libc/bionic/bionic_elf_tls.cpp - platform/bionic - Git at Google

 /*
  * Copyright (C) 2019 The Android Open Source Project
  * All rights reserved.
  *
  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions
  * are met:
  *  * Redistributions of source code must retain the above copyright
  *    notice, this list of conditions and the following disclaimer.
  *  * Redistributions in binary form must reproduce the above copyright
  *    notice, this list of conditions and the following disclaimer in
  *    the documentation and/or other materials provided with the
  *    distribution.
  *
  * THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
  * "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
  * LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
  * FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
  * COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
  * INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
  * BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
  * OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
  * AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
  * OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
  * OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
  * SUCH DAMAGE.
  */

 #include "private/bionic_elf_tls.h"

 #include <async_safe/log.h>
 #include <string.h>
 #include <sys/param.h>
 #include <unistd.h>

 #include "private/ScopedRWLock.h"
 #include "private/ScopedSignalBlocker.h"
 #include "private/bionic_globals.h"
 #include "private/bionic_macros.h"
 #include "private/bionic_tls.h"
 #include "pthread_internal.h"

 // Every call to __tls_get_addr needs to check the generation counter, so
 // accesses to the counter need to be as fast as possible. Keep a copy of it in
 // a hidden variable, which can be accessed without using the GOT. The linker
 // will update this variable when it updates its counter.
 //
 // To allow the linker to update this variable, libc.so's constructor passes its
 // address to the linker. To accommodate a possible __tls_get_addr call before
 // libc.so's constructor, this local copy is initialized to SIZE_MAX, forcing
 // __tls_get_addr to initially use the slow path.
 __LIBC_HIDDEN__ _Atomic(size_t) __libc_tls_generation_copy = SIZE_MAX;

 // Search for a TLS segment in the given phdr table. Returns true if it has a
 // TLS segment and false otherwise.
 bool __bionic_get_tls_segment(const ElfW(Phdr)* phdr_table, size_t phdr_count,
                               ElfW(Addr) load_bias, TlsSegment* out) {
   for (size_t i = 0; i < phdr_count; ++i) {
     const ElfW(Phdr)& phdr = phdr_table[i];
     if (phdr.p_type == PT_TLS) {
       *out = TlsSegment {
         phdr.p_memsz,
         phdr.p_align,
         reinterpret_cast<void*>(load_bias + phdr.p_vaddr),
         phdr.p_filesz,
       };
       return true;
     }
   }
   return false;
 }

 // Return true if the alignment of a TLS segment is a valid power-of-two. Also
 // cap the alignment if it's too high.
 bool __bionic_check_tls_alignment(size_t* alignment) {
   // N.B. The size does not need to be a multiple of the alignment. With
   // ld.bfd (or after using binutils' strip), the TLS segment's size isn't
   // rounded up.
   if (*alignment == 0 || !powerof2(*alignment)) {
     return false;
   }
   // Bionic only respects TLS alignment up to one page.
   *alignment = MIN(*alignment, PAGE_SIZE);
   return true;
 }

 size_t StaticTlsLayout::offset_thread_pointer() const {
   return offset_bionic_tcb_ + (-MIN_TLS_SLOT * sizeof(void*));
 }

 // Reserves space for the Bionic TCB and the executable's TLS segment. Returns
 // the offset of the executable's TLS segment.
 size_t StaticTlsLayout::reserve_exe_segment_and_tcb(const TlsSegment* exe_segment,
                                                     const char* progname __attribute__((unused))) {
   // Special case: if the executable has no TLS segment, then just allocate a
   // TCB and skip the minimum alignment check on ARM.
   if (exe_segment == nullptr) {
     offset_bionic_tcb_ = reserve_type<bionic_tcb>();
     return 0;
   }

 #if defined(__arm__) || defined(__aarch64__)

   // First reserve enough space for the TCB before the executable segment.
   reserve(sizeof(bionic_tcb), 1);

   // Then reserve the segment itself.
   const size_t result = reserve(exe_segment->size, exe_segment->alignment);

   // The variant 1 ABI that ARM linkers follow specifies a 2-word TCB between
   // the thread pointer and the start of the executable's TLS segment, but both
   // the thread pointer and the TLS segment are aligned appropriately for the
   // TLS segment. Calculate the distance between the thread pointer and the
   // EXE's segment.
   const size_t exe_tpoff = __BIONIC_ALIGN(sizeof(void*) * 2, exe_segment->alignment);

   const size_t min_bionic_alignment = BIONIC_ROUND_UP_POWER_OF_2(MAX_TLS_SLOT) * sizeof(void*);
   if (exe_tpoff < min_bionic_alignment) {
     async_safe_fatal("error: \"%s\": executable's TLS segment is underaligned: "
                      "alignment is %zu, needs to be at least %zu for %s Bionic",
                      progname, exe_segment->alignment, min_bionic_alignment,
                      (sizeof(void*) == 4 ? "ARM" : "ARM64"));
   }

   offset_bionic_tcb_ = result - exe_tpoff - (-MIN_TLS_SLOT * sizeof(void*));
   return result;

 #elif defined(__i386__) || defined(__x86_64__)

   // x86 uses variant 2 TLS layout. The executable's segment is located just
   // before the TCB.
   static_assert(MIN_TLS_SLOT == 0, "First slot of bionic_tcb must be slot #0 on x86");
   const size_t exe_size = round_up_with_overflow_check(exe_segment->size, exe_segment->alignment);
   reserve(exe_size, 1);
   const size_t max_align = MAX(alignof(bionic_tcb), exe_segment->alignment);
   offset_bionic_tcb_ = reserve(sizeof(bionic_tcb), max_align);
   return offset_bionic_tcb_ - exe_size;

 #else
 #error "Unrecognized architecture"
 #endif
 }

 void StaticTlsLayout::reserve_bionic_tls() {
   offset_bionic_tls_ = reserve_type<bionic_tls>();
 }

 void StaticTlsLayout::finish_layout() {
   // Round the offset up to the alignment.
   offset_ = round_up_with_overflow_check(offset_, alignment_);

   if (overflowed_) {
     async_safe_fatal("error: TLS segments in static TLS overflowed");
   }
 }

 // The size is not required to be a multiple of the alignment. The alignment
 // must be a positive power-of-two.
 size_t StaticTlsLayout::reserve(size_t size, size_t alignment) {
   offset_ = round_up_with_overflow_check(offset_, alignment);
   const size_t result = offset_;
   if (__builtin_add_overflow(offset_, size, &offset_)) overflowed_ = true;
   alignment_ = MAX(alignment_, alignment);
   return result;
 }

 size_t StaticTlsLayout::round_up_with_overflow_check(size_t value, size_t alignment) {
   const size_t old_value = value;
   value = __BIONIC_ALIGN(value, alignment);
   if (value < old_value) overflowed_ = true;
   return value;
 }

 // Copy each TLS module's initialization image into a newly-allocated block of
 // static TLS memory. To reduce dirty pages, this function only writes to pages
 // within the static TLS that need initialization. The memory should already be
 // zero-initialized on entry.
 void __init_static_tls(void* static_tls) {
   // The part of the table we care about (i.e. static TLS modules) never changes
   // after startup, but we still need the mutex because the table could grow,
   // moving the initial part. If this locking is too slow, we can duplicate the
   // static part of the table.
   TlsModules& modules = __libc_shared_globals()->tls_modules;
   ScopedSignalBlocker ssb;
   ScopedReadLock locker(&modules.rwlock);

   for (size_t i = 0; i < modules.module_count; ++i) {
     TlsModule& module = modules.module_table[i];
     if (module.static_offset == SIZE_MAX) {
       // All of the static modules come before all of the dynamic modules, so
       // once we see the first dynamic module, we're done.
       break;
     }
     if (module.segment.init_size == 0) {
       // Skip the memcpy call for TLS segments with no initializer, which is
       // common.
       continue;
     }
     memcpy(static_cast<char*>(static_tls) + module.static_offset,
            module.segment.init_ptr,
            module.segment.init_size);
   }
 }

 static inline size_t dtv_size_in_bytes(size_t module_count) {
   return sizeof(TlsDtv) + module_count * sizeof(void*);
 }

 // Calculates the number of module slots to allocate in a new DTV. For small
 // objects (up to 1KiB), the TLS allocator allocates memory in power-of-2 sizes,
 // so for better space usage, ensure that the DTV size (header + slots) is a
 // power of 2.
 //
 // The lock on TlsModules must be held.
 static size_t calculate_new_dtv_count() {
   size_t loaded_cnt = __libc_shared_globals()->tls_modules.module_count;
   size_t bytes = dtv_size_in_bytes(MAX(1, loaded_cnt));
   if (!powerof2(bytes)) {
     bytes = BIONIC_ROUND_UP_POWER_OF_2(bytes);
   }
   return (bytes - sizeof(TlsDtv)) / sizeof(void*);
 }

 // This function must be called with signals blocked and a write lock on
 // TlsModules held.
 static void update_tls_dtv(bionic_tcb* tcb) {
   const TlsModules& modules = __libc_shared_globals()->tls_modules;
   BionicAllocator& allocator = __libc_shared_globals()->tls_allocator;

   // Use the generation counter from the shared globals instead of the local
   // copy, which won't be initialized yet if __tls_get_addr is called before
   // libc.so's constructor.
   if (__get_tcb_dtv(tcb)->generation == atomic_load(&modules.generation)) {
     return;
   }

   const size_t old_cnt = __get_tcb_dtv(tcb)->count;

   // If the DTV isn't large enough, allocate a larger one. Because a signal
   // handler could interrupt the fast path of __tls_get_addr, we don't free the
   // old DTV. Instead, we add the old DTV to a list, then free all of a thread's
   // DTVs at thread-exit. Each time the DTV is reallocated, its size at least
   // doubles.
   if (modules.module_count > old_cnt) {
     size_t new_cnt = calculate_new_dtv_count();
     TlsDtv* const old_dtv = __get_tcb_dtv(tcb);
     TlsDtv* const new_dtv = static_cast<TlsDtv*>(allocator.alloc(dtv_size_in_bytes(new_cnt)));
     memcpy(new_dtv, old_dtv, dtv_size_in_bytes(old_cnt));
     new_dtv->count = new_cnt;
     new_dtv->next = old_dtv;
     __set_tcb_dtv(tcb, new_dtv);
   }

   TlsDtv* const dtv = __get_tcb_dtv(tcb);

   const StaticTlsLayout& layout = __libc_shared_globals()->static_tls_layout;
   char* static_tls = reinterpret_cast<char*>(tcb) - layout.offset_bionic_tcb();

   // Initialize static TLS modules and free unloaded modules.
   for (size_t i = 0; i < dtv->count; ++i) {
     if (i < modules.module_count) {
       const TlsModule& mod = modules.module_table[i];
       if (mod.static_offset != SIZE_MAX) {
         dtv->modules[i] = static_tls + mod.static_offset;
         continue;
       }
       if (mod.first_generation != kTlsGenerationNone &&
           mod.first_generation <= dtv->generation) {
         continue;
       }
     }
     allocator.free(dtv->modules[i]);
     dtv->modules[i] = nullptr;
   }

   dtv->generation = atomic_load(&modules.generation);
 }

 __attribute__((noinline)) static void* tls_get_addr_slow_path(const TlsIndex* ti) {
   TlsModules& modules = __libc_shared_globals()->tls_modules;
   bionic_tcb* tcb = __get_bionic_tcb();

   // Block signals and lock TlsModules. We may need the allocator, so take
   // a write lock.
   ScopedSignalBlocker ssb;
   ScopedWriteLock locker(&modules.rwlock);

   update_tls_dtv(tcb);

   TlsDtv* dtv = __get_tcb_dtv(tcb);
   const size_t module_idx = __tls_module_id_to_idx(ti->module_id);
   void* mod_ptr = dtv->modules[module_idx];
   if (mod_ptr == nullptr) {
     const TlsSegment& segment = modules.module_table[module_idx].segment;
     mod_ptr = __libc_shared_globals()->tls_allocator.memalign(segment.alignment, segment.size);
     if (segment.init_size > 0) {
       memcpy(mod_ptr, segment.init_ptr, segment.init_size);
     }
     dtv->modules[module_idx] = mod_ptr;
   }

   return static_cast<char*>(mod_ptr) + ti->offset;
 }

 // Returns the address of a thread's TLS memory given a module ID and an offset
 // into that module's TLS segment. This function is called on every access to a
 // dynamic TLS variable on targets that don't use TLSDESC. arm64 uses TLSDESC,
 // so it only calls this function on a thread's first access to a module's TLS
 // segment.
 //
 // On most targets, this accessor function is __tls_get_addr and
 // TLS_GET_ADDR_CCONV is unset. 32-bit x86 uses ___tls_get_addr instead and a
 // regparm() calling convention.
 extern "C" void* TLS_GET_ADDR(const TlsIndex* ti) TLS_GET_ADDR_CCONV {
   TlsDtv* dtv = __get_tcb_dtv(__get_bionic_tcb());

   // TODO: See if we can use a relaxed memory ordering here instead.
   size_t generation = atomic_load(&__libc_tls_generation_copy);
   if (__predict_true(generation == dtv->generation)) {
     void* mod_ptr = dtv->modules[__tls_module_id_to_idx(ti->module_id)];
     if (__predict_true(mod_ptr != nullptr)) {
       return static_cast<char*>(mod_ptr) + ti->offset;
     }
   }

   return tls_get_addr_slow_path(ti);
 }

 // This function frees:
 //  - TLS modules referenced by the current DTV.
 //  - The list of DTV objects associated with the current thread.
 //
 // The caller must have already blocked signals.
 void __free_dynamic_tls(bionic_tcb* tcb) {
   TlsModules& modules = __libc_shared_globals()->tls_modules;
   BionicAllocator& allocator = __libc_shared_globals()->tls_allocator;

   // If we didn't allocate any dynamic memory, skip out early without taking
   // the lock.
   TlsDtv* dtv = __get_tcb_dtv(tcb);
   if (dtv->generation == kTlsGenerationNone) {
     return;
   }

   // We need the write lock to use the allocator.
   ScopedWriteLock locker(&modules.rwlock);

   // First free everything in the current DTV.
   for (size_t i = 0; i < dtv->count; ++i) {
     if (i < modules.module_count && modules.module_table[i].static_offset != SIZE_MAX) {
       // This module's TLS memory is allocated statically, so don't free it here.
       continue;
     }
     allocator.free(dtv->modules[i]);
   }

   // Now free the thread's list of DTVs.
   while (dtv->generation != kTlsGenerationNone) {
     TlsDtv* next = dtv->next;
     allocator.free(dtv);
     dtv = next;
   }

   // Clear the DTV slot. The DTV must not be used again with this thread.
   tcb->tls_slot(TLS_SLOT_DTV) = nullptr;
 }
	/*
	* Copyright (C) 2019 The Android Open Source Project
	* All rights reserved.
	*
	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions
	* are met:
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above copyright
	* notice, this list of conditions and the following disclaimer in
	* the documentation and/or other materials provided with the
	* distribution.
	*
	* THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
	* "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
	* LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS
	* FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE
	* COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT,
	* INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING,
	* BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS
	* OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED
	* AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY,
	* OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT
	* OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF
	* SUCH DAMAGE.
	*/

	#include "private/bionic_elf_tls.h"

	#include <async_safe/log.h>
	#include <string.h>
	#include <sys/param.h>
	#include <unistd.h>

	#include "private/ScopedRWLock.h"
	#include "private/ScopedSignalBlocker.h"
	#include "private/bionic_globals.h"
	#include "private/bionic_macros.h"
	#include "private/bionic_tls.h"
	#include "pthread_internal.h"

	// Every call to __tls_get_addr needs to check the generation counter, so
	// accesses to the counter need to be as fast as possible. Keep a copy of it in
	// a hidden variable, which can be accessed without using the GOT. The linker
	// will update this variable when it updates its counter.
	//
	// To allow the linker to update this variable, libc.so's constructor passes its
	// address to the linker. To accommodate a possible __tls_get_addr call before
	// libc.so's constructor, this local copy is initialized to SIZE_MAX, forcing
	// __tls_get_addr to initially use the slow path.
	__LIBC_HIDDEN__ _Atomic(size_t) __libc_tls_generation_copy = SIZE_MAX;

	// Search for a TLS segment in the given phdr table. Returns true if it has a
	// TLS segment and false otherwise.
	bool __bionic_get_tls_segment(const ElfW(Phdr)* phdr_table, size_t phdr_count,
	ElfW(Addr) load_bias, TlsSegment* out) {
	for (size_t i = 0; i < phdr_count; ++i) {
	const ElfW(Phdr)& phdr = phdr_table[i];
	if (phdr.p_type == PT_TLS) {
	*out = TlsSegment {
	phdr.p_memsz,
	phdr.p_align,
	reinterpret_cast<void*>(load_bias + phdr.p_vaddr),
	phdr.p_filesz,
	};
	return true;
	}
	}
	return false;
	}

	// Return true if the alignment of a TLS segment is a valid power-of-two. Also
	// cap the alignment if it's too high.
	bool __bionic_check_tls_alignment(size_t* alignment) {
	// N.B. The size does not need to be a multiple of the alignment. With
	// ld.bfd (or after using binutils' strip), the TLS segment's size isn't
	// rounded up.
	if (alignment == 0 \|\| !powerof2(alignment)) {
	return false;
	}
	// Bionic only respects TLS alignment up to one page.
	alignment = MIN(alignment, PAGE_SIZE);
	return true;
	}

	size_t StaticTlsLayout::offset_thread_pointer() const {
	return offset_bionic_tcb_ + (-MIN_TLS_SLOT * sizeof(void*));
	}

	// Reserves space for the Bionic TCB and the executable's TLS segment. Returns
	// the offset of the executable's TLS segment.
	size_t StaticTlsLayout::reserve_exe_segment_and_tcb(const TlsSegment* exe_segment,
	const char* progname __attribute__((unused))) {
	// Special case: if the executable has no TLS segment, then just allocate a
	// TCB and skip the minimum alignment check on ARM.
	if (exe_segment == nullptr) {
	offset_bionic_tcb_ = reserve_type<bionic_tcb>();
	return 0;
	}

	#if defined(__arm__) \|\| defined(__aarch64__)

	// First reserve enough space for the TCB before the executable segment.
	reserve(sizeof(bionic_tcb), 1);

	// Then reserve the segment itself.
	const size_t result = reserve(exe_segment->size, exe_segment->alignment);

	// The variant 1 ABI that ARM linkers follow specifies a 2-word TCB between
	// the thread pointer and the start of the executable's TLS segment, but both
	// the thread pointer and the TLS segment are aligned appropriately for the
	// TLS segment. Calculate the distance between the thread pointer and the
	// EXE's segment.
	const size_t exe_tpoff = __BIONIC_ALIGN(sizeof(void) 2, exe_segment->alignment);

	const size_t min_bionic_alignment = BIONIC_ROUND_UP_POWER_OF_2(MAX_TLS_SLOT) * sizeof(void*);
	if (exe_tpoff < min_bionic_alignment) {
	async_safe_fatal("error: \"%s\": executable's TLS segment is underaligned: "
	"alignment is %zu, needs to be at least %zu for %s Bionic",
	progname, exe_segment->alignment, min_bionic_alignment,
	(sizeof(void*) == 4 ? "ARM" : "ARM64"));
	}

	offset_bionic_tcb_ = result - exe_tpoff - (-MIN_TLS_SLOT * sizeof(void*));
	return result;

	#elif defined(__i386__) \|\| defined(__x86_64__)

	// x86 uses variant 2 TLS layout. The executable's segment is located just
	// before the TCB.
	static_assert(MIN_TLS_SLOT == 0, "First slot of bionic_tcb must be slot #0 on x86");
	const size_t exe_size = round_up_with_overflow_check(exe_segment->size, exe_segment->alignment);
	reserve(exe_size, 1);
	const size_t max_align = MAX(alignof(bionic_tcb), exe_segment->alignment);
	offset_bionic_tcb_ = reserve(sizeof(bionic_tcb), max_align);
	return offset_bionic_tcb_ - exe_size;

	#else
	#error "Unrecognized architecture"
	#endif
	}

	void StaticTlsLayout::reserve_bionic_tls() {
	offset_bionic_tls_ = reserve_type<bionic_tls>();
	}

	void StaticTlsLayout::finish_layout() {
	// Round the offset up to the alignment.
	offset_ = round_up_with_overflow_check(offset_, alignment_);

	if (overflowed_) {
	async_safe_fatal("error: TLS segments in static TLS overflowed");
	}
	}

	// The size is not required to be a multiple of the alignment. The alignment
	// must be a positive power-of-two.
	size_t StaticTlsLayout::reserve(size_t size, size_t alignment) {
	offset_ = round_up_with_overflow_check(offset_, alignment);
	const size_t result = offset_;
	if (__builtin_add_overflow(offset_, size, &offset_)) overflowed_ = true;
	alignment_ = MAX(alignment_, alignment);
	return result;
	}

	size_t StaticTlsLayout::round_up_with_overflow_check(size_t value, size_t alignment) {
	const size_t old_value = value;
	value = __BIONIC_ALIGN(value, alignment);
	if (value < old_value) overflowed_ = true;
	return value;
	}

	// Copy each TLS module's initialization image into a newly-allocated block of
	// static TLS memory. To reduce dirty pages, this function only writes to pages
	// within the static TLS that need initialization. The memory should already be
	// zero-initialized on entry.
	void __init_static_tls(void* static_tls) {
	// The part of the table we care about (i.e. static TLS modules) never changes
	// after startup, but we still need the mutex because the table could grow,
	// moving the initial part. If this locking is too slow, we can duplicate the
	// static part of the table.
	TlsModules& modules = __libc_shared_globals()->tls_modules;
	ScopedSignalBlocker ssb;
	ScopedReadLock locker(&modules.rwlock);

	for (size_t i = 0; i < modules.module_count; ++i) {
	TlsModule& module = modules.module_table[i];
	if (module.static_offset == SIZE_MAX) {
	// All of the static modules come before all of the dynamic modules, so
	// once we see the first dynamic module, we're done.
	break;
	}
	if (module.segment.init_size == 0) {
	// Skip the memcpy call for TLS segments with no initializer, which is
	// common.
	continue;
	}
	memcpy(static_cast<char*>(static_tls) + module.static_offset,
	module.segment.init_ptr,
	module.segment.init_size);
	}
	}

	static inline size_t dtv_size_in_bytes(size_t module_count) {
	return sizeof(TlsDtv) + module_count * sizeof(void*);
	}

	// Calculates the number of module slots to allocate in a new DTV. For small
	// objects (up to 1KiB), the TLS allocator allocates memory in power-of-2 sizes,
	// so for better space usage, ensure that the DTV size (header + slots) is a
	// power of 2.
	//
	// The lock on TlsModules must be held.
	static size_t calculate_new_dtv_count() {
	size_t loaded_cnt = __libc_shared_globals()->tls_modules.module_count;
	size_t bytes = dtv_size_in_bytes(MAX(1, loaded_cnt));
	if (!powerof2(bytes)) {
	bytes = BIONIC_ROUND_UP_POWER_OF_2(bytes);
	}
	return (bytes - sizeof(TlsDtv)) / sizeof(void*);
	}

	// This function must be called with signals blocked and a write lock on
	// TlsModules held.
	static void update_tls_dtv(bionic_tcb* tcb) {
	const TlsModules& modules = __libc_shared_globals()->tls_modules;
	BionicAllocator& allocator = __libc_shared_globals()->tls_allocator;

	// Use the generation counter from the shared globals instead of the local
	// copy, which won't be initialized yet if __tls_get_addr is called before
	// libc.so's constructor.
	if (__get_tcb_dtv(tcb)->generation == atomic_load(&modules.generation)) {
	return;
	}

	const size_t old_cnt = __get_tcb_dtv(tcb)->count;

	// If the DTV isn't large enough, allocate a larger one. Because a signal
	// handler could interrupt the fast path of __tls_get_addr, we don't free the
	// old DTV. Instead, we add the old DTV to a list, then free all of a thread's
	// DTVs at thread-exit. Each time the DTV is reallocated, its size at least
	// doubles.
	if (modules.module_count > old_cnt) {
	size_t new_cnt = calculate_new_dtv_count();
	TlsDtv* const old_dtv = __get_tcb_dtv(tcb);
	TlsDtv* const new_dtv = static_cast<TlsDtv*>(allocator.alloc(dtv_size_in_bytes(new_cnt)));
	memcpy(new_dtv, old_dtv, dtv_size_in_bytes(old_cnt));
	new_dtv->count = new_cnt;
	new_dtv->next = old_dtv;
	__set_tcb_dtv(tcb, new_dtv);
	}

	TlsDtv* const dtv = __get_tcb_dtv(tcb);

	const StaticTlsLayout& layout = __libc_shared_globals()->static_tls_layout;
	char* static_tls = reinterpret_cast<char*>(tcb) - layout.offset_bionic_tcb();

	// Initialize static TLS modules and free unloaded modules.
	for (size_t i = 0; i < dtv->count; ++i) {
	if (i < modules.module_count) {
	const TlsModule& mod = modules.module_table[i];
	if (mod.static_offset != SIZE_MAX) {
	dtv->modules[i] = static_tls + mod.static_offset;
	continue;
	}
	if (mod.first_generation != kTlsGenerationNone &&
	mod.first_generation <= dtv->generation) {
	continue;
	}
	}
	allocator.free(dtv->modules[i]);
	dtv->modules[i] = nullptr;
	}

	dtv->generation = atomic_load(&modules.generation);
	}

	__attribute__((noinline)) static void* tls_get_addr_slow_path(const TlsIndex* ti) {
	TlsModules& modules = __libc_shared_globals()->tls_modules;
	bionic_tcb* tcb = __get_bionic_tcb();

	// Block signals and lock TlsModules. We may need the allocator, so take
	// a write lock.
	ScopedSignalBlocker ssb;
	ScopedWriteLock locker(&modules.rwlock);

	update_tls_dtv(tcb);

	TlsDtv* dtv = __get_tcb_dtv(tcb);
	const size_t module_idx = __tls_module_id_to_idx(ti->module_id);
	void* mod_ptr = dtv->modules[module_idx];
	if (mod_ptr == nullptr) {
	const TlsSegment& segment = modules.module_table[module_idx].segment;
	mod_ptr = __libc_shared_globals()->tls_allocator.memalign(segment.alignment, segment.size);
	if (segment.init_size > 0) {
	memcpy(mod_ptr, segment.init_ptr, segment.init_size);
	}
	dtv->modules[module_idx] = mod_ptr;
	}

	return static_cast<char*>(mod_ptr) + ti->offset;
	}

	// Returns the address of a thread's TLS memory given a module ID and an offset
	// into that module's TLS segment. This function is called on every access to a
	// dynamic TLS variable on targets that don't use TLSDESC. arm64 uses TLSDESC,
	// so it only calls this function on a thread's first access to a module's TLS
	// segment.
	//
	// On most targets, this accessor function is __tls_get_addr and
	// TLS_GET_ADDR_CCONV is unset. 32-bit x86 uses ___tls_get_addr instead and a
	// regparm() calling convention.
	extern "C" void* TLS_GET_ADDR(const TlsIndex* ti) TLS_GET_ADDR_CCONV {
	TlsDtv* dtv = __get_tcb_dtv(__get_bionic_tcb());

	// TODO: See if we can use a relaxed memory ordering here instead.
	size_t generation = atomic_load(&__libc_tls_generation_copy);
	if (__predict_true(generation == dtv->generation)) {
	void* mod_ptr = dtv->modules[__tls_module_id_to_idx(ti->module_id)];
	if (__predict_true(mod_ptr != nullptr)) {
	return static_cast<char*>(mod_ptr) + ti->offset;
	}
	}

	return tls_get_addr_slow_path(ti);
	}

	// This function frees:
	// - TLS modules referenced by the current DTV.
	// - The list of DTV objects associated with the current thread.
	//
	// The caller must have already blocked signals.
	void __free_dynamic_tls(bionic_tcb* tcb) {
	TlsModules& modules = __libc_shared_globals()->tls_modules;
	BionicAllocator& allocator = __libc_shared_globals()->tls_allocator;

	// If we didn't allocate any dynamic memory, skip out early without taking
	// the lock.
	TlsDtv* dtv = __get_tcb_dtv(tcb);
	if (dtv->generation == kTlsGenerationNone) {
	return;
	}

	// We need the write lock to use the allocator.
	ScopedWriteLock locker(&modules.rwlock);

	// First free everything in the current DTV.
	for (size_t i = 0; i < dtv->count; ++i) {
	if (i < modules.module_count && modules.module_table[i].static_offset != SIZE_MAX) {
	// This module's TLS memory is allocated statically, so don't free it here.
	continue;
	}
	allocator.free(dtv->modules[i]);
	}

	// Now free the thread's list of DTVs.
	while (dtv->generation != kTlsGenerationNone) {
	TlsDtv* next = dtv->next;
	allocator.free(dtv);
	dtv = next;
	}

	// Clear the DTV slot. The DTV must not be used again with this thread.
	tcb->tls_slot(TLS_SLOT_DTV) = nullptr;
	}