--- /dev/null
+++ libmalloc/libmalloc-715.140.5/src/magazine_zone.h
@@ -0,0 +1,903 @@
+/*
+ * Copyright (c) 2015 Apple Inc. All rights reserved.
+ *
+ * @APPLE_LICENSE_HEADER_START@
+ *
+ * This file contains Original Code and/or Modifications of Original Code
+ * as defined in and that are subject to the Apple Public Source License
+ * Version 2.0 (the 'License'). You may not use this file except in
+ * compliance with the License. Please obtain a copy of the License at
+ * http://www.opensource.apple.com/apsl/ and read it before using this
+ * file.
+ *
+ * The Original Code and all software distributed under the License are
+ * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER
+ * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES,
+ * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY,
+ * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT.
+ * Please see the License for the specific language governing rights and
+ * limitations under the License.
+ *
+ * @APPLE_LICENSE_HEADER_END@
+ */
+
+#ifndef __MAGAZINE_ZONE_H
+#define __MAGAZINE_ZONE_H
+
+#include <malloc/_ptrcheck.h>
+__ptrcheck_abi_assume_single()
+
+/*********************	DEFINITIONS	************************/
+
+// Out-of-band free list entry. Out-of-band free list entries are used
+// in specific cases where a free-list entry is the *only* data on a given page,
+// and the presence of that entry causes the page to stay dirty.
+//
+// `ptr` is all 16-bit quantum-sized index and packed, as that references a
+// block address inside the current region. `next` and `prev` have to be pointer
+// sized references, as these values can point to entries outside the current
+// region, so it's not safe to compact them.
+typedef struct {
+	uintptr_t prev;
+	uintptr_t next;
+	uint16_t ptr;
+} MALLOC_PACKED oob_free_entry_s, *oob_free_entry_t;
+
+// In-place free list entry. Unlike the out-of-band entry, the in-place entries
+// are stored at the start of the range that has been freed.
+typedef struct _inplace_free_entry_s * __single inplace_free_entry_t;
+
+typedef struct {
+	void *ptr;
+	uint8_t checksum;
+} inplace_linkage_s;
+
+typedef union {
+	inplace_free_entry_t p;
+	uintptr_t u;
+} inplace_union;
+
+typedef struct _inplace_free_entry_s {
+	inplace_union previous;
+	inplace_union next;
+} inplace_free_entry_s, * __single inplace_free_entry_t;
+
+#ifdef __LP64__
+MALLOC_STATIC_ASSERT(sizeof(inplace_free_entry_s) == 16, "inplace free list must be 16-bytes long");
+#else
+MALLOC_STATIC_ASSERT(sizeof(inplace_free_entry_s) == 8, "inplace free list must be 8-bytes long");
+#endif
+
+typedef struct _small_inplace_free_entry_s {
+	inplace_linkage_s previous;
+	inplace_linkage_s next;
+} small_inplace_free_entry_s, *small_inplace_free_entry_t;
+
+typedef struct _medium_inplace_free_entry_s {
+	inplace_linkage_s previous;
+	inplace_linkage_s next;
+} medium_inplace_free_entry_s, *medium_inplace_free_entry_t;
+
+typedef union {
+	small_inplace_free_entry_t small_inplace;
+	medium_inplace_free_entry_t medium_inplace;
+	inplace_free_entry_t inplace;
+	oob_free_entry_t oob;
+	void *p;
+} free_list_t;
+
+typedef struct {
+	inplace_union previous;
+	inplace_union next;
+} tiny_free_list_t;
+
+typedef unsigned int grain_t; // N.B. wide enough to index all free slots
+
+#define MAX_RECORDER_BUFFER 256
+
+/*********************	DEFINITIONS for tiny	************************/
+
+/*
+ * Memory in the Tiny range is allocated from regions (heaps) pointed to by the
+ * szone's hashed_regions pointer.
+ *
+ * Each region is laid out as a metadata block followed by a heap, all within
+ * a 1MB (2^20) block.  This means there are 64504 16-byte blocks and the metadata
+ * is 16138 bytes, making the total 1048458 bytes, leaving 118 bytes unused.
+ *
+ * The metadata block is arranged as in struct tiny_region defined just below, and
+ * consists of two bitfields (or bit arrays) interleaved 32 bits by 32 bits.
+ *
+ * Each bitfield comprises NUM_TINY_BLOCKS bits, and refers to the corresponding
+ * TINY_QUANTUM block within the heap.
+ *
+ * The bitfields are used to encode the state of memory within the heap.  The header bit indicates
+ * that the corresponding quantum is the first quantum in a block (either in use or free).  The
+ * in-use bit is set for the header if the block has been handed out (allocated).  If the header
+ * bit is not set, the in-use bit is invalid.
+ *
+ * The szone maintains an array of NUM_TINY_SLOTS freelists, each of which is used to hold
+ * free objects of the corresponding quantum size. In the tiny region, the free
+ * objects for each region are arranged so that they are grouped together in their
+ * per-slot freelists and the groups are ordered roughly in the order of regions
+ * as they appear in the magazine's region list. This approach helps to reduce
+ * fragmentation. Not guaranteeing strictly the same ordering as the regions
+ * helps reduce the CPU time required to reduce fragmentation.
+ *
+ * A free block is laid out depending on its size, in order to fit all free
+ * blocks in 16 bytes, on both 32 and 64 bit platforms.  One quantum blocks do
+ * not store their size in the block, instead relying on the header information
+ * to determine their size.  Blocks of two or more quanta have room to store
+ * their size in the block, and store it both after the 'next' pointer, and in
+ * the last 2 bytes of the block.
+ *
+ * With zero-on-free, free blocks of two or more quanta are zeroed out after
+ * their leading inline metadata.  This invariant is maintained when blocks are
+ * split and coalesced, enabling calloc(3) to return free blocks as-is after
+ * clearing the metadata.
+ *
+ * 1-quantum block
+ * Offset (32-bit mode)	(64-bit mode)
+ * 0x0          0x0      : previous
+ * 0x4          0x08     : next
+ * end          end
+ *
+ * >1-quantum block
+ * Offset (32-bit mode)	(64-bit mode)
+ * 0x0          0x0      : previous
+ * 0x4          0x08     : next
+ * 0x8          0x10     : size (in quantum counts)
+ * 0xa          0x12     : start of zeroed body
+ * end - 2      end - 2  : size (in quantum counts)
+ * end          end
+ *
+ * All fields are pointer-sized, except for the size which is an unsigned short.
+ *
+ */
+
+#define FOLLOWING_TINY_PTR(ptr, msize) (((unsigned char *)(ptr)) + ((msize) << SHIFT_TINY_QUANTUM))
+
+#define TINY_BLOCKS_ALIGN (SHIFT_TINY_CEIL_BLOCKS + SHIFT_TINY_QUANTUM) // 20
+
+#define TINY_ENTROPY_BITS 15
+#define TINY_ENTROPY_MASK ((1 << TINY_ENTROPY_BITS) - 1)
+
+/*
+ * Avoid having so much entropy that the end of a valid tiny allocation
+ * might overrun the end of the tiny region.
+ */
+#if TINY_ENTROPY_MASK + NUM_TINY_SLOTS > NUM_TINY_BLOCKS
+#error Too many entropy bits for tiny region requested
+#endif
+
+/*
+ * Enough room for the data, followed by the bit arrays (2-bits per block)
+ * plus rounding to the nearest page.
+ */
+#define CEIL_NUM_TINY_BLOCKS_WORDS (((NUM_TINY_BLOCKS + 31) & ~31) >> 5)
+
+#define TINY_HEAP_SIZE (NUM_TINY_BLOCKS * TINY_QUANTUM)
+#define TINY_METADATA_SIZE (sizeof(region_trailer_t) + sizeof(tiny_header_inuse_pair_t) * CEIL_NUM_TINY_BLOCKS_WORDS + (sizeof(region_free_blocks_t) * NUM_TINY_SLOTS))
+#define TINY_REGION_SIZE ((TINY_HEAP_SIZE + TINY_METADATA_SIZE + PAGE_MAX_SIZE - 1) & ~(PAGE_MAX_SIZE - 1))
+
+/*
+ * Location of the metadata for a given tiny region.
+ */
+#define TINY_REGION_METADATA(region) ((uintptr_t)&((tiny_region_t)region)->trailer)
+
+/*
+ * Beginning and end pointers for a region's heap.
+ */
+#define TINY_REGION_HEAP_BASE(region) ((void *)(((tiny_region_t)region)->blocks))
+#define TINY_REGION_HEAP_END(region) __unsafe_forge_single(void *, ((uintptr_t)TINY_REGION_HEAP_BASE(region)) + TINY_HEAP_SIZE)
+
+/*
+ * Locate the region for a pointer known to be within a tiny region.
+ */
+#define TINY_REGION_FOR_PTR(ptr) __unsafe_forge_single(tiny_region_t, (uintptr_t)(ptr) & ~((1 << TINY_BLOCKS_ALIGN) - 1))
+
+/*
+ * Convert between byte and msize units.
+ */
+#define TINY_BYTES_FOR_MSIZE(_m) ((_m) << SHIFT_TINY_QUANTUM)
+#define TINY_MSIZE_FOR_BYTES(_b) ((_b) >> SHIFT_TINY_QUANTUM)
+
+#if MALLOC_TARGET_64BIT
+#define TINY_FREE_SIZE(ptr) (((msize_t *)(ptr))[8])
+#else // MALLOC_TARGET_64BIT
+#define TINY_FREE_SIZE(ptr) (((msize_t *)(ptr))[4])
+#endif // MALLOC_TARGET_64BIT
+#define TINY_PREVIOUS_MSIZE(ptr) ((msize_t *)(ptr))[-1]
+
+/*
+ * Layout of a tiny region
+ */
+typedef uint32_t tiny_block_t[TINY_QUANTUM / sizeof(uint32_t)];
+MALLOC_STATIC_ASSERT(sizeof(tiny_block_t) == TINY_QUANTUM,
+		"Incorrect size tiny_block_t");
+
+#define TINY_REGION_PAD (TINY_REGION_SIZE - TINY_HEAP_SIZE - TINY_METADATA_SIZE - sizeof(region_cookie_t))
+
+typedef struct tiny_header_inuse_pair {
+	uint32_t header;
+	uint32_t inuse;
+} tiny_header_inuse_pair_t;
+
+typedef struct {
+	// Block indices are +1 so that 0 represents no free block.
+	uint16_t first_block;
+	uint16_t last_block;
+} region_free_blocks_t;
+
+typedef uint32_t region_cookie_t;
+
+OS_ENUM(rack_dispose_flags, uint32_t,
+	RACK_DISPOSE_DELAY = 0x1,
+	RACK_DISPOSE_NEEDED = 0x2,
+);
+
+typedef struct region_trailer {
+	struct region_trailer *prev;
+	struct region_trailer *next;
+	unsigned bytes_used;
+	unsigned objects_in_use;  // Used only by tiny allocator.
+	mag_index_t mag_index;
+	volatile int32_t pinned_to_depot;
+	bool recirc_suitable;
+	// Locking: dispose_flags must be locked under the rack's region lock
+	rack_dispose_flags_t dispose_flags;
+} region_trailer_t;
+
+typedef struct tiny_region {
+	// This must be first (because TINY_REGION_METADATA assumes it).
+	region_trailer_t trailer;
+
+	// The interleaved bit arrays comprising the header and inuse bitfields.
+	// The unused bits of each component in the last pair will be initialized to sentinel values.
+	tiny_header_inuse_pair_t pairs[CEIL_NUM_TINY_BLOCKS_WORDS];
+
+	// Indices of the first and last free block in this region. Value is the
+	// block index + 1 so that 0 indicates no free block in this region for the
+	// corresponding slot.
+	region_free_blocks_t free_blocks_by_slot[NUM_TINY_SLOTS];
+
+	uint8_t pad[TINY_REGION_PAD];
+
+	// Intended to catch backward overspills from the heap into this structure.
+	region_cookie_t region_cookie;
+
+	tiny_block_t blocks[NUM_TINY_BLOCKS];
+} * tiny_region_t;
+
+// The layout described above should result in a tiny_region_t being 1MB.
+MALLOC_STATIC_ASSERT(TINY_REGION_SIZE == (1024 * 1024), "incorrect TINY_REGION_SIZE");
+MALLOC_STATIC_ASSERT(sizeof(struct tiny_region) == TINY_REGION_SIZE, "incorrect tiny_region_size");
+
+/*
+ * Per-region meta data for tiny allocator
+ */
+#define REGION_TRAILER_FOR_TINY_REGION(r) (&(((tiny_region_t)(r))->trailer))
+#define REGION_COOKIE_FOR_TINY_REGION(r) (((tiny_region_t)(r))->region_cookie)
+#define MAGAZINE_INDEX_FOR_TINY_REGION(r) (REGION_TRAILER_FOR_TINY_REGION(r)->mag_index)
+#define BYTES_USED_FOR_TINY_REGION(r) (REGION_TRAILER_FOR_TINY_REGION(r)->bytes_used)
+#define OBJECTS_IN_USE_FOR_TINY_REGION(r) (REGION_TRAILER_FOR_TINY_REGION(r)->objects_in_use)
+
+/*
+ * Locate the block header for a pointer known to be within a tiny region.
+ */
+#define TINY_BLOCK_HEADER_FOR_PTR(ptr) ((void *)&(((tiny_region_t)TINY_REGION_FOR_PTR(ptr))->pairs))
+
+/*
+ * Locate the block header for a tiny region.
+ */
+#define TINY_BLOCK_HEADER_FOR_REGION(region) ((void *)&(((tiny_region_t)region)->pairs))
+
+/*
+ * Locate the inuse map for a given block header pointer.
+ */
+#define TINY_INUSE_FOR_HEADER(_h) ((void *)&(((tiny_header_inuse_pair_t *)(_h))->inuse))
+
+/*
+ * Heap offset for a pointer known to be within a tiny region.
+ */
+#define TINY_HEAP_OFFSET_FOR_PTR(ptr) ((uintptr_t)(ptr) - (uintptr_t)TINY_REGION_HEAP_BASE(TINY_REGION_FOR_PTR(ptr)))
+
+/*
+ * Compute the bitmap index for a pointer known to be within a tiny region.
+ */
+#define TINY_INDEX_FOR_PTR(ptr) ((TINY_HEAP_OFFSET_FOR_PTR(ptr) >> SHIFT_TINY_QUANTUM) & (NUM_TINY_CEIL_BLOCKS - 1))
+
+/*
+ * Get the pointer for a given index in a region.
+ */
+#define TINY_PTR_FOR_INDEX(index, region) (void *)((uintptr_t)TINY_REGION_HEAP_BASE(region) + ((index) << SHIFT_TINY_QUANTUM))
+
+/*
+ * Offset back to an szone_t given prior knowledge that this rack_t
+ * is contained within an szone_t.
+ *
+ * Note: the only place this is used, the dtrace probes, only occurs
+ *       when the rack has been set up inside a scalable zone. Should
+ *       this ever be used somewhere that this does not hold true
+ *       (say, the test cases) then the pointer returned will be junk.
+ */
+#define TINY_SZONE_FROM_RACK(_r) \
+		(szone_t *)((uintptr_t)(_r) - offsetof(struct szone_s, tiny_rack))
+
+
+#if !CONFIG_TINY_CACHE
+#warning CONFIG_TINY_CACHE turned off
+#endif
+
+
+/*********************	DEFINITIONS for small	************************/
+
+/*
+ * Memory in the small range is allocated from regions (heaps) pointed to by the szone's hashed_regions
+ * pointer.
+ *
+ * Each region is laid out as metadata followed by the heap, all within an 8MB (2^23) block.
+ * The metadata block is arranged as in struct small_region defined just below.
+ * The array is arranged as an array of shorts, one for each SMALL_QUANTUM in the heap. There are
+ * 16319 512-byte blocks and the array is 16319*2 bytes, which totals 8387966, leaving 642 bytes unused.
+ * Once the region trailer is accounted for, there is room for 61 out-of-band free list entries in
+ * the remaining padding (or 6, if the region was split into 16320 blocks, not 16319).
+ *
+ * The 16-bit shorts in the region are used for allocation metadata. The MSB bit marks a block as
+ * either free, or not. The remaining 15-bits give the size of the allocation, defined in "msize", the
+ * quantum-shifted size of the allocation.
+ *
+ * The metadata table either:
+ *
+ *    1. Stores the allocation size in the first short for the block, with the MSB cleared to indicate
+ *       that the block is allocated and in-use, or,
+ *
+ *    2. Stores the free-allocation size in the first and last shorts for the block, with the MSB set
+ *       in both places to indicate that the block is freed. (Storing the range in last block allows
+ *       for coalescing of adjacent free entries).
+ *
+ *    3. Zero, or "middle", meaning that this block in the region is not the start or end of an
+ *       allocated block.
+ *
+ * The small zone represents the free list in one of two ways:
+ *
+ *    1. In-line free list entries. These are stored at the starting address of the just-freed memory
+ *       and both the previous and next pointer are checksummed to attempt to detect use-after-free
+ *       writes.
+ *
+ *       An in-line free list entry is laid out as:
+ *           |prev (uintptr_t)|checksum (uint8_t)|next (uintptr_t)|checksum (uint8_t)
+ *
+ *    2. Out-of-band free list entries. These utilitise the remaining padding in the 8mb region that
+ *       follows the blocks, metadata and region trailer. Out-of-band entries are used *iff* the
+ *       freed address lies on a page boundary and the freed region spans more than a page. If we were
+ *       to store the free list entry in-line in that memory, it would keep the entire page dirty,
+ *       so an out-of-band entry is used.
+ *
+ *       An out-of-band free list entry is laid out as:
+ *           |prev (uintptr_t)|next (uintptr_t)|ptr (uint16_t)|
+ *
+ * The szone maintains an array of 32 freelists, each of which is used to hold free objects
+ * of the corresponding quantum size.
+ */
+
+#define SMALL_IS_FREE (1 << 15)
+#define FOLLOWING_SMALL_PTR(ptr, msize) (((unsigned char *)(ptr)) + ((msize) << SHIFT_SMALL_QUANTUM))
+
+/*
+ * SMALL_IS_OOB is used to mark the MSB of OOB free list entries to show that they are in use, and
+ * distinguish them from their initial, empty, state.
+ */
+#define SMALL_IS_OOB (1 << 15)
+
+#define SMALL_ENTROPY_BITS 13
+#define SMALL_ENTROPY_MASK ((1 << SMALL_ENTROPY_BITS) - 1)
+
+/*
+ * Avoid having so much entropy that the end of a valid small allocation
+ * might overrun the end of the small region.
+ */
+#if SMALL_ENTROPY_MASK + NUM_SMALL_SLOTS > NUM_SMALL_BLOCKS
+#error Too many entropy bits for small region requested
+#endif
+
+#define SMALL_HEAP_SIZE (NUM_SMALL_BLOCKS * SMALL_QUANTUM)
+#define SMALL_METADATA_SIZE (sizeof(region_trailer_t) + NUM_SMALL_BLOCKS * sizeof(msize_t))
+#define SMALL_REGION_SIZE ((SMALL_HEAP_SIZE + SMALL_METADATA_SIZE + PAGE_MAX_SIZE - 1) & ~(PAGE_MAX_SIZE - 1))
+
+/*
+ * Location of the metadata for a given small region.
+ */
+#define SMALL_REGION_METADATA(region) ((uintptr_t)&((small_region_t)region)->trailer)
+
+/*
+ * Beginning and end pointers for a region's heap.
+ */
+#define SMALL_REGION_HEAP_BASE(region) ((void *)((small_region_t)region)->blocks)
+#define SMALL_REGION_HEAP_END(region) (SMALL_REGION_HEAP_BASE(region) + SMALL_HEAP_SIZE)
+
+/*
+ * Locate the heap base for a pointer known to be within a small region.
+ */
+#define SMALL_REGION_FOR_PTR(ptr) __unsafe_forge_single(small_region_t, (uintptr_t)(ptr) & ~((1 << SMALL_BLOCKS_ALIGN) - 1))
+#define SMALL_REGION_OFFSET_FOR_PTR(ptr) ((uintptr_t)(ptr) & ((1 << SMALL_BLOCKS_ALIGN) - 1))
+
+/*
+ * Convert between byte and msize units.
+ */
+#define SMALL_BYTES_FOR_MSIZE(_m) ((uint32_t)(_m) << SHIFT_SMALL_QUANTUM)
+#define SMALL_MSIZE_FOR_BYTES(_b) ((_b) >> SHIFT_SMALL_QUANTUM)
+
+#define SMALL_PREVIOUS_MSIZE(ptr) (*SMALL_METADATA_FOR_PTR(ptr - 1) & ~SMALL_IS_FREE)
+
+/*
+ * Convert from msize unit to free list slot.
+ */
+#define SMALL_FREE_SLOT_COUNT(_r) \
+		(NUM_SMALL_SLOTS + 1)
+#define SMALL_FREE_SLOT_FOR_MSIZE(_r, _m) \
+		(((_m) <= SMALL_FREE_SLOT_COUNT(_r)) ? ((_m) - 1) : (SMALL_FREE_SLOT_COUNT(_r) - 1))
+/* compare with MAGAZINE_FREELIST_BITMAP_WORDS */
+#define SMALL_FREELIST_BITMAP_WORDS(_r) ((SMALL_FREE_SLOT_COUNT(_r) + 31) >> 5)
+
+/*
+ * Offset back to an szone_t given prior knowledge that this rack_t
+ * is contained within an szone_t.
+ *
+ * Note: the only place this is used, the dtrace probes, only occurs
+ *       when the rack has been set up inside a scalable zone. Should
+ *       this ever be used somewhere that this does not hold true
+ *       (say, the test cases) then the pointer returned will be junk.
+ */
+#define SMALL_SZONE_FROM_RACK(_r) \
+		(szone_t *)((uintptr_t)(_r) - offsetof(struct szone_s, small_rack))
+
+/*
+ * Layout of a small region
+ */
+typedef uint32_t small_block_t[SMALL_QUANTUM / sizeof(uint32_t)];
+MALLOC_STATIC_ASSERT(sizeof(small_block_t) == SMALL_QUANTUM, "Incorrect size for small_block_t");
+#define SMALL_OOB_COUNT ((SMALL_REGION_SIZE - SMALL_HEAP_SIZE - SMALL_METADATA_SIZE - sizeof(region_cookie_t)) / sizeof(oob_free_entry_s))
+#define SMALL_OOB_SIZE (SMALL_OOB_COUNT * sizeof(oob_free_entry_s))
+#define SMALL_REGION_PAD (SMALL_REGION_SIZE - SMALL_HEAP_SIZE - SMALL_METADATA_SIZE - SMALL_OOB_SIZE - sizeof(region_cookie_t))
+
+typedef struct small_region {
+	// This must be first (because SMALL_REGION_METADATA assumes it).
+	region_trailer_t trailer;
+	msize_t small_meta_words[NUM_SMALL_BLOCKS];
+	oob_free_entry_s small_oob_free_entries[SMALL_OOB_COUNT];
+	uint8_t pad[SMALL_REGION_PAD];
+	region_cookie_t region_cookie;
+	small_block_t blocks[NUM_SMALL_BLOCKS];
+} * small_region_t;
+
+// The layout described above should result in a small_region_t being 8MB.
+MALLOC_STATIC_ASSERT(SMALL_REGION_SIZE == (8 * 1024 * 1024), "incorrect SMALL_REGION_SIZE");
+MALLOC_STATIC_ASSERT(sizeof(struct small_region) == SMALL_REGION_SIZE, "incorrect small_region_size");
+
+/*
+ * Per-region meta data for small allocator
+ */
+#define REGION_TRAILER_FOR_SMALL_REGION(r) (&(((small_region_t)(r))->trailer))
+#define REGION_COOKIE_FOR_SMALL_REGION(r) (((small_region_t)(r))->region_cookie)
+#define MAGAZINE_INDEX_FOR_SMALL_REGION(r) (REGION_TRAILER_FOR_SMALL_REGION(r)->mag_index)
+#define BYTES_USED_FOR_SMALL_REGION(r) (REGION_TRAILER_FOR_SMALL_REGION(r)->bytes_used)
+
+/*
+ * Locate the metadata base for a small region.
+ */
+#define SMALL_META_HEADER_FOR_REGION(region) (((small_region_t)region)->small_meta_words)
+
+/*
+ * Locate the metadata base for a pointer known to be within a small region.
+ */
+#define SMALL_META_HEADER_FOR_PTR(ptr) (((small_region_t)SMALL_REGION_FOR_PTR(ptr))->small_meta_words)
+
+/*
+ * Heap offset for a pointer known to be within a small region.
+ */
+#define SMALL_HEAP_OFFSET_FOR_PTR(ptr) ((uintptr_t)(ptr) - (uintptr_t)SMALL_REGION_HEAP_BASE(SMALL_REGION_FOR_PTR(ptr)))
+
+/*
+ * Compute the metadata index for a pointer known to be within a small region.
+ */
+#define SMALL_META_INDEX_FOR_PTR(ptr) ((SMALL_HEAP_OFFSET_FOR_PTR(ptr) >> SHIFT_SMALL_QUANTUM) & (NUM_SMALL_CEIL_BLOCKS - 1))
+
+/*
+ * Find the metadata word for a pointer known to be within a small region.
+ */
+#define SMALL_METADATA_FOR_PTR(ptr) (SMALL_META_HEADER_FOR_PTR(ptr) + SMALL_META_INDEX_FOR_PTR(ptr))
+
+/*
+ * Determine whether a pointer known to be within a small region points to memory which is free.
+ */
+#define SMALL_PTR_IS_FREE(ptr) (*SMALL_METADATA_FOR_PTR(ptr) & SMALL_IS_FREE)
+
+/*
+ * Extract the msize value for a pointer known to be within a small region.
+ */
+#define SMALL_PTR_SIZE(ptr) (*SMALL_METADATA_FOR_PTR(ptr) & ~SMALL_IS_FREE)
+
+#if !CONFIG_SMALL_CACHE
+#warning CONFIG_SMALL_CACHE turned off
+#endif
+
+
+/*********************	DEFINITIONS for medium	************************/
+
+/*
+ * Memory in the medium range is allocated from regions (heaps) pointed to by the szone's hashed_regions
+ * pointer.
+ *
+ * Each region is laid out as a metadata array, followed by the heap, all within an 512MB block.
+ * The array is arranged as an array of shorts, one for each MEDIUM_QUANTUM in the heap. There are
+ * 16382 32k-blocks and the array is 16382*2 bytes, which totals 8387966, leaving 32,772b unused.
+ *
+ * The 16-bit shorts in the region are used for allocation metadata. The MSB bit marks a block as
+ * either free, or not. The remaining 15-bits give the size of the allocation, defined in "msize", the
+ * quantum-shifted size of the allocation.
+ *
+ * The metadata table either:
+ *
+ *    1. Stores the allocation size in the first short for the block, with the MSB cleared to indicate
+ *       that the block is allocated and in-use, or,
+ *
+ *    2. Stores the free-allocation size in the first and last shorts for the block, with the MSB set
+ *       in both places to indicate that the block is freed. (Storing the range in last block allows
+ *       for coalescing of adjacent free entries).
+ *
+ *    3. Zero, or "middle", meaning that this block in the region is not the start or end of an
+ *       allocated block.
+ *
+ * The medium zone represents the free list in one of two ways:
+ *
+ *    1. In-line free list entries. These are stored at the starting address of the just-freed memory
+ *       and both the previous and next pointer are checksummed to attempt to detect use-after-free
+ *       writes.
+ *
+ *       An in-line free list entry is laid out as:
+ *           |prev (uintptr_t)|checksum (uint8_t)|next (uintptr_t)|checksum (uint8_t)
+ *
+ *    2. Out-of-band free list entries. These utilitise the remaining padding in the 8mb region that
+ *       follows the blocks, metadata and region trailer. Out-of-band entries are used *iff* the
+ *       freed address lies on a page boundary and the freed region spans more than a page. If we were
+ *       to store the free list entry in-line in that memory, it would keep the entire page dirty,
+ *       so an out-of-band entry is used.
+ *
+ *       An out-of-band free list entry is laid out as:
+ *           |prev (uintptr_t)|next (uintptr_t)|ptr (uint16_t)|
+ *
+ * The szone maintains an array of 256 freelists, each of which is used to hold free objects
+ * of the corresponding quantum size.
+ */
+
+#define MEDIUM_IS_FREE (1 << 15)
+#define MEDIUM_IS_ADVISED (1 << 15)
+#define FOLLOWING_MEDIUM_PTR(ptr, msize) (((unsigned char *)(ptr)) + ((msize) << SHIFT_MEDIUM_QUANTUM))
+#define MEDIUM_MAX_MSIZE ((uint16_t)(NUM_MEDIUM_BLOCKS >> SHIFT_MEDIUM_QUANTUM) \
+		& ~(uint16_t)MEDIUM_IS_FREE)
+
+// Ensure that the we don't overflow the number of blocks that msize can
+// represent (without running into the free bit).
+MALLOC_STATIC_ASSERT(NUM_MEDIUM_BLOCKS <= (uint16_t)(~MEDIUM_IS_FREE),
+		"NUM_MEDIUM_BLOCKS should fit into a msize_t");
+
+/*
+ * MEDIUM_IS_OOB is used mark to the MSB of OOB free list entries to show that they are in use, and
+ * distinguish them from their initial, empty, state.
+ */
+#define MEDIUM_IS_OOB (1 << 15)
+
+#define MEDIUM_ENTROPY_BITS 11
+#define MEDIUM_ENTROPY_MASK ((1 << MEDIUM_ENTROPY_BITS) - 1)
+
+/*
+ * Avoid having so much entropy that the end of a valid medium allocation
+ * might overrun the end of the medium region.
+ */
+#if MEDIUM_ENTROPY_MASK + NUM_MEDIUM_SLOTS > NUM_MEDIUM_BLOCKS
+#error Too many entropy bits for medium region requested
+#endif
+
+#define MEDIUM_HEAP_SIZE (NUM_MEDIUM_BLOCKS * MEDIUM_QUANTUM)
+#define MEDIUM_METADATA_SIZE (sizeof(region_trailer_t) + \
+		(NUM_MEDIUM_BLOCKS * sizeof(msize_t)) + \
+		(NUM_MEDIUM_BLOCKS * sizeof(msize_t)))
+// Note: The other instances of x_REGION_SIZE use PAGE_MAX_SIZE as the rounding
+// and truncating constant but because medium's quanta size is larger than a
+// page, it's used instead.
+#define MEDIUM_REGION_SIZE ((MEDIUM_HEAP_SIZE + \
+		MEDIUM_METADATA_SIZE + MEDIUM_QUANTUM - 1) & ~(MEDIUM_QUANTUM - 1))
+
+/*
+ * Location of the metadata for a given medium region.
+ */
+#define MEDIUM_REGION_METADATA(region) ((uintptr_t)&((medium_region_t)region)->trailer)
+
+/*
+ * Beginning and end pointers for a region's heap.
+ */
+#define MEDIUM_REGION_HEAP_BASE(region) ((void *)((medium_region_t)region)->blocks)
+#define MEDIUM_REGION_HEAP_END(region) (MEDIUM_REGION_HEAP_BASE(region) + MEDIUM_HEAP_SIZE)
+
+/*
+ * Locate the heap base for a pointer known to be within a medium region.
+ */
+#define MEDIUM_REGION_FOR_PTR(ptr) __unsafe_forge_single(void *, (uintptr_t)(ptr) & ~((1ull << MEDIUM_BLOCKS_ALIGN) - 1))
+#define MEDIUM_REGION_OFFSET_FOR_PTR(ptr) ((uintptr_t)(ptr) & ((1ull << MEDIUM_BLOCKS_ALIGN) - 1))
+
+/*
+ * Convert between byte and msize units.
+ */
+#define MEDIUM_BYTES_FOR_MSIZE(_m) ((uint32_t)(_m) << SHIFT_MEDIUM_QUANTUM)
+#define MEDIUM_MSIZE_FOR_BYTES(_b) ((_b) >> SHIFT_MEDIUM_QUANTUM)
+
+#define MEDIUM_PREVIOUS_MSIZE(ptr) (*MEDIUM_METADATA_FOR_PTR(ptr - 1) & ~MEDIUM_IS_FREE)
+
+/*
+ * Convert from msize unit to free list slot.
+ */
+#define MEDIUM_FREE_SLOT_COUNT(_r) (NUM_MEDIUM_SLOTS + 1)
+#define MEDIUM_FREE_SLOT_FOR_MSIZE(_r, _m) \
+		(((_m) <= MEDIUM_FREE_SLOT_COUNT(_r)) ? ((_m) - 1) : (MEDIUM_FREE_SLOT_COUNT(_r) - 1))
+/* compare with MAGAZINE_FREELIST_BITMAP_WORDS */
+#define MEDIUM_FREELIST_BITMAP_WORDS(_r) ((MEDIUM_FREE_SLOT_COUNT(_r) + 31) >> 5)
+
+/*
+ * Offset back to an szone_t given prior knowledge that this rack_t
+ * is contained within an szone_t.
+ *
+ * Note: the only place this is used, the dtrace probes, only occurs
+ *       when the rack has been set up inside a scalable zone. Should
+ *       this ever be used somewhere that this does not hold true
+ *       (say, the test cases) then the pointer returned will be junk.
+ */
+#define MEDIUM_SZONE_FROM_RACK(_r) \
+		(szone_t *)((uintptr_t)(_r) - offsetof(struct szone_s, medium_rack))
+
+/*
+ * Layout of a medium region
+ */
+typedef uint32_t medium_block_t[MEDIUM_QUANTUM / sizeof(uint32_t)];
+MALLOC_STATIC_ASSERT(sizeof(medium_block_t) == MEDIUM_QUANTUM,
+		"Incorrect size medium_block_t");
+#define MEDIUM_OOB_COUNT ((MEDIUM_REGION_SIZE - MEDIUM_HEAP_SIZE - \
+		MEDIUM_METADATA_SIZE - sizeof(region_cookie_t)) / sizeof(oob_free_entry_s))
+#define MEDIUM_OOB_SIZE (MEDIUM_OOB_COUNT * sizeof(oob_free_entry_s))
+#define MEDIUM_REGION_PAD (MEDIUM_REGION_SIZE - MEDIUM_HEAP_SIZE - \
+		MEDIUM_METADATA_SIZE - MEDIUM_OOB_SIZE - sizeof(region_cookie_t))
+
+typedef struct medium_region {
+	// This must be first (because MEDIUM_REGION_METADATA assumes it).
+	region_trailer_t trailer;
+	msize_t medium_meta_words[NUM_MEDIUM_BLOCKS];
+	msize_t medium_madvise_words[NUM_MEDIUM_BLOCKS];
+	oob_free_entry_s medium_oob_free_entries[MEDIUM_OOB_COUNT];
+	uint8_t pad[MEDIUM_REGION_PAD];
+	region_cookie_t region_cookie;
+	medium_block_t blocks[NUM_MEDIUM_BLOCKS];
+} * medium_region_t;
+
+// The layout described above should result in a medium_region_t being 512MB.
+MALLOC_STATIC_ASSERT(sizeof(struct medium_region) == 128 * 1024 * 1024,
+		"incorrect medium_region_size");
+
+/*
+ * Per-region meta data for medium allocator
+ */
+#define REGION_TRAILER_FOR_MEDIUM_REGION(r) (&(((medium_region_t)(r))->trailer))
+#define REGION_COOKIE_FOR_MEDIUM_REGION(r) (((medium_region_t)(r))->region_cookie)
+#define MAGAZINE_INDEX_FOR_MEDIUM_REGION(r) (REGION_TRAILER_FOR_MEDIUM_REGION(r)->mag_index)
+#define BYTES_USED_FOR_MEDIUM_REGION(r) (REGION_TRAILER_FOR_MEDIUM_REGION(r)->bytes_used)
+
+/*
+ * Locate the metadata base for a pointer known to be within a medium region.
+ */
+#define MEDIUM_META_HEADER_FOR_PTR(ptr) (((medium_region_t)MEDIUM_REGION_FOR_PTR(ptr))->medium_meta_words)
+#define MEDIUM_MADVISE_HEADER_FOR_PTR(ptr) (((medium_region_t)MEDIUM_REGION_FOR_PTR(ptr))->medium_madvise_words)
+#define MEDIUM_META_HEADER_FOR_REGION(region) (((medium_region_t)region)->medium_meta_words)
+
+/*
+ * Heap offset for a pointer known to be within a medium region.
+ */
+#define MEDIUM_HEAP_OFFSET_FOR_PTR(ptr) ((uintptr_t)(ptr) - (uintptr_t)MEDIUM_REGION_HEAP_BASE(MEDIUM_REGION_FOR_PTR(ptr)))
+
+/*
+ * Compute the metadata index for a pointer known to be within a medium region.
+ */
+#define MEDIUM_META_INDEX_FOR_PTR(ptr) ((MEDIUM_HEAP_OFFSET_FOR_PTR(ptr) >> SHIFT_MEDIUM_QUANTUM) & (NUM_MEDIUM_CEIL_BLOCKS - 1))
+#define MEDIUM_PTR_FOR_META_INDEX(region, i) (MEDIUM_REGION_HEAP_BASE(region) + MEDIUM_BYTES_FOR_MSIZE(i))
+
+/*
+ * Find the metadata word for a pointer known to be within a medium region.
+ */
+#define MEDIUM_METADATA_FOR_PTR(ptr) (MEDIUM_META_HEADER_FOR_PTR(ptr) + MEDIUM_META_INDEX_FOR_PTR(ptr))
+
+/*
+ * Determine whether a pointer known to be within a medium region points to memory which is free.
+ */
+#define MEDIUM_PTR_IS_FREE(ptr) (*MEDIUM_METADATA_FOR_PTR(ptr) & MEDIUM_IS_FREE)
+
+/*
+ * Extract the msize value for a pointer known to be within a medium region.
+ */
+#define MEDIUM_PTR_SIZE(ptr) (*MEDIUM_METADATA_FOR_PTR(ptr) & ~MEDIUM_IS_FREE)
+
+#if !CONFIG_MEDIUM_CACHE
+#warning CONFIG_MEDIUM_CACHE turned off
+#endif
+
+#define MEDIUM_REGION_PAYLOAD_BYTES (NUM_MEDIUM_BLOCKS * MEDIUM_QUANTUM)
+
+/*************************  DEFINITIONS for large  ****************************/
+
+
+typedef struct large_entry_s {
+	vm_address_t address;
+	vm_size_t size;
+#if CONFIG_MAGAZINE_DEFERRED_RECLAIM
+	mach_vm_reclaim_id_t reclaim_index;
+#else
+	boolean_t did_madvise_reusable;
+#endif /* CONFIG_MAGAZINE_DEFERRED_RECLAIM */
+} large_entry_t;
+
+#if !CONFIG_LARGE_CACHE && DEBUG_MALLOC
+#warning CONFIG_LARGE_CACHE turned off
+#endif
+
+#if CONFIG_MEDIUM_ALLOCATOR
+#define LARGE_THRESHOLD(szone) ((szone)->is_medium_engaged ? \
+		(MEDIUM_LIMIT_THRESHOLD) : (SMALL_LIMIT_THRESHOLD))
+#else // CONFIG_MEDIUM_ALLOCATOR
+#define LARGE_THRESHOLD(szone) (SMALL_LIMIT_THRESHOLD)
+#endif // CONFIG_MEDIUM_ALLOCATOR
+
+// Gets the correct guard page flags for tiny/small/medium allocators.
+// The rules are:
+// 1. If MallocGuardEdges == "all" (which is indicated by MALLOC_GUARD_ALL being
+// set), we need to allocate just a postlude guard page in tiny/small/medium.
+// 2. If MallocGuardEdges is defined and has any value other than "all"
+// (indicated by MALLOC_GUARD_ALL being unset), we don't add any guard pages for
+// these allocators.
+//
+// This macro returns a copy of "flags" in which either the prelude guard page
+// bit or both guard page bits are turned off, depending on the value of the
+// MALLOC_GUARD_ALL bit. We can't simply keep the correct set of flags in the
+// zone or rack debug_flags field because the large allocator has different
+// rules (it allocates both guard pages when MallocGuardEdges is defined, and no
+// guard pages if it is not.)
+#define MALLOC_FIX_GUARD_PAGE_FLAGS(flags) 					\
+		((flags) & MALLOC_GUARD_ALL) ?						\
+				((flags) & ~MALLOC_ADD_PRELUDE_GUARD_PAGE)	\
+				: (((flags) & ~MALLOC_ADD_GUARD_PAGE_FLAGS))
+
+// rdar://50715272 - allow us to have an escape hatch to disable ASLR sliding
+// on large allocatins for bincompat
+#define MALLOC_APPLY_LARGE_ASLR(flags) 						\
+		(((flags) & DISABLE_LARGE_ASLR) ? ((flags) | DISABLE_ASLR) : (flags))
+
+/*******************************************************************************
+ * Per-processor magazine for tiny and small allocators
+ ******************************************************************************/
+
+typedef struct magazine_s { // vm_allocate()'d, so the array of magazines is page-aligned to begin with.
+	// Take magazine_lock first,  Depot lock when needed for recirc, then szone->{tiny,small}_regions_lock when needed for alloc
+	_malloc_lock_s magazine_lock MALLOC_CACHE_ALIGN;
+	// Protection for the crtical section that does allocate_pages outside the magazine_lock
+	_malloc_lock_s magazine_alloc_lock;
+
+	// One element deep "death row", optimizes malloc/free/malloc for identical size.
+	void *mag_last_free;
+	msize_t mag_last_free_msize;	// msize for mag_last_free
+#if MALLOC_TARGET_64BIT
+	uint32_t _pad;
+#endif
+	region_t mag_last_free_rgn; // holds the region for mag_last_free
+
+	free_list_t mag_free_list[MAGAZINE_FREELIST_SLOTS];
+	uint32_t mag_bitmap[MAGAZINE_FREELIST_BITMAP_WORDS];
+
+	// the first and last free region in the last block are treated as big blocks in use that are not accounted for
+	size_t mag_bytes_free_at_end;
+	size_t mag_bytes_free_at_start;
+	region_t mag_last_region; // Valid iff mag_bytes_free_at_end || mag_bytes_free_at_start > 0
+
+	// bean counting ...
+	size_t mag_num_bytes_in_objects;
+	size_t num_bytes_in_magazine;
+	unsigned mag_num_objects;
+
+	// recirculation list -- invariant: all regions owned by this magazine that meet the emptiness criteria
+	// are located nearer to the head of the list than any region that doesn't satisfy that criteria.
+	// Doubly linked list for efficient extraction.
+	unsigned recirculation_entries;
+	region_trailer_t *firstNode;
+	region_trailer_t *lastNode;
+
+#if MALLOC_TARGET_64BIT
+	uintptr_t pad[320 - 14 - MAGAZINE_FREELIST_SLOTS -
+			(MAGAZINE_FREELIST_BITMAP_WORDS + 1) / 2];
+#else
+	uintptr_t pad[320 - 16 - MAGAZINE_FREELIST_SLOTS -
+			MAGAZINE_FREELIST_BITMAP_WORDS];
+#endif
+
+} magazine_t;
+
+#if MALLOC_TARGET_64BIT
+MALLOC_STATIC_ASSERT(sizeof(magazine_t) == 2560, "Incorrect padding in magazine_t");
+#else
+MALLOC_STATIC_ASSERT(sizeof(magazine_t) == 1280, "Incorrect padding in magazine_t");
+#endif
+
+#define TINY_MAX_MAGAZINES 64 /* MUST BE A POWER OF 2! */
+#define TINY_MAGAZINE_PAGED_SIZE                                                   \
+	(((sizeof(magazine_t) * (TINY_MAX_MAGAZINES + 1)) + vm_page_quanta_size - 1) & \
+	~(vm_page_quanta_size - 1)) /* + 1 for the Depot */
+
+#define SMALL_MAX_MAGAZINES 64 /* MUST BE A POWER OF 2! */
+#define SMALL_MAGAZINE_PAGED_SIZE                                                   \
+	(((sizeof(magazine_t) * (SMALL_MAX_MAGAZINES + 1)) + vm_page_quanta_size - 1) & \
+	~(vm_page_quanta_size - 1)) /* + 1 for the Depot */
+
+#define DEPOT_MAGAZINE_INDEX -1
+
+/****************************** zone itself ***********************************/
+
+/*
+ * Note that objects whose adddress are held in pointers here must be pursued
+ * individually in the {tiny,small}_in_use_enumeration() routines. See for
+ * example the treatment of region_hash_generation and tiny_magazines below.
+ */
+
+typedef struct szone_s {	  // vm_allocate()'d, so page-aligned to begin with.
+	malloc_zone_t basic_zone; // first page will be given read-only protection
+	uint8_t pad[PAGE_MAX_SIZE - sizeof(malloc_zone_t)];
+
+	unsigned long cpu_id_key; // unused
+	// remainder of structure is R/W (contains no function pointers)
+	unsigned debug_flags;
+	void *log_address;
+
+	/* Allocation racks per allocator type. */
+	struct rack_s tiny_rack;
+	struct rack_s small_rack;
+	struct rack_s medium_rack;
+
+	/* large objects: all the rest */
+	_malloc_lock_s large_szone_lock MALLOC_CACHE_ALIGN; // One customer at a time for large
+	unsigned num_large_objects_in_use;
+	unsigned num_large_entries;
+	large_entry_t *large_entries; // hashed by location; null entries don't count
+	size_t num_bytes_in_large_objects;
+
+#if CONFIG_LARGE_CACHE
+	int large_entry_cache_oldest;
+	int large_entry_cache_newest;
+	large_entry_t large_entry_cache[LARGE_ENTRY_CACHE_SIZE_HIGH]; // "death row" for large malloc/free
+	int large_cache_depth;
+	size_t large_cache_entry_limit;
+	boolean_t large_legacy_reset_mprotect;
+	size_t large_entry_cache_reserve_bytes;
+	size_t large_entry_cache_reserve_limit;
+	size_t large_entry_cache_bytes; // total size of death row, bytes
+#endif
+
+	/* flag and limits pertaining to altered malloc behavior for systems with
+	 * large amounts of physical memory */
+	bool is_medium_engaged;
+
+	/* security cookie */
+	uintptr_t cookie;
+
+	/* The purgeable zone constructed by create_purgeable_zone() would like to hand off tiny and small
+	 * allocations to the default scalable zone. Record the latter as the "helper" zone here. */
+	struct szone_s *helper_zone;
+
+	boolean_t flotsam_enabled;
+} szone_t;
+
+#define SZONE_PAGED_SIZE round_page_quanta((sizeof(szone_t)))
+
+#endif // __MAGAZINE_ZONE_H