/* GC.hpp * * author: Roland Conybeare, jul 2025 */ #pragma once #include "ListAlloc.hpp" #include "xo/indentlog/print/array.hpp" #include #include namespace xo { /** types that can participate in GC inherit from this base class. See Object.hpp in this directory **/ class Object; namespace gc { enum class generation { nursery, tenured, N }; constexpr std::size_t gen2int(generation x) { return static_cast(x); } enum class generation_result { nursery, tenured, not_found }; enum class role { /** nursery: generation for new objects **/ from_space, /** tenured: generation for objects that have survived two collections **/ to_space, N, }; constexpr std::size_t role2int(role x) { return static_cast(x); } /** @class Config * @brief garbage collector configuration **/ struct Config { /** initial size in bytes for youngest (Nursery) generation. * GC allocates two nursery spaces of this size. * Will allocate more space as needed **/ std::size_t initial_nursery_z_ = 0; /** initial size in bytes for oldest (Tenured) generation. * GC allocates two tenured spaces of this size * Will allocate more space as needed **/ std::size_t initial_tenured_z_ = 0; /** true to permit incremental garbage collection **/ bool allow_incremental_gc_ = true; /** true to enable debug logging **/ bool debug_flag_ = false; }; /** @class ObjectStatistics * @brief placeholder for type-driven allocation statistics * * Passed to @ref Object::deep_move for example **/ class ObjectStatistics { }; /** @class PerGenerationStatistics * @brief garbage collection statistics for particular GC generation **/ class PerGenerationStatistics { public: /** update statistics after a GC cycle * @param alloc_z. new allocations (since preceding GC) * @param before_z. generation size (bytes allocated) before collection * @param after_z. generation size after collection * @param promote_z. bytes promoted to next generation **/ void include_gc(std::size_t alloc_z, std::size_t before_z, std::size_t after_z, std::size_t promote_z); /** update with current state (use at end of gc cycle) **/ void update_snapshot(std::size_t after_z); /** @param os. write stats on this output stream **/ void display(std::ostream & os) const; /** number of bytes currently in use **/ std::size_t used_z_ = 0; /** number of collection cycles completed **/ std::size_t n_gc_ = 0; /** sum of new alloc bytes, sampled at start of each collection cycle **/ std::size_t new_alloc_z_ = 0; /** sum of allocated bytes sampled at beginning of each collection cycle **/ std::size_t scanned_z_ = 0; /** sum of bytes remaining after collection cycle **/ std::size_t survive_z_ = 0; /** sum of bytes promoted to next generation **/ std::size_t promote_z_ = 0; }; inline std::ostream & operator<< (std::ostream & os, const PerGenerationStatistics & x) { x.display(os); return os; } /** @class GcStatistics * @brief garbage collection statistics **/ class GcStatistics { public: /** update statistics after a GC cycle * @param upto. nursery -> incremental collection; tenured -> full collection * @param alloc_z. new allocations (since preceding GC) * @param before_z. generation size (bytes allocated) before collection * @param after_z. generation size after collection * @param promote_z. bytes promoted to next generation **/ void include_gc(generation upto, std::size_t alloc_z, std::size_t before_z, std::size_t after_z, std::size_t promote_z); /** update snapshot for current state. * Use with tenured stats after incremental gc **/ void update_snapshot(generation upto, std::size_t after_z); /** @param os. write stats on this output stream **/ void display(std::ostream & os) const; /** statistics gathered across {incr, full} GCs respectively **/ std::array(generation::N)> gen_v_; /** total bytes allocated since inception **/ std::size_t total_allocated_ = 0; /** snapshot of total bytes promoted asof beginning of last gc cycle **/ std::size_t total_promoted_sab_ = 0; /** total bytes promoted from nursery->tenured since inception **/ std::size_t total_promoted_ = 0; /** total number of mutations to already-allocated objects, * whether or not GC needs to log them. **/ std::size_t n_mutation_ = 0; /** total number of mutation eligible for logging **/ std::size_t n_logged_mutation_ = 0; /** total number of cross-generation mutations (tenured->nursery when reported) **/ std::size_t n_xgen_mutation_ = 0; /** total number of cross-checkpoint mutations (N0 -> N1 when reported) **/ std::size_t n_xckp_mutation_ = 0; /** per-type statistics (placeholder) **/ ObjectStatistics per_type_stats_; }; inline std::ostream & operator<< (std::ostream & os, const GcStatistics & x) { x.display(os); return os; } /** @class GCRunstate * @brief encapsulate state needed while GC is running * * state pertaining to a single GC invocation. * We stash an instance of this in @ref GC as context, * so that per-Object-derived-type auxiliary functions can be slightly streamlined **/ class GCRunstate { public: GCRunstate() = default; explicit GCRunstate(bool in_progress, bool full_move) : in_progress_{in_progress}, full_move_{full_move} {} bool in_progress() const { return in_progress_; } bool full_move() const { return full_move_; } private: /** true when GC begins; remains true until GC cycle complete **/ bool in_progress_ = false; /** true for full GC; false for incremental GC **/ bool full_move_ = false; }; class MutationLogEntry { public: MutationLogEntry(Object * parent, Object ** lhs) : parent_{parent}, lhs_{lhs} {} Object * parent() const { return parent_; } Object ** lhs() const { return lhs_; } Object * child() const { return *lhs_; } bool is_child_forwarded() const; bool is_parent_forwarded() const; Object * parent_destination() const; /** Flag obsolete mutation. * Future proofing, never happens for regular objects **/ bool is_dead() const { return false; } MutationLogEntry update_parent_moved(Object * parent_to) const; void fixup_parent_child_moved(Object * child_to) { *lhs_ = child_to; } private: Object * parent_; Object ** lhs_; }; using MutationLog = std::vector; /** @class GC * @brief generational garbage collector * * Works with objects of type @ref xo::Object **/ class GC : public IAlloc { public: /** create new GC instance with configuration @p config **/ explicit GC(const Config & config); virtual ~GC(); /** create GC allocator. * * Initial memory consumption: * approximately 2x @ref Config::nursery_size_ + 2x @ref Config::tenured_size_ **/ static up make(const Config & config); const GCRunstate & runstate() const { return runstate_; } const GcStatistics & gc_statistics() const { return gc_statistics_; } /** true iff GC permitted in current state **/ bool is_gc_enabled() const { return gc_enabled_ == 0; } /** true during (and only during) a GC cycle **/ bool gc_in_progress() const { return runstate_.in_progress(); } /** @return generation to which object at @p x belongs **/ generation_result tospace_generation_of(const void * x) const; /** @return generation that contains @p x, given it's in from-space **/ generation_result fromspace_generation_of(const void * x) const; /** true iff from-space contains @p x **/ bool fromspace_contains(const void * x) const; /** @return free pointer for generation @p gen, i.e. nursery or tenured space **/ std::byte * free_ptr(generation gen); /** @return current size of (number of entries in) mutation log **/ std::size_t mlog_size() const; /** add gc root at address @p addr . Gc will keep alive anything reachable * from @c *addr **/ void add_gc_root(Object ** addr); /** request garbage collection. **/ void request_gc(generation g); /** disable garbage collection until matching call to @ref enable_gc. * * GC is disabled when number of calls to @ref disable_gc exceeds number of * calls to @ref enable_gc. **/ void disable_gc(); /** enable garbage collection * * GC is enabled when number of calls to @ref enable_gc is at least as large * as number of calls to @ref disable_gc. **/ void enable_gc(); // inherited from IAlloc.. virtual const std::string & name() const final override; /** capacity in bytes (counting both free+allocated) for object storage. * only counts one of {to-space, from-space}, * since one role is always held empty between collections. **/ virtual std::size_t size() const final override; virtual std::size_t allocated() const final override; virtual std::size_t available() const final override; /** only tests to-space **/ virtual bool contains(const void * x) const final override; virtual bool is_before_checkpoint(const void * x) const final override; virtual std::size_t before_checkpoint() const final override; virtual std::size_t after_checkpoint() const final override; virtual bool debug_flag() const final override; virtual void clear() final override; virtual void checkpoint() final override; /** GC bookkeeping for an assignment that modifes an Object reference. * Whenever an @ref Object instance P contains a member variable that can refer * to another @ref Object, then we need to involve GC to perform the assignment. * In particular a side-effect that changes the target of such reference to Q after P * has been promoted, may lead to a tenured->nursery cross-generational pointer. * GC needs to know about such pointers to it can update them as part of subsequent * incremental collections. * * @param parent. object with member variable being modified * @param lhs. address of a member variable within the allocation of @p parent. * @param rhs. new target for @p *lhs **/ virtual void assign_member(Object * parent, Object ** lhs, Object* rhs) final override; virtual std::byte * alloc(std::size_t z) final override; virtual std::byte * alloc_gc_copy(std::size_t z, const void * src) final override; virtual void release_redline_memory() final override; private: /** begin GC now **/ void execute_gc(generation g); /** cleanup phase. aux function for @ref execute_gc **/ void cleanup_phase(generation g); /** swap roles of From/To spaces for nursery generation **/ void swap_nursery(); /** swap roles of From/To spaces for tenured generation **/ void swap_tenured(); /** swap roles of From/To spaces for mutation log **/ void swap_mutation_log(); /** swap roles of FromSpace/ToSpace **/ void swap_spaces(generation g); /** copy object **/ void copy_object(Object ** addr, generation upto, ObjectStatistics * object_stats); /** copy everything reachable from global gc roots **/ void copy_globals(generation g); /** review mutation log; may discover+rescue reachable objects. **/ void forward_mutation_log(generation upto); /** Aux function for @ref execute_gc. Updates bookkeeping for cross-generational * (T->N, aka xgen) and (N1->N0, aka xckp) pointers **/ void incremental_gc_forward_mlog(ObjectStatistics * per_type_stats); /** * Aux function for @ref incremental_gc_forward_mlog. Calls this function until * fixpoint. * * @param from_mlog incoming mutation log. Contains {xgen,xckp} pointers before GC. * Contents of this log is consumed (+discarded) before method returns. * @param to_mlog outgoing mutation log. Will contain {xgen,xckp} pointers after GC. * @param defer_mlog contains log entries associated with possible garbage. **/ void incremental_gc_forward_mlog_phase(MutationLog * from_mlog, MutationLog * to_mlog, MutationLog * defer_mlog, ObjectStatistics * per_type_stats); private: /** garbage collector configuration **/ Config config_; /** contains allocated objects, along with unreachable garbage to be collected. * roles reverse after each incremental, or full, collection. **/ std::array, role2int(role::N)> nursery_; /** empty space, destination for objects that survive collection. * roles reverse after each full collection. **/ std::array, role2int(role::N)> tenured_; /** current state of GC activity. * @text * in_progress full_move descr * ----------------------------------------- * false * gc not running * true false incremental gc * true true full gc * ----------------------------------------- * @endtext **/ GCRunstate runstate_; /** root object handles: targets of handles in this vector are always preserved by GC. * Application can introduce new root object pointers at any time provided GC not running, * but cannot withdraw them. **/ std::vector gc_root_v_; /** log cross-generational and cross-checkpoint mutations. * These need to be adjusted on next incremental collection **/ std::array, role2int(role::N)> mutation_log_; /** temporary mutation log (for deferred entries) **/ up defer_mutation_log_; /** allocation/collection counters **/ GcStatistics gc_statistics_; /** trigger full GC whenever this much data arrives in tenured generation **/ std::size_t full_gc_threshold_ = 0; /** trigger incr GC whenever this much data arrives in nuresery generation **/ std::size_t incr_gc_threshold_ = 0; /** true when GC requested, * remains true until GC.. completes? begins? **/ bool incr_gc_pending_ = false; bool full_gc_pending_ = false; /** enabled when 0. disabled when <0 **/ int gc_enabled_ = 0; }; } /*namespace gc*/ } /*namespace xo*/ /* end GC.hpp */