| #ifndef JEMALLOC_INTERNAL_RTREE_H |
| #define JEMALLOC_INTERNAL_RTREE_H |
| |
| #include "jemalloc/internal/atomic.h" |
| #include "jemalloc/internal/mutex.h" |
| #include "jemalloc/internal/rtree_tsd.h" |
| #include "jemalloc/internal/size_classes.h" |
| #include "jemalloc/internal/tsd.h" |
| |
| /* |
| * This radix tree implementation is tailored to the singular purpose of |
| * associating metadata with extents that are currently owned by jemalloc. |
| * |
| ******************************************************************************* |
| */ |
| |
| /* Number of high insignificant bits. */ |
| #define RTREE_NHIB ((1U << (LG_SIZEOF_PTR+3)) - LG_VADDR) |
| /* Number of low insigificant bits. */ |
| #define RTREE_NLIB LG_PAGE |
| /* Number of significant bits. */ |
| #define RTREE_NSB (LG_VADDR - RTREE_NLIB) |
| /* Number of levels in radix tree. */ |
| #if RTREE_NSB <= 10 |
| # define RTREE_HEIGHT 1 |
| #elif RTREE_NSB <= 36 |
| # define RTREE_HEIGHT 2 |
| #elif RTREE_NSB <= 52 |
| # define RTREE_HEIGHT 3 |
| #else |
| # error Unsupported number of significant virtual address bits |
| #endif |
| /* Use compact leaf representation if virtual address encoding allows. */ |
| #if RTREE_NHIB >= LG_CEIL_NSIZES |
| # define RTREE_LEAF_COMPACT |
| #endif |
| |
| /* Needed for initialization only. */ |
| #define RTREE_LEAFKEY_INVALID ((uintptr_t)1) |
| |
| typedef struct rtree_node_elm_s rtree_node_elm_t; |
| struct rtree_node_elm_s { |
| atomic_p_t child; /* (rtree_{node,leaf}_elm_t *) */ |
| }; |
| |
| struct rtree_leaf_elm_s { |
| #ifdef RTREE_LEAF_COMPACT |
| /* |
| * Single pointer-width field containing all three leaf element fields. |
| * For example, on a 64-bit x64 system with 48 significant virtual |
| * memory address bits, the index, extent, and slab fields are packed as |
| * such: |
| * |
| * x: index |
| * e: extent |
| * b: slab |
| * |
| * 00000000 xxxxxxxx eeeeeeee [...] eeeeeeee eeee000b |
| */ |
| atomic_p_t le_bits; |
| #else |
| atomic_p_t le_extent; /* (extent_t *) */ |
| atomic_u_t le_szind; /* (szind_t) */ |
| atomic_b_t le_slab; /* (bool) */ |
| #endif |
| }; |
| |
| typedef struct rtree_level_s rtree_level_t; |
| struct rtree_level_s { |
| /* Number of key bits distinguished by this level. */ |
| unsigned bits; |
| /* |
| * Cumulative number of key bits distinguished by traversing to |
| * corresponding tree level. |
| */ |
| unsigned cumbits; |
| }; |
| |
| typedef struct rtree_s rtree_t; |
| struct rtree_s { |
| malloc_mutex_t init_lock; |
| /* Number of elements based on rtree_levels[0].bits. */ |
| #if RTREE_HEIGHT > 1 |
| rtree_node_elm_t root[1U << (RTREE_NSB/RTREE_HEIGHT)]; |
| #else |
| rtree_leaf_elm_t root[1U << (RTREE_NSB/RTREE_HEIGHT)]; |
| #endif |
| }; |
| |
| /* |
| * Split the bits into one to three partitions depending on number of |
| * significant bits. It the number of bits does not divide evenly into the |
| * number of levels, place one remainder bit per level starting at the leaf |
| * level. |
| */ |
| static const rtree_level_t rtree_levels[] = { |
| #if RTREE_HEIGHT == 1 |
| {RTREE_NSB, RTREE_NHIB + RTREE_NSB} |
| #elif RTREE_HEIGHT == 2 |
| {RTREE_NSB/2, RTREE_NHIB + RTREE_NSB/2}, |
| {RTREE_NSB/2 + RTREE_NSB%2, RTREE_NHIB + RTREE_NSB} |
| #elif RTREE_HEIGHT == 3 |
| {RTREE_NSB/3, RTREE_NHIB + RTREE_NSB/3}, |
| {RTREE_NSB/3 + RTREE_NSB%3/2, |
| RTREE_NHIB + RTREE_NSB/3*2 + RTREE_NSB%3/2}, |
| {RTREE_NSB/3 + RTREE_NSB%3 - RTREE_NSB%3/2, RTREE_NHIB + RTREE_NSB} |
| #else |
| # error Unsupported rtree height |
| #endif |
| }; |
| |
| bool rtree_new(rtree_t *rtree, bool zeroed); |
| |
| typedef rtree_node_elm_t *(rtree_node_alloc_t)(tsdn_t *, rtree_t *, size_t); |
| extern rtree_node_alloc_t *JET_MUTABLE rtree_node_alloc; |
| |
| typedef rtree_leaf_elm_t *(rtree_leaf_alloc_t)(tsdn_t *, rtree_t *, size_t); |
| extern rtree_leaf_alloc_t *JET_MUTABLE rtree_leaf_alloc; |
| |
| typedef void (rtree_node_dalloc_t)(tsdn_t *, rtree_t *, rtree_node_elm_t *); |
| extern rtree_node_dalloc_t *JET_MUTABLE rtree_node_dalloc; |
| |
| typedef void (rtree_leaf_dalloc_t)(tsdn_t *, rtree_t *, rtree_leaf_elm_t *); |
| extern rtree_leaf_dalloc_t *JET_MUTABLE rtree_leaf_dalloc; |
| #ifdef JEMALLOC_JET |
| void rtree_delete(tsdn_t *tsdn, rtree_t *rtree); |
| #endif |
| rtree_leaf_elm_t *rtree_leaf_elm_lookup_hard(tsdn_t *tsdn, rtree_t *rtree, |
| rtree_ctx_t *rtree_ctx, uintptr_t key, bool dependent, bool init_missing); |
| |
| JEMALLOC_ALWAYS_INLINE uintptr_t |
| rtree_leafkey(uintptr_t key) { |
| unsigned ptrbits = ZU(1) << (LG_SIZEOF_PTR+3); |
| unsigned cumbits = (rtree_levels[RTREE_HEIGHT-1].cumbits - |
| rtree_levels[RTREE_HEIGHT-1].bits); |
| unsigned maskbits = ptrbits - cumbits; |
| uintptr_t mask = ~((ZU(1) << maskbits) - 1); |
| return (key & mask); |
| } |
| |
| JEMALLOC_ALWAYS_INLINE size_t |
| rtree_cache_direct_map(uintptr_t key) { |
| unsigned ptrbits = ZU(1) << (LG_SIZEOF_PTR+3); |
| unsigned cumbits = (rtree_levels[RTREE_HEIGHT-1].cumbits - |
| rtree_levels[RTREE_HEIGHT-1].bits); |
| unsigned maskbits = ptrbits - cumbits; |
| return (size_t)((key >> maskbits) & (RTREE_CTX_NCACHE - 1)); |
| } |
| |
| JEMALLOC_ALWAYS_INLINE uintptr_t |
| rtree_subkey(uintptr_t key, unsigned level) { |
| unsigned ptrbits = ZU(1) << (LG_SIZEOF_PTR+3); |
| unsigned cumbits = rtree_levels[level].cumbits; |
| unsigned shiftbits = ptrbits - cumbits; |
| unsigned maskbits = rtree_levels[level].bits; |
| uintptr_t mask = (ZU(1) << maskbits) - 1; |
| return ((key >> shiftbits) & mask); |
| } |
| |
| /* |
| * Atomic getters. |
| * |
| * dependent: Reading a value on behalf of a pointer to a valid allocation |
| * is guaranteed to be a clean read even without synchronization, |
| * because the rtree update became visible in memory before the |
| * pointer came into existence. |
| * !dependent: An arbitrary read, e.g. on behalf of ivsalloc(), may not be |
| * dependent on a previous rtree write, which means a stale read |
| * could result if synchronization were omitted here. |
| */ |
| # ifdef RTREE_LEAF_COMPACT |
| JEMALLOC_ALWAYS_INLINE uintptr_t |
| rtree_leaf_elm_bits_read(tsdn_t *tsdn, rtree_t *rtree, rtree_leaf_elm_t *elm, |
| bool dependent) { |
| return (uintptr_t)atomic_load_p(&elm->le_bits, dependent |
| ? ATOMIC_RELAXED : ATOMIC_ACQUIRE); |
| } |
| |
| JEMALLOC_ALWAYS_INLINE extent_t * |
| rtree_leaf_elm_bits_extent_get(uintptr_t bits) { |
| # ifdef __aarch64__ |
| /* |
| * aarch64 doesn't sign extend the highest virtual address bit to set |
| * the higher ones. Instead, the high bits gets zeroed. |
| */ |
| uintptr_t high_bit_mask = ((uintptr_t)1 << LG_VADDR) - 1; |
| /* Mask off the slab bit. */ |
| uintptr_t low_bit_mask = ~(uintptr_t)1; |
| uintptr_t mask = high_bit_mask & low_bit_mask; |
| return (extent_t *)(bits & mask); |
| # else |
| /* Restore sign-extended high bits, mask slab bit. */ |
| return (extent_t *)((uintptr_t)((intptr_t)(bits << RTREE_NHIB) >> |
| RTREE_NHIB) & ~((uintptr_t)0x1)); |
| # endif |
| } |
| |
| JEMALLOC_ALWAYS_INLINE szind_t |
| rtree_leaf_elm_bits_szind_get(uintptr_t bits) { |
| return (szind_t)(bits >> LG_VADDR); |
| } |
| |
| JEMALLOC_ALWAYS_INLINE bool |
| rtree_leaf_elm_bits_slab_get(uintptr_t bits) { |
| return (bool)(bits & (uintptr_t)0x1); |
| } |
| |
| # endif |
| |
| JEMALLOC_ALWAYS_INLINE extent_t * |
| rtree_leaf_elm_extent_read(UNUSED tsdn_t *tsdn, UNUSED rtree_t *rtree, |
| rtree_leaf_elm_t *elm, bool dependent) { |
| #ifdef RTREE_LEAF_COMPACT |
| uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, dependent); |
| return rtree_leaf_elm_bits_extent_get(bits); |
| #else |
| extent_t *extent = (extent_t *)atomic_load_p(&elm->le_extent, dependent |
| ? ATOMIC_RELAXED : ATOMIC_ACQUIRE); |
| return extent; |
| #endif |
| } |
| |
| JEMALLOC_ALWAYS_INLINE szind_t |
| rtree_leaf_elm_szind_read(UNUSED tsdn_t *tsdn, UNUSED rtree_t *rtree, |
| rtree_leaf_elm_t *elm, bool dependent) { |
| #ifdef RTREE_LEAF_COMPACT |
| uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, dependent); |
| return rtree_leaf_elm_bits_szind_get(bits); |
| #else |
| return (szind_t)atomic_load_u(&elm->le_szind, dependent ? ATOMIC_RELAXED |
| : ATOMIC_ACQUIRE); |
| #endif |
| } |
| |
| JEMALLOC_ALWAYS_INLINE bool |
| rtree_leaf_elm_slab_read(UNUSED tsdn_t *tsdn, UNUSED rtree_t *rtree, |
| rtree_leaf_elm_t *elm, bool dependent) { |
| #ifdef RTREE_LEAF_COMPACT |
| uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, dependent); |
| return rtree_leaf_elm_bits_slab_get(bits); |
| #else |
| return atomic_load_b(&elm->le_slab, dependent ? ATOMIC_RELAXED : |
| ATOMIC_ACQUIRE); |
| #endif |
| } |
| |
| static inline void |
| rtree_leaf_elm_extent_write(UNUSED tsdn_t *tsdn, UNUSED rtree_t *rtree, |
| rtree_leaf_elm_t *elm, extent_t *extent) { |
| #ifdef RTREE_LEAF_COMPACT |
| uintptr_t old_bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, true); |
| uintptr_t bits = ((uintptr_t)rtree_leaf_elm_bits_szind_get(old_bits) << |
| LG_VADDR) | ((uintptr_t)extent & (((uintptr_t)0x1 << LG_VADDR) - 1)) |
| | ((uintptr_t)rtree_leaf_elm_bits_slab_get(old_bits)); |
| atomic_store_p(&elm->le_bits, (void *)bits, ATOMIC_RELEASE); |
| #else |
| atomic_store_p(&elm->le_extent, extent, ATOMIC_RELEASE); |
| #endif |
| } |
| |
| static inline void |
| rtree_leaf_elm_szind_write(UNUSED tsdn_t *tsdn, UNUSED rtree_t *rtree, |
| rtree_leaf_elm_t *elm, szind_t szind) { |
| assert(szind <= NSIZES); |
| |
| #ifdef RTREE_LEAF_COMPACT |
| uintptr_t old_bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, |
| true); |
| uintptr_t bits = ((uintptr_t)szind << LG_VADDR) | |
| ((uintptr_t)rtree_leaf_elm_bits_extent_get(old_bits) & |
| (((uintptr_t)0x1 << LG_VADDR) - 1)) | |
| ((uintptr_t)rtree_leaf_elm_bits_slab_get(old_bits)); |
| atomic_store_p(&elm->le_bits, (void *)bits, ATOMIC_RELEASE); |
| #else |
| atomic_store_u(&elm->le_szind, szind, ATOMIC_RELEASE); |
| #endif |
| } |
| |
| static inline void |
| rtree_leaf_elm_slab_write(UNUSED tsdn_t *tsdn, UNUSED rtree_t *rtree, |
| rtree_leaf_elm_t *elm, bool slab) { |
| #ifdef RTREE_LEAF_COMPACT |
| uintptr_t old_bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, |
| true); |
| uintptr_t bits = ((uintptr_t)rtree_leaf_elm_bits_szind_get(old_bits) << |
| LG_VADDR) | ((uintptr_t)rtree_leaf_elm_bits_extent_get(old_bits) & |
| (((uintptr_t)0x1 << LG_VADDR) - 1)) | ((uintptr_t)slab); |
| atomic_store_p(&elm->le_bits, (void *)bits, ATOMIC_RELEASE); |
| #else |
| atomic_store_b(&elm->le_slab, slab, ATOMIC_RELEASE); |
| #endif |
| } |
| |
| static inline void |
| rtree_leaf_elm_write(tsdn_t *tsdn, rtree_t *rtree, rtree_leaf_elm_t *elm, |
| extent_t *extent, szind_t szind, bool slab) { |
| #ifdef RTREE_LEAF_COMPACT |
| uintptr_t bits = ((uintptr_t)szind << LG_VADDR) | |
| ((uintptr_t)extent & (((uintptr_t)0x1 << LG_VADDR) - 1)) | |
| ((uintptr_t)slab); |
| atomic_store_p(&elm->le_bits, (void *)bits, ATOMIC_RELEASE); |
| #else |
| rtree_leaf_elm_slab_write(tsdn, rtree, elm, slab); |
| rtree_leaf_elm_szind_write(tsdn, rtree, elm, szind); |
| /* |
| * Write extent last, since the element is atomically considered valid |
| * as soon as the extent field is non-NULL. |
| */ |
| rtree_leaf_elm_extent_write(tsdn, rtree, elm, extent); |
| #endif |
| } |
| |
| static inline void |
| rtree_leaf_elm_szind_slab_update(tsdn_t *tsdn, rtree_t *rtree, |
| rtree_leaf_elm_t *elm, szind_t szind, bool slab) { |
| assert(!slab || szind < NBINS); |
| |
| /* |
| * The caller implicitly assures that it is the only writer to the szind |
| * and slab fields, and that the extent field cannot currently change. |
| */ |
| rtree_leaf_elm_slab_write(tsdn, rtree, elm, slab); |
| rtree_leaf_elm_szind_write(tsdn, rtree, elm, szind); |
| } |
| |
| JEMALLOC_ALWAYS_INLINE rtree_leaf_elm_t * |
| rtree_leaf_elm_lookup(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, |
| uintptr_t key, bool dependent, bool init_missing) { |
| assert(key != 0); |
| assert(!dependent || !init_missing); |
| |
| size_t slot = rtree_cache_direct_map(key); |
| uintptr_t leafkey = rtree_leafkey(key); |
| assert(leafkey != RTREE_LEAFKEY_INVALID); |
| |
| /* Fast path: L1 direct mapped cache. */ |
| if (likely(rtree_ctx->cache[slot].leafkey == leafkey)) { |
| rtree_leaf_elm_t *leaf = rtree_ctx->cache[slot].leaf; |
| /* ANDROID CHANGE: Bad pointers return NULL */ |
| /* assert(leaf != NULL); */ |
| if (leaf == NULL) { |
| return NULL; |
| } |
| /* ANDROID END CHANGE */ |
| uintptr_t subkey = rtree_subkey(key, RTREE_HEIGHT-1); |
| return &leaf[subkey]; |
| } |
| /* |
| * Search the L2 LRU cache. On hit, swap the matching element into the |
| * slot in L1 cache, and move the position in L2 up by 1. |
| */ |
| #define RTREE_CACHE_CHECK_L2(i) do { \ |
| if (likely(rtree_ctx->l2_cache[i].leafkey == leafkey)) { \ |
| rtree_leaf_elm_t *leaf = rtree_ctx->l2_cache[i].leaf; \ |
| /* ANDROID CHANGE: Bad pointers return NULL */ \ |
| /* assert(leaf != NULL); */ \ |
| if (leaf == NULL) { \ |
| return NULL; \ |
| } \ |
| /* ANDROID END CHANGE */ \ |
| if (i > 0) { \ |
| /* Bubble up by one. */ \ |
| rtree_ctx->l2_cache[i].leafkey = \ |
| rtree_ctx->l2_cache[i - 1].leafkey; \ |
| rtree_ctx->l2_cache[i].leaf = \ |
| rtree_ctx->l2_cache[i - 1].leaf; \ |
| rtree_ctx->l2_cache[i - 1].leafkey = \ |
| rtree_ctx->cache[slot].leafkey; \ |
| rtree_ctx->l2_cache[i - 1].leaf = \ |
| rtree_ctx->cache[slot].leaf; \ |
| } else { \ |
| rtree_ctx->l2_cache[0].leafkey = \ |
| rtree_ctx->cache[slot].leafkey; \ |
| rtree_ctx->l2_cache[0].leaf = \ |
| rtree_ctx->cache[slot].leaf; \ |
| } \ |
| rtree_ctx->cache[slot].leafkey = leafkey; \ |
| rtree_ctx->cache[slot].leaf = leaf; \ |
| uintptr_t subkey = rtree_subkey(key, RTREE_HEIGHT-1); \ |
| return &leaf[subkey]; \ |
| } \ |
| } while (0) |
| /* Check the first cache entry. */ |
| RTREE_CACHE_CHECK_L2(0); |
| /* Search the remaining cache elements. */ |
| for (unsigned i = 1; i < RTREE_CTX_NCACHE_L2; i++) { |
| RTREE_CACHE_CHECK_L2(i); |
| } |
| #undef RTREE_CACHE_CHECK_L2 |
| |
| return rtree_leaf_elm_lookup_hard(tsdn, rtree, rtree_ctx, key, |
| dependent, init_missing); |
| } |
| |
| static inline bool |
| rtree_write(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, uintptr_t key, |
| extent_t *extent, szind_t szind, bool slab) { |
| /* Use rtree_clear() to set the extent to NULL. */ |
| assert(extent != NULL); |
| |
| rtree_leaf_elm_t *elm = rtree_leaf_elm_lookup(tsdn, rtree, rtree_ctx, |
| key, false, true); |
| if (elm == NULL) { |
| return true; |
| } |
| |
| assert(rtree_leaf_elm_extent_read(tsdn, rtree, elm, false) == NULL); |
| rtree_leaf_elm_write(tsdn, rtree, elm, extent, szind, slab); |
| |
| return false; |
| } |
| |
| JEMALLOC_ALWAYS_INLINE rtree_leaf_elm_t * |
| rtree_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, uintptr_t key, |
| bool dependent) { |
| rtree_leaf_elm_t *elm = rtree_leaf_elm_lookup(tsdn, rtree, rtree_ctx, |
| key, dependent, false); |
| /* ANDROID CHANGE: Bad pointers return NULL */ |
| /* if (!dependent && elm == NULL) { */ |
| if (elm == NULL) { |
| /* ANDROID END CHANGE */ |
| return NULL; |
| } |
| assert(elm != NULL); |
| return elm; |
| } |
| |
| JEMALLOC_ALWAYS_INLINE extent_t * |
| rtree_extent_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, |
| uintptr_t key, bool dependent) { |
| rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key, |
| dependent); |
| /* ANDROID CHANGE: Bad pointers return NULL */ |
| /* if (!dependent && elm == NULL) { */ |
| if (elm == NULL) { |
| /* ANDROID END CHANGE */ |
| return NULL; |
| } |
| return rtree_leaf_elm_extent_read(tsdn, rtree, elm, dependent); |
| } |
| |
| JEMALLOC_ALWAYS_INLINE szind_t |
| rtree_szind_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, |
| uintptr_t key, bool dependent) { |
| rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key, |
| dependent); |
| /* ANDROID CHANGE: Bad pointers return NULL */ |
| /* if (!dependent && elm == NULL) { */ |
| if (elm == NULL) { |
| return NSIZES; |
| } |
| return rtree_leaf_elm_szind_read(tsdn, rtree, elm, dependent); |
| } |
| |
| /* |
| * rtree_slab_read() is intentionally omitted because slab is always read in |
| * conjunction with szind, which makes rtree_szind_slab_read() a better choice. |
| */ |
| |
| JEMALLOC_ALWAYS_INLINE bool |
| rtree_extent_szind_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, |
| uintptr_t key, bool dependent, extent_t **r_extent, szind_t *r_szind) { |
| rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key, |
| dependent); |
| /* ANDROID CHANGE: Bad pointers return NULL */ |
| /* if (!dependent && elm == NULL) { */ |
| if (elm == NULL) { |
| /* ANDROID END CHANGE */ |
| return true; |
| } |
| *r_extent = rtree_leaf_elm_extent_read(tsdn, rtree, elm, dependent); |
| *r_szind = rtree_leaf_elm_szind_read(tsdn, rtree, elm, dependent); |
| return false; |
| } |
| |
| JEMALLOC_ALWAYS_INLINE bool |
| rtree_szind_slab_read(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, |
| uintptr_t key, bool dependent, szind_t *r_szind, bool *r_slab) { |
| rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key, |
| dependent); |
| /* ANDROID CHANGE: Bad pointers return NULL */ |
| /* if (!dependent && elm == NULL) { */ |
| if (elm == NULL) { |
| /* ANDROID END CHANGE */ |
| return true; |
| } |
| #ifdef RTREE_LEAF_COMPACT |
| uintptr_t bits = rtree_leaf_elm_bits_read(tsdn, rtree, elm, dependent); |
| *r_szind = rtree_leaf_elm_bits_szind_get(bits); |
| *r_slab = rtree_leaf_elm_bits_slab_get(bits); |
| #else |
| *r_szind = rtree_leaf_elm_szind_read(tsdn, rtree, elm, dependent); |
| *r_slab = rtree_leaf_elm_slab_read(tsdn, rtree, elm, dependent); |
| #endif |
| return false; |
| } |
| |
| static inline void |
| rtree_szind_slab_update(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, |
| uintptr_t key, szind_t szind, bool slab) { |
| assert(!slab || szind < NBINS); |
| |
| rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key, true); |
| rtree_leaf_elm_szind_slab_update(tsdn, rtree, elm, szind, slab); |
| } |
| |
| static inline void |
| rtree_clear(tsdn_t *tsdn, rtree_t *rtree, rtree_ctx_t *rtree_ctx, |
| uintptr_t key) { |
| rtree_leaf_elm_t *elm = rtree_read(tsdn, rtree, rtree_ctx, key, true); |
| assert(rtree_leaf_elm_extent_read(tsdn, rtree, elm, false) != |
| NULL); |
| rtree_leaf_elm_write(tsdn, rtree, elm, NULL, NSIZES, false); |
| } |
| |
| #endif /* JEMALLOC_INTERNAL_RTREE_H */ |
