/* ---------------------------------------------------------------------------- Copyright (c) 2018-2025, Microsoft Research, Daan Leijen This is free software; you can redistribute it and/or modify it under the terms of the MIT license. A copy of the license can be found in the file "LICENSE" at the root of this distribution. -----------------------------------------------------------------------------*/ #if !defined(MI_IN_ALLOC_C) #error "this file should be included from 'alloc.c' (so aliases can work from alloc-override)" // add includes help an IDE #include "mimalloc.h" #include "mimalloc/internal.h" #include "mimalloc/prim.h" // _mi_prim_thread_id() #endif // forward declarations static void mi_check_padding(const mi_page_t* page, const mi_block_t* block); static bool mi_check_is_double_free(const mi_page_t* page, const mi_block_t* block); static size_t mi_page_usable_size_of(const mi_page_t* page, const mi_block_t* block, bool was_guarded); static void mi_stat_free(const mi_page_t* page, const mi_block_t* block); // ------------------------------------------------------ // Free // ------------------------------------------------------ // regular free of a (thread local) block pointer // fast path written carefully to prevent spilling on the stack static inline void mi_free_block_local(mi_page_t* page, mi_block_t* block, bool was_guarded, bool track_stats, bool check_full) { MI_UNUSED(was_guarded); // checks if mi_unlikely(mi_check_is_double_free(page, block)) return; if (!was_guarded) { mi_check_padding(page, block); } if (track_stats) { mi_stat_free(page, block); } #if (MI_DEBUG>0) && !MI_TRACK_ENABLED && !MI_TSAN memset(block, MI_DEBUG_FREED, mi_page_block_size(page)); #endif if (track_stats) { mi_track_free_size(block, mi_page_usable_size_of(page, block, was_guarded)); } // faster then mi_usable_size as we already know the page and that p is unaligned // actual free: push on the local free list mi_block_set_next(page, block, page->local_free); page->local_free = block; if mi_unlikely(--page->used == 0) { if (page->retire_expire==0) { // no need to re-retire retired pages (happens when we alloc/free one block repeatedly in an empty page) _mi_page_retire(page); } } else if mi_unlikely(check_full && mi_page_is_in_full(page)) { _mi_page_unfull(page); } } // Forward declaration for multi-threaded collect static void mi_decl_noinline mi_free_try_collect_mt(mi_page_t* page, mi_block_t* mt_free) mi_attr_noexcept; // Free a block multi-threaded static inline void mi_free_block_mt(mi_page_t* page, mi_block_t* block, bool was_guarded) mi_attr_noexcept { MI_UNUSED(was_guarded); // adjust stats (after padding check and potentially recursive `mi_free` above) mi_stat_free(page, block); // stat_free may access the padding mi_track_free_size(block, mi_page_usable_size_of(page, block, was_guarded)); // _mi_padding_shrink(page, block, sizeof(mi_block_t)); #if (MI_DEBUG>0) && !MI_TRACK_ENABLED && !MI_TSAN // note: when tracking, cannot use mi_usable_size with multi-threading if (!was_guarded) { size_t dbgsize = mi_usable_size(block); if (dbgsize > MI_MiB) { dbgsize = MI_MiB; } _mi_memset_aligned(block, MI_DEBUG_FREED, dbgsize); } #endif // push atomically on the page thread free list mi_thread_free_t tf_new; mi_thread_free_t tf_old = mi_atomic_load_relaxed(&page->xthread_free); do { mi_block_set_next(page, block, mi_tf_block(tf_old)); tf_new = mi_tf_create(block, true /* always use owned: try to claim it if the page is abandoned */); } while (!mi_atomic_cas_weak_acq_rel(&page->xthread_free, &tf_old, tf_new)); // todo: release is enough? // and atomically try to collect the page if it was abandoned const bool is_owned_now = !mi_tf_is_owned(tf_old); if (is_owned_now) { mi_assert_internal(mi_page_is_abandoned(page)); mi_free_try_collect_mt(page,block); } } // Adjust a block that was allocated aligned, to the actual start of the block in the page. // note: this can be called from `mi_free_generic_mt` where a non-owning thread accesses the // `page_start` and `block_size` fields; however these are constant and the page won't be // deallocated (as the block we are freeing keeps it alive) and thus safe to read concurrently. mi_block_t* _mi_page_ptr_unalign(const mi_page_t* page, const void* p) { mi_assert_internal(page!=NULL && p!=NULL); const size_t diff = (uint8_t*)p - mi_page_start(page); const size_t block_size = mi_page_block_size(page); const size_t adjust = (_mi_is_power_of_two(block_size) ? diff & (block_size - 1) : diff % block_size); return (mi_block_t*)((uintptr_t)p - adjust); } // forward declaration for a MI_GUARDED build #if MI_GUARDED static void mi_block_unguard(mi_page_t* page, mi_block_t* block, void* p); // forward declaration static inline bool mi_block_check_unguard(mi_page_t* page, mi_block_t* block, void* p) { if (mi_block_ptr_is_guarded(block, p)) { mi_block_unguard(page, block, p); return true; } else { return false; } } #else static inline bool mi_block_check_unguard(mi_page_t* page, mi_block_t* block, void* p) { MI_UNUSED(page); MI_UNUSED(block); MI_UNUSED(p); return false; } #endif static inline mi_block_t* mi_validate_block_from_ptr( const mi_page_t* page, void* p ) { mi_assert(_mi_page_ptr_unalign(page,p) == (mi_block_t*)p); // should never be an interior pointer #if MI_SECURE > 0 // in secure mode we always unalign to guard against free-ing interior pointers return _mi_page_ptr_unalign(page,p); #else MI_UNUSED(page); return (mi_block_t*)p; #endif } // free a local pointer (page parameter comes first for better codegen) static void mi_decl_noinline mi_free_generic_local(mi_page_t* page, void* p) mi_attr_noexcept { mi_assert_internal(p!=NULL && page != NULL); mi_block_t* const block = (mi_page_has_interior_pointers(page) ? _mi_page_ptr_unalign(page, p) : mi_validate_block_from_ptr(page,p)); const bool was_guarded = mi_block_check_unguard(page, block, p); mi_free_block_local(page, block, was_guarded, true /* track stats */, true /* check for a full page */); } // free a pointer owned by another thread (page parameter comes first for better codegen) static void mi_decl_noinline mi_free_generic_mt(mi_page_t* page, void* p) mi_attr_noexcept { mi_assert_internal(p!=NULL && page != NULL); mi_block_t* const block = (mi_page_has_interior_pointers(page) ? _mi_page_ptr_unalign(page, p) : mi_validate_block_from_ptr(page,p)); const bool was_guarded = mi_block_check_unguard(page, block, p); mi_free_block_mt(page, block, was_guarded); } // generic free (for runtime integration) void mi_decl_noinline _mi_free_generic(mi_page_t* page, bool is_local, void* p) mi_attr_noexcept { if (is_local) mi_free_generic_local(page,p); else mi_free_generic_mt(page,p); } // Get the page belonging to a pointer // Does further checks in debug mode to see if this was a valid pointer. static inline mi_page_t* mi_validate_ptr_page(const void* p, const char* msg) { MI_UNUSED_RELEASE(msg); #if MI_DEBUG if mi_unlikely(((uintptr_t)p & (MI_INTPTR_SIZE - 1)) != 0 && !mi_option_is_enabled(mi_option_guarded_precise)) { _mi_error_message(EINVAL, "%s: invalid (unaligned) pointer: %p\n", msg, p); return NULL; } mi_page_t* page = _mi_safe_ptr_page(p); if (p != NULL && page == NULL) { _mi_error_message(EINVAL, "%s: invalid pointer: %p\n", msg, p); } return page; #else return _mi_ptr_page(p); #endif } // Free a block // Fast path written carefully to prevent register spilling on the stack static mi_decl_forceinline void mi_free_ex(void* p, size_t* usable, mi_page_t* page) { if mi_unlikely(page==NULL) return; // page will be NULL if p==NULL mi_assert_internal(p!=NULL && page!=NULL); if (usable!=NULL) { *usable = mi_page_usable_block_size(page); } const mi_threadid_t xtid = (_mi_prim_thread_id() ^ mi_page_xthread_id(page)); if mi_likely(xtid == 0) { // `tid == mi_page_thread_id(page) && mi_page_flags(page) == 0` // thread-local, aligned, and not a full page mi_block_t* const block = mi_validate_block_from_ptr(page,p); mi_free_block_local(page, block, false /* was guarded */, true /* track stats */, false /* no need to check if the page is full */); } else if (xtid <= MI_PAGE_FLAG_MASK) { // `tid == mi_page_thread_id(page) && mi_page_flags(page) != 0` // page is local, but is full or contains (inner) aligned blocks; use generic path mi_free_generic_local(page, p); } // free-ing in a page owned by a theap in another thread, or an abandoned page (not belonging to a theap) else if ((xtid & MI_PAGE_FLAG_MASK) == 0) { // `tid != mi_page_thread_id(page) && mi_page_flags(page) == 0` // blocks are aligned (and not a full page); push on the thread_free list mi_block_t* const block = mi_validate_block_from_ptr(page,p); mi_free_block_mt(page,block,false /* was_guarded */); } else { // page is full or contains (inner) aligned blocks; use generic multi-thread path mi_free_generic_mt(page, p); } } void mi_free(void* p) mi_attr_noexcept { mi_page_t* const page = mi_validate_ptr_page(p,"mi_free"); mi_free_ex(p, NULL, page); } void mi_ufree(void* p, size_t* usable) mi_attr_noexcept { mi_page_t* const page = mi_validate_ptr_page(p,"mi_ufree"); mi_free_ex(p, usable, page); } void mi_free_small(void* p) mi_attr_noexcept { // We can only call `mi_free_small` for pointers allocated with `mi_(heap_)malloc_small`. // If we keep page info in front of the page area for small objects, we can find the info // just by aligning down the pointer instead of looking it up in the page map. #if MI_PAGE_META_ALIGNED_FREE_SMALL #if MI_GUARDED #warning "MI_PAGE_META_ALIGNED_FREE_SMALL ignored as MI_GUARDED is defined" mi_free(p); #elif MI_ARENA_SLICE_ALIGN < MI_SMALL_PAGE_SIZE #warning "MI_PAGE_META_ALIGNED_FREE_SMALL ignored as the MI_ARENA_SLICE_ALIGN is less than the small page size" mi_free(p); #else mi_page_t* const page = (mi_page_t*)_mi_align_down_ptr(p,MI_SMALL_PAGE_SIZE); mi_assert(page == mi_validate_ptr_page(p,"mi_free_small")); mi_assert((void*)page == _mi_align_down_ptr(page->page_start,MI_SMALL_PAGE_SIZE)); mi_assert(page->block_size <= MI_SMALL_SIZE_MAX); // note: not `MI_SMALL_MAX_OBJ_SIZE` as we need to match `mi_(heap_)malloc_small` mi_free_ex(p, NULL, page); #endif #else mi_free(p); #endif } // -------------------------------------------------------------------------------------------- // `mi_free_try_collect_mt`: Potentially collect a page in a free in an abandoned page. // 1. if the page becomes empty, free it // 2. if it can be reclaimed, reclaim it in our theap // 3. if it went to < 7/8th used, re-abandon to be mapped (so it can be found by theaps looking for free pages) // -------------------------------------------------------------------------------------------- // Helper for mi_free_try_collect_mt: free if the page has no more used blocks (this is updated by `_mi_page_free_collect(_partly)`) static bool mi_abandoned_page_try_free(mi_page_t* page) { if (!mi_page_all_free(page)) return false; // first remove it from the abandoned pages in the arena (if mapped, this might wait for any readers to finish) _mi_arenas_page_unabandon(page,NULL); _mi_arenas_page_free(page,NULL); // we can now free the page directly return true; } // Helper for mi_free_try_collect_mt: try if we can reabandon a previously abandoned mostly full page to be mapped static bool mi_abandoned_page_try_reabandon_to_mapped(mi_page_t* page) { // if the page is unmapped, try to reabandon so it can possibly be mapped and found for allocations // We only reabandon if a full page starts to have enough blocks available to prevent immediate re-abandon of a full page if (mi_page_is_mostly_used(page)) return false; // not too full if (page->memid.memkind != MI_MEM_ARENA || mi_page_is_abandoned_mapped(page)) return false; // and not already mapped (or unmappable) mi_assert(!mi_page_is_full(page)); return _mi_arenas_page_try_reabandon_to_mapped(page); } // Release ownership of a page. This may free or reabandoned the page if other blocks are concurrently // freed in the meantime. Returns `true` if the page was freed. // By passing the captured `expected_thread_free`, we can often avoid calling `mi_page_free_collect`. static void mi_abandoned_page_unown_from_free(mi_page_t* page, mi_block_t* expected_thread_free) { mi_assert_internal(mi_page_is_owned(page)); mi_assert_internal(mi_page_is_abandoned(page)); mi_assert_internal(!mi_page_all_free(page)); // try to cas atomically the original free list (`mt_free`) back with the ownership cleared. mi_thread_free_t tf_expect = mi_tf_create(expected_thread_free, true); mi_thread_free_t tf_new = mi_tf_create(expected_thread_free, false); while mi_unlikely(!mi_atomic_cas_weak_acq_rel(&page->xthread_free, &tf_expect, tf_new)) { mi_assert_internal(mi_tf_is_owned(tf_expect)); // while the xthread_free list is not empty.. while (mi_tf_block(tf_expect) != NULL) { // if there were concurrent updates to the thread-free list, we retry to free or reabandon to mapped (if it became !mosty_used). _mi_page_free_collect(page,false); // update used count if (mi_abandoned_page_try_free(page)) return; if (mi_abandoned_page_try_reabandon_to_mapped(page)) return; // otherwise continue un-owning tf_expect = mi_atomic_load_relaxed(&page->xthread_free); } // and try again to release ownership mi_assert_internal(mi_tf_block(tf_expect)==NULL); tf_new = mi_tf_create(NULL, false); } } static inline bool mi_page_queue_len_is_atmost( mi_theap_t* theap, size_t block_size, long atmost) { if (atmost < 0) return false; mi_page_queue_t* const pq = mi_page_queue(theap,block_size); mi_assert_internal(pq!=NULL); return (pq->count <= (size_t)atmost); } // Helper for mi_free_try_collect_mt: try to reclaim the page for ourselves static mi_decl_noinline bool mi_abandoned_page_try_reclaim(mi_page_t* page, long reclaim_on_free) mi_attr_noexcept { // note: reclaiming can improve benchmarks like `larson` or `rbtree-ck` a lot even in the single-threaded case, // since free-ing from an owned page avoids atomic operations. However, if we reclaim too eagerly in // a multi-threaded scenario we may start to hold on to too much memory and reduce reuse among threads. // If the current theap is where the page originally came from, we reclaim much more eagerly while // 'cross-thread' reclaiming on free is by default off (and we only 'reclaim' these by finding the abandoned // pages when we allocate a fresh page). mi_assert_internal(mi_page_is_owned(page)); mi_assert_internal(mi_page_is_abandoned(page)); mi_assert_internal(!mi_page_all_free(page)); mi_assert_internal(page->block_size <= MI_SMALL_SIZE_MAX); mi_assert_internal(reclaim_on_free >= 0); // dont reclaim if we just have terminated this thread and we should // not reinitialize the theap for this thread. (can happen due to thread-local destructors for example -- issue #944) if (!_mi_thread_is_initialized()) return false; // get our theap mi_theap_t* const theap = _mi_page_associated_theap_peek(page); if (theap==NULL || !theap->allow_page_reclaim) return false; // todo: cache `is_in_threadpool` and `exclusive_arena` directly in the theap for performance? // set max_reclaim limit long max_reclaim = 0; if mi_likely(theap == page->theap) { // did this page originate from the current theap? (and thus allocated from this thread) // originating theap max_reclaim = _mi_option_get_fast(theap->tld->is_in_threadpool ? mi_option_page_cross_thread_max_reclaim : mi_option_page_max_reclaim); } else if (reclaim_on_free == 1 && // if cross-thread is allowed !theap->tld->is_in_threadpool && // and we are not part of a threadpool !mi_page_is_mostly_used(page) && // and the page is not too full _mi_arena_memid_is_suitable(page->memid, _mi_theap_heap(theap)->exclusive_arena)) { // and it fits our memory // across threads max_reclaim = _mi_option_get_fast(mi_option_page_cross_thread_max_reclaim); } // are we within the reclaim limit? if (max_reclaim >= 0 && !mi_page_queue_len_is_atmost(theap, page->block_size, max_reclaim)) { return false; } // reclaim the page into this theap // first remove it from the abandoned pages in the arena -- this might wait for any readers to finish _mi_arenas_page_unabandon(page, theap); _mi_theap_page_reclaim(theap, page); mi_theap_stat_counter_increase(theap, pages_reclaim_on_free, 1); return true; } // We freed a block in an abandoned page (that was not owned). Try to collect static void mi_decl_noinline mi_free_try_collect_mt(mi_page_t* page, mi_block_t* mt_free) mi_attr_noexcept { mi_assert_internal(mi_page_is_owned(page)); mi_assert_internal(mi_page_is_abandoned(page)); mi_assert_internal(mt_free != NULL); // we own the page now, and it is safe to collect the thread atomic free list if (page->block_size <= MI_SMALL_SIZE_MAX) { // use the `_partly` version to avoid atomic operations since we already have the `mt_free` pointing into the thread free list // (after this the `used` count might be too high (as some blocks may have been concurrently added to the thread free list and are yet uncounted). // however, if the page became completely free, the used count is guaranteed to be 0.) mi_assert_internal(page->reserved>=16); // below this even one freed block goes from full to no longer mostly used. _mi_page_free_collect_partly(page, mt_free); } else { // for larger blocks we use the regular collect _mi_page_free_collect(page,false /* no force */); mt_free = NULL; // expected page->xthread_free value after collection } const long reclaim_on_free = _mi_option_get_fast(mi_option_page_reclaim_on_free); #if MI_DEBUG > 1 if (mi_page_is_singleton(page)) { mi_assert_internal(mi_page_all_free(page)); } if (mi_page_is_full(page)) { mi_assert(mi_page_is_mostly_used(page)); } #endif // try to: 1. free it, 2. reclaim it, or 3. reabandon it to be mapped if (mi_abandoned_page_try_free(page)) return; if (page->block_size <= MI_SMALL_SIZE_MAX && reclaim_on_free >= 0) { // early test for better codegen if (mi_abandoned_page_try_reclaim(page, reclaim_on_free)) return; } if (mi_abandoned_page_try_reabandon_to_mapped(page)) return; // otherwise unown the page again mi_abandoned_page_unown_from_free(page, mt_free); } // ------------------------------------------------------ // Usable size // ------------------------------------------------------ // Bytes available in a block static size_t mi_decl_noinline mi_page_usable_aligned_size_of(const mi_page_t* page, const void* p) mi_attr_noexcept { const mi_block_t* block = _mi_page_ptr_unalign(page, p); const bool is_guarded = mi_block_ptr_is_guarded(block,p); const size_t size = mi_page_usable_size_of(page, block, is_guarded); const ptrdiff_t adjust = (uint8_t*)p - (uint8_t*)block; mi_assert_internal(adjust >= 0 && (size_t)adjust <= size); const size_t aligned_size = (size - adjust); return aligned_size; } static inline size_t _mi_usable_size(const void* p, const mi_page_t* page) mi_attr_noexcept { if mi_unlikely(page==NULL) return 0; if mi_likely(!mi_page_has_interior_pointers(page)) { const mi_block_t* block = (const mi_block_t*)p; return mi_page_usable_size_of(page, block, false /* is guarded */); } else { // split out to separate routine for improved code generation return mi_page_usable_aligned_size_of(page, p); } } mi_decl_nodiscard size_t mi_usable_size(const void* p) mi_attr_noexcept { const mi_page_t* const page = mi_validate_ptr_page(p,"mi_usable_size"); return _mi_usable_size(p,page); } // ------------------------------------------------------ // Free variants // ------------------------------------------------------ void mi_free_size(void* p, size_t size) mi_attr_noexcept { MI_UNUSED_RELEASE(size); #if MI_DEBUG const mi_page_t* const page = mi_validate_ptr_page(p,"mi_free_size"); const size_t available = _mi_usable_size(p,page); mi_assert(p == NULL || size <= available || available == 0 /* invalid pointer */ ); #endif mi_free(p); } void mi_free_size_aligned(void* p, size_t size, size_t alignment) mi_attr_noexcept { MI_UNUSED_RELEASE(alignment); mi_assert(((uintptr_t)p % alignment) == 0); mi_free_size(p,size); } void mi_free_aligned(void* p, size_t alignment) mi_attr_noexcept { MI_UNUSED_RELEASE(alignment); mi_assert(((uintptr_t)p % alignment) == 0); mi_free(p); } // ------------------------------------------------------ // Check for double free in secure and debug mode // This is somewhat expensive so only enabled for secure mode 4 // ------------------------------------------------------ #if (MI_ENCODE_FREELIST && (MI_SECURE>=4 || MI_DEBUG!=0)) // linear check if the free list contains a specific element static bool mi_list_contains(const mi_page_t* page, const mi_block_t* list, const mi_block_t* elem) { while (list != NULL) { if (elem==list) return true; list = mi_block_next(page, list); } return false; } static mi_decl_noinline bool mi_check_is_double_freex(const mi_page_t* page, const mi_block_t* block) { // The decoded value is in the same page (or NULL). // Walk the free lists to verify positively if it is already freed if (mi_list_contains(page, page->free, block) || mi_list_contains(page, page->local_free, block) || mi_list_contains(page, mi_page_thread_free(page), block)) { _mi_error_message(EAGAIN, "double free detected of block %p with size %zu\n", block, mi_page_block_size(page)); return true; } return false; } #define mi_track_page(page,access) { size_t psize; void* pstart = _mi_page_start(_mi_page_segment(page),page,&psize); mi_track_mem_##access( pstart, psize); } static inline bool mi_check_is_double_free(const mi_page_t* page, const mi_block_t* block) { bool is_double_free = false; mi_block_t* n = mi_block_nextx(page, block, page->keys); // pretend it is freed, and get the decoded first field if (((uintptr_t)n & (MI_INTPTR_SIZE-1))==0 && // quick check: aligned pointer? (n==NULL || mi_is_in_same_page(block, n))) // quick check: in same page or NULL? { // Suspicious: decoded value a in block is in the same page (or NULL) -- maybe a double free? // (continue in separate function to improve code generation) is_double_free = mi_check_is_double_freex(page, block); } return is_double_free; } #else static inline bool mi_check_is_double_free(const mi_page_t* page, const mi_block_t* block) { MI_UNUSED(page); MI_UNUSED(block); return false; } #endif // --------------------------------------------------------------------------- // Check for theap block overflow by setting up padding at the end of the block // --------------------------------------------------------------------------- #if MI_PADDING // && !MI_TRACK_ENABLED static bool mi_page_decode_padding(const mi_page_t* page, const mi_block_t* block, size_t* delta, size_t* bsize) { *bsize = mi_page_usable_block_size(page); const mi_padding_t* const padding = (mi_padding_t*)((uint8_t*)block + *bsize); mi_track_mem_defined(padding,sizeof(mi_padding_t)); *delta = padding->delta; uint32_t canary = padding->canary; uintptr_t keys[2]; keys[0] = page->keys[0]; keys[1] = page->keys[1]; bool ok = (mi_ptr_encode_canary(page,block,keys) == canary && *delta <= *bsize); mi_track_mem_noaccess(padding,sizeof(mi_padding_t)); return ok; } // Return the exact usable size of a block. static size_t mi_page_usable_size_of(const mi_page_t* page, const mi_block_t* block, bool is_guarded) { if (is_guarded) { const size_t bsize = mi_page_block_size(page); return (bsize - _mi_os_page_size()); } else { size_t bsize; size_t delta; bool ok = mi_page_decode_padding(page, block, &delta, &bsize); mi_assert_internal(ok); mi_assert_internal(delta <= bsize); return (ok ? bsize - delta : 0); } } // When a non-thread-local block is freed, it becomes part of the thread delayed free // list that is freed later by the owning theap. If the exact usable size is too small to // contain the pointer for the delayed list, then shrink the padding (by decreasing delta) // so it will later not trigger an overflow error in `mi_free_block`. void _mi_padding_shrink(const mi_page_t* page, const mi_block_t* block, const size_t min_size) { size_t bsize; size_t delta; bool ok = mi_page_decode_padding(page, block, &delta, &bsize); mi_assert_internal(ok); if (!ok || (bsize - delta) >= min_size) return; // usually already enough space mi_assert_internal(bsize >= min_size); if (bsize < min_size) return; // should never happen size_t new_delta = (bsize - min_size); mi_assert_internal(new_delta < bsize); mi_padding_t* padding = (mi_padding_t*)((uint8_t*)block + bsize); mi_track_mem_defined(padding,sizeof(mi_padding_t)); padding->delta = (uint32_t)new_delta; mi_track_mem_noaccess(padding,sizeof(mi_padding_t)); } #else static size_t mi_page_usable_size_of(const mi_page_t* page, const mi_block_t* block, bool is_guarded) { MI_UNUSED(is_guarded); MI_UNUSED(block); return mi_page_usable_block_size(page); } void _mi_padding_shrink(const mi_page_t* page, const mi_block_t* block, const size_t min_size) { MI_UNUSED(page); MI_UNUSED(block); MI_UNUSED(min_size); } #endif #if MI_PADDING && MI_PADDING_CHECK static bool mi_verify_padding(const mi_page_t* page, const mi_block_t* block, size_t* size, size_t* wrong) { size_t bsize; size_t delta; bool ok = mi_page_decode_padding(page, block, &delta, &bsize); *size = *wrong = bsize; if (!ok) return false; mi_assert_internal(bsize >= delta); *size = bsize - delta; if (!mi_page_is_huge(page)) { uint8_t* fill = (uint8_t*)block + bsize - delta; const size_t maxpad = (delta > MI_MAX_ALIGN_SIZE ? MI_MAX_ALIGN_SIZE : delta); // check at most the first N padding bytes mi_track_mem_defined(fill, maxpad); for (size_t i = 0; i < maxpad; i++) { if (fill[i] != MI_DEBUG_PADDING) { *wrong = bsize - delta + i; ok = false; break; } } mi_track_mem_noaccess(fill, maxpad); } return ok; } static void mi_check_padding(const mi_page_t* page, const mi_block_t* block) { size_t size; size_t wrong; if (!mi_verify_padding(page,block,&size,&wrong)) { _mi_error_message(EFAULT, "buffer overflow in theap block %p of size %zu: write after %zu bytes\n", block, size, wrong ); } } #else static void mi_check_padding(const mi_page_t* page, const mi_block_t* block) { MI_UNUSED(page); MI_UNUSED(block); } #endif // only maintain stats for smaller objects if requested #if (MI_STAT>0) static void mi_stat_free(const mi_page_t* page, const mi_block_t* block) { MI_UNUSED(block); mi_theap_t* const theap = _mi_theap_default(); if (!mi_theap_is_initialized(theap)) return; // (for now) skip statistics if free'd after thread_done was called (usually a thread cleanup call by the OS) const size_t bsize = mi_page_usable_block_size(page); // #if (MI_STAT>1) // const size_t usize = mi_page_usable_size_of(page, block); // mi_theap_stat_decrease(theap, malloc_requested, usize); // #endif if (bsize <= MI_LARGE_MAX_OBJ_SIZE) { mi_theap_stat_decrease(theap, malloc_normal, bsize); #if (MI_STAT > 1) mi_theap_stat_decrease(theap, malloc_bins[_mi_bin(bsize)], 1); #endif } else { const size_t bpsize = mi_page_block_size(page); // match stat in page.c:mi_huge_page_alloc mi_theap_stat_decrease(theap, malloc_huge, bpsize); } } #else void mi_stat_free(const mi_page_t* page, const mi_block_t* block) { MI_UNUSED(page); MI_UNUSED(block); } #endif // Remove guard page when building with MI_GUARDED #if MI_GUARDED static void mi_block_unguard(mi_page_t* page, mi_block_t* block, void* p) { MI_UNUSED(p); mi_assert_internal(mi_block_ptr_is_guarded(block, p)); mi_assert_internal(mi_page_has_interior_pointers(page)); mi_assert_internal((uint8_t*)p - (uint8_t*)block >= (ptrdiff_t)sizeof(mi_block_t)); mi_assert_internal(block->next == MI_BLOCK_TAG_GUARDED); const size_t bsize = mi_page_block_size(page); const size_t psize = _mi_os_page_size(); mi_assert_internal(bsize > psize); mi_assert_internal(!page->memid.is_pinned); void* gpage = (uint8_t*)block + bsize - psize; mi_assert_internal(_mi_is_aligned(gpage, psize)); _mi_os_unprotect(gpage, psize); } #endif