--- /dev/null
+++ libmalloc/libmalloc-374.40.6/tests/nano_tests.c
@@ -0,0 +1,404 @@
+//
+//  nano_tests.c
+//  libmalloc
+//
+//  Tests that are specific to the implementation details of Nanov2.
+//
+#include <TargetConditionals.h>
+#include <darwintest.h>
+#include <darwintest_utils.h>
+#include <spawn.h>
+#include <stdlib.h>
+#include <string.h>
+#include <sys/wait.h>
+#include <malloc/malloc.h>
+#include <../private/malloc_private.h>
+#include <../src/internal.h>
+
+#if CONFIG_NANOZONE
+
+#pragma mark -
+#pragma mark Enumerator access
+
+static int range_count;					// Total number of allocated ranges
+static int ptr_count;					// Total number of allocated pointers
+static size_t total_ranges_size;		// Size of all allocated ranges
+static size_t total_in_use_ptr_size;	// Size of all allocated pointers
+
+static void
+range_recorder(task_t task, void *context, unsigned type, vm_range_t *ranges,
+			   unsigned count)
+{
+	for (int i = 0; i < count; i++) {
+		total_ranges_size += ranges[i].size;
+	}
+	range_count += count;
+}
+
+static void
+pointer_recorder(task_t task, void *context, unsigned type, vm_range_t *ranges,
+			 unsigned count)
+{
+	for (int i = 0; i < count; i++) {
+		total_in_use_ptr_size += ranges[i].size;
+	}
+	ptr_count += count;
+}
+
+static kern_return_t
+memory_reader(task_t remote_task, vm_address_t remote_address, vm_size_t size,
+			  void **local_memory)
+{
+	if (local_memory) {
+		*local_memory = (void*)remote_address;
+		return KERN_SUCCESS;
+	}
+	return KERN_FAILURE;
+}
+
+static void
+run_enumerator()
+{
+	total_ranges_size = 0;
+	total_in_use_ptr_size = 0;
+	range_count = 0;
+	ptr_count = 0;
+	malloc_zone_t *zone = malloc_default_zone();
+	zone->introspect->enumerator(mach_task_self(), NULL,
+			MALLOC_PTR_REGION_RANGE_TYPE, (vm_address_t)zone, memory_reader,
+			range_recorder);
+	zone->introspect->enumerator(mach_task_self(), NULL,
+			MALLOC_PTR_IN_USE_RANGE_TYPE, (vm_address_t)zone, memory_reader,
+			pointer_recorder);
+}
+
+#endif // CONFIG_NANOZONE
+
+#pragma mark -
+#pragma mark Enumerator tests
+
+#if TARGET_OS_WATCH
+#define ALLOCATION_COUNT 10000
+#else // TARGET_OS_WATCH
+#define ALLOCATION_COUNT 100000
+#endif // TARGET_OS_WATCH
+
+static void *allocations[ALLOCATION_COUNT];
+
+T_GLOBAL_META(T_META_RUN_CONCURRENTLY(true));
+
+T_DECL(nano_active_test, "Test that Nano is activated",
+	   T_META_ENVVAR("MallocNanoZone=1"))
+{
+#if CONFIG_NANOZONE
+	void *ptr = malloc(16);
+	T_LOG("Nano ptr is %p\n", ptr);
+	T_ASSERT_EQ(NANOZONE_SIGNATURE, (uint64_t)((uintptr_t)ptr) >> SHIFT_NANO_SIGNATURE,
+			"Nanozone is active");
+	T_ASSERT_NE(malloc_engaged_nano(), 0, "Nanozone engaged");
+	free(ptr);
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+
+T_DECL(nano_enumerator_test, "Test the Nanov2 enumerator",
+	   T_META_ENVVAR("MallocNanoZone=V2"))
+{
+#if CONFIG_NANOZONE
+	T_ASSERT_EQ(malloc_engaged_nano(), 2, "Nanozone V2 engaged");
+
+	// This test is problematic because the allocator is used before the test
+	// starts, so we can't start everything from zero.
+	// Grab a baseline
+	malloc_statistics_t stats;
+	malloc_zone_statistics(malloc_default_zone(), &stats);
+	const unsigned int initial_blocks_in_use = stats.blocks_in_use;
+	const size_t initial_size_in_use = stats.size_in_use;
+	const size_t initial_size_allocated = stats.size_allocated;
+
+	run_enumerator();
+	const int initial_ptrs = ptr_count;
+	const size_t initial_ranges_size = total_ranges_size;
+	const size_t initial_in_use_ptr_size = total_in_use_ptr_size;
+
+	// Allocate memory of random sizes, all less than the max Nano size.
+	size_t total_requested_size = 0;
+	for (int i = 0; i < ALLOCATION_COUNT; i++) {
+		size_t sz = malloc_good_size(arc4random_uniform(257));
+		allocations[i] = malloc(sz);
+		total_requested_size += sz;
+	}
+
+	// Get the stats and enumerator values again and check whether the result is consistent.
+	malloc_zone_statistics(malloc_default_zone(), &stats);
+	run_enumerator();
+
+	T_ASSERT_EQ(stats.blocks_in_use, initial_blocks_in_use + ALLOCATION_COUNT,
+			"Incorrect blocks_in_use");
+	T_ASSERT_EQ(stats.size_in_use, initial_size_in_use + total_requested_size,
+			"Incorrect size_in_use");
+	T_ASSERT_TRUE(stats.size_allocated - initial_size_allocated >= total_requested_size,
+			"Size allocated must be >= size requested");
+
+	T_ASSERT_EQ(ptr_count, initial_ptrs + ALLOCATION_COUNT,
+			"Incorrect number of pointers");
+	T_ASSERT_EQ(total_in_use_ptr_size, initial_in_use_ptr_size + total_requested_size,
+			"Incorrect in-use pointer size");
+
+	// Free half of the memory and recheck the statistics
+	size_t size_freed = 0;
+	for (int i = 0; i < ALLOCATION_COUNT / 2; i++) {
+		size_freed += malloc_size(allocations[i]);
+		free(allocations[i]);
+	}
+
+	// Check the stats and enumerator values.
+	malloc_zone_statistics(malloc_default_zone(), &stats);
+	run_enumerator();
+	T_ASSERT_EQ(stats.blocks_in_use, initial_blocks_in_use + ALLOCATION_COUNT/2,
+			"Incorrect blocks_in_use after half free");
+	T_ASSERT_EQ(stats.size_in_use,
+			initial_size_in_use + total_requested_size - size_freed,
+			"Incorrect size_in_use after half free");
+	T_ASSERT_TRUE(stats.size_allocated >= initial_size_allocated ,
+			"Size allocated must be >= size requested");
+
+	T_ASSERT_EQ(ptr_count, initial_ptrs + ALLOCATION_COUNT / 2,
+			"Incorrect number of pointers after half free");
+	T_ASSERT_EQ(total_in_use_ptr_size,
+			initial_in_use_ptr_size + total_requested_size - size_freed,
+			"Incorrect in-use pointer size after half free");
+
+	// Free the rest the memory and recheck the statistics
+	for (int i = ALLOCATION_COUNT / 2; i < ALLOCATION_COUNT; i++) {
+		free(allocations[i]);
+	}
+	
+	// Check the stats and enumerator values one more time.
+	malloc_zone_statistics(malloc_default_zone(), &stats);
+	run_enumerator();
+
+	T_ASSERT_EQ(stats.blocks_in_use, initial_blocks_in_use,
+			"Incorrect blocks_in_use after full free");
+	T_ASSERT_EQ(stats.size_in_use, initial_size_in_use,
+			"Incorrect size_in_use after full free");
+	T_ASSERT_TRUE(stats.size_allocated >= initial_size_allocated ,
+			"Size allocated must be >= size requested");
+	
+	T_ASSERT_EQ(ptr_count, initial_ptrs, "Incorrect number of pointers after free");
+	T_ASSERT_EQ(total_in_use_ptr_size, initial_in_use_ptr_size,
+			"Incorrect in-use pointer size after free");
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+
+#pragma mark -
+#pragma mark Nano realloc tests
+
+// These tests are specific to the Nano implementation of realloc(). They
+// don't necessarily work with other allocators, since the behavior tested is
+// not part of the documented behavior of realloc().
+
+const char * const data = "abcdefghijklm";
+
+T_DECL(realloc_nano_size_class_change, "realloc with size class change",
+	   T_META_ENVVAR("MallocNanoZone=1"))
+{
+#if CONFIG_NANOZONE
+	void *ptr = malloc(16);
+	strcpy(ptr, data);
+	void *new_ptr;
+
+	// Each pass of the loop realloc's to the next size class up. We must
+	// get a new pointer each time and the content must have been copied.
+	for (int i = 32; i <= 256; i += 16) {
+		new_ptr = realloc(ptr, i);
+		T_QUIET; T_ASSERT_TRUE(ptr != new_ptr, "realloc pointer should change");
+		T_QUIET; T_ASSERT_EQ(i, (int)malloc_size(new_ptr), "Check size for new allocation");
+		T_QUIET; T_ASSERT_TRUE(!strncmp(new_ptr, data, strlen(data)), "Content must be copied");
+		T_QUIET; T_ASSERT_EQ(0, (int)malloc_size(ptr), "Old allocation not freed");
+		ptr = new_ptr;
+	}
+	free(new_ptr);
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+
+T_DECL(realloc_nano_ptr_change, "realloc with pointer change",
+	   T_META_ENVVAR("MallocNanoZone=1"))
+{
+#if CONFIG_NANOZONE
+	void *ptr = malloc(32);
+	strcpy(ptr, data);
+
+	void *new_ptr = realloc(ptr, 128);
+	T_ASSERT_TRUE(ptr != new_ptr, "realloc pointer should change");
+	T_ASSERT_EQ(128, (int)malloc_size(new_ptr), "Wrong size for new allocation");
+	T_ASSERT_TRUE(!strncmp(new_ptr, data, strlen(data)), "Content must be copied");
+	T_ASSERT_EQ(0, (int)malloc_size(ptr), "Old allocation not freed");
+	
+	free(new_ptr);
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+
+T_DECL(realloc_nano_to_other, "realloc with allocator change (nano)",
+	   T_META_ENVVAR("MallocNanoZone=1"))
+{
+#if CONFIG_NANOZONE
+	void *ptr = malloc(32);					// From Nano
+	strcpy(ptr, data);
+
+	void *new_ptr = realloc(ptr, 1024);		// Cannot be Nano.
+
+	T_ASSERT_TRUE(ptr != new_ptr, "realloc pointer should change");
+	T_ASSERT_EQ(1024, (int)malloc_size(new_ptr), "Wrong size for new allocation");
+	T_ASSERT_TRUE(!strncmp(new_ptr, data, strlen(data)), "Content must be copied");
+	T_ASSERT_EQ(0, (int)malloc_size(ptr), "Old allocation not freed");
+
+	free(new_ptr);
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+
+T_DECL(realloc_nano_to_zero_size, "realloc with target size zero",
+	   T_META_ENVVAR("MallocNanoZone=1"))
+{
+#if CONFIG_NANOZONE
+	void *ptr = malloc(16);
+
+	// Realloc to 0 frees the old memory and returns a valid pointer.
+	void *new_ptr = realloc(ptr, 0);
+	T_ASSERT_EQ(0, (int)malloc_size(ptr), "Old allocation not freed");
+	T_ASSERT_NOTNULL(new_ptr, "New allocation must be non-NULL");
+	T_ASSERT_TRUE(malloc_size(new_ptr) > 0, "New allocation not known");
+
+	free(new_ptr);
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+
+T_DECL(realloc_nano_shrink, "realloc to smaller size",
+	   T_META_ENVVAR("MallocNanoZone=1"))
+{
+#if CONFIG_NANOZONE
+	void *ptr = malloc(64);
+	strcpy(ptr, data);
+
+	// Reallocate to greater than half the current size - should remain
+	// in-place.
+	void *new_ptr = realloc(ptr, 40);
+	T_ASSERT_TRUE(ptr == new_ptr, "realloc pointer should not change");
+	T_ASSERT_TRUE(!strncmp(new_ptr, data, strlen(data)), "Content changed");
+
+	// Reallocate to less than half the current size - should get a new pointer
+	// Realloc to 0 frees the old memory and returns a valid pointer.
+	ptr = new_ptr;
+	new_ptr = realloc(ptr, 16);
+	T_ASSERT_TRUE(ptr != new_ptr, "realloc pointer should change");
+	T_ASSERT_TRUE(!strncmp(new_ptr, data, strlen(data)), "Content must be copied");
+
+	free(new_ptr);
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+
+#pragma mark -
+#pragma mark Nanov2 tests
+
+// These tests are specific to the implementation of the Nanov2 allocator.
+
+// Guaranteed number of 256-byte allocations to be sure we fill an arena.
+#define ALLOCS_PER_ARENA ((NANOV2_ARENA_SIZE)/256)
+
+T_DECL(overspill_arena, "force overspill of an arena",
+	   T_META_ENVVAR("MallocNanoZone=V2"),
+	   T_META_ENVVAR("MallocGuardEdges=all"))
+{
+#if CONFIG_NANOZONE
+	void **ptrs = calloc(ALLOCS_PER_ARENA, sizeof(void *));
+	T_QUIET; T_ASSERT_NOTNULL(ptrs, "Unable to allocate pointers");
+	int index;
+
+	nanov2_addr_t first_ptr;
+	ptrs[0] = malloc(256);
+	T_QUIET; T_ASSERT_NOTNULL(ptrs[index], "Failed to allocate");
+	first_ptr.addr = ptrs[0];
+
+	for (index = 1; index < ALLOCS_PER_ARENA; index++) {
+		ptrs[index] = malloc(256);
+		T_QUIET; T_ASSERT_NOTNULL(ptrs[index], "Failed to allocate");
+
+		// Stop allocating once we have crossed into a new arena.
+		nanov2_addr_t current_ptr;
+		current_ptr.addr = ptrs[index];
+		if (current_ptr.fields.nano_arena != first_ptr.fields.nano_arena) {
+			break;
+		}
+
+		// Write to the pointer to ensure the containing block is not
+		// a guard block.
+		*(int *)ptrs[index] = 0;
+	}
+
+	// Free everything, which is a check that the book-keeping works across
+	// arenas.
+	for (int i = 0; i <= index; i++) {
+		free(ptrs[i]);
+	}
+	free(ptrs);
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+
+#if TARGET_OS_OSX
+
+// Guaranteed number of 256-byte allocations to be sure we fill a region.
+#define ALLOCS_PER_REGION ((NANOV2_REGION_SIZE)/256)
+
+// This test is required only on macOS because iOS only uses one region.
+T_DECL(overspill_region, "force overspill of a region",
+	   T_META_ENVVAR("MallocNanoZone=V2"))
+{
+#if CONFIG_NANOZONE
+	void **ptrs = calloc(ALLOCS_PER_REGION, sizeof(void *));
+	T_QUIET; T_ASSERT_NOTNULL(ptrs, "Unable to allocate pointers");
+	int index;
+
+	nanov2_addr_t first_ptr;
+	ptrs[0] = malloc(256);
+	T_QUIET; T_ASSERT_NOTNULL(ptrs[index], "Failed to allocate");
+	first_ptr.addr = ptrs[0];
+
+	for (index = 1; index < ALLOCS_PER_REGION; index++) {
+		ptrs[index] = malloc(256);
+		T_QUIET; T_ASSERT_NOTNULL(ptrs[index], "Failed to allocate");
+
+		// Stop allocating once we have crossed into a new region.
+		nanov2_addr_t current_ptr;
+		current_ptr.addr = ptrs[index];
+		if (current_ptr.fields.nano_region != first_ptr.fields.nano_region) {
+			break;
+		}
+	}
+
+	// Free everything, which is a check that the book-keeping works across
+	// regions.
+	for (int i = 0; i <= index; i++) {
+		free(ptrs[i]);
+	}
+	free(ptrs);
+#else // CONFIG_NANOZONE
+	T_SKIP("Nano allocator not configured");
+#endif // CONFIG_NANOZONE
+}
+#endif // TARGET_OS_OSX
+