/* ---------------------------------------------------------------------------- Copyright (c) 2018-2021, 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. -----------------------------------------------------------------------------*/ #include "mimalloc.h" #include "mimalloc/internal.h" #include "mimalloc/prim.h" // mi_prim_get_default_heap #include // memset // ------------------------------------------------------ // Aligned Allocation // ------------------------------------------------------ static bool mi_malloc_is_naturally_aligned( size_t size, size_t alignment ) { // objects up to `MI_MAX_ALIGN_GUARANTEE` are allocated aligned to their size (see `segment.c:_mi_segment_page_start`). mi_assert_internal(_mi_is_power_of_two(alignment) && (alignment > 0)); if (alignment > size) return false; if (alignment <= MI_MAX_ALIGN_SIZE) return true; const size_t bsize = mi_good_size(size); return (bsize <= MI_MAX_ALIGN_GUARANTEE && (bsize & (alignment-1)) == 0); } #if MI_GUARDED static mi_decl_restrict void* mi_heap_malloc_guarded_aligned(mi_heap_t* heap, size_t size, size_t alignment, bool zero) mi_attr_noexcept { // use over allocation for guarded blocksl mi_assert_internal(alignment > 0 && alignment < MI_BLOCK_ALIGNMENT_MAX); const size_t oversize = size + alignment - 1; void* base = _mi_heap_malloc_guarded(heap, oversize, zero); void* p = mi_align_up_ptr(base, alignment); mi_track_align(base, p, (uint8_t*)p - (uint8_t*)base, size); mi_assert_internal(mi_usable_size(p) >= size); mi_assert_internal(_mi_is_aligned(p, alignment)); return p; } static void* mi_heap_malloc_zero_no_guarded(mi_heap_t* heap, size_t size, bool zero, size_t* usable) { const size_t rate = heap->guarded_sample_rate; // only write if `rate!=0` so we don't write to the constant `_mi_heap_empty` if (rate != 0) { heap->guarded_sample_rate = 0; } void* p = _mi_heap_malloc_zero_ex(heap, size, zero, 0, usable); if (rate != 0) { heap->guarded_sample_rate = rate; } return p; } #else static void* mi_heap_malloc_zero_no_guarded(mi_heap_t* heap, size_t size, bool zero, size_t* usable) { return _mi_heap_malloc_zero_ex(heap, size, zero, 0, usable); } #endif // Fallback aligned allocation that over-allocates -- split out for better codegen static mi_decl_noinline void* mi_heap_malloc_zero_aligned_at_overalloc(mi_heap_t* const heap, const size_t size, const size_t alignment, const size_t offset, const bool zero, size_t* usable) mi_attr_noexcept { mi_assert_internal(size <= (MI_MAX_ALLOC_SIZE - MI_PADDING_SIZE)); mi_assert_internal(alignment != 0 && _mi_is_power_of_two(alignment)); void* p; size_t oversize; if mi_unlikely(alignment > MI_BLOCK_ALIGNMENT_MAX) { // use OS allocation for very large alignment and allocate inside a huge page (dedicated segment with 1 page) // This can support alignments >= MI_SEGMENT_SIZE by ensuring the object can be aligned at a point in the // first (and single) page such that the segment info is `MI_SEGMENT_SIZE` bytes before it (so it can be found by aligning the pointer down) if mi_unlikely(offset != 0) { // todo: cannot support offset alignment for very large alignments yet #if MI_DEBUG > 0 _mi_error_message(EOVERFLOW, "aligned allocation with a very large alignment cannot be used with an alignment offset (size %zu, alignment %zu, offset %zu)\n", size, alignment, offset); #endif return NULL; } oversize = (size <= MI_SMALL_SIZE_MAX ? MI_SMALL_SIZE_MAX + 1 /* ensure we use generic malloc path */ : size); // note: no guarded as alignment > 0 p = _mi_heap_malloc_zero_ex(heap, oversize, false, alignment, usable); // the page block size should be large enough to align in the single huge page block // zero afterwards as only the area from the aligned_p may be committed! if (p == NULL) return NULL; } else { // otherwise over-allocate oversize = (size < MI_MAX_ALIGN_SIZE ? MI_MAX_ALIGN_SIZE : size) + alignment - 1; // adjust for size <= 16; with size 0 and aligment 64k, we would allocate a 64k block and pointing just beyond that. p = mi_heap_malloc_zero_no_guarded(heap, oversize, zero, usable); if (p == NULL) return NULL; } mi_page_t* page = _mi_ptr_page(p); // .. and align within the allocation const uintptr_t align_mask = alignment - 1; // for any x, `(x & align_mask) == (x % alignment)` const uintptr_t poffset = ((uintptr_t)p + offset) & align_mask; const uintptr_t adjust = (poffset == 0 ? 0 : alignment - poffset); mi_assert_internal(adjust < alignment); void* aligned_p = (void*)((uintptr_t)p + adjust); if (aligned_p != p) { mi_page_set_has_aligned(page, true); #if MI_GUARDED // set tag to aligned so mi_usable_size works with guard pages if (adjust >= sizeof(mi_block_t)) { mi_block_t* const block = (mi_block_t*)p; block->next = MI_BLOCK_TAG_ALIGNED; } #endif _mi_padding_shrink(page, (mi_block_t*)p, adjust + size); } // todo: expand padding if overallocated ? mi_assert_internal(mi_page_usable_block_size(page) >= adjust + size); mi_assert_internal(((uintptr_t)aligned_p + offset) % alignment == 0); mi_assert_internal(mi_usable_size(aligned_p)>=size); mi_assert_internal(mi_usable_size(p) == mi_usable_size(aligned_p)+adjust); #if MI_DEBUG > 1 mi_page_t* const apage = _mi_ptr_page(aligned_p); void* unalign_p = _mi_page_ptr_unalign(apage, aligned_p); mi_assert_internal(p == unalign_p); #endif // now zero the block if needed if (alignment > MI_BLOCK_ALIGNMENT_MAX) { // for the tracker, on huge aligned allocations only the memory from the start of the large block is defined mi_track_mem_undefined(aligned_p, size); if (zero) { _mi_memzero_aligned(aligned_p, mi_usable_size(aligned_p)); } } if (p != aligned_p) { mi_track_align(p,aligned_p,adjust,mi_usable_size(aligned_p)); #if MI_GUARDED mi_track_mem_defined(p, sizeof(mi_block_t)); #endif } return aligned_p; } // Generic primitive aligned allocation -- split out for better codegen static mi_decl_noinline void* mi_heap_malloc_zero_aligned_at_generic(mi_heap_t* const heap, const size_t size, const size_t alignment, const size_t offset, const bool zero, size_t* usable) mi_attr_noexcept { mi_assert_internal(alignment != 0 && _mi_is_power_of_two(alignment)); // we don't allocate more than MI_MAX_ALLOC_SIZE (see ) if mi_unlikely(size > (MI_MAX_ALLOC_SIZE - MI_PADDING_SIZE)) { #if MI_DEBUG > 0 _mi_error_message(EOVERFLOW, "aligned allocation request is too large (size %zu, alignment %zu)\n", size, alignment); #endif return NULL; } // use regular allocation if it is guaranteed to fit the alignment constraints. // this is important to try as the fast path in `mi_heap_malloc_zero_aligned` only works when there exist // a page with the right block size, and if we always use the over-alloc fallback that would never happen. if (offset == 0 && mi_malloc_is_naturally_aligned(size,alignment)) { void* p = mi_heap_malloc_zero_no_guarded(heap, size, zero, usable); mi_assert_internal(p == NULL || ((uintptr_t)p % alignment) == 0); const bool is_aligned_or_null = (((uintptr_t)p) & (alignment-1))==0; if mi_likely(is_aligned_or_null) { return p; } else { // this should never happen if the `mi_malloc_is_naturally_aligned` check is correct.. mi_assert(false); mi_free(p); } } // fall back to over-allocation return mi_heap_malloc_zero_aligned_at_overalloc(heap,size,alignment,offset,zero,usable); } // Primitive aligned allocation static void* mi_heap_malloc_zero_aligned_at(mi_heap_t* const heap, const size_t size, const size_t alignment, const size_t offset, const bool zero, size_t* usable) mi_attr_noexcept { // note: we don't require `size > offset`, we just guarantee that the address at offset is aligned regardless of the allocated size. if mi_unlikely(alignment == 0 || !_mi_is_power_of_two(alignment)) { // require power-of-two (see ) #if MI_DEBUG > 0 _mi_error_message(EOVERFLOW, "aligned allocation requires the alignment to be a power-of-two (size %zu, alignment %zu)\n", size, alignment); #endif return NULL; } #if MI_GUARDED if (offset==0 && alignment < MI_BLOCK_ALIGNMENT_MAX && mi_heap_malloc_use_guarded(heap,size)) { return mi_heap_malloc_guarded_aligned(heap, size, alignment, zero); } #endif // try first if there happens to be a small block available with just the right alignment if mi_likely(size <= MI_SMALL_SIZE_MAX && alignment <= size) { const uintptr_t align_mask = alignment-1; // for any x, `(x & align_mask) == (x % alignment)` const size_t padsize = size + MI_PADDING_SIZE; mi_page_t* page = _mi_heap_get_free_small_page(heap, padsize); if mi_likely(page->free != NULL) { const bool is_aligned = (((uintptr_t)page->free + offset) & align_mask)==0; if mi_likely(is_aligned) { if (usable!=NULL) { *usable = mi_page_usable_block_size(page); } void* p = (zero ? _mi_page_malloc_zeroed(heap,page,padsize) : _mi_page_malloc(heap,page,padsize)); // call specific page malloc for better codegen mi_assert_internal(p != NULL); mi_assert_internal(((uintptr_t)p + offset) % alignment == 0); mi_track_malloc(p,size,zero); return p; } } } // fallback to generic aligned allocation return mi_heap_malloc_zero_aligned_at_generic(heap, size, alignment, offset, zero, usable); } // ------------------------------------------------------ // Optimized mi_heap_malloc_aligned / mi_malloc_aligned // ------------------------------------------------------ mi_decl_nodiscard mi_decl_restrict void* mi_heap_malloc_aligned_at(mi_heap_t* heap, size_t size, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_malloc_zero_aligned_at(heap, size, alignment, offset, false, NULL); } mi_decl_nodiscard mi_decl_restrict void* mi_heap_malloc_aligned(mi_heap_t* heap, size_t size, size_t alignment) mi_attr_noexcept { return mi_heap_malloc_aligned_at(heap, size, alignment, 0); } // ensure a definition is emitted #if defined(__cplusplus) void* _mi_extern_heap_malloc_aligned = (void*)&mi_heap_malloc_aligned; #endif // ------------------------------------------------------ // Aligned Allocation // ------------------------------------------------------ mi_decl_nodiscard mi_decl_restrict void* mi_heap_zalloc_aligned_at(mi_heap_t* heap, size_t size, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_malloc_zero_aligned_at(heap, size, alignment, offset, true, NULL); } mi_decl_nodiscard mi_decl_restrict void* mi_heap_zalloc_aligned(mi_heap_t* heap, size_t size, size_t alignment) mi_attr_noexcept { return mi_heap_zalloc_aligned_at(heap, size, alignment, 0); } mi_decl_nodiscard mi_decl_restrict void* mi_heap_calloc_aligned_at(mi_heap_t* heap, size_t count, size_t size, size_t alignment, size_t offset) mi_attr_noexcept { size_t total; if (mi_count_size_overflow(count, size, &total)) return NULL; return mi_heap_zalloc_aligned_at(heap, total, alignment, offset); } mi_decl_nodiscard mi_decl_restrict void* mi_heap_calloc_aligned(mi_heap_t* heap, size_t count, size_t size, size_t alignment) mi_attr_noexcept { return mi_heap_calloc_aligned_at(heap,count,size,alignment,0); } mi_decl_nodiscard mi_decl_restrict void* mi_malloc_aligned_at(size_t size, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_malloc_aligned_at(mi_prim_get_default_heap(), size, alignment, offset); } mi_decl_nodiscard mi_decl_restrict void* mi_malloc_aligned(size_t size, size_t alignment) mi_attr_noexcept { return mi_heap_malloc_aligned(mi_prim_get_default_heap(), size, alignment); } mi_decl_nodiscard mi_decl_restrict void* mi_umalloc_aligned(size_t size, size_t alignment, size_t* block_size) mi_attr_noexcept { return mi_heap_malloc_zero_aligned_at(mi_prim_get_default_heap(), size, alignment, 0, false, block_size); } mi_decl_nodiscard mi_decl_restrict void* mi_zalloc_aligned_at(size_t size, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_zalloc_aligned_at(mi_prim_get_default_heap(), size, alignment, offset); } mi_decl_nodiscard mi_decl_restrict void* mi_zalloc_aligned(size_t size, size_t alignment) mi_attr_noexcept { return mi_heap_zalloc_aligned(mi_prim_get_default_heap(), size, alignment); } mi_decl_nodiscard mi_decl_restrict void* mi_uzalloc_aligned(size_t size, size_t alignment, size_t* block_size) mi_attr_noexcept { return mi_heap_malloc_zero_aligned_at(mi_prim_get_default_heap(), size, alignment, 0, true, block_size); } mi_decl_nodiscard mi_decl_restrict void* mi_calloc_aligned_at(size_t count, size_t size, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_calloc_aligned_at(mi_prim_get_default_heap(), count, size, alignment, offset); } mi_decl_nodiscard mi_decl_restrict void* mi_calloc_aligned(size_t count, size_t size, size_t alignment) mi_attr_noexcept { return mi_heap_calloc_aligned(mi_prim_get_default_heap(), count, size, alignment); } // ------------------------------------------------------ // Aligned re-allocation // ------------------------------------------------------ static void* mi_heap_realloc_zero_aligned_at(mi_heap_t* heap, void* p, size_t newsize, size_t alignment, size_t offset, bool zero) mi_attr_noexcept { mi_assert(alignment > 0); if (alignment <= sizeof(uintptr_t)) return _mi_heap_realloc_zero(heap,p,newsize,zero,NULL,NULL); if (p == NULL) return mi_heap_malloc_zero_aligned_at(heap,newsize,alignment,offset,zero,NULL); size_t size = mi_usable_size(p); if (newsize <= size && newsize >= (size - (size / 2)) && (((uintptr_t)p + offset) % alignment) == 0) { return p; // reallocation still fits, is aligned and not more than 50% waste } else { // note: we don't zero allocate upfront so we only zero initialize the expanded part void* newp = mi_heap_malloc_aligned_at(heap,newsize,alignment,offset); if (newp != NULL) { if (zero && newsize > size) { // also set last word in the previous allocation to zero to ensure any padding is zero-initialized size_t start = (size >= sizeof(intptr_t) ? size - sizeof(intptr_t) : 0); _mi_memzero((uint8_t*)newp + start, newsize - start); } _mi_memcpy_aligned(newp, p, (newsize > size ? size : newsize)); mi_free(p); // only free if successful } return newp; } } static void* mi_heap_realloc_zero_aligned(mi_heap_t* heap, void* p, size_t newsize, size_t alignment, bool zero) mi_attr_noexcept { mi_assert(alignment > 0); if (alignment <= sizeof(uintptr_t)) return _mi_heap_realloc_zero(heap,p,newsize,zero,NULL,NULL); size_t offset = ((uintptr_t)p % alignment); // use offset of previous allocation (p can be NULL) return mi_heap_realloc_zero_aligned_at(heap,p,newsize,alignment,offset,zero); } mi_decl_nodiscard void* mi_heap_realloc_aligned_at(mi_heap_t* heap, void* p, size_t newsize, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_realloc_zero_aligned_at(heap,p,newsize,alignment,offset,false); } mi_decl_nodiscard void* mi_heap_realloc_aligned(mi_heap_t* heap, void* p, size_t newsize, size_t alignment) mi_attr_noexcept { return mi_heap_realloc_zero_aligned(heap,p,newsize,alignment,false); } mi_decl_nodiscard void* mi_heap_rezalloc_aligned_at(mi_heap_t* heap, void* p, size_t newsize, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_realloc_zero_aligned_at(heap, p, newsize, alignment, offset, true); } mi_decl_nodiscard void* mi_heap_rezalloc_aligned(mi_heap_t* heap, void* p, size_t newsize, size_t alignment) mi_attr_noexcept { return mi_heap_realloc_zero_aligned(heap, p, newsize, alignment, true); } mi_decl_nodiscard void* mi_heap_recalloc_aligned_at(mi_heap_t* heap, void* p, size_t newcount, size_t size, size_t alignment, size_t offset) mi_attr_noexcept { size_t total; if (mi_count_size_overflow(newcount, size, &total)) return NULL; return mi_heap_rezalloc_aligned_at(heap, p, total, alignment, offset); } mi_decl_nodiscard void* mi_heap_recalloc_aligned(mi_heap_t* heap, void* p, size_t newcount, size_t size, size_t alignment) mi_attr_noexcept { size_t total; if (mi_count_size_overflow(newcount, size, &total)) return NULL; return mi_heap_rezalloc_aligned(heap, p, total, alignment); } mi_decl_nodiscard void* mi_realloc_aligned_at(void* p, size_t newsize, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_realloc_aligned_at(mi_prim_get_default_heap(), p, newsize, alignment, offset); } mi_decl_nodiscard void* mi_realloc_aligned(void* p, size_t newsize, size_t alignment) mi_attr_noexcept { return mi_heap_realloc_aligned(mi_prim_get_default_heap(), p, newsize, alignment); } mi_decl_nodiscard void* mi_rezalloc_aligned_at(void* p, size_t newsize, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_rezalloc_aligned_at(mi_prim_get_default_heap(), p, newsize, alignment, offset); } mi_decl_nodiscard void* mi_rezalloc_aligned(void* p, size_t newsize, size_t alignment) mi_attr_noexcept { return mi_heap_rezalloc_aligned(mi_prim_get_default_heap(), p, newsize, alignment); } mi_decl_nodiscard void* mi_recalloc_aligned_at(void* p, size_t newcount, size_t size, size_t alignment, size_t offset) mi_attr_noexcept { return mi_heap_recalloc_aligned_at(mi_prim_get_default_heap(), p, newcount, size, alignment, offset); } mi_decl_nodiscard void* mi_recalloc_aligned(void* p, size_t newcount, size_t size, size_t alignment) mi_attr_noexcept { return mi_heap_recalloc_aligned(mi_prim_get_default_heap(), p, newcount, size, alignment); }