);
{
ractor_wakeup(tr, wait_taking, wakeup_by_close);
}
RACTOR_UNLOCK(tr);
}
}
// raising yielding Ractor
ractor_wakeup(r, wait_yielding, wakeup_by_close);
VM_ASSERT(ractor_queue_empty_p(r, ts));
}
RACTOR_UNLOCK(r);
return prev;
}
// creation/termination
static uint32_t
ractor_next_id(void)
{
uint32_t id;
id = (uint32_t)(RUBY_ATOMIC_FETCH_ADD(ractor_last_id, 1) + 1);
return id;
}
static void
vm_insert_ractor0(rb_vm_t *vm, rb_ractor_t *r, bool single_ractor_mode)
{
RUBY_DEBUG_LOG("r:%u ractor.cnt:%u++", r->pub.id, vm->ractor.cnt);
VM_ASSERT(single_ractor_mode || RB_VM_LOCKED_P());
ccan_list_add_tail(&vm->ractor.set, &r->vmlr_node);
vm->ractor.cnt++;
}
static void
cancel_single_ractor_mode(void)
{
// enable multi-ractor mode
RUBY_DEBUG_LOG("enable multi-ractor mode");
VALUE was_disabled = rb_gc_enable();
rb_gc_start();
if (was_disabled) {
rb_gc_disable();
}
ruby_single_main_ractor = NULL;
}
static void
vm_insert_ractor(rb_vm_t *vm, rb_ractor_t *r)
{
VM_ASSERT(ractor_status_p(r, ractor_created));
if (rb_multi_ractor_p()) {
RB_VM_LOCK();
{
vm_insert_ractor0(vm, r, false);
vm_ractor_blocking_cnt_inc(vm, r, __FILE__, __LINE__);
}
RB_VM_UNLOCK();
}
else {
if (vm->ractor.cnt == 0) {
// main ractor
vm_insert_ractor0(vm, r, true);
ractor_status_set(r, ractor_blocking);
ractor_status_set(r, ractor_running);
}
else {
cancel_single_ractor_mode();
vm_insert_ractor0(vm, r, true);
vm_ractor_blocking_cnt_inc(vm, r, __FILE__, __LINE__);
}
}
}
static void
vm_remove_ractor(rb_vm_t *vm, rb_ractor_t *cr)
{
VM_ASSERT(ractor_status_p(cr, ractor_running));
VM_ASSERT(vm->ractor.cnt > 1);
VM_ASSERT(cr->threads.cnt == 1);
RB_VM_LOCK();
{
RUBY_DEBUG_LOG("ractor.cnt:%u-- terminate_waiting:%d",
vm->ractor.cnt, vm->ractor.sync.terminate_waiting);
VM_ASSERT(vm->ractor.cnt > 0);
ccan_list_del(&cr->vmlr_node);
if (vm->ractor.cnt <= 2 && vm->ractor.sync.terminate_waiting) {
rb_native_cond_signal(&vm->ractor.sync.terminate_cond);
}
vm->ractor.cnt--;
/* Clear the cached freelist to prevent a memory leak. */
rb_gc_ractor_newobj_cache_clear(&cr->newobj_cache);
ractor_status_set(cr, ractor_terminated);
}
RB_VM_UNLOCK();
}
static VALUE
ractor_alloc(VALUE klass)
{
rb_ractor_t *r;
VALUE rv = TypedData_Make_Struct(klass, rb_ractor_t, &ractor_data_type, r);
FL_SET_RAW(rv, RUBY_FL_SHAREABLE);
r->pub.self = rv;
VM_ASSERT(ractor_status_p(r, ractor_created));
return rv;
}
rb_ractor_t *
rb_ractor_main_alloc(void)
{
rb_ractor_t *r = ruby_mimmalloc(sizeof(rb_ractor_t));
if (r == NULL) {
fprintf(stderr, "[FATAL] failed to allocate memory for main ractor\n");
exit(EXIT_FAILURE);
}
MEMZERO(r, rb_ractor_t, 1);
r->pub.id = ++ractor_last_id;
r->loc = Qnil;
r->name = Qnil;
r->pub.self = Qnil;
ruby_single_main_ractor = r;
return r;
}
#if defined(HAVE_WORKING_FORK)
void
rb_ractor_atfork(rb_vm_t *vm, rb_thread_t *th)
{
// initialize as a main ractor
vm->ractor.cnt = 0;
vm->ractor.blocking_cnt = 0;
ruby_single_main_ractor = th->ractor;
th->ractor->status_ = ractor_created;
rb_ractor_living_threads_init(th->ractor);
rb_ractor_living_threads_insert(th->ractor, th);
VM_ASSERT(vm->ractor.blocking_cnt == 0);
VM_ASSERT(vm->ractor.cnt == 1);
}
#endif
void rb_thread_sched_init(struct rb_thread_sched *, bool atfork);
void
rb_ractor_living_threads_init(rb_ractor_t *r)
{
ccan_list_head_init(&r->threads.set);
r->threads.cnt = 0;
r->threads.blocking_cnt = 0;
}
static void
ractor_init(rb_ractor_t *r, VALUE name, VALUE loc)
{
ractor_queue_setup(&r->sync.recv_queue);
ractor_queue_setup(&r->sync.takers_queue);
rb_native_mutex_initialize(&r->sync.lock);
rb_native_cond_initialize(&r->barrier_wait_cond);
#ifdef RUBY_THREAD_WIN32_H
rb_native_cond_initialize(&r->sync.cond);
rb_native_cond_initialize(&r->barrier_wait_cond);
#endif
// thread management
rb_thread_sched_init(&r->threads.sched, false);
rb_ractor_living_threads_init(r);
// naming
2020-09-18 09:02:14 +03:00
if (!NIL_P(name)) {
rb_encoding *enc;
StringValueCStr(name);
enc = rb_enc_get(name);
if (!rb_enc_asciicompat(enc)) {
rb_raise(rb_eArgError, "ASCII incompatible encoding (%s)",
rb_enc_name(enc));
}
name = rb_str_new_frozen(name);
}
r->name = name;
r->loc = loc;
}
void
rb_ractor_main_setup(rb_vm_t *vm, rb_ractor_t *r, rb_thread_t *th)
{
r->pub.self = TypedData_Wrap_Struct(rb_cRactor, &ractor_data_type, r);
FL_SET_RAW(r->pub.self, RUBY_FL_SHAREABLE);
ractor_init(r, Qnil, Qnil);
r->threads.main = th;
rb_ractor_living_threads_insert(r, th);
}
static VALUE
ractor_create(rb_execution_context_t *ec, VALUE self, VALUE loc, VALUE name, VALUE args, VALUE block)
{
VALUE rv = ractor_alloc(self);
rb_ractor_t *r = RACTOR_PTR(rv);
ractor_init(r, name, loc);
// can block here
r->pub.id = ractor_next_id();
RUBY_DEBUG_LOG("r:%u", r->pub.id);
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
r->verbose = cr->verbose;
r->debug = cr->debug;
rb_yjit_before_ractor_spawn();
2023-03-07 10:17:25 +03:00
rb_rjit_before_ractor_spawn();
rb_thread_create_ractor(r, args, block);
RB_GC_GUARD(rv);
return rv;
}
static void
ractor_yield_atexit(rb_execution_context_t *ec, rb_ractor_t *cr, VALUE v, bool exc)
{
if (cr->sync.outgoing_port_closed) {
return;
}
ASSERT_ractor_unlocking(cr);
struct rb_ractor_queue *ts = &cr->sync.takers_queue;
2020-09-19 11:40:31 +03:00
retry:
if (ractor_try_yield(ec, cr, ts, v, Qfalse, exc, true)) {
// OK.
}
else {
bool retry = false;
RACTOR_LOCK(cr);
{
if (!ractor_check_take_basket(cr, ts)) {
VM_ASSERT(cr->sync.wait.status == wait_none);
RUBY_DEBUG_LOG("leave a will");
ractor_basket_fill_will(cr, &cr->sync.will_basket, v, exc);
}
else {
RUBY_DEBUG_LOG("rare timing!");
retry = true; // another ractor is waiting for the yield.
}
}
RACTOR_UNLOCK(cr);
if (retry) goto retry;
}
}
void
rb_ractor_atexit(rb_execution_context_t *ec, VALUE result)
{
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
ractor_yield_atexit(ec, cr, result, false);
}
void
rb_ractor_atexit_exception(rb_execution_context_t *ec)
{
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
ractor_yield_atexit(ec, cr, ec->errinfo, true);
}
void
rb_ractor_teardown(rb_execution_context_t *ec)
{
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
ractor_close_incoming(ec, cr);
ractor_close_outgoing(ec, cr);
// sync with rb_ractor_terminate_interrupt_main_thread()
RB_VM_LOCK_ENTER();
{
VM_ASSERT(cr->threads.main != NULL);
cr->threads.main = NULL;
}
RB_VM_LOCK_LEAVE();
}
void
rb_ractor_receive_parameters(rb_execution_context_t *ec, rb_ractor_t *r, int len, VALUE *ptr)
{
for (int i=0; i<len; i++) {
ptr[i] = ractor_receive(ec, r);
}
}
void
rb_ractor_send_parameters(rb_execution_context_t *ec, rb_ractor_t *r, VALUE args)
{
int len = RARRAY_LENINT(args);
for (int i=0; i<len; i++) {
ractor_send(ec, r, RARRAY_AREF(args, i), false);
}
}
2023-03-07 08:34:31 +03:00
bool
rb_ractor_main_p_(void)
{
VM_ASSERT(rb_multi_ractor_p());
rb_execution_context_t *ec = GET_EC();
return rb_ec_ractor_ptr(ec) == rb_ec_vm_ptr(ec)->ractor.main_ractor;
}
2020-09-04 09:17:42 +03:00
bool
rb_obj_is_main_ractor(VALUE gv)
{
if (!rb_ractor_p(gv)) return false;
rb_ractor_t *r = DATA_PTR(gv);
return r == GET_VM()->ractor.main_ractor;
}
int
rb_ractor_living_thread_num(const rb_ractor_t *r)
{
return r->threads.cnt;
}
// only for current ractor
VALUE
rb_ractor_thread_list(void)
{
rb_ractor_t *r = GET_RACTOR();
rb_thread_t *th = 0;
VALUE ary = rb_ary_new();
ccan_list_for_each(&r->threads.set, th, lt_node) {
switch (th->status) {
case THREAD_RUNNABLE:
case THREAD_STOPPED:
case THREAD_STOPPED_FOREVER:
rb_ary_push(ary, th->self);
default:
break;
}
}
return ary;
}
void
rb_ractor_living_threads_insert(rb_ractor_t *r, rb_thread_t *th)
{
VM_ASSERT(th != NULL);
RACTOR_LOCK(r);
{
RUBY_DEBUG_LOG("r(%d)->threads.cnt:%d++", r->pub.id, r->threads.cnt);
ccan_list_add_tail(&r->threads.set, &th->lt_node);
r->threads.cnt++;
}
RACTOR_UNLOCK(r);
// first thread for a ractor
if (r->threads.cnt == 1) {
VM_ASSERT(ractor_status_p(r, ractor_created));
vm_insert_ractor(th->vm, r);
}
}
static void
vm_ractor_blocking_cnt_inc(rb_vm_t *vm, rb_ractor_t *r, const char *file, int line)
{
ractor_status_set(r, ractor_blocking);
RUBY_DEBUG_LOG2(file, line, "vm->ractor.blocking_cnt:%d++", vm->ractor.blocking_cnt);
vm->ractor.blocking_cnt++;
VM_ASSERT(vm->ractor.blocking_cnt <= vm->ractor.cnt);
}
void
rb_vm_ractor_blocking_cnt_inc(rb_vm_t *vm, rb_ractor_t *cr, const char *file, int line)
{
ASSERT_vm_locking();
VM_ASSERT(GET_RACTOR() == cr);
vm_ractor_blocking_cnt_inc(vm, cr, file, line);
}
void
rb_vm_ractor_blocking_cnt_dec(rb_vm_t *vm, rb_ractor_t *cr, const char *file, int line)
{
ASSERT_vm_locking();
VM_ASSERT(GET_RACTOR() == cr);
RUBY_DEBUG_LOG2(file, line, "vm->ractor.blocking_cnt:%d--", vm->ractor.blocking_cnt);
VM_ASSERT(vm->ractor.blocking_cnt > 0);
vm->ractor.blocking_cnt--;
ractor_status_set(cr, ractor_running);
}
static void
2020-09-05 19:58:44 +03:00
ractor_check_blocking(rb_ractor_t *cr, unsigned int remained_thread_cnt, const char *file, int line)
{
VM_ASSERT(cr == GET_RACTOR());
RUBY_DEBUG_LOG2(file, line,
"cr->threads.cnt:%u cr->threads.blocking_cnt:%u vm->ractor.cnt:%u vm->ractor.blocking_cnt:%u",
cr->threads.cnt, cr->threads.blocking_cnt,
GET_VM()->ractor.cnt, GET_VM()->ractor.blocking_cnt);
VM_ASSERT(cr->threads.cnt >= cr->threads.blocking_cnt + 1);
2020-09-05 19:58:44 +03:00
if (remained_thread_cnt > 0 &&
// will be block
cr->threads.cnt == cr->threads.blocking_cnt + 1) {
// change ractor status: running -> blocking
rb_vm_t *vm = GET_VM();
ASSERT_vm_unlocking();
RB_VM_LOCK();
{
rb_vm_ractor_blocking_cnt_inc(vm, cr, file, line);
}
RB_VM_UNLOCK();
}
}
void rb_threadptr_remove(rb_thread_t *th);
void
rb_ractor_living_threads_remove(rb_ractor_t *cr, rb_thread_t *th)
{
VM_ASSERT(cr == GET_RACTOR());
RUBY_DEBUG_LOG("r->threads.cnt:%d--", cr->threads.cnt);
ractor_check_blocking(cr, cr->threads.cnt - 1, __FILE__, __LINE__);
rb_threadptr_remove(th);
if (cr->threads.cnt == 1) {
vm_remove_ractor(th->vm, cr);
}
else {
RACTOR_LOCK(cr);
{
ccan_list_del(&th->lt_node);
cr->threads.cnt--;
}
RACTOR_UNLOCK(cr);
}
}
void
rb_ractor_blocking_threads_inc(rb_ractor_t *cr, const char *file, int line)
{
RUBY_DEBUG_LOG2(file, line, "cr->threads.blocking_cnt:%d++", cr->threads.blocking_cnt);
VM_ASSERT(cr->threads.cnt > 0);
VM_ASSERT(cr == GET_RACTOR());
ractor_check_blocking(cr, cr->threads.cnt, __FILE__, __LINE__);
cr->threads.blocking_cnt++;
}
void
rb_ractor_blocking_threads_dec(rb_ractor_t *cr, const char *file, int line)
{
RUBY_DEBUG_LOG2(file, line,
"r->threads.blocking_cnt:%d--, r->threads.cnt:%u",
cr->threads.blocking_cnt, cr->threads.cnt);
VM_ASSERT(cr == GET_RACTOR());
if (cr->threads.cnt == cr->threads.blocking_cnt) {
rb_vm_t *vm = GET_VM();
RB_VM_LOCK_ENTER();
{
rb_vm_ractor_blocking_cnt_dec(vm, cr, __FILE__, __LINE__);
}
RB_VM_LOCK_LEAVE();
}
cr->threads.blocking_cnt--;
}
void
rb_ractor_vm_barrier_interrupt_running_thread(rb_ractor_t *r)
{
VM_ASSERT(r != GET_RACTOR());
ASSERT_ractor_unlocking(r);
ASSERT_vm_locking();
RACTOR_LOCK(r);
{
if (ractor_status_p(r, ractor_running)) {
rb_execution_context_t *ec = r->threads.running_ec;
if (ec) {
RUBY_VM_SET_VM_BARRIER_INTERRUPT(ec);
}
}
}
RACTOR_UNLOCK(r);
}
void
rb_ractor_terminate_interrupt_main_thread(rb_ractor_t *r)
{
VM_ASSERT(r != GET_RACTOR());
ASSERT_ractor_unlocking(r);
ASSERT_vm_locking();
rb_thread_t *main_th = r->threads.main;
if (main_th) {
if (main_th->status != THREAD_KILLED) {
RUBY_VM_SET_TERMINATE_INTERRUPT(main_th->ec);
rb_threadptr_interrupt(main_th);
}
else {
RUBY_DEBUG_LOG("killed (%p)", (void *)main_th);
}
}
}
void rb_thread_terminate_all(rb_thread_t *th); // thread.c
static void
ractor_terminal_interrupt_all(rb_vm_t *vm)
{
if (vm->ractor.cnt > 1) {
// send terminate notification to all ractors
rb_ractor_t *r = 0;
ccan_list_for_each(&vm->ractor.set, r, vmlr_node) {
if (r != vm->ractor.main_ractor) {
RUBY_DEBUG_LOG("r:%d", rb_ractor_id(r));
rb_ractor_terminate_interrupt_main_thread(r);
}
}
}
}
void rb_add_running_thread(rb_thread_t *th);
void rb_del_running_thread(rb_thread_t *th);
void
rb_ractor_terminate_all(void)
{
rb_vm_t *vm = GET_VM();
rb_ractor_t *cr = vm->ractor.main_ractor;
RUBY_DEBUG_LOG("ractor.cnt:%d", (int)vm->ractor.cnt);
VM_ASSERT(cr == GET_RACTOR()); // only main-ractor's main-thread should kick it.
if (vm->ractor.cnt > 1) {
RB_VM_LOCK();
{
ractor_terminal_interrupt_all(vm); // kill all ractors
}
RB_VM_UNLOCK();
}
rb_thread_terminate_all(GET_THREAD()); // kill other threads in main-ractor and wait
RB_VM_LOCK();
{
while (vm->ractor.cnt > 1) {
RUBY_DEBUG_LOG("terminate_waiting:%d", vm->ractor.sync.terminate_waiting);
vm->ractor.sync.terminate_waiting = true;
// wait for 1sec
rb_vm_ractor_blocking_cnt_inc(vm, cr, __FILE__, __LINE__);
rb_del_running_thread(rb_ec_thread_ptr(cr->threads.running_ec));
rb_vm_cond_timedwait(vm, &vm->ractor.sync.terminate_cond, 1000 /* ms */);
rb_add_running_thread(rb_ec_thread_ptr(cr->threads.running_ec));
rb_vm_ractor_blocking_cnt_dec(vm, cr, __FILE__, __LINE__);
ractor_terminal_interrupt_all(vm);
}
}
RB_VM_UNLOCK();
}
rb_execution_context_t *
rb_vm_main_ractor_ec(rb_vm_t *vm)
{
/* This code needs to carefully work around two bugs:
* - Bug #20016: When M:N threading is enabled, running_ec is NULL if no thread is
* actually currently running (as opposed to without M:N threading, when
* running_ec will still point to the _last_ thread which ran)
* - Bug #20197: If the main thread is sleeping, setting its postponed job
* interrupt flag is pointless; it won't look at the flag until it stops sleeping
* for some reason. It would be better to set the flag on the running ec, which
* will presumably look at it soon.
*
* Solution: use running_ec if it's set, otherwise fall back to the main thread ec.
* This is still susceptible to some rare race conditions (what if the last thread
* to run just entered a long-running sleep?), but seems like the best balance of
* robustness and complexity.
*/
rb_execution_context_t *running_ec = vm->ractor.main_ractor->threads.running_ec;
if (running_ec) { return running_ec; }
return vm->ractor.main_thread->ec;
}
static VALUE
ractor_moved_missing(int argc, VALUE *argv, VALUE self)
{
rb_raise(rb_eRactorMovedError, "can not send any methods to a moved object");
}
#ifndef USE_RACTOR_SELECTOR
#define USE_RACTOR_SELECTOR 0
#endif
RUBY_SYMBOL_EXPORT_BEGIN
void rb_init_ractor_selector(void);
RUBY_SYMBOL_EXPORT_END
void
rb_init_ractor_selector(void)
{
rb_cRactorSelector = rb_define_class_under(rb_cRactor, "Selector", rb_cObject);
rb_undef_alloc_func(rb_cRactorSelector);
rb_define_singleton_method(rb_cRactorSelector, "new", ractor_selector_new , -1);
rb_define_method(rb_cRactorSelector, "add", ractor_selector_add, 1);
rb_define_method(rb_cRactorSelector, "remove", ractor_selector_remove, 1);
rb_define_method(rb_cRactorSelector, "clear", ractor_selector_clear, 0);
rb_define_method(rb_cRactorSelector, "empty?", ractor_selector_empty_p, 0);
rb_define_method(rb_cRactorSelector, "wait", ractor_selector_wait, -1);
rb_define_method(rb_cRactorSelector, "_wait", ractor_selector__wait, 4);
}
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/*
* Document-class: Ractor::ClosedError
*
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* Raised when an attempt is made to send a message to a closed port,
* or to retrieve a message from a closed and empty port.
* Ports may be closed explicitly with Ractor#close_outgoing/close_incoming
* and are closed implicitly when a Ractor terminates.
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*
* r = Ractor.new { sleep(500) }
* r.close_outgoing
* r.take # Ractor::ClosedError
*
* ClosedError is a descendant of StopIteration, so the closing of the ractor will break
* the loops without propagating the error:
*
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* r = Ractor.new do
* loop do
* msg = receive # raises ClosedError and loop traps it
* puts "Received: #{msg}"
* end
* puts "loop exited"
* end
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*
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* 3.times{|i| r << i}
* r.close_incoming
* r.take
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* puts "Continue successfully"
*
* This will print:
*
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* Received: 0
* Received: 1
* Received: 2
* loop exited
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* Continue successfully
*/
/*
* Document-class: Ractor::RemoteError
*
* Raised on attempt to Ractor#take if there was an uncaught exception in the Ractor.
* Its +cause+ will contain the original exception, and +ractor+ is the original ractor
* it was raised in.
*
* r = Ractor.new { raise "Something weird happened" }
*
* begin
* r.take
* rescue => e
* p e # => #<Ractor::RemoteError: thrown by remote Ractor.>
* p e.ractor == r # => true
* p e.cause # => #<RuntimeError: Something weird happened>
* end
*
*/
/*
* Document-class: Ractor::MovedError
*
* Raised on an attempt to access an object which was moved in Ractor#send or Ractor.yield.
*
* r = Ractor.new { sleep }
*
* ary = [1, 2, 3]
* r.send(ary, move: true)
* ary.inspect
* # Ractor::MovedError (can not send any methods to a moved object)
*
*/
/*
* Document-class: Ractor::MovedObject
*
* A special object which replaces any value that was moved to another ractor in Ractor#send
* or Ractor.yield. Any attempt to access the object results in Ractor::MovedError.
*
* r = Ractor.new { receive }
*
* ary = [1, 2, 3]
* r.send(ary, move: true)
* p Ractor::MovedObject === ary
* # => true
* ary.inspect
* # Ractor::MovedError (can not send any methods to a moved object)
*/
// Main docs are in ractor.rb, but without this clause there are weird artifacts
// in their rendering.
/*
* Document-class: Ractor
*
*/
void
Init_Ractor(void)
{
rb_cRactor = rb_define_class("Ractor", rb_cObject);
rb_undef_alloc_func(rb_cRactor);
rb_eRactorError = rb_define_class_under(rb_cRactor, "Error", rb_eRuntimeError);
rb_eRactorIsolationError = rb_define_class_under(rb_cRactor, "IsolationError", rb_eRactorError);
rb_eRactorRemoteError = rb_define_class_under(rb_cRactor, "RemoteError", rb_eRactorError);
rb_eRactorMovedError = rb_define_class_under(rb_cRactor, "MovedError", rb_eRactorError);
rb_eRactorClosedError = rb_define_class_under(rb_cRactor, "ClosedError", rb_eStopIteration);
rb_eRactorUnsafeError = rb_define_class_under(rb_cRactor, "UnsafeError", rb_eRactorError);
rb_cRactorMovedObject = rb_define_class_under(rb_cRactor, "MovedObject", rb_cBasicObject);
rb_undef_alloc_func(rb_cRactorMovedObject);
rb_define_method(rb_cRactorMovedObject, "method_missing", ractor_moved_missing, -1);
// override methods defined in BasicObject
rb_define_method(rb_cRactorMovedObject, "__send__", ractor_moved_missing, -1);
rb_define_method(rb_cRactorMovedObject, "!", ractor_moved_missing, -1);
rb_define_method(rb_cRactorMovedObject, "==", ractor_moved_missing, -1);
rb_define_method(rb_cRactorMovedObject, "!=", ractor_moved_missing, -1);
rb_define_method(rb_cRactorMovedObject, "__id__", ractor_moved_missing, -1);
rb_define_method(rb_cRactorMovedObject, "equal?", ractor_moved_missing, -1);
rb_define_method(rb_cRactorMovedObject, "instance_eval", ractor_moved_missing, -1);
rb_define_method(rb_cRactorMovedObject, "instance_exec", ractor_moved_missing, -1);
#if USE_RACTOR_SELECTOR
rb_init_ractor_selector();
#endif
}
void
rb_ractor_dump(void)
{
rb_vm_t *vm = GET_VM();
rb_ractor_t *r = 0;
ccan_list_for_each(&vm->ractor.set, r, vmlr_node) {
if (r != vm->ractor.main_ractor) {
fprintf(stderr, "r:%u (%s)\n", r->pub.id, ractor_status_str(r->status_));
}
}
}
VALUE
rb_ractor_stdin(void)
{
if (rb_ractor_main_p()) {
return rb_stdin;
}
else {
rb_ractor_t *cr = GET_RACTOR();
return cr->r_stdin;
}
}
VALUE
rb_ractor_stdout(void)
{
if (rb_ractor_main_p()) {
return rb_stdout;
}
else {
rb_ractor_t *cr = GET_RACTOR();
return cr->r_stdout;
}
}
VALUE
rb_ractor_stderr(void)
{
if (rb_ractor_main_p()) {
return rb_stderr;
}
else {
rb_ractor_t *cr = GET_RACTOR();
return cr->r_stderr;
}
}
void
rb_ractor_stdin_set(VALUE in)
{
if (rb_ractor_main_p()) {
rb_stdin = in;
}
else {
rb_ractor_t *cr = GET_RACTOR();
RB_OBJ_WRITE(cr->pub.self, &cr->r_stdin, in);
}
}
void
rb_ractor_stdout_set(VALUE out)
{
if (rb_ractor_main_p()) {
rb_stdout = out;
}
else {
rb_ractor_t *cr = GET_RACTOR();
RB_OBJ_WRITE(cr->pub.self, &cr->r_stdout, out);
}
}
void
rb_ractor_stderr_set(VALUE err)
{
if (rb_ractor_main_p()) {
rb_stderr = err;
}
else {
rb_ractor_t *cr = GET_RACTOR();
RB_OBJ_WRITE(cr->pub.self, &cr->r_stderr, err);
}
}
rb_hook_list_t *
rb_ractor_hooks(rb_ractor_t *cr)
{
return &cr->pub.hooks;
}
/// traverse function
// 2: stop search
// 1: skip child
// 0: continue
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enum obj_traverse_iterator_result {
traverse_cont,
traverse_skip,
traverse_stop,
};
typedef enum obj_traverse_iterator_result (*rb_obj_traverse_enter_func)(VALUE obj);
typedef enum obj_traverse_iterator_result (*rb_obj_traverse_leave_func)(VALUE obj);
typedef enum obj_traverse_iterator_result (*rb_obj_traverse_final_func)(VALUE obj);
static enum obj_traverse_iterator_result null_leave(VALUE obj);
struct obj_traverse_data {
rb_obj_traverse_enter_func enter_func;
rb_obj_traverse_leave_func leave_func;
st_table *rec;
VALUE rec_hash;
};
struct obj_traverse_callback_data {
bool stop;
struct obj_traverse_data *data;
};
static int obj_traverse_i(VALUE obj, struct obj_traverse_data *data);
static int
obj_hash_traverse_i(VALUE key, VALUE val, VALUE ptr)
{
struct obj_traverse_callback_data *d = (struct obj_traverse_callback_data *)ptr;
if (obj_traverse_i(key, d->data)) {
d->stop = true;
return ST_STOP;
}
if (obj_traverse_i(val, d->data)) {
d->stop = true;
return ST_STOP;
}
return ST_CONTINUE;
}
static void
obj_traverse_reachable_i(VALUE obj, void *ptr)
{
struct obj_traverse_callback_data *d = (struct obj_traverse_callback_data *)ptr;
if (obj_traverse_i(obj, d->data)) {
d->stop = true;
}
}
static struct st_table *
obj_traverse_rec(struct obj_traverse_data *data)
{
if (UNLIKELY(!data->rec)) {
data->rec_hash = rb_ident_hash_new();
data->rec = RHASH_ST_TABLE(data->rec_hash);
}
return data->rec;
}
static int
obj_traverse_ivar_foreach_i(ID key, VALUE val, st_data_t ptr)
{
struct obj_traverse_callback_data *d = (struct obj_traverse_callback_data *)ptr;
if (obj_traverse_i(val, d->data)) {
d->stop = true;
return ST_STOP;
}
return ST_CONTINUE;
}
static int
obj_traverse_i(VALUE obj, struct obj_traverse_data *data)
{
if (RB_SPECIAL_CONST_P(obj)) return 0;
switch (data->enter_func(obj)) {
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case traverse_cont: break;
case traverse_skip: return 0; // skip children
case traverse_stop: return 1; // stop search
}
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if (UNLIKELY(st_insert(obj_traverse_rec(data), obj, 1))) {
// already traversed
return 0;
}
struct obj_traverse_callback_data d = {
.stop = false,
.data = data,
};
rb_ivar_foreach(obj, obj_traverse_ivar_foreach_i, (st_data_t)&d);
if (d.stop) return 1;
switch (BUILTIN_TYPE(obj)) {
// no child node
case T_STRING:
case T_FLOAT:
case T_BIGNUM:
case T_REGEXP:
case T_FILE:
case T_SYMBOL:
case T_MATCH:
break;
case T_OBJECT:
/* Instance variables already traversed. */
break;
case T_ARRAY:
{
for (int i = 0; i < RARRAY_LENINT(obj); i++) {
VALUE e = rb_ary_entry(obj, i);
if (obj_traverse_i(e, data)) return 1;
}
}
break;
case T_HASH:
{
if (obj_traverse_i(RHASH_IFNONE(obj), data)) return 1;
struct obj_traverse_callback_data d = {
.stop = false,
.data = data,
};
rb_hash_foreach(obj, obj_hash_traverse_i, (VALUE)&d);
if (d.stop) return 1;
}
break;
case T_STRUCT:
{
long len = RSTRUCT_LEN(obj);
const VALUE *ptr = RSTRUCT_CONST_PTR(obj);
for (long i=0; i<len; i++) {
if (obj_traverse_i(ptr[i], data)) return 1;
}
}
break;
case T_RATIONAL:
if (obj_traverse_i(RRATIONAL(obj)->num, data)) return 1;
if (obj_traverse_i(RRATIONAL(obj)->den, data)) return 1;
break;
case T_COMPLEX:
if (obj_traverse_i(RCOMPLEX(obj)->real, data)) return 1;
if (obj_traverse_i(RCOMPLEX(obj)->imag, data)) return 1;
break;
case T_DATA:
case T_IMEMO:
{
struct obj_traverse_callback_data d = {
.stop = false,
.data = data,
};
RB_VM_LOCK_ENTER_NO_BARRIER();
{
rb_objspace_reachable_objects_from(obj, obj_traverse_reachable_i, &d);
}
RB_VM_LOCK_LEAVE_NO_BARRIER();
if (d.stop) return 1;
}
break;
// unreachable
case T_CLASS:
case T_MODULE:
case T_ICLASS:
default:
rp(obj);
rb_bug("unreachable");
}
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if (data->leave_func(obj) == traverse_stop) {
return 1;
}
else {
return 0;
}
}
struct rb_obj_traverse_final_data {
rb_obj_traverse_final_func final_func;
int stopped;
};
static int
obj_traverse_final_i(st_data_t key, st_data_t val, st_data_t arg)
{
struct rb_obj_traverse_final_data *data = (void *)arg;
if (data->final_func(key)) {
data->stopped = 1;
return ST_STOP;
}
return ST_CONTINUE;
}
// 0: traverse all
// 1: stopped
static int
rb_obj_traverse(VALUE obj,
rb_obj_traverse_enter_func enter_func,
rb_obj_traverse_leave_func leave_func,
rb_obj_traverse_final_func final_func)
{
struct obj_traverse_data data = {
.enter_func = enter_func,
.leave_func = leave_func,
.rec = NULL,
};
if (obj_traverse_i(obj, &data)) return 1;
if (final_func && data.rec) {
struct rb_obj_traverse_final_data f = {final_func, 0};
st_foreach(data.rec, obj_traverse_final_i, (st_data_t)&f);
return f.stopped;
}
return 0;
}
static int
frozen_shareable_p(VALUE obj, bool *made_shareable)
{
if (!RB_TYPE_P(obj, T_DATA)) {
return true;
}
else if (RTYPEDDATA_P(obj)) {
const rb_data_type_t *type = RTYPEDDATA_TYPE(obj);
if (type->flags & RUBY_TYPED_FROZEN_SHAREABLE) {
return true;
}
else if (made_shareable && rb_obj_is_proc(obj)) {
// special path to make shareable Proc.
rb_proc_ractor_make_shareable(obj);
*made_shareable = true;
VM_ASSERT(RB_OBJ_SHAREABLE_P(obj));
return false;
}
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}
return false;
}
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static enum obj_traverse_iterator_result
make_shareable_check_shareable(VALUE obj)
{
VM_ASSERT(!SPECIAL_CONST_P(obj));
bool made_shareable = false;
if (rb_ractor_shareable_p(obj)) {
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return traverse_skip;
}
else if (!frozen_shareable_p(obj, &made_shareable)) {
if (made_shareable) {
return traverse_skip;
}
else {
rb_raise(rb_eRactorError, "can not make shareable object for %"PRIsVALUE, obj);
}
}
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if (!RB_OBJ_FROZEN_RAW(obj)) {
rb_funcall(obj, idFreeze, 0);
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if (UNLIKELY(!RB_OBJ_FROZEN_RAW(obj))) {
rb_raise(rb_eRactorError, "#freeze does not freeze object correctly");
}
if (RB_OBJ_SHAREABLE_P(obj)) {
return traverse_skip;
}
}
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return traverse_cont;
}
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static enum obj_traverse_iterator_result
mark_shareable(VALUE obj)
{
FL_SET_RAW(obj, RUBY_FL_SHAREABLE);
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return traverse_cont;
}
VALUE
rb_ractor_make_shareable(VALUE obj)
{
rb_obj_traverse(obj,
make_shareable_check_shareable,
null_leave, mark_shareable);
return obj;
}
VALUE
rb_ractor_make_shareable_copy(VALUE obj)
{
VALUE copy = ractor_copy(obj);
return rb_ractor_make_shareable(copy);
}
VALUE
rb_ractor_ensure_shareable(VALUE obj, VALUE name)
{
if (!rb_ractor_shareable_p(obj)) {
VALUE message = rb_sprintf("cannot assign unshareable object to %"PRIsVALUE,
name);
rb_exc_raise(rb_exc_new_str(rb_eRactorIsolationError, message));
}
return obj;
}
void
rb_ractor_ensure_main_ractor(const char *msg)
{
if (!rb_ractor_main_p()) {
rb_raise(rb_eRactorIsolationError, "%s", msg);
}
}
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static enum obj_traverse_iterator_result
shareable_p_enter(VALUE obj)
{
if (RB_OBJ_SHAREABLE_P(obj)) {
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return traverse_skip;
}
else if (RB_TYPE_P(obj, T_CLASS) ||
RB_TYPE_P(obj, T_MODULE) ||
RB_TYPE_P(obj, T_ICLASS)) {
// TODO: remove it
mark_shareable(obj);
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return traverse_skip;
}
else if (RB_OBJ_FROZEN_RAW(obj) &&
frozen_shareable_p(obj, NULL)) {
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return traverse_cont;
}
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return traverse_stop; // fail
}
2023-03-07 08:34:31 +03:00
bool
rb_ractor_shareable_p_continue(VALUE obj)
{
if (rb_obj_traverse(obj,
shareable_p_enter, null_leave,
mark_shareable)) {
return false;
}
else {
return true;
}
}
#if RACTOR_CHECK_MODE > 0
static enum obj_traverse_iterator_result
reset_belonging_enter(VALUE obj)
{
if (rb_ractor_shareable_p(obj)) {
return traverse_skip;
}
else {
rb_ractor_setup_belonging(obj);
return traverse_cont;
}
}
#endif
static enum obj_traverse_iterator_result
null_leave(VALUE obj)
{
return traverse_cont;
}
static VALUE
ractor_reset_belonging(VALUE obj)
{
#if RACTOR_CHECK_MODE > 0
rb_obj_traverse(obj, reset_belonging_enter, null_leave, NULL);
#endif
return obj;
}
/// traverse and replace function
// 2: stop search
// 1: skip child
// 0: continue
struct obj_traverse_replace_data;
static int obj_traverse_replace_i(VALUE obj, struct obj_traverse_replace_data *data);
typedef enum obj_traverse_iterator_result (*rb_obj_traverse_replace_enter_func)(VALUE obj, struct obj_traverse_replace_data *data);
typedef enum obj_traverse_iterator_result (*rb_obj_traverse_replace_leave_func)(VALUE obj, struct obj_traverse_replace_data *data);
struct obj_traverse_replace_data {
rb_obj_traverse_replace_enter_func enter_func;
rb_obj_traverse_replace_leave_func leave_func;
st_table *rec;
VALUE rec_hash;
VALUE replacement;
bool move;
};
struct obj_traverse_replace_callback_data {
bool stop;
VALUE src;
struct obj_traverse_replace_data *data;
};
static int
obj_hash_traverse_replace_foreach_i(st_data_t key, st_data_t value, st_data_t argp, int error)
{
return ST_REPLACE;
}
static int
obj_hash_traverse_replace_i(st_data_t *key, st_data_t *val, st_data_t ptr, int exists)
{
struct obj_traverse_replace_callback_data *d = (struct obj_traverse_replace_callback_data *)ptr;
struct obj_traverse_replace_data *data = d->data;
if (obj_traverse_replace_i(*key, data)) {
d->stop = true;
return ST_STOP;
}
else if (*key != data->replacement) {
VALUE v = *key = data->replacement;
RB_OBJ_WRITTEN(d->src, Qundef, v);
}
if (obj_traverse_replace_i(*val, data)) {
d->stop = true;
return ST_STOP;
}
else if (*val != data->replacement) {
VALUE v = *val = data->replacement;
RB_OBJ_WRITTEN(d->src, Qundef, v);
}
return ST_CONTINUE;
}
static int
obj_iv_hash_traverse_replace_foreach_i(st_data_t _key, st_data_t _val, st_data_t _data, int _x)
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
{
return ST_REPLACE;
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
}
static int
obj_iv_hash_traverse_replace_i(st_data_t * _key, st_data_t * val, st_data_t ptr, int exists)
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
{
struct obj_traverse_replace_callback_data *d = (struct obj_traverse_replace_callback_data *)ptr;
struct obj_traverse_replace_data *data = d->data;
if (obj_traverse_replace_i(*(VALUE *)val, data)) {
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
d->stop = true;
return ST_STOP;
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
}
else if (*(VALUE *)val != data->replacement) {
VALUE v = *(VALUE *)val = data->replacement;
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
RB_OBJ_WRITTEN(d->src, Qundef, v);
}
return ST_CONTINUE;
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
}
static struct st_table *
obj_traverse_replace_rec(struct obj_traverse_replace_data *data)
{
if (UNLIKELY(!data->rec)) {
data->rec_hash = rb_ident_hash_new();
data->rec = RHASH_ST_TABLE(data->rec_hash);
}
return data->rec;
}
static void
obj_refer_only_shareables_p_i(VALUE obj, void *ptr)
{
int *pcnt = (int *)ptr;
if (!rb_ractor_shareable_p(obj)) {
++*pcnt;
}
}
static int
obj_refer_only_shareables_p(VALUE obj)
{
int cnt = 0;
RB_VM_LOCK_ENTER_NO_BARRIER();
{
rb_objspace_reachable_objects_from(obj, obj_refer_only_shareables_p_i, &cnt);
}
RB_VM_LOCK_LEAVE_NO_BARRIER();
return cnt == 0;
}
static int
obj_traverse_replace_i(VALUE obj, struct obj_traverse_replace_data *data)
{
2022-04-07 13:19:13 +03:00
st_data_t replacement;
if (RB_SPECIAL_CONST_P(obj)) {
data->replacement = obj;
return 0;
}
switch (data->enter_func(obj, data)) {
case traverse_cont: break;
case traverse_skip: return 0; // skip children
case traverse_stop: return 1; // stop search
}
2022-04-07 13:19:13 +03:00
replacement = (st_data_t)data->replacement;
2022-04-07 13:19:13 +03:00
if (UNLIKELY(st_lookup(obj_traverse_replace_rec(data), (st_data_t)obj, &replacement))) {
data->replacement = (VALUE)replacement;
return 0;
}
else {
2022-04-07 13:19:13 +03:00
st_insert(obj_traverse_replace_rec(data), (st_data_t)obj, replacement);
}
if (!data->move) {
obj = replacement;
}
#define CHECK_AND_REPLACE(v) do { \
VALUE _val = (v); \
if (obj_traverse_replace_i(_val, data)) { return 1; } \
else if (data->replacement != _val) { RB_OBJ_WRITE(obj, &v, data->replacement); } \
} while (0)
if (UNLIKELY(FL_TEST_RAW(obj, FL_EXIVAR))) {
struct gen_ivtbl *ivtbl;
rb_ivar_generic_ivtbl_lookup(obj, &ivtbl);
if (UNLIKELY(rb_shape_obj_too_complex(obj))) {
struct obj_traverse_replace_callback_data d = {
.stop = false,
.data = data,
.src = obj,
};
rb_st_foreach_with_replace(
ivtbl->as.complex.table,
obj_iv_hash_traverse_replace_foreach_i,
obj_iv_hash_traverse_replace_i,
(st_data_t)&d
);
if (d.stop) return 1;
}
else {
for (uint32_t i = 0; i < ivtbl->as.shape.numiv; i++) {
if (!UNDEF_P(ivtbl->as.shape.ivptr[i])) {
CHECK_AND_REPLACE(ivtbl->as.shape.ivptr[i]);
}
}
}
}
switch (BUILTIN_TYPE(obj)) {
// no child node
case T_FLOAT:
case T_BIGNUM:
case T_REGEXP:
case T_FILE:
case T_SYMBOL:
case T_MATCH:
break;
case T_STRING:
rb_str_make_independent(obj);
break;
case T_OBJECT:
{
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
if (rb_shape_obj_too_complex(obj)) {
struct obj_traverse_replace_callback_data d = {
.stop = false,
.data = data,
.src = obj,
};
rb_st_foreach_with_replace(
ROBJECT_IV_HASH(obj),
obj_iv_hash_traverse_replace_foreach_i,
obj_iv_hash_traverse_replace_i,
(st_data_t)&d
);
if (d.stop) return 1;
Transition complex objects to "too complex" shape When an object becomes "too complex" (in other words it has too many variations in the shape tree), we transition it to use a "too complex" shape and use a hash for storing instance variables. Without this patch, there were rare cases where shape tree growth could "explode" and cause performance degradation on what would otherwise have been cached fast paths. This patch puts a limit on shape tree growth, and gracefully degrades in the rare case where there could be a factorial growth in the shape tree. For example: ```ruby class NG; end HUGE_NUMBER.times do NG.new.instance_variable_set(:"@unique_ivar_#{_1}", 1) end ``` We consider objects to be "too complex" when the object's class has more than SHAPE_MAX_VARIATIONS (currently 8) leaf nodes in the shape tree and the object introduces a new variation (a new leaf node) associated with that class. For example, new variations on instances of the following class would be considered "too complex" because those instances create more than 8 leaves in the shape tree: ```ruby class Foo; end 9.times { Foo.new.instance_variable_set(":@uniq_#{_1}", 1) } ``` However, the following class is *not* too complex because it only has one leaf in the shape tree: ```ruby class Foo def initialize @a = @b = @c = @d = @e = @f = @g = @h = @i = nil end end 9.times { Foo.new } `` This case is rare, so we don't expect this change to impact performance of most applications, but it needs to be handled. Co-Authored-By: Aaron Patterson <tenderlove@ruby-lang.org>
2022-12-09 01:16:52 +03:00
}
else {
uint32_t len = ROBJECT_IV_COUNT(obj);
VALUE *ptr = ROBJECT_IVPTR(obj);
for (uint32_t i = 0; i < len; i++) {
CHECK_AND_REPLACE(ptr[i]);
}
}
}
break;
case T_ARRAY:
{
rb_ary_cancel_sharing(obj);
for (int i = 0; i < RARRAY_LENINT(obj); i++) {
VALUE e = rb_ary_entry(obj, i);
if (obj_traverse_replace_i(e, data)) {
return 1;
}
else if (e != data->replacement) {
RARRAY_ASET(obj, i, data->replacement);
}
}
RB_GC_GUARD(obj);
}
break;
case T_HASH:
{
struct obj_traverse_replace_callback_data d = {
.stop = false,
.data = data,
.src = obj,
};
rb_hash_stlike_foreach_with_replace(obj,
obj_hash_traverse_replace_foreach_i,
obj_hash_traverse_replace_i,
(VALUE)&d);
if (d.stop) return 1;
// TODO: rehash here?
VALUE ifnone = RHASH_IFNONE(obj);
if (obj_traverse_replace_i(ifnone, data)) {
return 1;
}
else if (ifnone != data->replacement) {
RHASH_SET_IFNONE(obj, data->replacement);
}
}
break;
case T_STRUCT:
{
long len = RSTRUCT_LEN(obj);
const VALUE *ptr = RSTRUCT_CONST_PTR(obj);
for (long i=0; i<len; i++) {
CHECK_AND_REPLACE(ptr[i]);
}
}
break;
case T_RATIONAL:
CHECK_AND_REPLACE(RRATIONAL(obj)->num);
CHECK_AND_REPLACE(RRATIONAL(obj)->den);
break;
case T_COMPLEX:
CHECK_AND_REPLACE(RCOMPLEX(obj)->real);
CHECK_AND_REPLACE(RCOMPLEX(obj)->imag);
break;
case T_DATA:
if (!data->move && obj_refer_only_shareables_p(obj)) {
break;
}
else {
rb_raise(rb_eRactorError, "can not %s %"PRIsVALUE" object.",
data->move ? "move" : "copy", rb_class_of(obj));
}
case T_IMEMO:
// not supported yet
return 1;
// unreachable
case T_CLASS:
case T_MODULE:
case T_ICLASS:
default:
rp(obj);
rb_bug("unreachable");
}
2022-04-07 13:19:13 +03:00
data->replacement = (VALUE)replacement;
if (data->leave_func(obj, data) == traverse_stop) {
return 1;
}
else {
return 0;
}
}
// 0: traverse all
// 1: stopped
static VALUE
rb_obj_traverse_replace(VALUE obj,
rb_obj_traverse_replace_enter_func enter_func,
rb_obj_traverse_replace_leave_func leave_func,
bool move)
{
struct obj_traverse_replace_data data = {
.enter_func = enter_func,
.leave_func = leave_func,
.rec = NULL,
.replacement = Qundef,
.move = move,
};
if (obj_traverse_replace_i(obj, &data)) {
return Qundef;
}
else {
return data.replacement;
}
}
struct RVALUE {
VALUE flags;
VALUE klass;
VALUE v1;
VALUE v2;
VALUE v3;
};
2020-11-02 11:31:50 +03:00
static const VALUE fl_users = FL_USER1 | FL_USER2 | FL_USER3 |
FL_USER4 | FL_USER5 | FL_USER6 | FL_USER7 |
FL_USER8 | FL_USER9 | FL_USER10 | FL_USER11 |
FL_USER12 | FL_USER13 | FL_USER14 | FL_USER15 |
FL_USER16 | FL_USER17 | FL_USER18 | FL_USER19;
static void
ractor_moved_bang(VALUE obj)
{
// invalidate src object
struct RVALUE *rv = (void *)obj;
rv->klass = rb_cRactorMovedObject;
rv->v1 = 0;
rv->v2 = 0;
rv->v3 = 0;
rv->flags = rv->flags & ~fl_users;
if (BUILTIN_TYPE(obj) == T_OBJECT) ROBJECT_SET_SHAPE_ID(obj, ROOT_SHAPE_ID);
// TODO: record moved location
}
static enum obj_traverse_iterator_result
move_enter(VALUE obj, struct obj_traverse_replace_data *data)
{
if (rb_ractor_shareable_p(obj)) {
data->replacement = obj;
return traverse_skip;
}
else {
VALUE moved = rb_obj_alloc(RBASIC_CLASS(obj));
rb_shape_set_shape(moved, rb_shape_get_shape(obj));
data->replacement = moved;
return traverse_cont;
}
}
void rb_replace_generic_ivar(VALUE clone, VALUE obj); // variable.c
static enum obj_traverse_iterator_result
move_leave(VALUE obj, struct obj_traverse_replace_data *data)
{
VALUE v = data->replacement;
struct RVALUE *dst = (struct RVALUE *)v;
struct RVALUE *src = (struct RVALUE *)obj;
dst->flags = (dst->flags & ~fl_users) | (src->flags & fl_users);
dst->v1 = src->v1;
dst->v2 = src->v2;
dst->v3 = src->v3;
if (UNLIKELY(FL_TEST_RAW(obj, FL_EXIVAR))) {
rb_replace_generic_ivar(v, obj);
}
// TODO: generic_ivar
ractor_moved_bang(obj);
return traverse_cont;
}
static VALUE
ractor_move(VALUE obj)
{
VALUE val = rb_obj_traverse_replace(obj, move_enter, move_leave, true);
2022-11-15 07:24:08 +03:00
if (!UNDEF_P(val)) {
return val;
}
else {
rb_raise(rb_eRactorError, "can not move the object");
}
}
static enum obj_traverse_iterator_result
copy_enter(VALUE obj, struct obj_traverse_replace_data *data)
{
if (rb_ractor_shareable_p(obj)) {
data->replacement = obj;
return traverse_skip;
}
else {
data->replacement = rb_obj_clone(obj);
return traverse_cont;
}
}
static enum obj_traverse_iterator_result
copy_leave(VALUE obj, struct obj_traverse_replace_data *data)
{
return traverse_cont;
}
static VALUE
ractor_copy(VALUE obj)
{
VALUE val = rb_obj_traverse_replace(obj, copy_enter, copy_leave, false);
2022-11-15 07:24:08 +03:00
if (!UNDEF_P(val)) {
return val;
}
else {
rb_raise(rb_eRactorError, "can not copy the object");
}
}
// Ractor local storage
struct rb_ractor_local_key_struct {
const struct rb_ractor_local_storage_type *type;
void *main_cache;
};
static struct freed_ractor_local_keys_struct {
int cnt;
int capa;
rb_ractor_local_key_t *keys;
} freed_ractor_local_keys;
static int
ractor_local_storage_mark_i(st_data_t key, st_data_t val, st_data_t dmy)
{
struct rb_ractor_local_key_struct *k = (struct rb_ractor_local_key_struct *)key;
if (k->type->mark) (*k->type->mark)((void *)val);
return ST_CONTINUE;
}
static enum rb_id_table_iterator_result
idkey_local_storage_mark_i(ID id, VALUE val, void *dmy)
{
rb_gc_mark(val);
return ID_TABLE_CONTINUE;
}
static void
ractor_local_storage_mark(rb_ractor_t *r)
{
if (r->local_storage) {
st_foreach(r->local_storage, ractor_local_storage_mark_i, 0);
for (int i=0; i<freed_ractor_local_keys.cnt; i++) {
rb_ractor_local_key_t key = freed_ractor_local_keys.keys[i];
2022-04-07 13:19:13 +03:00
st_data_t val, k = (st_data_t)key;
if (st_delete(r->local_storage, &k, &val) &&
(key = (rb_ractor_local_key_t)k)->type->free) {
(*key->type->free)((void *)val);
}
}
}
if (r->idkey_local_storage) {
rb_id_table_foreach(r->idkey_local_storage, idkey_local_storage_mark_i, NULL);
}
}
static int
ractor_local_storage_free_i(st_data_t key, st_data_t val, st_data_t dmy)
{
struct rb_ractor_local_key_struct *k = (struct rb_ractor_local_key_struct *)key;
if (k->type->free) (*k->type->free)((void *)val);
return ST_CONTINUE;
}
static void
ractor_local_storage_free(rb_ractor_t *r)
{
if (r->local_storage) {
st_foreach(r->local_storage, ractor_local_storage_free_i, 0);
st_free_table(r->local_storage);
}
if (r->idkey_local_storage) {
rb_id_table_free(r->idkey_local_storage);
}
}
static void
rb_ractor_local_storage_value_mark(void *ptr)
{
rb_gc_mark((VALUE)ptr);
}
static const struct rb_ractor_local_storage_type ractor_local_storage_type_null = {
NULL,
NULL,
};
const struct rb_ractor_local_storage_type rb_ractor_local_storage_type_free = {
NULL,
ruby_xfree,
};
static const struct rb_ractor_local_storage_type ractor_local_storage_type_value = {
rb_ractor_local_storage_value_mark,
NULL,
};
rb_ractor_local_key_t
rb_ractor_local_storage_ptr_newkey(const struct rb_ractor_local_storage_type *type)
{
rb_ractor_local_key_t key = ALLOC(struct rb_ractor_local_key_struct);
key->type = type ? type : &ractor_local_storage_type_null;
key->main_cache = (void *)Qundef;
return key;
}
rb_ractor_local_key_t
rb_ractor_local_storage_value_newkey(void)
{
return rb_ractor_local_storage_ptr_newkey(&ractor_local_storage_type_value);
}
void
rb_ractor_local_storage_delkey(rb_ractor_local_key_t key)
{
RB_VM_LOCK_ENTER();
{
if (freed_ractor_local_keys.cnt == freed_ractor_local_keys.capa) {
freed_ractor_local_keys.capa = freed_ractor_local_keys.capa ? freed_ractor_local_keys.capa * 2 : 4;
REALLOC_N(freed_ractor_local_keys.keys, rb_ractor_local_key_t, freed_ractor_local_keys.capa);
}
freed_ractor_local_keys.keys[freed_ractor_local_keys.cnt++] = key;
}
RB_VM_LOCK_LEAVE();
}
static bool
ractor_local_ref(rb_ractor_local_key_t key, void **pret)
{
if (rb_ractor_main_p()) {
2022-11-15 07:24:08 +03:00
if (!UNDEF_P((VALUE)key->main_cache)) {
*pret = key->main_cache;
return true;
}
else {
return false;
}
}
else {
rb_ractor_t *cr = GET_RACTOR();
if (cr->local_storage && st_lookup(cr->local_storage, (st_data_t)key, (st_data_t *)pret)) {
return true;
}
else {
return false;
}
}
}
static void
ractor_local_set(rb_ractor_local_key_t key, void *ptr)
{
rb_ractor_t *cr = GET_RACTOR();
if (cr->local_storage == NULL) {
cr->local_storage = st_init_numtable();
}
st_insert(cr->local_storage, (st_data_t)key, (st_data_t)ptr);
if (rb_ractor_main_p()) {
key->main_cache = ptr;
}
}
VALUE
rb_ractor_local_storage_value(rb_ractor_local_key_t key)
{
2022-04-07 13:19:13 +03:00
void *val;
if (ractor_local_ref(key, &val)) {
return (VALUE)val;
}
else {
return Qnil;
}
}
bool
rb_ractor_local_storage_value_lookup(rb_ractor_local_key_t key, VALUE *val)
{
if (ractor_local_ref(key, (void **)val)) {
return true;
}
else {
return false;
}
}
void
rb_ractor_local_storage_value_set(rb_ractor_local_key_t key, VALUE val)
{
ractor_local_set(key, (void *)val);
}
void *
rb_ractor_local_storage_ptr(rb_ractor_local_key_t key)
{
void *ret;
if (ractor_local_ref(key, &ret)) {
return ret;
}
else {
return NULL;
}
}
void
rb_ractor_local_storage_ptr_set(rb_ractor_local_key_t key, void *ptr)
{
ractor_local_set(key, ptr);
}
#define DEFAULT_KEYS_CAPA 0x10
void
rb_ractor_finish_marking(void)
{
for (int i=0; i<freed_ractor_local_keys.cnt; i++) {
ruby_xfree(freed_ractor_local_keys.keys[i]);
}
freed_ractor_local_keys.cnt = 0;
if (freed_ractor_local_keys.capa > DEFAULT_KEYS_CAPA) {
freed_ractor_local_keys.capa = DEFAULT_KEYS_CAPA;
REALLOC_N(freed_ractor_local_keys.keys, rb_ractor_local_key_t, DEFAULT_KEYS_CAPA);
}
}
static VALUE
ractor_local_value(rb_execution_context_t *ec, VALUE self, VALUE sym)
{
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
ID id = rb_check_id(&sym);
struct rb_id_table *tbl = cr->idkey_local_storage;
VALUE val;
if (id && tbl && rb_id_table_lookup(tbl, id, &val)) {
return val;
}
else {
return Qnil;
}
}
static VALUE
ractor_local_value_set(rb_execution_context_t *ec, VALUE self, VALUE sym, VALUE val)
{
rb_ractor_t *cr = rb_ec_ractor_ptr(ec);
ID id = SYM2ID(rb_to_symbol(sym));
struct rb_id_table *tbl = cr->idkey_local_storage;
if (tbl == NULL) {
tbl = cr->idkey_local_storage = rb_id_table_create(2);
}
rb_id_table_insert(tbl, id, val);
return val;
}
#include "ractor.rbinc"