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xo-umbrella2/xo-gc/src/gc/GCObjectStore.cpp

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/** @file GCObjectStore.cpp
*
* @author Roland Conybeare, Apr 2026
**/
#include "GCObjectStore.hpp"
#include "GCObjectStoreVisitor.hpp"
#include "X1VerifyStats.hpp"
#include <xo/object2/Dictionary.hpp>
#include <xo/object2/Array.hpp>
#include <xo/object2/Integer.hpp>
#include <xo/object2/Boolean.hpp>
#include <xo/stringtable2/String.hpp>
#include <xo/arena/DArenaIterator.hpp>
#include <xo/arena/backtrace.hpp>
#include <xo/facet/TypeRegistry.hpp>
#include <xo/indentlog/scope.hpp>
#include <cassert>
#include <unistd.h> // for ::getpagesize()
namespace xo {
using xo::scm::DDictionary;
using xo::scm::DArray;
using xo::scm::DString;
using xo::scm::DInteger;
using xo::mm::DArena;
using xo::facet::TypeRegistry;
using xo::reflect::typeseq;
namespace mm {
GCObjectStore::GCObjectStore(const GCObjectStoreConfig & cfg,
X1VerifyStats * p_verify_stats)
: config_{cfg}, p_verify_stats_{p_verify_stats}
{
assert(config_.arena_config_.header_.size_bits_ +
config_.arena_config_.header_.age_bits_ +
config_.arena_config_.header_.tseq_bits_ <= 64);
size_t page_z = getpagesize();
this->_init_object_types(page_z);
this->_init_space();
}
void
GCObjectStore::_init_object_types(std::size_t page_z)
{
/* 1MB reserved address space enough for up to 128k distinct types.
* In this case don't want to use hugepages since actual #of types
* likely << .size/8
*/
this->object_types_
= ObjectTypeTable::map(ArenaConfig{.name_ = "x1-object-types",
.size_ = config_.object_types_z_,
.hugepage_z_ = page_z,
.store_header_flag_ = false});
}
void
GCObjectStore::_init_space()
{
assert(c_n_role == 2);
for (uint32_t igen = 0, ngen = config_.n_generation_; igen < ngen; ++igen) {
if (igen < c_max_generation) {
{
char buf[40];
snprintf(buf, sizeof(buf), "x1-space-G%u-a", igen);
this->space_storage_[0][igen]
= DArena::map(config_.arena_config_.with_name(std::string(buf)));
}
{
char buf[40];
snprintf(buf, sizeof(buf), "x1-space-G%u-b", igen);
this->space_storage_[1][igen]
= DArena::map(config_.arena_config_.with_name(std::string(buf)));
}
this->space_[Role::to_space()][igen] = &space_storage_[0][igen];
this->space_[Role::from_space()][igen] = &space_storage_[1][igen];
} else {
assert(false);
}
}
for (uint32_t igen = config_.n_generation_; igen < c_max_generation; ++igen) {
this->space_[Role::to_space()][igen] = nullptr;
this->space_[Role::from_space()][igen] = nullptr;
}
if (config_.n_generation_ == 2) {
assert(this->get_space(Role::to_space(), Generation{2}) == nullptr);
}
}
bool
GCObjectStore::is_type_installed(typeseq tseq) const noexcept
{
if (tseq.is_sentinel()
|| static_cast<ObjectTypeTable::size_type>(tseq.seqno()) > object_types_.size()) {
return false;
}
const ObjectTypeSlot & slot = object_types_[tseq.seqno()];
return slot.is_occupied();
}
AGCObject *
GCObjectStore::lookup_type(typeseq tseq) const noexcept
{
scope log(XO_DEBUG(false));
if (tseq.is_sentinel()
|| (static_cast<ObjectTypeTable::size_type>(tseq.seqno())
> object_types_.size())) {
// LCOV_EXCL_START
log.retroactively_enable("out-of-bounds",
xtag("tseq", tseq),
xtag("tname", TypeRegistry::id2name(tseq)));
log(xtag("types.size", object_types_.size()),
xtag("types.allocated", object_types_.store()->allocated()),
xtag("types.committed", object_types_.store()->committed()),
xtag("types.lo", object_types_.store()->lo_),
xtag("types.limit", object_types_.store()->limit_),
xtag("types.hi", object_types_.store()->hi_));
return nullptr;
// LCOV_EXCL_STOP
}
const ObjectTypeSlot & slot = object_types_[tseq.seqno()];
if (slot.is_null()) {
// LCOV_EXCL_START
log.retroactively_enable("null-vtable",
xtag("tseq", tseq),
xtag("tname", TypeRegistry::id2name(tseq)));
assert(false);
return nullptr;
// LCOV_EXCL_STOP
}
return slot.iface();
}
namespace {
using size_type = GCObjectStore::size_type;
size_type
stat_helper(const GCObjectStore & d,
size_type (DArena::* getter)() const,
Generation g,
Role r)
{
const DArena * arena = d.get_space(r, g);
if (arena) [[likely]] {
return (arena->*getter)();
}
return 0;
}
}
auto
GCObjectStore::allocated(Generation g, Role r) const noexcept -> size_type
{
return stat_helper(*this, &DArena::allocated, g, r);
}
auto
GCObjectStore::committed(Generation g, Role r) const noexcept -> size_type
{
return stat_helper(*this, &DArena::committed, g, r);
}
auto
GCObjectStore::reserved(Generation g, Role r) const noexcept -> size_type
{
return stat_helper(*this, &DArena::reserved, g, r);
}
Generation
GCObjectStore::generation_of(Role r, const void * addr) const noexcept
{
for (Generation gi{0}; gi < config_.n_generation_; ++gi) {
const DArena * arena = this->get_space(r, gi);
if (arena->contains(addr))
return gi;
}
return Generation::sentinel();
}
AllocError
GCObjectStore::last_error() const noexcept
{
return this->get_space(Role::to_space(), Generation{0})->last_error();
}
auto
GCObjectStore::header2size(header_type hdr) const noexcept -> size_type
{
uint32_t z = config_.arena_config_.header_.size(hdr);
return z;
}
object_age
GCObjectStore::header2age(header_type hdr) const noexcept
{
uint32_t age = config_.arena_config_.header_.age(hdr);
assert(age < c_max_object_age);
return object_age(age);
}
uint32_t
GCObjectStore::header2tseq(header_type hdr) const noexcept
{
uint32_t tseq = config_.arena_config_.header_.tseq(hdr);
return tseq;
}
bool
GCObjectStore::is_forwarding_header(header_type hdr) const noexcept
{
/** forwarding pointer encoded as sentinel tseq **/
return config_.arena_config_.header_.is_forwarding_tseq(hdr);
}
AllocInfo
GCObjectStore::alloc_info(value_type mem) const noexcept {
for (Role ri : Role::all()) {
for (Generation gj{0}; gj < config_.n_generation_; ++gj) {
const DArena * arena = this->get_space(ri, gj);
assert(arena);
if (arena->contains(mem)) {
return arena->alloc_info(mem);
}
}
}
// deliberately attempt on nursery to-space, to capture error info + return sentinel
return this->get_space(Role::to_space(), Generation{0})->alloc_info(mem);
}
void
GCObjectStore::visit_pools(const MemorySizeVisitor & visitor) const
{
for (uint32_t j = 0; j < config_.n_generation_; ++j) {
for (uint32_t i = 0; i < c_n_role; ++i) {
space_storage_[i][j].visit_pools(visitor);
}
}
object_types_.visit_pools(visitor);
}
bool
GCObjectStore::contains(Role r, const void * addr) const noexcept
{
return !(this->generation_of(r, addr).is_sentinel());
}
bool
GCObjectStore::contains_allocated(Role r, const void * addr) const noexcept
{
Generation g = this->generation_of(r, addr);
if (g.is_sentinel())
return false;
return this->get_space(r, g)->contains_allocated(addr);
}
bool
GCObjectStore::report_object_types(obj<AAllocator> mm,
obj<AAllocator> error_mm,
obj<AGCObject> * p_output) const noexcept
{
scope log(XO_DEBUG(this->config_.debug_flag_));
(void)error_mm;
bool ok = true;
// stats, indexed by tseq
// could use c++ vector in scratch space instead of running on
// boxed types.
//
DArray * stats_v = DArray::empty(mm, object_types_.size());
if (!stats_v)
return false;
stats_v->resize(stats_v->capacity());
log && log(xtag("object_types_.size", object_types_.size()),
xtag("stats_v.capacity", stats_v->capacity()),
xtag("stats_v.size", stats_v->size()));
// count #of occupied type slots
std::uint32_t n_tseq_present = 0;
// largest tseq present with non-null AGCObject* iface
std::int32_t max_tseq = 0;
for (const ObjectTypeSlot & slot : object_types_) {
AGCObject * iface = slot.iface();
if (iface) {
typeseq tseq = iface->_typeseq();
++n_tseq_present;
if (max_tseq < tseq.seqno())
max_tseq = tseq.seqno();
assert(tseq.seqno() >= 0);
auto tname_sv = TypeRegistry::id2name(tseq);
DString * tname = DString::from_view(mm, tname_sv);
DDictionary * recd = DDictionary::make(mm);
if (!recd)
return false;
recd->upsert_cstr(mm, "name", obj<AGCObject,DString>(tname));
recd->upsert_cstr(mm, "tseq", DInteger::box(mm, tseq.seqno()));
recd->upsert_cstr(mm, "n-live", DInteger::box(mm, 0));
recd->upsert_cstr(mm, "bytes", DInteger::box(mm, 0));
stats_v->assign_at(tseq.seqno(), obj<AGCObject,DDictionary>(recd));
}
}
// scan to-space, count objects by type
for (Generation g{0}; g < config_.n_generation_; ++g) {
const DArena * arena = this->get_space(Role::to_space(), g);
for (AllocInfo info : *arena) {
if (info.is_forwarding_tseq()) {
assert(false);
return false;
}
uint32_t ix = info.tseq();
size_t z = info.size();
auto recd = obj<AGCObject,DDictionary>::from(stats_v->at(ix));
assert(recd);
auto n_live_opt = recd->lookup_cstr("n-live");
assert(n_live_opt);
auto bytes_opt = recd->lookup_cstr("bytes");
assert(bytes_opt);
if (n_live_opt && bytes_opt) {
auto n_live_gco = obj<AGCObject,DInteger>::from(n_live_opt.value());
auto bytes_gco = obj<AGCObject,DInteger>::from(bytes_opt.value());
n_live_gco->assign_value(n_live_gco->value() + 1);
bytes_gco->assign_value(bytes_gco->value() + z);
}
}
}
stats_v->resize(max_tseq + 1);
DArray * final_stats_v = DArray::empty(mm, n_tseq_present);
for (std::size_t i = 0, n = stats_v->size(); i < n; ++i) {
auto recd = stats_v->at(i);
if (recd) {
bool ok = final_stats_v->push_back(recd);
assert(ok);
}
}
*p_output = obj<AGCObject,DArray>(final_stats_v);
return ok;
}
bool
GCObjectStore::report_object_ages(obj<AAllocator> mm,
obj<AAllocator> error_mm,
obj<AGCObject> * p_output) const noexcept
{
scope log(XO_DEBUG(this->config_.debug_flag_));
(void)error_mm;
std::uint32_t hard_n_age = config_.arena_config_.header_.max_age() + 1;
// maximum age of a still-existing object
std::uint32_t soft_max_age = 0;
// first pass, establish max age
for (Generation g{0}; g < config_.n_generation_; ++g) {
const DArena * arena = this->get_space(Role::to_space(), g);
for (AllocInfo info : *arena) {
if (info.is_forwarding_tseq()) {
assert(false);
return false;
}
uint32_t age = info.age();
assert(age < hard_n_age);
soft_max_age = std::max(soft_max_age, age);
}
}
// stats, indexed by age
DArray * stats_v = DArray::empty(mm, soft_max_age + 1);
if (!stats_v)
return false;
for (std::uint32_t a = 0; a <= soft_max_age; ++a) {
DDictionary * recd = DDictionary::make(mm);
if (!recd)
return false;
recd->upsert_cstr(mm, "age", DInteger::box(mm, a));
recd->upsert_cstr(mm, "n-live", DInteger::box(mm, 0));
recd->upsert_cstr(mm, "bytes", DInteger::box(mm, 0));
stats_v->push_back(obj<AGCObject,DDictionary>(recd));
}
log && log(xtag("soft_max_age", soft_max_age),
xtag("stats_v.size", stats_v->size()));
// second pass, populate
// scan to-space, count objects by age
//
for (Generation g{0}; g < config_.n_generation_; ++g) {
const DArena * arena = this->get_space(Role::to_space(), g);
for (AllocInfo info : *arena) {
if (info.is_forwarding_tseq()) {
assert(false);
return false;
}
uint32_t age = info.age();
size_t z = info.size();
auto recd = obj<AGCObject,DDictionary>::from(stats_v->at(age));
assert(recd);
auto n_live_opt = recd->lookup_cstr("n-live");
assert(n_live_opt);
auto bytes_opt = recd->lookup_cstr("bytes");
assert(bytes_opt);
if (n_live_opt && bytes_opt) {
auto n_live_gco = obj<AGCObject,DInteger>::from(n_live_opt.value());
auto bytes_gco = obj<AGCObject,DInteger>::from(bytes_opt.value());
n_live_gco->assign_value(n_live_gco->value() + 1);
bytes_gco->assign_value(bytes_gco->value() + z);
}
}
}
*p_output = obj<AGCObject,DArray>(stats_v);
return true;
}
bool
GCObjectStore::_check_move_policy(header_type alloc_hdr,
void * object_data,
Generation upto) const noexcept
{
(void)object_data;
// when gc is moving objects, to- and from- spaces have been
// reversed: forwarding pointers are located in from-space and
// refer to to-space.
object_age age = this->header2age(alloc_hdr);
Generation g = config_.age2gen(age);
//assert(runstate_.is_running());
return (g < upto);
}
void
GCObjectStore::_forward_inplace_aux(obj<AGCObjectVisitor> gc,
AGCObject * lhs_iface,
void ** lhs_data,
Generation upto)
{
// upto == runstate_.gc_upto()
scope log(XO_DEBUG(config_.debug_flag_),
xtag("lhs_data", lhs_data),
xtag("*lhs_data", lhs_data ? *lhs_data : nullptr));
/* coordinates with _deep_move() */
/*
* lhs obj<AGCObject>
* | +---------+ +---+-+----+
* \--->| .iface | | T |G|size| header
* +---------+ object_data +---+-+----+
* | .data x----------------->| alloc |
* +---------+ | data |
* | for |
* | instance |
* | ... |
* +----------+
*/
void * object_data = (std::byte *)*lhs_data;
if (!object_data) {
/* trivial to forward nullptr */
return;
} else if (!this->contains(Role::from_space(), object_data)) {
/* *lhs_data either:
* 1. already in to-space
* 2. not in GC-allocated space at all
* (small number of niche examples of this)
*
* It's important we recognize case (2) up front.
* Since not allocated from GC, they don't have
* an alloc-header.
*/
log && log("disposition: not in from-space. Don't forward, but check children");
obj<AGCObject> gco(lhs_iface, object_data);
gco.visit_gco_children(VisitReason::forward(), gc);
return;
}
log && log("disposition: in from-space");
/** NOTE: for form's sake:
* lookup actual arena that
* allocated object data.
* Only using this to get alloc header
**/
DArena * some_arena = this->from_space(Generation(0));
DArena::header_type * p_header
= some_arena->obj2hdr(object_data);
DArena::header_type alloc_hdr = *p_header;
/* recover allocation size */
std::size_t alloc_z = some_arena->config_.header_.size_with_padding(alloc_hdr);
if (log) {
log(xtag("some_arena.lo", some_arena->lo_),
xtag("p_header", p_header),
xtag("alloc_z", alloc_z));
AllocInfo info = this->alloc_info((std::byte *)object_data);
log(xtag("tseq", info.tseq()),
xtag("tname", TypeRegistry::id2name(typeseq(info.tseq()))),
xtag("is_forwarding_tseq", info.is_forwarding_tseq()),
xtag("age", info.age()),
xtag("size", info.size()));
}
/* need to be able to fit forwarding pointer
* in place of forwarded object.
*
* This is guaranteed anyway, by alignment rules
*/
if (alloc_z < sizeof(uintptr_t)) {
assert(false);
}
if (this->is_forwarding_header(alloc_hdr)) {
/* *lhs_data already refers to a forwarding pointer */
/*
* lhs obj<AGCObject> (from-space)
* | +---------+ +---+-+----+
* \--->| .iface | |FWD|G|size| alloc_hdr
* +---------+ object_data +---+-+----+
* | .data x----------------->| x--------\
* +---------+ | | | dest
* | | |
* +----------+ |
* |
* (to-space) |
* +---+-+----+ |
* |TSQ|G|size| |
* +---+-+----+ |
* | | <-/
* | |
* | |
* +----------+
*/
void * dest = *(void**)object_data;
*lhs_data = dest;
/*
* lhs obj<AGCObject>
* | +---------+
* \--->| .iface |
* +---------+
* | .data x------------\
* +---------+ |
* | dest
* |
* |
* | (to-space)
* | +---+-+----+
* | |TSQ|G|size|
* | +---+-+----+
* \---> | |
* | |
* | |
* +----------+
*/
if (log) {
log("lhs_data already forwarded", xtag("dest", dest));
AllocInfo info = this->alloc_info((std::byte *)dest);
log(xtag("tseq", info.tseq()),
xtag("tname", TypeRegistry::id2name(typeseq(info.tseq()))),
xtag("age", info.age()), xtag("size", info.size()));
}
} else if (this->_check_move_policy(alloc_hdr, object_data, upto)) {
/* copy object *lhs + replace with forwarding pointer */
log && log("forward object now");
/*
* lhs obj<AGCObject> (from-space)
* | +---------+ +---+-+----+
* \--->| .iface | |TSQ|G|size| alloc_hdr
* +---------+ object_data +---+-+----+
* | .data x----------------> | |
* +---------+ | |
* | |
* +----------+
*/
*lhs_data = this->_shallow_move(gc, lhs_iface, *lhs_data);
/*
* lhs obj<AGCObject> (from-space)
* | +---------+ +---+-+----+
* \--->| .iface | |FWD|G|SIZE|
* +---------+ +---+-+----+
* | .data x------------\ | x--------\
* +---------+ | | | |
* | | | |
* dest | +----------+ |
* | |
* | (to-space) |
* | +---+-+----+ |
* | |TSQ|G|size| |
* | +---+-+----+ |
* \---> | | <-/
* | |
* | |
* +----------+
*/
} else {
log && log("object not eligible/required to forward");
/* object doesn't need to move.
* e.g. incremental collection + object is tenured
*/
}
} /*_forward_inplace_aux*/
void
GCObjectStore::_verify_aux(AGCObject * iface, void * data)
{
scope log(XO_DEBUG(config_.debug_flag_));
(void)iface;
Generation g1 = this->generation_of(Role::to_space(), data);
if (g1.is_sentinel()) {
assert(this->contains(Role::to_space(), data) == false);
Generation g2 = this->generation_of(Role::from_space(), data);
if (!g2.is_sentinel()) {
// verify failure - live pointer still refers to from-space
print_backtrace_dwarf(true /*demangle*/);
++(p_verify_stats_->n_from_);
} else {
++(p_verify_stats_->n_ext_);
}
} else {
assert(this->contains(Role::to_space(), data));
++(p_verify_stats_->n_to_);
AllocInfo info = this->alloc_info((std::byte *)data);
if (config_.age2gen(object_age(info.age())) == g1)
++(p_verify_stats_->n_age_ok_);
else
++(p_verify_stats_->n_age_bad_);
}
}
auto
GCObjectStore::snap_move_checkpoint(Generation upto) -> GCMoveCheckpoint
{
GCMoveCheckpoint gray_lo_v;
// If we're collecting gen0, still need to allow for objects getting promoted
for (uint32_t g = 0; g < std::min(upto + 1, config_.n_generation_); ++g) {
gray_lo_v[g] = this->to_space(Generation{g})->free_;
}
return gray_lo_v;
}
void
GCObjectStore::verify_ok() noexcept
{
Generation unused_gen;
DGCObjectStoreVisitor visitor{this, unused_gen};
for (Generation g(0); g < config_.n_generation_; ++g) {
const DArena * space = this->get_space(Role::to_space(), g);
for (const AllocInfo & info : *space) {
if (info.is_forwarding_tseq()) {
++(p_verify_stats_->n_fwd_);
} else {
typeseq tseq(info.tseq());
const AGCObject * iface = this->lookup_type(tseq);
if (iface && !(iface->_has_null_vptr())) {
const void * data = info.payload().first;
// assembled fop for gc-aware object
obj<AGCObject> gco(iface, const_cast<void *>(data));
gco.visit_gco_children(VisitReason::verify(), visitor.ref());
// nested control reenters at GCObjectStore::_verify_aux()
} else {
++(p_verify_stats_->n_no_iface_);
continue;
}
}
}
}
}
/* editor bait: register_type */
bool
GCObjectStore::install_type(const AGCObject & meta) noexcept
{
scope log(XO_DEBUG(config_.debug_flag_),
xtag("tseq", meta._typeseq()));
typeseq tseq = meta._typeseq();
assert(tseq.seqno() > 0);
auto ix = static_cast<ObjectTypeTable::size_type>(tseq.seqno());
if (ix >= object_types_.size()) {
if (!object_types_.resize(std::max(2 * object_types_.size(), ix + 1))) {
log && log("could not increase object_types_ size");
return false;
}
}
assert(ix < object_types_.size());
ObjectTypeSlot & slot = object_types_[ix];
slot.store_iface(&meta);
return true;
}
void
GCObjectStore::swap_roles(Generation upto) noexcept
{
scope log(XO_DEBUG(config_.debug_flag_),
xtag("upto", upto));
for (Generation g = Generation{0}; g < upto; ++g) {
log && log("swap roles", xtag("g", g));
std::swap(space_[Role::to_space()][g], space_[Role::from_space()][g]);
}
}
void
GCObjectStore::cleanup_phase(Generation upto,
bool sanitize_flag)
{
scope log(XO_DEBUG(config_.debug_flag_), xtag("upto", upto));
// everything live has been copied out of from-space
// -> now set to empty
//
for (Generation g = Generation{0}; g < upto; ++g) {
if (sanitize_flag) {
space_[Role::from_space()][g]->scrub();
}
space_[Role::from_space()][g]->clear();
}
}
void *
GCObjectStore::deep_move_root(const AGCObject * root_iface,
void ** root_data,
Generation upto)
{
// NOTE:
// Some roots are non-gc-owned nodes.
// GC must still visit immediate children of these nodes
// to move gc-owned children.
// This implements virtual root node feature,
// intended to mitigate mutation log churn.
scope log(XO_DEBUG(config_.debug_flag_));
if (!root_data || !*root_data)
return nullptr;
bool src_in_from_space = this->contains(Role::from_space(), *root_data);
DGCObjectStoreVisitor visitor(this, upto);
if (src_in_from_space) {
*root_data = this->_deep_move_gc_owned(visitor.ref(), *root_data, upto);
} else {
// we aren't moving from_src, it's not gc-owned.
// However we are moving all its gc-owned children
GCMoveCheckpoint gray_lo_v
= this->snap_move_checkpoint(upto);
auto root = obj<AGCObject>(root_iface, *root_data);
root.visit_gco_children(VisitReason::forward(), visitor.ref());
// For each generation g:
// traverse objects newer than gray_lo_v[g], to make sure children
// are forwarded. Fixpoint reached when gray_lo_v[g] doesn't change.
// Remember that forwarding may promote objects to older generation,
// so need multiple passes
//
this->_forward_children_until_fixpoint(visitor.ref(), upto, gray_lo_v);
// reminder: *root_data preserved
}
return *root_data;
}
void *
GCObjectStore::deep_move_interior(obj<AGCObjectVisitor> gc,
void * from_src,
Generation upto)
{
scope log(XO_DEBUG(config_.debug_flag_));
if (!from_src)
return nullptr;
bool src_in_from_space = this->contains(Role::from_space(), from_src);
if (!src_in_from_space)
return from_src;
return this->_deep_move_gc_owned(gc, from_src, upto);
}
std::byte *
GCObjectStore::alloc_copy(void * src) noexcept
{
scope log(XO_DEBUG(config_.debug_flag_));
AllocInfo src_info = this->alloc_info((std::byte *)src);
uint32_t age1p = std::min(src_info.age() + 1,
c_max_object_age);
/** g_copy will be one of {g, g+1} where g
* is the generation of src
**/
Generation g_copy = config_.age2gen(object_age(age1p));
DArena * dest_arena = this->to_space(g_copy);
log && log(xtag("age1p", age1p), xtag("g_copy", g_copy));
// 1. we could have used
// dest_arena->alloc_copy((std::byte *)src);
// here.
// 2. but then dest_arena will have to recompute object header.
// 3. instead prefer the header info we already have at hand.
return dest_arena->_alloc(src_info.size(),
DArena::alloc_mode::standard,
typeseq(src_info.tseq()),
age1p,
__PRETTY_FUNCTION__);
}
void *
GCObjectStore::_deep_move_gc_owned(obj<AGCObjectVisitor> gc,
void * from_src,
Generation upto)
{
scope log(XO_DEBUG(config_.debug_flag_));
AllocInfo info = this->alloc_info((std::byte *)from_src);
AllocHeader hdr = info.header();
typeseq tseq(info.tseq());
assert(this->contains_allocated(Role::from_space(), from_src));
if (this->is_forwarding_header(hdr)) {
/* already forwarded - pickup destination
*
* Coordinates with forward_inplace()
*/
log && log("disposition: already forwarded");
return *(void **)from_src;
}
/* here: object at from_src not already forwarded */
if (!this->_check_move_policy(hdr, from_src, upto)) {
if (log) {
object_age age = this->header2age(hdr);
Generation expect_g = config_.age2gen(age);
Generation actual_g = this->generation_of(Role::to_space(), from_src);
Generation actual_g2 = this->generation_of(Role::from_space(), from_src);
/* object at from_src is in generation that is not being collected.
* g = intended generation
*/
log("disposition: not moving from_src",
xtag("age", age),
xtag("expect-g", expect_g),
xtag("actual-g", actual_g),
xtag("actual-g2", actual_g2));
}
return from_src;
}
log && log("disposition: move subtree");
/* TODO: AllocIterator pointing to free pointer */
GCMoveCheckpoint gray_lo_v = this->snap_move_checkpoint(upto);
AGCObject * iface = this->lookup_type(tseq);
//assert(iface && (iface->_has_null_vptr() == false));
void * to_dest = nullptr;
if (iface) [[likely]] {
to_dest = this->_shallow_move(gc, iface, from_src);
this->_forward_children_until_fixpoint(gc, upto, gray_lo_v);
log && log(xtag("to_dest", to_dest));
}
return to_dest;
} /*_deep_move_gc_owned*/
void *
GCObjectStore::_shallow_move(obj<AGCObjectVisitor> gc,
AGCObject * iface,
void * from_src)
{
scope log(XO_DEBUG(config_.debug_flag_));
AllocInfo info = this->alloc_info((std::byte *)from_src);
void * to_dest = iface->gco_shallow_move(from_src, gc);
log && log(xtag("from_src", from_src), xtag("to_dest", to_dest));
log && log(xtag("tseq", info.tseq()),
xtag("tname", TypeRegistry::id2name(typeseq(info.tseq()))),
xtag("age", info.age()),
xtag("size", info.size()));
if (config_.debug_flag_) {
AllocInfo info_copy = this->alloc_info((std::byte *)to_dest);
log && log(xtag("age2", info_copy.age()), xtag("size2", info_copy.size()));
assert((info_copy.age() == config_.arena_config_.header_.max_age())
|| (info_copy.age() == info.age() + 1));
}
if(to_dest == from_src) {
assert(false);
} else {
*(const_cast<AllocHeader*>(info.p_header_))
= AllocHeader(config_
.arena_config_
.header_
.mark_forwarding_tseq(*info.p_header_));
*(void **)from_src = to_dest;
}
return to_dest;
} /*_shallow_move*/
void
GCObjectStore::_forward_children_until_fixpoint(obj<AGCObjectVisitor> gc,
Generation upto,
GCMoveCheckpoint gray_lo_v)
{
scope log(XO_DEBUG(config_.debug_flag_));
/**
* To-space:
*
* to_lo = start of to-space
* w,W = white objects. An object x is white if x
* + all immediate children of x are in to-space
* (also implies this GC cycle put it there)
* g,G = grey objects. An object x is gray if it's in to-space,
* but possibly has >0 black children
* _ = free to-space memory
* N = nursery space (generation{0})
* T = tenured space (generation{1})
*
* wwwwwwwwwwwwwwwwwwwggggggggggggggggggggg_________________...
* ^ ^ ^
* to_lo grey_lo(N) free_ptr(N)
*
* After moving children of one object,
* advancing {nursery_grey_lo, nursery_free_ptr}
*
* wwwwwwwwwwwwwwwwwwwWWWWgggggggggggggggggGGGGGGGGGGG______...
* ^ ^ ^
* to_lo grey_lo(N) free_ptr(N)
*
* Invariant:
*
* objects in [to_lo, gray_lo) are white.
* all gray objects are in [gray_lo, free_ptr)
* memory starting at free_ptr is free.
*
* deep_move terminates when gray_lo catches up to free_ptr
*
* Above is simplified. Complication is that GC (including incremental) may
* promote objects from nursery (N) to tenured (T)
*
* So more accurate before/after picture
*
* N wwwwwwwwwwwwwwwwwwwggggggggggggggggggggg_________________...
* ^ ^ ^
* to_lo(N) grey_lo(N) free_ptr(N)
*
* T wwwwwwwwwwwwwwgggggggggggg_______________________________...
* ^ ^ ^
* to_lo(T) grey_lo(T) free_ptr(N)
*
* After moving children of one object,
* advancing {nursery_grey_lo, nursery_free_ptr}
*
* N wwwwwwwwwwwwwwwwwwwWWWWgggggggggggggggggGGGGGGGGGGG_____...
* ^ ^ ^
* to_lo(N) grey_lo(N) free_ptr(N)
*
* T wwwwwwwwwwwwwwggggggggggggGGGGG_________________________...
* ^ ^ ^
* to_lo(T) grey_lo(T) free_ptr(T)
*
* deep_move terminates when both:
* - gray_lo(N) catches up with free_ptr(N)
* - gray_lo(T) catches up with free_ptr(T)
*
**/
std::size_t fixup_work = 0;
/* TODO:
* - loop here is bad for memory locality
* - replace with depth-first traversal
*/
do {
fixup_work = 0;
// reminder: oldest collected generation is upto-1.
// Objects that were in generation upto-1 may have promoted
// to generation upto < config_.n_generation_
//
Generation g_ub(std::min(upto + 1, config_.n_generation_));
for (Generation g = Generation{0}; g < g_ub; ++g) {
/** object index for this pass **/
size_t i_obj = 0;
/* TODO: use AllocIterator here */
while(gray_lo_v[g] < to_space(g)->free_) {
AllocHeader * hdr = (AllocHeader *)gray_lo_v[g];
void * src = (hdr + 1);
const auto & hdr_cfg = config_.arena_config_.header_;
typeseq tseq = typeseq(hdr_cfg.tseq(*hdr));
size_t z = hdr_cfg.size_with_padding(*hdr);
log && log("deep_move_gc_owned: fwd to-space children",
xtag("g", g),
xtag("i_obj", i_obj),
xtag("src", src),
xtag("tseq", tseq),
xtag("tname", TypeRegistry::id2name(tseq)),
xtag("z", z));
const AGCObject * iface = this->lookup_type(tseq);
assert(iface->_has_null_vptr() == false);
iface->visit_gco_children(src, VisitReason::forward(), gc);
gray_lo_v[g] = ((std::byte *)src) + z;
++i_obj;
++fixup_work;
}
}
} while (fixup_work > 0);
} /*_forward_children_until_fixpoint*/
} /*namespace mm*/
} /*namespace xo*/
/* end GCObjectStore.cpp */
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