#ifndef JEMALLOC_INTERNAL_PA_H #define JEMALLOC_INTERNAL_PA_H #include "jemalloc/internal/base.h" #include "jemalloc/internal/decay.h" #include "jemalloc/internal/ecache.h" #include "jemalloc/internal/edata_cache.h" #include "jemalloc/internal/emap.h" #include "jemalloc/internal/hpa.h" #include "jemalloc/internal/lockedint.h" #include "jemalloc/internal/pac.h" #include "jemalloc/internal/pai.h" #include "jemalloc/internal/sec.h" /* * The page allocator; responsible for acquiring pages of memory for * allocations. It picks the implementation of the page allocator interface * (i.e. a pai_t) to handle a given page-level allocation request. For now, the * only such implementation is the PAC code ("page allocator classic"), but * others will be coming soon. */ /* * The stats for a particular pa_shard. Because of the way the ctl module * handles stats epoch data collection (it has its own arena_stats, and merges * the stats from each arena into it), this needs to live in the arena_stats_t; * hence we define it here and let the pa_shard have a pointer (rather than the * more natural approach of just embedding it in the pa_shard itself). * * We follow the arena_stats_t approach of marking the derived fields. These * are the ones that are not maintained on their own; instead, their values are * derived during those stats merges. */ typedef struct pa_shard_stats_s pa_shard_stats_t; struct pa_shard_stats_s { /* Number of edata_t structs allocated by base, but not being used. */ size_t edata_avail; /* Derived. */ /* * Stats specific to the PAC. For now, these are the only stats that * exist, but there will eventually be other page allocators. Things * like edata_avail make sense in a cross-PA sense, but things like * npurges don't. */ pac_stats_t pac_stats; }; /* * The local allocator handle. Keeps the state necessary to satisfy page-sized * allocations. * * The contents are mostly internal to the PA module. The key exception is that * arena decay code is allowed to grab pointers to the dirty and muzzy ecaches * decay_ts, for a couple of queries, passing them back to a PA function, or * acquiring decay.mtx and looking at decay.purging. The reasoning is that, * while PA decides what and how to purge, the arena code decides when and where * (e.g. on what thread). It's allowed to use the presence of another purger to * decide. * (The background thread code also touches some other decay internals, but * that's not fundamental; its' just an artifact of a partial refactoring, and * its accesses could be straightforwardly moved inside the decay module). */ typedef struct pa_shard_s pa_shard_t; struct pa_shard_s { /* * Number of pages in active extents. * * Synchronization: atomic. */ atomic_zu_t nactive; /* * Whether or not we should prefer the hugepage allocator. Atomic since * it may be concurrently modified by a thread setting extent hooks. * Note that we still may do HPA operations in this arena; if use_hpa is * changed from true to false, we'll free back to the hugepage allocator * for those allocations. */ atomic_b_t use_hpa; /* * If we never used the HPA to begin with, it wasn't initialized, and so * we shouldn't try to e.g. acquire its mutexes during fork. This * tracks that knowledge. */ bool ever_used_hpa; /* Allocates from a PAC. */ pac_t pac; /* * We place a small extent cache in front of the HPA, since we intend * these configurations to use many fewer arenas, and therefore have a * higher risk of hot locks. */ sec_t hpa_sec; hpa_shard_t hpa_shard; /* The source of edata_t objects. */ edata_cache_t edata_cache; unsigned ind; malloc_mutex_t *stats_mtx; pa_shard_stats_t *stats; /* The emap this shard is tied to. */ emap_t *emap; /* The base from which we get the ehooks and allocate metadat. */ base_t *base; }; static inline bool pa_shard_dont_decay_muzzy(pa_shard_t *shard) { return ecache_npages_get(&shard->pac.ecache_muzzy) == 0 && pac_decay_ms_get(&shard->pac, extent_state_muzzy) <= 0; } static inline ehooks_t * pa_shard_ehooks_get(pa_shard_t *shard) { return base_ehooks_get(shard->base); } /* Returns true on error. */ bool pa_shard_init(tsdn_t *tsdn, pa_shard_t *shard, emap_t *emap, base_t *base, unsigned ind, pa_shard_stats_t *stats, malloc_mutex_t *stats_mtx, nstime_t *cur_time, size_t oversize_threshold, ssize_t dirty_decay_ms, ssize_t muzzy_decay_ms); /* * This isn't exposed to users; we allow late enablement of the HPA shard so * that we can boot without worrying about the HPA, then turn it on in a0. */ bool pa_shard_enable_hpa(pa_shard_t *shard, const hpa_shard_opts_t *hpa_opts, size_t sec_nshards, size_t sec_alloc_max, size_t sec_bytes_max); /* * We stop using the HPA when custom extent hooks are installed, but still * redirect deallocations to it. */ void pa_shard_disable_hpa(tsdn_t *tsdn, pa_shard_t *shard); /* * This does the PA-specific parts of arena reset (i.e. freeing all active * allocations). */ void pa_shard_reset(tsdn_t *tsdn, pa_shard_t *shard); /* * Destroy all the remaining retained extents. Should only be called after * decaying all active, dirty, and muzzy extents to the retained state, as the * last step in destroying the shard. */ void pa_shard_destroy(tsdn_t *tsdn, pa_shard_t *shard); /* Gets an edata for the given allocation. */ edata_t *pa_alloc(tsdn_t *tsdn, pa_shard_t *shard, size_t size, size_t alignment, bool slab, szind_t szind, bool zero); /* Returns true on error, in which case nothing changed. */ bool pa_expand(tsdn_t *tsdn, pa_shard_t *shard, edata_t *edata, size_t old_size, size_t new_size, szind_t szind, bool zero); /* * The same. Sets *generated_dirty to true if we produced new dirty pages, and * false otherwise. */ bool pa_shrink(tsdn_t *tsdn, pa_shard_t *shard, edata_t *edata, size_t old_size, size_t new_size, szind_t szind, bool *generated_dirty); /* * Frees the given edata back to the pa. Sets *generated_dirty if we produced * new dirty pages (well, we alwyas set it for now; but this need not be the * case). * (We could make generated_dirty the return value of course, but this is more * consistent with the shrink pathway and our error codes here). */ void pa_dalloc(tsdn_t *tsdn, pa_shard_t *shard, edata_t *edata, bool *generated_dirty); bool pa_decay_ms_set(tsdn_t *tsdn, pa_shard_t *shard, extent_state_t state, ssize_t decay_ms, pac_purge_eagerness_t eagerness); ssize_t pa_decay_ms_get(pa_shard_t *shard, extent_state_t state); /******************************************************************************/ /* * Various bits of "boring" functionality that are still part of this module, * but that we relegate to pa_extra.c, to keep the core logic in pa.c as * readable as possible. */ /* * These fork phases are synchronized with the arena fork phase numbering to * make it easy to keep straight. That's why there's no prefork1. */ void pa_shard_prefork0(tsdn_t *tsdn, pa_shard_t *shard); void pa_shard_prefork2(tsdn_t *tsdn, pa_shard_t *shard); void pa_shard_prefork3(tsdn_t *tsdn, pa_shard_t *shard); void pa_shard_prefork4(tsdn_t *tsdn, pa_shard_t *shard); void pa_shard_prefork5(tsdn_t *tsdn, pa_shard_t *shard); void pa_shard_postfork_parent(tsdn_t *tsdn, pa_shard_t *shard); void pa_shard_postfork_child(tsdn_t *tsdn, pa_shard_t *shard); void pa_shard_basic_stats_merge(pa_shard_t *shard, size_t *nactive, size_t *ndirty, size_t *nmuzzy); void pa_shard_stats_merge(tsdn_t *tsdn, pa_shard_t *shard, pa_shard_stats_t *pa_shard_stats_out, pac_estats_t *estats_out, hpa_shard_stats_t *hpa_stats_out, sec_stats_t *sec_stats_out, size_t *resident); /* * Reads the PA-owned mutex stats into the output stats array, at the * appropriate positions. Morally, these stats should really live in * pa_shard_stats_t, but the indices are sort of baked into the various mutex * prof macros. This would be a good thing to do at some point. */ void pa_shard_mtx_stats_read(tsdn_t *tsdn, pa_shard_t *shard, mutex_prof_data_t mutex_prof_data[mutex_prof_num_arena_mutexes]); #endif /* JEMALLOC_INTERNAL_PA_H */