compiler-rt/lib/builtins/emutls.c - llvm-project - Git at Google

 //===---------- emutls.c - Implements __emutls_get_address ---------------===//
 //
 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
 // See https://llvm.org/LICENSE.txt for license information.
 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
 //
 //===----------------------------------------------------------------------===//

 #include <stdint.h>
 #include <stdlib.h>
 #include <string.h>

 #include "int_lib.h"

 #ifdef __BIONIC__
 // There are 4 pthread key cleanup rounds on Bionic. Delay emutls deallocation
 // to round 2. We need to delay deallocation because:
 //  - Android versions older than M lack __cxa_thread_atexit_impl, so apps
 //    use a pthread key destructor to call C++ destructors.
 //  - Apps might use __thread/thread_local variables in pthread destructors.
 // We can't wait until the final two rounds, because jemalloc needs two rounds
 // after the final malloc/free call to free its thread-specific data (see
 // https://reviews.llvm.org/D46978#1107507).
 #define EMUTLS_SKIP_DESTRUCTOR_ROUNDS 1
 #else
 #define EMUTLS_SKIP_DESTRUCTOR_ROUNDS 0
 #endif

 #if defined(_MSC_VER) && !defined(__clang__)
 // MSVC raises a warning about a nonstandard extension being used for the 0
 // sized element in this array. Disable this for warn-as-error builds.
 #pragma warning(push)
 #pragma warning(disable : 4206)
 #endif

 typedef struct emutls_address_array {
   uintptr_t skip_destructor_rounds;
   uintptr_t size; // number of elements in the 'data' array
   void *data[];
 } emutls_address_array;

 #if defined(_MSC_VER) && !defined(__clang__)
 #pragma warning(pop)
 #endif

 static void emutls_shutdown(emutls_address_array *array);

 #ifndef _WIN32

 #include <pthread.h>

 static pthread_mutex_t emutls_mutex = PTHREAD_MUTEX_INITIALIZER;
 static pthread_key_t emutls_pthread_key;
 static bool emutls_key_created = false;

 typedef unsigned int gcc_word __attribute__((mode(word)));
 typedef unsigned int gcc_pointer __attribute__((mode(pointer)));

 // Default is not to use posix_memalign, so systems like Android
 // can use thread local data without heavier POSIX memory allocators.
 #ifndef EMUTLS_USE_POSIX_MEMALIGN
 #define EMUTLS_USE_POSIX_MEMALIGN 0
 #endif

 static __inline void *emutls_memalign_alloc(size_t align, size_t size) {
   void *base;
 #if EMUTLS_USE_POSIX_MEMALIGN
   if (posix_memalign(&base, align, size) != 0)
     abort();
 #else
 #define EXTRA_ALIGN_PTR_BYTES (align - 1 + sizeof(void *))
   char *object;
   if ((object = (char *)malloc(EXTRA_ALIGN_PTR_BYTES + size)) == NULL)
     abort();
   base = (void *)(((uintptr_t)(object + EXTRA_ALIGN_PTR_BYTES)) &
                   ~(uintptr_t)(align - 1));

   ((void **)base)[-1] = object;
 #endif
   return base;
 }

 static __inline void emutls_memalign_free(void *base) {
 #if EMUTLS_USE_POSIX_MEMALIGN
   free(base);
 #else
   // The mallocated address is in ((void**)base)[-1]
   free(((void **)base)[-1]);
 #endif
 }

 static __inline void emutls_setspecific(emutls_address_array *value) {
   pthread_setspecific(emutls_pthread_key, (void *)value);
 }

 static __inline emutls_address_array *emutls_getspecific() {
   return (emutls_address_array *)pthread_getspecific(emutls_pthread_key);
 }

 static void emutls_key_destructor(void *ptr) {
   emutls_address_array *array = (emutls_address_array *)ptr;
   if (array->skip_destructor_rounds > 0) {
     // emutls is deallocated using a pthread key destructor. These
     // destructors are called in several rounds to accommodate destructor
     // functions that (re)initialize key values with pthread_setspecific.
     // Delay the emutls deallocation to accommodate other end-of-thread
     // cleanup tasks like calling thread_local destructors (e.g. the
     // __cxa_thread_atexit fallback in libc++abi).
     array->skip_destructor_rounds--;
     emutls_setspecific(array);
   } else {
     emutls_shutdown(array);
     free(ptr);
   }
 }

 static __inline void emutls_init(void) {
   if (pthread_key_create(&emutls_pthread_key, emutls_key_destructor) != 0)
     abort();
   emutls_key_created = true;
 }

 static __inline void emutls_init_once(void) {
   static pthread_once_t once = PTHREAD_ONCE_INIT;
   pthread_once(&once, emutls_init);
 }

 static __inline void emutls_lock() { pthread_mutex_lock(&emutls_mutex); }

 static __inline void emutls_unlock() { pthread_mutex_unlock(&emutls_mutex); }

 #else // _WIN32

 #include <assert.h>
 #include <malloc.h>
 #include <stdio.h>
 #include <windows.h>

 static LPCRITICAL_SECTION emutls_mutex;
 static DWORD emutls_tls_index = TLS_OUT_OF_INDEXES;

 typedef uintptr_t gcc_word;
 typedef void *gcc_pointer;

 static void win_error(DWORD last_err, const char *hint) {
   char *buffer = NULL;
   if (FormatMessageA(FORMAT_MESSAGE_ALLOCATE_BUFFER |
                          FORMAT_MESSAGE_FROM_SYSTEM |
                          FORMAT_MESSAGE_MAX_WIDTH_MASK,
                      NULL, last_err, 0, (LPSTR)&buffer, 1, NULL)) {
     fprintf(stderr, "Windows error: %s\n", buffer);
   } else {
     fprintf(stderr, "Unknown Windows error: %s\n", hint);
   }
   LocalFree(buffer);
 }

 static __inline void win_abort(DWORD last_err, const char *hint) {
   win_error(last_err, hint);
   abort();
 }

 static __inline void *emutls_memalign_alloc(size_t align, size_t size) {
   void *base = _aligned_malloc(size, align);
   if (!base)
     win_abort(GetLastError(), "_aligned_malloc");
   return base;
 }

 static __inline void emutls_memalign_free(void *base) { _aligned_free(base); }

 static void emutls_exit(void) {
   if (emutls_mutex) {
     DeleteCriticalSection(emutls_mutex);
     _aligned_free(emutls_mutex);
     emutls_mutex = NULL;
   }
   if (emutls_tls_index != TLS_OUT_OF_INDEXES) {
     emutls_shutdown((emutls_address_array *)TlsGetValue(emutls_tls_index));
     TlsFree(emutls_tls_index);
     emutls_tls_index = TLS_OUT_OF_INDEXES;
   }
 }

 static BOOL CALLBACK emutls_init(PINIT_ONCE p0, PVOID p1, PVOID *p2) {
   (void)p0;
   (void)p1;
   (void)p2;
   emutls_mutex =
       (LPCRITICAL_SECTION)_aligned_malloc(sizeof(CRITICAL_SECTION), 16);
   if (!emutls_mutex) {
     win_error(GetLastError(), "_aligned_malloc");
     return FALSE;
   }
   InitializeCriticalSection(emutls_mutex);

   emutls_tls_index = TlsAlloc();
   if (emutls_tls_index == TLS_OUT_OF_INDEXES) {
     emutls_exit();
     win_error(GetLastError(), "TlsAlloc");
     return FALSE;
   }
   atexit(&emutls_exit);
   return TRUE;
 }

 static __inline void emutls_init_once(void) {
   static INIT_ONCE once;
   InitOnceExecuteOnce(&once, emutls_init, NULL, NULL);
 }

 static __inline void emutls_lock() { EnterCriticalSection(emutls_mutex); }

 static __inline void emutls_unlock() { LeaveCriticalSection(emutls_mutex); }

 static __inline void emutls_setspecific(emutls_address_array *value) {
   if (TlsSetValue(emutls_tls_index, (LPVOID)value) == 0)
     win_abort(GetLastError(), "TlsSetValue");
 }

 static __inline emutls_address_array *emutls_getspecific() {
   LPVOID value = TlsGetValue(emutls_tls_index);
   if (value == NULL) {
     const DWORD err = GetLastError();
     if (err != ERROR_SUCCESS)
       win_abort(err, "TlsGetValue");
   }
   return (emutls_address_array *)value;
 }

 // Provide atomic load/store functions for emutls_get_index if built with MSVC.
 #if !defined(__ATOMIC_RELEASE)
 #include <intrin.h>

 enum { __ATOMIC_ACQUIRE = 2, __ATOMIC_RELEASE = 3 };

 static __inline uintptr_t __atomic_load_n(void *ptr, unsigned type) {
   assert(type == __ATOMIC_ACQUIRE);
   // These return the previous value - but since we do an OR with 0,
   // it's equivalent to a plain load.
 #ifdef _WIN64
   return InterlockedOr64(ptr, 0);
 #else
   return InterlockedOr(ptr, 0);
 #endif
 }

 static __inline void __atomic_store_n(void *ptr, uintptr_t val, unsigned type) {
   assert(type == __ATOMIC_RELEASE);
   InterlockedExchangePointer((void *volatile *)ptr, (void *)val);
 }

 #endif // __ATOMIC_RELEASE

 #endif // _WIN32

 static size_t emutls_num_object = 0; // number of allocated TLS objects

 // Free the allocated TLS data
 static void emutls_shutdown(emutls_address_array *array) {
   if (array) {
     uintptr_t i;
     for (i = 0; i < array->size; ++i) {
       if (array->data[i])
         emutls_memalign_free(array->data[i]);
     }
   }
 }

 // For every TLS variable xyz,
 // there is one __emutls_control variable named __emutls_v.xyz.
 // If xyz has non-zero initial value, __emutls_v.xyz's "value"
 // will point to __emutls_t.xyz, which has the initial value.
 typedef struct __emutls_control {
   // Must use gcc_word here, instead of size_t, to match GCC.  When
   // gcc_word is larger than size_t, the upper extra bits are all
   // zeros.  We can use variables of size_t to operate on size and
   // align.
   gcc_word size;  // size of the object in bytes
   gcc_word align; // alignment of the object in bytes
   union {
     uintptr_t index; // data[index-1] is the object address
     void *address;   // object address, when in single thread env
   } object;
   void *value; // null or non-zero initial value for the object
 } __emutls_control;

 // Emulated TLS objects are always allocated at run-time.
 static __inline void *emutls_allocate_object(__emutls_control *control) {
   // Use standard C types, check with gcc's emutls.o.
   COMPILE_TIME_ASSERT(sizeof(uintptr_t) == sizeof(gcc_pointer));
   COMPILE_TIME_ASSERT(sizeof(uintptr_t) == sizeof(void *));

   size_t size = control->size;
   size_t align = control->align;
   void *base;
   if (align < sizeof(void *))
     align = sizeof(void *);
   // Make sure that align is power of 2.
   if ((align & (align - 1)) != 0)
     abort();

   base = emutls_memalign_alloc(align, size);
   if (control->value)
     memcpy(base, control->value, size);
   else
     memset(base, 0, size);
   return base;
 }

 // Returns control->object.index; set index if not allocated yet.
 static __inline uintptr_t emutls_get_index(__emutls_control *control) {
   uintptr_t index = __atomic_load_n(&control->object.index, __ATOMIC_ACQUIRE);
   if (!index) {
     emutls_init_once();
     emutls_lock();
     index = control->object.index;
     if (!index) {
       index = ++emutls_num_object;
       __atomic_store_n(&control->object.index, index, __ATOMIC_RELEASE);
     }
     emutls_unlock();
   }
   return index;
 }

 // Updates newly allocated thread local emutls_address_array.
 static __inline void emutls_check_array_set_size(emutls_address_array *array,
                                                  uintptr_t size) {
   if (array == NULL)
     abort();
   array->size = size;
   emutls_setspecific(array);
 }

 // Returns the new 'data' array size, number of elements,
 // which must be no smaller than the given index.
 static __inline uintptr_t emutls_new_data_array_size(uintptr_t index) {
   // Need to allocate emutls_address_array with extra slots
   // to store the header.
   // Round up the emutls_address_array size to multiple of 16.
   uintptr_t header_words = sizeof(emutls_address_array) / sizeof(void *);
   return ((index + header_words + 15) & ~((uintptr_t)15)) - header_words;
 }

 // Returns the size in bytes required for an emutls_address_array with
 // N number of elements for data field.
 static __inline uintptr_t emutls_asize(uintptr_t N) {
   return N * sizeof(void *) + sizeof(emutls_address_array);
 }

 // Returns the thread local emutls_address_array.
 // Extends its size if necessary to hold address at index.
 static __inline emutls_address_array *
 emutls_get_address_array(uintptr_t index) {
   emutls_address_array *array = emutls_getspecific();
   if (array == NULL) {
     uintptr_t new_size = emutls_new_data_array_size(index);
     array = (emutls_address_array *)malloc(emutls_asize(new_size));
     if (array) {
       memset(array->data, 0, new_size * sizeof(void *));
       array->skip_destructor_rounds = EMUTLS_SKIP_DESTRUCTOR_ROUNDS;
     }
     emutls_check_array_set_size(array, new_size);
   } else if (index > array->size) {
     uintptr_t orig_size = array->size;
     uintptr_t new_size = emutls_new_data_array_size(index);
     array = (emutls_address_array *)realloc(array, emutls_asize(new_size));
     if (array)
       memset(array->data + orig_size, 0,
              (new_size - orig_size) * sizeof(void *));
     emutls_check_array_set_size(array, new_size);
   }
   return array;
 }

 #ifndef _WIN32
 // Our emulated TLS implementation relies on local state (e.g. for the pthread
 // key), and if we duplicate this state across different shared libraries,
 // accesses to the same TLS variable from different shared libraries will yield
 // different results (see https://github.com/android/ndk/issues/1551 for an
 // example). __emutls_get_address is the only external entry point for emulated
 // TLS, and by making it default visibility and weak, we can rely on the dynamic
 // linker to coalesce multiple copies at runtime and ensure a single unique copy
 // of TLS state. This is a best effort; it won't work if the user is linking
 // with -Bsymbolic or -Bsymbolic-functions, and it also won't work on Windows,
 // where the dynamic linker has no notion of coalescing weak symbols at runtime.
 // A more robust solution would be to create a separate shared library for
 // emulated TLS, to ensure a single copy of its state.
 __attribute__((visibility("default"), weak))
 #endif
 void *__emutls_get_address(__emutls_control *control) {
   uintptr_t index = emutls_get_index(control);
   emutls_address_array *array = emutls_get_address_array(index--);
   if (array->data[index] == NULL)
     array->data[index] = emutls_allocate_object(control);
   return array->data[index];
 }

 #ifdef __BIONIC__
 // Called by Bionic on dlclose to delete the emutls pthread key.
 __attribute__((visibility("hidden"))) void __emutls_unregister_key(void) {
   if (emutls_key_created) {
     pthread_key_delete(emutls_pthread_key);
     emutls_key_created = false;
   }
 }
 #endif
	//===---------- emutls.c - Implements __emutls_get_address ---------------===//
	//
	// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
	// See https://llvm.org/LICENSE.txt for license information.
	// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
	//
	//===----------------------------------------------------------------------===//

	#include <stdint.h>
	#include <stdlib.h>
	#include <string.h>

	#include "int_lib.h"

	#ifdef __BIONIC__
	// There are 4 pthread key cleanup rounds on Bionic. Delay emutls deallocation
	// to round 2. We need to delay deallocation because:
	// - Android versions older than M lack __cxa_thread_atexit_impl, so apps
	// use a pthread key destructor to call C++ destructors.
	// - Apps might use __thread/thread_local variables in pthread destructors.
	// We can't wait until the final two rounds, because jemalloc needs two rounds
	// after the final malloc/free call to free its thread-specific data (see
	// https://reviews.llvm.org/D46978#1107507).
	#define EMUTLS_SKIP_DESTRUCTOR_ROUNDS 1
	#else
	#define EMUTLS_SKIP_DESTRUCTOR_ROUNDS 0
	#endif

	#if defined(_MSC_VER) && !defined(__clang__)
	// MSVC raises a warning about a nonstandard extension being used for the 0
	// sized element in this array. Disable this for warn-as-error builds.
	#pragma warning(push)
	#pragma warning(disable : 4206)
	#endif

	typedef struct emutls_address_array {
	uintptr_t skip_destructor_rounds;
	uintptr_t size; // number of elements in the 'data' array
	void *data[];
	} emutls_address_array;

	#if defined(_MSC_VER) && !defined(__clang__)
	#pragma warning(pop)
	#endif

	static void emutls_shutdown(emutls_address_array *array);

	#ifndef _WIN32

	#include <pthread.h>

	static pthread_mutex_t emutls_mutex = PTHREAD_MUTEX_INITIALIZER;
	static pthread_key_t emutls_pthread_key;
	static bool emutls_key_created = false;

	typedef unsigned int gcc_word __attribute__((mode(word)));
	typedef unsigned int gcc_pointer __attribute__((mode(pointer)));

	// Default is not to use posix_memalign, so systems like Android
	// can use thread local data without heavier POSIX memory allocators.
	#ifndef EMUTLS_USE_POSIX_MEMALIGN
	#define EMUTLS_USE_POSIX_MEMALIGN 0
	#endif

	static __inline void *emutls_memalign_alloc(size_t align, size_t size) {
	void *base;
	#if EMUTLS_USE_POSIX_MEMALIGN
	if (posix_memalign(&base, align, size) != 0)
	abort();
	#else
	#define EXTRA_ALIGN_PTR_BYTES (align - 1 + sizeof(void *))
	char *object;
	if ((object = (char *)malloc(EXTRA_ALIGN_PTR_BYTES + size)) == NULL)
	abort();
	base = (void *)(((uintptr_t)(object + EXTRA_ALIGN_PTR_BYTES)) &
	~(uintptr_t)(align - 1));

	((void **)base)[-1] = object;
	#endif
	return base;
	}

	static __inline void emutls_memalign_free(void *base) {
	#if EMUTLS_USE_POSIX_MEMALIGN
	free(base);
	#else
	// The mallocated address is in ((void**)base)[-1]
	free(((void **)base)[-1]);
	#endif
	}

	static __inline void emutls_setspecific(emutls_address_array *value) {
	pthread_setspecific(emutls_pthread_key, (void *)value);
	}

	static __inline emutls_address_array *emutls_getspecific() {
	return (emutls_address_array *)pthread_getspecific(emutls_pthread_key);
	}

	static void emutls_key_destructor(void *ptr) {
	emutls_address_array array = (emutls_address_array )ptr;
	if (array->skip_destructor_rounds > 0) {
	// emutls is deallocated using a pthread key destructor. These
	// destructors are called in several rounds to accommodate destructor
	// functions that (re)initialize key values with pthread_setspecific.
	// Delay the emutls deallocation to accommodate other end-of-thread
	// cleanup tasks like calling thread_local destructors (e.g. the
	// __cxa_thread_atexit fallback in libc++abi).
	array->skip_destructor_rounds--;
	emutls_setspecific(array);
	} else {
	emutls_shutdown(array);
	free(ptr);
	}
	}

	static __inline void emutls_init(void) {
	if (pthread_key_create(&emutls_pthread_key, emutls_key_destructor) != 0)
	abort();
	emutls_key_created = true;
	}

	static __inline void emutls_init_once(void) {
	static pthread_once_t once = PTHREAD_ONCE_INIT;
	pthread_once(&once, emutls_init);
	}

	static __inline void emutls_lock() { pthread_mutex_lock(&emutls_mutex); }

	static __inline void emutls_unlock() { pthread_mutex_unlock(&emutls_mutex); }

	#else // _WIN32

	#include <assert.h>
	#include <malloc.h>
	#include <stdio.h>
	#include <windows.h>

	static LPCRITICAL_SECTION emutls_mutex;
	static DWORD emutls_tls_index = TLS_OUT_OF_INDEXES;

	typedef uintptr_t gcc_word;
	typedef void *gcc_pointer;

	static void win_error(DWORD last_err, const char *hint) {
	char *buffer = NULL;
	if (FormatMessageA(FORMAT_MESSAGE_ALLOCATE_BUFFER \|
	FORMAT_MESSAGE_FROM_SYSTEM \|
	FORMAT_MESSAGE_MAX_WIDTH_MASK,
	NULL, last_err, 0, (LPSTR)&buffer, 1, NULL)) {
	fprintf(stderr, "Windows error: %s\n", buffer);
	} else {
	fprintf(stderr, "Unknown Windows error: %s\n", hint);
	}
	LocalFree(buffer);
	}

	static __inline void win_abort(DWORD last_err, const char *hint) {
	win_error(last_err, hint);
	abort();
	}

	static __inline void *emutls_memalign_alloc(size_t align, size_t size) {
	void *base = _aligned_malloc(size, align);
	if (!base)
	win_abort(GetLastError(), "_aligned_malloc");
	return base;
	}

	static __inline void emutls_memalign_free(void *base) { _aligned_free(base); }

	static void emutls_exit(void) {
	if (emutls_mutex) {
	DeleteCriticalSection(emutls_mutex);
	_aligned_free(emutls_mutex);
	emutls_mutex = NULL;
	}
	if (emutls_tls_index != TLS_OUT_OF_INDEXES) {
	emutls_shutdown((emutls_address_array *)TlsGetValue(emutls_tls_index));
	TlsFree(emutls_tls_index);
	emutls_tls_index = TLS_OUT_OF_INDEXES;
	}
	}

	static BOOL CALLBACK emutls_init(PINIT_ONCE p0, PVOID p1, PVOID *p2) {
	(void)p0;
	(void)p1;
	(void)p2;
	emutls_mutex =
	(LPCRITICAL_SECTION)_aligned_malloc(sizeof(CRITICAL_SECTION), 16);
	if (!emutls_mutex) {
	win_error(GetLastError(), "_aligned_malloc");
	return FALSE;
	}
	InitializeCriticalSection(emutls_mutex);

	emutls_tls_index = TlsAlloc();
	if (emutls_tls_index == TLS_OUT_OF_INDEXES) {
	emutls_exit();
	win_error(GetLastError(), "TlsAlloc");
	return FALSE;
	}
	atexit(&emutls_exit);
	return TRUE;
	}

	static __inline void emutls_init_once(void) {
	static INIT_ONCE once;
	InitOnceExecuteOnce(&once, emutls_init, NULL, NULL);
	}

	static __inline void emutls_lock() { EnterCriticalSection(emutls_mutex); }

	static __inline void emutls_unlock() { LeaveCriticalSection(emutls_mutex); }

	static __inline void emutls_setspecific(emutls_address_array *value) {
	if (TlsSetValue(emutls_tls_index, (LPVOID)value) == 0)
	win_abort(GetLastError(), "TlsSetValue");
	}

	static __inline emutls_address_array *emutls_getspecific() {
	LPVOID value = TlsGetValue(emutls_tls_index);
	if (value == NULL) {
	const DWORD err = GetLastError();
	if (err != ERROR_SUCCESS)
	win_abort(err, "TlsGetValue");
	}
	return (emutls_address_array *)value;
	}

	// Provide atomic load/store functions for emutls_get_index if built with MSVC.
	#if !defined(__ATOMIC_RELEASE)
	#include <intrin.h>

	enum { __ATOMIC_ACQUIRE = 2, __ATOMIC_RELEASE = 3 };

	static __inline uintptr_t __atomic_load_n(void *ptr, unsigned type) {
	assert(type == __ATOMIC_ACQUIRE);
	// These return the previous value - but since we do an OR with 0,
	// it's equivalent to a plain load.
	#ifdef _WIN64
	return InterlockedOr64(ptr, 0);
	#else
	return InterlockedOr(ptr, 0);
	#endif
	}

	static __inline void __atomic_store_n(void *ptr, uintptr_t val, unsigned type) {
	assert(type == __ATOMIC_RELEASE);
	InterlockedExchangePointer((void volatile )ptr, (void *)val);
	}

	#endif // __ATOMIC_RELEASE

	#endif // _WIN32

	static size_t emutls_num_object = 0; // number of allocated TLS objects

	// Free the allocated TLS data
	static void emutls_shutdown(emutls_address_array *array) {
	if (array) {
	uintptr_t i;
	for (i = 0; i < array->size; ++i) {
	if (array->data[i])
	emutls_memalign_free(array->data[i]);
	}
	}
	}

	// For every TLS variable xyz,
	// there is one __emutls_control variable named __emutls_v.xyz.
	// If xyz has non-zero initial value, __emutls_v.xyz's "value"
	// will point to __emutls_t.xyz, which has the initial value.
	typedef struct __emutls_control {
	// Must use gcc_word here, instead of size_t, to match GCC. When
	// gcc_word is larger than size_t, the upper extra bits are all
	// zeros. We can use variables of size_t to operate on size and
	// align.
	gcc_word size; // size of the object in bytes
	gcc_word align; // alignment of the object in bytes
	union {
	uintptr_t index; // data[index-1] is the object address
	void *address; // object address, when in single thread env
	} object;
	void *value; // null or non-zero initial value for the object
	} __emutls_control;

	// Emulated TLS objects are always allocated at run-time.
	static __inline void emutls_allocate_object(__emutls_control control) {
	// Use standard C types, check with gcc's emutls.o.
	COMPILE_TIME_ASSERT(sizeof(uintptr_t) == sizeof(gcc_pointer));
	COMPILE_TIME_ASSERT(sizeof(uintptr_t) == sizeof(void *));

	size_t size = control->size;
	size_t align = control->align;
	void *base;
	if (align < sizeof(void *))
	align = sizeof(void *);
	// Make sure that align is power of 2.
	if ((align & (align - 1)) != 0)
	abort();

	base = emutls_memalign_alloc(align, size);
	if (control->value)
	memcpy(base, control->value, size);
	else
	memset(base, 0, size);
	return base;
	}

	// Returns control->object.index; set index if not allocated yet.
	static __inline uintptr_t emutls_get_index(__emutls_control *control) {
	uintptr_t index = __atomic_load_n(&control->object.index, __ATOMIC_ACQUIRE);
	if (!index) {
	emutls_init_once();
	emutls_lock();
	index = control->object.index;
	if (!index) {
	index = ++emutls_num_object;
	__atomic_store_n(&control->object.index, index, __ATOMIC_RELEASE);
	}
	emutls_unlock();
	}
	return index;
	}

	// Updates newly allocated thread local emutls_address_array.
	static __inline void emutls_check_array_set_size(emutls_address_array *array,
	uintptr_t size) {
	if (array == NULL)
	abort();
	array->size = size;
	emutls_setspecific(array);
	}

	// Returns the new 'data' array size, number of elements,
	// which must be no smaller than the given index.
	static __inline uintptr_t emutls_new_data_array_size(uintptr_t index) {
	// Need to allocate emutls_address_array with extra slots
	// to store the header.
	// Round up the emutls_address_array size to multiple of 16.
	uintptr_t header_words = sizeof(emutls_address_array) / sizeof(void *);
	return ((index + header_words + 15) & ~((uintptr_t)15)) - header_words;
	}

	// Returns the size in bytes required for an emutls_address_array with
	// N number of elements for data field.
	static __inline uintptr_t emutls_asize(uintptr_t N) {
	return N * sizeof(void *) + sizeof(emutls_address_array);
	}

	// Returns the thread local emutls_address_array.
	// Extends its size if necessary to hold address at index.
	static __inline emutls_address_array *
	emutls_get_address_array(uintptr_t index) {
	emutls_address_array *array = emutls_getspecific();
	if (array == NULL) {
	uintptr_t new_size = emutls_new_data_array_size(index);
	array = (emutls_address_array *)malloc(emutls_asize(new_size));
	if (array) {
	memset(array->data, 0, new_size * sizeof(void *));
	array->skip_destructor_rounds = EMUTLS_SKIP_DESTRUCTOR_ROUNDS;
	}
	emutls_check_array_set_size(array, new_size);
	} else if (index > array->size) {
	uintptr_t orig_size = array->size;
	uintptr_t new_size = emutls_new_data_array_size(index);
	array = (emutls_address_array *)realloc(array, emutls_asize(new_size));
	if (array)
	memset(array->data + orig_size, 0,
	(new_size - orig_size) * sizeof(void *));
	emutls_check_array_set_size(array, new_size);
	}
	return array;
	}

	#ifndef _WIN32
	// Our emulated TLS implementation relies on local state (e.g. for the pthread
	// key), and if we duplicate this state across different shared libraries,
	// accesses to the same TLS variable from different shared libraries will yield
	// different results (see https://github.com/android/ndk/issues/1551 for an
	// example). __emutls_get_address is the only external entry point for emulated
	// TLS, and by making it default visibility and weak, we can rely on the dynamic
	// linker to coalesce multiple copies at runtime and ensure a single unique copy
	// of TLS state. This is a best effort; it won't work if the user is linking
	// with -Bsymbolic or -Bsymbolic-functions, and it also won't work on Windows,
	// where the dynamic linker has no notion of coalescing weak symbols at runtime.
	// A more robust solution would be to create a separate shared library for
	// emulated TLS, to ensure a single copy of its state.
	__attribute__((visibility("default"), weak))
	#endif
	void __emutls_get_address(__emutls_control control) {
	uintptr_t index = emutls_get_index(control);
	emutls_address_array *array = emutls_get_address_array(index--);
	if (array->data[index] == NULL)
	array->data[index] = emutls_allocate_object(control);
	return array->data[index];
	}

	#ifdef __BIONIC__
	// Called by Bionic on dlclose to delete the emutls pthread key.
	__attribute__((visibility("hidden"))) void __emutls_unregister_key(void) {
	if (emutls_key_created) {
	pthread_key_delete(emutls_pthread_key);
	emutls_key_created = false;
	}
	}
	#endif