runtime/jit/jit_memory_region.cc - platform/art - Git at Google

 /*
  * Copyright 2019 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include "jit_memory_region.h"

 #include <fcntl.h>
 #include <unistd.h>

 #include <android-base/unique_fd.h>
 #include "base/bit_utils.h"  // For RoundDown, RoundUp
 #include "base/globals.h"
 #include "base/logging.h"  // For VLOG.
 #include "base/membarrier.h"
 #include "base/memfd.h"
 #include "base/systrace.h"
 #include "gc/allocator/dlmalloc.h"
 #include "jit/jit_scoped_code_cache_write.h"
 #include "oat_quick_method_header.h"
 #include "palette/palette.h"

 using android::base::unique_fd;

 namespace art {
 namespace jit {

 // Data cache will be half of the capacity
 // Code cache will be the other half of the capacity.
 // TODO: Make this variable?
 static constexpr size_t kCodeAndDataCapacityDivider = 2;

 bool JitMemoryRegion::Initialize(size_t initial_capacity,
                                  size_t max_capacity,
                                  bool rwx_memory_allowed,
                                  bool is_zygote,
                                  std::string* error_msg) {
   ScopedTrace trace(__PRETTY_FUNCTION__);

   CHECK_GE(max_capacity, initial_capacity);
   CHECK(max_capacity <= 1 * GB) << "The max supported size for JIT code cache is 1GB";
   // Align both capacities to page size, as that's the unit mspaces use.
   initial_capacity_ = RoundDown(initial_capacity, 2 * kPageSize);
   max_capacity_ = RoundDown(max_capacity, 2 * kPageSize);
   current_capacity_ = initial_capacity,
   data_end_ = initial_capacity / kCodeAndDataCapacityDivider;
   exec_end_ = initial_capacity - data_end_;

   const size_t capacity = max_capacity_;
   const size_t data_capacity = capacity / kCodeAndDataCapacityDivider;
   const size_t exec_capacity = capacity - data_capacity;

   // File descriptor enabling dual-view mapping of code section.
   unique_fd mem_fd;

   if (is_zygote) {
     // Because we are not going to GC code generated by the zygote, just use all available.
     current_capacity_ = max_capacity;
     mem_fd = unique_fd(CreateZygoteMemory(capacity, error_msg));
     if (mem_fd.get() < 0) {
       return false;
     }
   } else {
     // Bionic supports memfd_create, but the call may fail on older kernels.
     mem_fd = unique_fd(art::memfd_create("/jit-cache", /* flags= */ 0));
     if (mem_fd.get() < 0) {
       std::ostringstream oss;
       oss << "Failed to initialize dual view JIT. memfd_create() error: " << strerror(errno);
       if (!rwx_memory_allowed) {
         // Without using RWX page permissions, the JIT can not fallback to single mapping as it
         // requires tranitioning the code pages to RWX for updates.
         *error_msg = oss.str();
         return false;
       }
       VLOG(jit) << oss.str();
     } else if (ftruncate(mem_fd, capacity) != 0) {
       std::ostringstream oss;
       oss << "Failed to initialize memory file: " << strerror(errno);
       *error_msg = oss.str();
       return false;
     }
   }

   std::string data_cache_name = is_zygote ? "zygote-data-code-cache" : "data-code-cache";
   std::string exec_cache_name = is_zygote ? "zygote-jit-code-cache" : "jit-code-cache";

   std::string error_str;
   // Map name specific for android_os_Debug.cpp accounting.
   // Map in low 4gb to simplify accessing root tables for x86_64.
   // We could do PC-relative addressing to avoid this problem, but that
   // would require reserving code and data area before submitting, which
   // means more windows for the code memory to be RWX.
   int base_flags;
   MemMap data_pages;
   if (mem_fd.get() >= 0) {
     // Dual view of JIT code cache case. Create an initial mapping of data pages large enough
     // for data and non-writable view of JIT code pages. We use the memory file descriptor to
     // enable dual mapping - we'll create a second mapping using the descriptor below. The
     // mappings will look like:
     //
     //       VA                  PA
     //
     //       +---------------+
     //       | non exec code |\
     //       +---------------+ \
     //       :               :\ \
     //       +---------------+.\.+---------------+
     //       |  exec code    |  \|     code      |
     //       +---------------+...+---------------+
     //       |      data     |   |     data      |
     //       +---------------+...+---------------+
     //
     // In this configuration code updates are written to the non-executable view of the code
     // cache, and the executable view of the code cache has fixed RX memory protections.
     //
     // This memory needs to be mapped shared as the code portions will have two mappings.
     //
     // Additionally, the zyzote will create a dual view of the data portion of
     // the cache. This mapping will be read-only, whereas the second mapping
     // will be writable.
     base_flags = MAP_SHARED;
     data_pages = MemMap::MapFile(
         data_capacity + exec_capacity,
         is_zygote ? kProtR : kProtRW,
         base_flags,
         mem_fd,
         /* start= */ 0,
         /* low_4gb= */ true,
         data_cache_name.c_str(),
         &error_str);
   } else {
     // Single view of JIT code cache case. Create an initial mapping of data pages large enough
     // for data and JIT code pages. The mappings will look like:
     //
     //       VA                  PA
     //
     //       +---------------+...+---------------+
     //       |  exec code    |   |     code      |
     //       +---------------+...+---------------+
     //       |      data     |   |     data      |
     //       +---------------+...+---------------+
     //
     // In this configuration code updates are written to the executable view of the code cache,
     // and the executable view of the code cache transitions RX to RWX for the update and then
     // back to RX after the update.
     base_flags = MAP_PRIVATE | MAP_ANON;
     data_pages = MemMap::MapAnonymous(
         data_cache_name.c_str(),
         data_capacity + exec_capacity,
         kProtRW,
         /* low_4gb= */ true,
         &error_str);
   }

   if (!data_pages.IsValid()) {
     std::ostringstream oss;
     oss << "Failed to create read write cache: " << error_str << " size=" << capacity;
     *error_msg = oss.str();
     return false;
   }

   MemMap exec_pages;
   MemMap non_exec_pages;
   MemMap writable_data_pages;
   if (exec_capacity > 0) {
     uint8_t* const divider = data_pages.Begin() + data_capacity;
     // Set initial permission for executable view to catch any SELinux permission problems early
     // (for processes that cannot map WX pages). Otherwise, this region does not need to be
     // executable as there is no code in the cache yet.
     exec_pages = data_pages.RemapAtEnd(divider,
                                        exec_cache_name.c_str(),
                                        kProtRX,
                                        base_flags | MAP_FIXED,
                                        mem_fd.get(),
                                        (mem_fd.get() >= 0) ? data_capacity : 0,
                                        &error_str);
     if (!exec_pages.IsValid()) {
       std::ostringstream oss;
       oss << "Failed to create read execute code cache: " << error_str << " size=" << capacity;
       *error_msg = oss.str();
       return false;
     }

     if (mem_fd.get() >= 0) {
       // For dual view, create the secondary view of code memory used for updating code. This view
       // is never executable.
       std::string name = exec_cache_name + "-rw";
       non_exec_pages = MemMap::MapFile(exec_capacity,
                                        kProtR,
                                        base_flags,
                                        mem_fd,
                                        /* start= */ data_capacity,
                                        /* low_4GB= */ false,
                                        name.c_str(),
                                        &error_str);
       if (!non_exec_pages.IsValid()) {
         static const char* kFailedNxView = "Failed to map non-executable view of JIT code cache";
         if (rwx_memory_allowed) {
           // Log and continue as single view JIT (requires RWX memory).
           VLOG(jit) << kFailedNxView;
         } else {
           *error_msg = kFailedNxView;
           return false;
         }
       }
       // For the zygote, create a dual view of the data cache.
       if (is_zygote) {
         name = data_cache_name + "-rw";
         writable_data_pages = MemMap::MapFile(data_capacity,
                                               kProtRW,
                                               base_flags,
                                               mem_fd,
                                               /* start= */ 0,
                                               /* low_4GB= */ false,
                                               name.c_str(),
                                               &error_str);
         if (!writable_data_pages.IsValid()) {
           std::ostringstream oss;
           oss << "Failed to create dual data view for zygote: " << error_str;
           *error_msg = oss.str();
           return false;
         }
         if (writable_data_pages.MadviseDontFork() != 0) {
           *error_msg = "Failed to madvise dont fork the writable data view";
           return false;
         }
         if (non_exec_pages.MadviseDontFork() != 0) {
           *error_msg = "Failed to madvise dont fork the writable code view";
           return false;
         }
         // Now that we have created the writable and executable mappings, prevent creating any new
         // ones.
         if (!ProtectZygoteMemory(mem_fd.get(), error_msg)) {
           return false;
         }
       }
     }
   } else {
     // Profiling only. No memory for code required.
   }

   data_pages_ = std::move(data_pages);
   exec_pages_ = std::move(exec_pages);
   non_exec_pages_ = std::move(non_exec_pages);
   writable_data_pages_ = std::move(writable_data_pages);

   VLOG(jit) << "Created JitMemoryRegion"
             << ": data_pages=" << reinterpret_cast<void*>(data_pages_.Begin())
             << ", exec_pages=" << reinterpret_cast<void*>(exec_pages_.Begin())
             << ", non_exec_pages=" << reinterpret_cast<void*>(non_exec_pages_.Begin())
             << ", writable_data_pages=" << reinterpret_cast<void*>(writable_data_pages_.Begin());

   // Now that the pages are initialized, initialize the spaces.

   // Initialize the data heap.
   data_mspace_ = create_mspace_with_base(
       HasDualDataMapping() ? writable_data_pages_.Begin() : data_pages_.Begin(),
       data_end_,
       /* locked= */ false);
   CHECK(data_mspace_ != nullptr) << "create_mspace_with_base (data) failed";

   // Initialize the code heap.
   MemMap* code_heap = nullptr;
   if (non_exec_pages_.IsValid()) {
     code_heap = &non_exec_pages_;
   } else if (exec_pages_.IsValid()) {
     code_heap = &exec_pages_;
   }
   if (code_heap != nullptr) {
     // Make all pages reserved for the code heap writable. The mspace allocator, that manages the
     // heap, will take and initialize pages in create_mspace_with_base().
     CheckedCall(mprotect, "create code heap", code_heap->Begin(), code_heap->Size(), kProtRW);
     exec_mspace_ = create_mspace_with_base(code_heap->Begin(), exec_end_, false /*locked*/);
     CHECK(exec_mspace_ != nullptr) << "create_mspace_with_base (exec) failed";
     SetFootprintLimit(current_capacity_);
     // Protect pages containing heap metadata. Updates to the code heap toggle write permission to
     // perform the update and there are no other times write access is required.
     CheckedCall(mprotect, "protect code heap", code_heap->Begin(), code_heap->Size(), kProtR);
   } else {
     exec_mspace_ = nullptr;
     SetFootprintLimit(current_capacity_);
   }
   return true;
 }

 void JitMemoryRegion::SetFootprintLimit(size_t new_footprint) {
   size_t data_space_footprint = new_footprint / kCodeAndDataCapacityDivider;
   DCHECK(IsAlignedParam(data_space_footprint, kPageSize));
   DCHECK_EQ(data_space_footprint * kCodeAndDataCapacityDivider, new_footprint);
   mspace_set_footprint_limit(data_mspace_, data_space_footprint);
   if (HasCodeMapping()) {
     ScopedCodeCacheWrite scc(*this);
     mspace_set_footprint_limit(exec_mspace_, new_footprint - data_space_footprint);
   }
 }

 bool JitMemoryRegion::IncreaseCodeCacheCapacity() {
   if (current_capacity_ == max_capacity_) {
     return false;
   }

   // Double the capacity if we're below 1MB, or increase it by 1MB if
   // we're above.
   if (current_capacity_ < 1 * MB) {
     current_capacity_ *= 2;
   } else {
     current_capacity_ += 1 * MB;
   }
   if (current_capacity_ > max_capacity_) {
     current_capacity_ = max_capacity_;
   }

   VLOG(jit) << "Increasing code cache capacity to " << PrettySize(current_capacity_);

   SetFootprintLimit(current_capacity_);

   return true;
 }

 // NO_THREAD_SAFETY_ANALYSIS as this is called from mspace code, at which point the lock
 // is already held.
 void* JitMemoryRegion::MoreCore(const void* mspace, intptr_t increment) NO_THREAD_SAFETY_ANALYSIS {
   if (mspace == exec_mspace_) {
     CHECK(exec_mspace_ != nullptr);
     const MemMap* const code_pages = GetUpdatableCodeMapping();
     void* result = code_pages->Begin() + exec_end_;
     exec_end_ += increment;
     return result;
   } else {
     CHECK_EQ(data_mspace_, mspace);
     const MemMap* const writable_data_pages = GetWritableDataMapping();
     void* result = writable_data_pages->Begin() + data_end_;
     data_end_ += increment;
     return result;
   }
 }

 const uint8_t* JitMemoryRegion::AllocateCode(const uint8_t* code,
                                              size_t code_size,
                                              const uint8_t* stack_map,
                                              bool has_should_deoptimize_flag) {
   ScopedCodeCacheWrite scc(*this);

   size_t alignment = GetInstructionSetAlignment(kRuntimeISA);
   // Ensure the header ends up at expected instruction alignment.
   size_t header_size = RoundUp(sizeof(OatQuickMethodHeader), alignment);
   size_t total_size = header_size + code_size;

   // Each allocation should be on its own set of cache lines.
   // `total_size` covers the OatQuickMethodHeader, the JIT generated machine code,
   // and any alignment padding.
   DCHECK_GT(total_size, header_size);
   uint8_t* w_memory = reinterpret_cast<uint8_t*>(
       mspace_memalign(exec_mspace_, alignment, total_size));
   if (w_memory == nullptr) {
     return nullptr;
   }
   uint8_t* x_memory = GetExecutableAddress(w_memory);
   // Ensure the header ends up at expected instruction alignment.
   DCHECK_ALIGNED_PARAM(reinterpret_cast<uintptr_t>(w_memory + header_size), alignment);
   used_memory_for_code_ += mspace_usable_size(w_memory);
   const uint8_t* result = x_memory + header_size;

   // Write the code.
   std::copy(code, code + code_size, w_memory + header_size);

   // Write the header.
   OatQuickMethodHeader* method_header =
       OatQuickMethodHeader::FromCodePointer(w_memory + header_size);
   new (method_header) OatQuickMethodHeader(
       (stack_map != nullptr) ? result - stack_map : 0u,
       code_size);
   if (has_should_deoptimize_flag) {
     method_header->SetHasShouldDeoptimizeFlag();
   }

   // Both instruction and data caches need flushing to the point of unification where both share
   // a common view of memory. Flushing the data cache ensures the dirty cachelines from the
   // newly added code are written out to the point of unification. Flushing the instruction
   // cache ensures the newly written code will be fetched from the point of unification before
   // use. Memory in the code cache is re-cycled as code is added and removed. The flushes
   // prevent stale code from residing in the instruction cache.
   //
   // Caches are flushed before write permission is removed because some ARMv8 Qualcomm kernels
   // may trigger a segfault if a page fault occurs when requesting a cache maintenance
   // operation. This is a kernel bug that we need to work around until affected devices
   // (e.g. Nexus 5X and 6P) stop being supported or their kernels are fixed.
   //
   // For reference, this behavior is caused by this commit:
   // https://android.googlesource.com/kernel/msm/+/3fbe6bc28a6b9939d0650f2f17eb5216c719950c
   //
   bool cache_flush_success = true;
   if (HasDualCodeMapping()) {
     // Flush d-cache for the non-executable mapping.
     cache_flush_success = FlushCpuCaches(w_memory, w_memory + total_size);
   }

   // Invalidate i-cache for the executable mapping.
   if (cache_flush_success) {
     cache_flush_success = FlushCpuCaches(x_memory, x_memory + total_size);
   }

   // If flushing the cache has failed, reject the allocation because we can't guarantee
   // correctness of the instructions present in the processor caches.
   if (!cache_flush_success) {
     PLOG(ERROR) << "Cache flush failed triggering code allocation failure";
     FreeCode(x_memory);
     return nullptr;
   }

   // Ensure CPU instruction pipelines are flushed for all cores. This is necessary for
   // correctness as code may still be in instruction pipelines despite the i-cache flush. It is
   // not safe to assume that changing permissions with mprotect (RX->RWX->RX) will cause a TLB
   // shootdown (incidentally invalidating the CPU pipelines by sending an IPI to all cores to
   // notify them of the TLB invalidation). Some architectures, notably ARM and ARM64, have
   // hardware support that broadcasts TLB invalidations and so their kernels have no software
   // based TLB shootdown. The sync-core flavor of membarrier was introduced in Linux 4.16 to
   // address this (see mbarrier(2)). The membarrier here will fail on prior kernels and on
   // platforms lacking the appropriate support.
   art::membarrier(art::MembarrierCommand::kPrivateExpeditedSyncCore);

   return result;
 }

 static void FillRootTable(uint8_t* roots_data, const std::vector<Handle<mirror::Object>>& roots)
     REQUIRES(Locks::jit_lock_)
     REQUIRES_SHARED(Locks::mutator_lock_) {
   GcRoot<mirror::Object>* gc_roots = reinterpret_cast<GcRoot<mirror::Object>*>(roots_data);
   const uint32_t length = roots.size();
   // Put all roots in `roots_data`.
   for (uint32_t i = 0; i < length; ++i) {
     ObjPtr<mirror::Object> object = roots[i].Get();
     gc_roots[i] = GcRoot<mirror::Object>(object);
   }
   // Store the length of the table at the end. This will allow fetching it from a stack_map
   // pointer.
   reinterpret_cast<uint32_t*>(roots_data)[length] = length;
 }

 bool JitMemoryRegion::CommitData(uint8_t* roots_data,
                                  const std::vector<Handle<mirror::Object>>& roots,
                                  const uint8_t* stack_map,
                                  size_t stack_map_size) {
   roots_data = GetWritableDataAddress(roots_data);
   size_t root_table_size = ComputeRootTableSize(roots.size());
   uint8_t* stack_map_data = roots_data + root_table_size;
   FillRootTable(roots_data, roots);
   memcpy(stack_map_data, stack_map, stack_map_size);
   // Flush data cache, as compiled code references literals in it.
   // TODO(oth): establish whether this is necessary.
   if (UNLIKELY(!FlushCpuCaches(roots_data, roots_data + root_table_size + stack_map_size))) {
     VLOG(jit) << "Failed to flush data in CommitData";
     return false;
   }
   return true;
 }

 void JitMemoryRegion::FreeCode(const uint8_t* code) {
   code = GetNonExecutableAddress(code);
   used_memory_for_code_ -= mspace_usable_size(code);
   mspace_free(exec_mspace_, const_cast<uint8_t*>(code));
 }

 uint8_t* JitMemoryRegion::AllocateData(size_t data_size) {
   void* result = mspace_malloc(data_mspace_, data_size);
   used_memory_for_data_ += mspace_usable_size(result);
   return reinterpret_cast<uint8_t*>(GetNonWritableDataAddress(result));
 }

 void JitMemoryRegion::FreeData(uint8_t* data) {
   data = GetWritableDataAddress(data);
   used_memory_for_data_ -= mspace_usable_size(data);
   mspace_free(data_mspace_, data);
 }

 #if defined(__BIONIC__)

 int JitMemoryRegion::CreateZygoteMemory(size_t capacity, std::string* error_msg) {
   /* Check if kernel support exists, otherwise fall back to ashmem */
   static const char* kRegionName = "/jit-zygote-cache";
   if (art::IsSealFutureWriteSupported()) {
     int fd = art::memfd_create(kRegionName, MFD_ALLOW_SEALING);
     if (fd == -1) {
       std::ostringstream oss;
       oss << "Failed to create zygote mapping: " << strerror(errno);
       *error_msg = oss.str();
       return -1;
     }

     if (ftruncate(fd, capacity) != 0) {
       std::ostringstream oss;
       oss << "Failed to create zygote mapping: " << strerror(errno);
       *error_msg = oss.str();
       return -1;
     }

     return fd;
   }

   LOG(INFO) << "Falling back to ashmem implementation for JIT zygote mapping";

   int fd;
   PaletteStatus status = PaletteAshmemCreateRegion(kRegionName, capacity, &fd);
   if (status != PaletteStatus::kOkay) {
     CHECK_EQ(status, PaletteStatus::kCheckErrno);
     std::ostringstream oss;
     oss << "Failed to create zygote mapping: " << strerror(errno);
     *error_msg = oss.str();
     return -1;
   }
   return fd;
 }

 bool JitMemoryRegion::ProtectZygoteMemory(int fd, std::string* error_msg) {
   if (art::IsSealFutureWriteSupported()) {
     if (fcntl(fd, F_ADD_SEALS, F_SEAL_SHRINK | F_SEAL_GROW | F_SEAL_SEAL | F_SEAL_FUTURE_WRITE)
             == -1) {
       std::ostringstream oss;
       oss << "Failed to protect zygote mapping: " << strerror(errno);
       *error_msg = oss.str();
       return false;
     }
   } else {
     PaletteStatus status = PaletteAshmemSetProtRegion(fd, PROT_READ);
     if (status != PaletteStatus::kOkay) {
       CHECK_EQ(status, PaletteStatus::kCheckErrno);
       std::ostringstream oss;
       oss << "Failed to protect zygote mapping: " << strerror(errno);
       *error_msg = oss.str();
       return false;
     }
   }
   return true;
 }

 #else

 // When running on non-bionic configuration, this is not supported.
 int JitMemoryRegion::CreateZygoteMemory(size_t capacity ATTRIBUTE_UNUSED,
                                         std::string* error_msg ATTRIBUTE_UNUSED) {
   return -1;
 }

 bool JitMemoryRegion::ProtectZygoteMemory(int fd ATTRIBUTE_UNUSED,
                                           std::string* error_msg ATTRIBUTE_UNUSED) {
   return true;
 }

 #endif

 }  // namespace jit
 }  // namespace art
	/*
	* Copyright 2019 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include "jit_memory_region.h"

	#include <fcntl.h>
	#include <unistd.h>

	#include <android-base/unique_fd.h>
	#include "base/bit_utils.h" // For RoundDown, RoundUp
	#include "base/globals.h"
	#include "base/logging.h" // For VLOG.
	#include "base/membarrier.h"
	#include "base/memfd.h"
	#include "base/systrace.h"
	#include "gc/allocator/dlmalloc.h"
	#include "jit/jit_scoped_code_cache_write.h"
	#include "oat_quick_method_header.h"
	#include "palette/palette.h"

	using android::base::unique_fd;

	namespace art {
	namespace jit {

	// Data cache will be half of the capacity
	// Code cache will be the other half of the capacity.
	// TODO: Make this variable?
	static constexpr size_t kCodeAndDataCapacityDivider = 2;

	bool JitMemoryRegion::Initialize(size_t initial_capacity,
	size_t max_capacity,
	bool rwx_memory_allowed,
	bool is_zygote,
	std::string* error_msg) {
	ScopedTrace trace(__PRETTY_FUNCTION__);

	CHECK_GE(max_capacity, initial_capacity);
	CHECK(max_capacity <= 1 * GB) << "The max supported size for JIT code cache is 1GB";
	// Align both capacities to page size, as that's the unit mspaces use.
	initial_capacity_ = RoundDown(initial_capacity, 2 * kPageSize);
	max_capacity_ = RoundDown(max_capacity, 2 * kPageSize);
	current_capacity_ = initial_capacity,
	data_end_ = initial_capacity / kCodeAndDataCapacityDivider;
	exec_end_ = initial_capacity - data_end_;

	const size_t capacity = max_capacity_;
	const size_t data_capacity = capacity / kCodeAndDataCapacityDivider;
	const size_t exec_capacity = capacity - data_capacity;

	// File descriptor enabling dual-view mapping of code section.
	unique_fd mem_fd;

	if (is_zygote) {
	// Because we are not going to GC code generated by the zygote, just use all available.
	current_capacity_ = max_capacity;
	mem_fd = unique_fd(CreateZygoteMemory(capacity, error_msg));
	if (mem_fd.get() < 0) {
	return false;
	}
	} else {
	// Bionic supports memfd_create, but the call may fail on older kernels.
	mem_fd = unique_fd(art::memfd_create("/jit-cache", /* flags= */ 0));
	if (mem_fd.get() < 0) {
	std::ostringstream oss;
	oss << "Failed to initialize dual view JIT. memfd_create() error: " << strerror(errno);
	if (!rwx_memory_allowed) {
	// Without using RWX page permissions, the JIT can not fallback to single mapping as it
	// requires tranitioning the code pages to RWX for updates.
	*error_msg = oss.str();
	return false;
	}
	VLOG(jit) << oss.str();
	} else if (ftruncate(mem_fd, capacity) != 0) {
	std::ostringstream oss;
	oss << "Failed to initialize memory file: " << strerror(errno);
	*error_msg = oss.str();
	return false;
	}
	}

	std::string data_cache_name = is_zygote ? "zygote-data-code-cache" : "data-code-cache";
	std::string exec_cache_name = is_zygote ? "zygote-jit-code-cache" : "jit-code-cache";

	std::string error_str;
	// Map name specific for android_os_Debug.cpp accounting.
	// Map in low 4gb to simplify accessing root tables for x86_64.
	// We could do PC-relative addressing to avoid this problem, but that
	// would require reserving code and data area before submitting, which
	// means more windows for the code memory to be RWX.
	int base_flags;
	MemMap data_pages;
	if (mem_fd.get() >= 0) {
	// Dual view of JIT code cache case. Create an initial mapping of data pages large enough
	// for data and non-writable view of JIT code pages. We use the memory file descriptor to
	// enable dual mapping - we'll create a second mapping using the descriptor below. The
	// mappings will look like:
	//
	// VA PA
	//
	// +---------------+
	// \| non exec code \|\
	// +---------------+ \
	// : :\ \
	// +---------------+.\.+---------------+
	// \| exec code \| \\| code \|
	// +---------------+...+---------------+
	// \| data \| \| data \|
	// +---------------+...+---------------+
	//
	// In this configuration code updates are written to the non-executable view of the code
	// cache, and the executable view of the code cache has fixed RX memory protections.
	//
	// This memory needs to be mapped shared as the code portions will have two mappings.
	//
	// Additionally, the zyzote will create a dual view of the data portion of
	// the cache. This mapping will be read-only, whereas the second mapping
	// will be writable.
	base_flags = MAP_SHARED;
	data_pages = MemMap::MapFile(
	data_capacity + exec_capacity,
	is_zygote ? kProtR : kProtRW,
	base_flags,
	mem_fd,
	/* start= */ 0,
	/* low_4gb= */ true,
	data_cache_name.c_str(),
	&error_str);
	} else {
	// Single view of JIT code cache case. Create an initial mapping of data pages large enough
	// for data and JIT code pages. The mappings will look like:
	//
	// VA PA
	//
	// +---------------+...+---------------+
	// \| exec code \| \| code \|
	// +---------------+...+---------------+
	// \| data \| \| data \|
	// +---------------+...+---------------+
	//
	// In this configuration code updates are written to the executable view of the code cache,
	// and the executable view of the code cache transitions RX to RWX for the update and then
	// back to RX after the update.
	base_flags = MAP_PRIVATE \| MAP_ANON;
	data_pages = MemMap::MapAnonymous(
	data_cache_name.c_str(),
	data_capacity + exec_capacity,
	kProtRW,
	/* low_4gb= */ true,
	&error_str);
	}

	if (!data_pages.IsValid()) {
	std::ostringstream oss;
	oss << "Failed to create read write cache: " << error_str << " size=" << capacity;
	*error_msg = oss.str();
	return false;
	}

	MemMap exec_pages;
	MemMap non_exec_pages;
	MemMap writable_data_pages;
	if (exec_capacity > 0) {
	uint8_t* const divider = data_pages.Begin() + data_capacity;
	// Set initial permission for executable view to catch any SELinux permission problems early
	// (for processes that cannot map WX pages). Otherwise, this region does not need to be
	// executable as there is no code in the cache yet.
	exec_pages = data_pages.RemapAtEnd(divider,
	exec_cache_name.c_str(),
	kProtRX,
	base_flags \| MAP_FIXED,
	mem_fd.get(),
	(mem_fd.get() >= 0) ? data_capacity : 0,
	&error_str);
	if (!exec_pages.IsValid()) {
	std::ostringstream oss;
	oss << "Failed to create read execute code cache: " << error_str << " size=" << capacity;
	*error_msg = oss.str();
	return false;
	}

	if (mem_fd.get() >= 0) {
	// For dual view, create the secondary view of code memory used for updating code. This view
	// is never executable.
	std::string name = exec_cache_name + "-rw";
	non_exec_pages = MemMap::MapFile(exec_capacity,
	kProtR,
	base_flags,
	mem_fd,
	/* start= */ data_capacity,
	/* low_4GB= */ false,
	name.c_str(),
	&error_str);
	if (!non_exec_pages.IsValid()) {
	static const char* kFailedNxView = "Failed to map non-executable view of JIT code cache";
	if (rwx_memory_allowed) {
	// Log and continue as single view JIT (requires RWX memory).
	VLOG(jit) << kFailedNxView;
	} else {
	*error_msg = kFailedNxView;
	return false;
	}
	}
	// For the zygote, create a dual view of the data cache.
	if (is_zygote) {
	name = data_cache_name + "-rw";
	writable_data_pages = MemMap::MapFile(data_capacity,
	kProtRW,
	base_flags,
	mem_fd,
	/* start= */ 0,
	/* low_4GB= */ false,
	name.c_str(),
	&error_str);
	if (!writable_data_pages.IsValid()) {
	std::ostringstream oss;
	oss << "Failed to create dual data view for zygote: " << error_str;
	*error_msg = oss.str();
	return false;
	}
	if (writable_data_pages.MadviseDontFork() != 0) {
	*error_msg = "Failed to madvise dont fork the writable data view";
	return false;
	}
	if (non_exec_pages.MadviseDontFork() != 0) {
	*error_msg = "Failed to madvise dont fork the writable code view";
	return false;
	}
	// Now that we have created the writable and executable mappings, prevent creating any new
	// ones.
	if (!ProtectZygoteMemory(mem_fd.get(), error_msg)) {
	return false;
	}
	}
	}
	} else {
	// Profiling only. No memory for code required.
	}

	data_pages_ = std::move(data_pages);
	exec_pages_ = std::move(exec_pages);
	non_exec_pages_ = std::move(non_exec_pages);
	writable_data_pages_ = std::move(writable_data_pages);

	VLOG(jit) << "Created JitMemoryRegion"
	<< ": data_pages=" << reinterpret_cast<void*>(data_pages_.Begin())
	<< ", exec_pages=" << reinterpret_cast<void*>(exec_pages_.Begin())
	<< ", non_exec_pages=" << reinterpret_cast<void*>(non_exec_pages_.Begin())
	<< ", writable_data_pages=" << reinterpret_cast<void*>(writable_data_pages_.Begin());

	// Now that the pages are initialized, initialize the spaces.

	// Initialize the data heap.
	data_mspace_ = create_mspace_with_base(
	HasDualDataMapping() ? writable_data_pages_.Begin() : data_pages_.Begin(),
	data_end_,
	/* locked= */ false);
	CHECK(data_mspace_ != nullptr) << "create_mspace_with_base (data) failed";

	// Initialize the code heap.
	MemMap* code_heap = nullptr;
	if (non_exec_pages_.IsValid()) {
	code_heap = &non_exec_pages_;
	} else if (exec_pages_.IsValid()) {
	code_heap = &exec_pages_;
	}
	if (code_heap != nullptr) {
	// Make all pages reserved for the code heap writable. The mspace allocator, that manages the
	// heap, will take and initialize pages in create_mspace_with_base().
	CheckedCall(mprotect, "create code heap", code_heap->Begin(), code_heap->Size(), kProtRW);
	exec_mspace_ = create_mspace_with_base(code_heap->Begin(), exec_end_, false /locked/);
	CHECK(exec_mspace_ != nullptr) << "create_mspace_with_base (exec) failed";
	SetFootprintLimit(current_capacity_);
	// Protect pages containing heap metadata. Updates to the code heap toggle write permission to
	// perform the update and there are no other times write access is required.
	CheckedCall(mprotect, "protect code heap", code_heap->Begin(), code_heap->Size(), kProtR);
	} else {
	exec_mspace_ = nullptr;
	SetFootprintLimit(current_capacity_);
	}
	return true;
	}

	void JitMemoryRegion::SetFootprintLimit(size_t new_footprint) {
	size_t data_space_footprint = new_footprint / kCodeAndDataCapacityDivider;
	DCHECK(IsAlignedParam(data_space_footprint, kPageSize));
	DCHECK_EQ(data_space_footprint * kCodeAndDataCapacityDivider, new_footprint);
	mspace_set_footprint_limit(data_mspace_, data_space_footprint);
	if (HasCodeMapping()) {
	ScopedCodeCacheWrite scc(*this);
	mspace_set_footprint_limit(exec_mspace_, new_footprint - data_space_footprint);
	}
	}

	bool JitMemoryRegion::IncreaseCodeCacheCapacity() {
	if (current_capacity_ == max_capacity_) {
	return false;
	}

	// Double the capacity if we're below 1MB, or increase it by 1MB if
	// we're above.
	if (current_capacity_ < 1 * MB) {
	current_capacity_ *= 2;
	} else {
	current_capacity_ += 1 * MB;
	}
	if (current_capacity_ > max_capacity_) {
	current_capacity_ = max_capacity_;
	}

	VLOG(jit) << "Increasing code cache capacity to " << PrettySize(current_capacity_);

	SetFootprintLimit(current_capacity_);

	return true;
	}

	// NO_THREAD_SAFETY_ANALYSIS as this is called from mspace code, at which point the lock
	// is already held.
	void* JitMemoryRegion::MoreCore(const void* mspace, intptr_t increment) NO_THREAD_SAFETY_ANALYSIS {
	if (mspace == exec_mspace_) {
	CHECK(exec_mspace_ != nullptr);
	const MemMap* const code_pages = GetUpdatableCodeMapping();
	void* result = code_pages->Begin() + exec_end_;
	exec_end_ += increment;
	return result;
	} else {
	CHECK_EQ(data_mspace_, mspace);
	const MemMap* const writable_data_pages = GetWritableDataMapping();
	void* result = writable_data_pages->Begin() + data_end_;
	data_end_ += increment;
	return result;
	}
	}

	const uint8_t* JitMemoryRegion::AllocateCode(const uint8_t* code,
	size_t code_size,
	const uint8_t* stack_map,
	bool has_should_deoptimize_flag) {
	ScopedCodeCacheWrite scc(*this);

	size_t alignment = GetInstructionSetAlignment(kRuntimeISA);
	// Ensure the header ends up at expected instruction alignment.
	size_t header_size = RoundUp(sizeof(OatQuickMethodHeader), alignment);
	size_t total_size = header_size + code_size;

	// Each allocation should be on its own set of cache lines.
	// `total_size` covers the OatQuickMethodHeader, the JIT generated machine code,
	// and any alignment padding.
	DCHECK_GT(total_size, header_size);
	uint8_t* w_memory = reinterpret_cast<uint8_t*>(
	mspace_memalign(exec_mspace_, alignment, total_size));
	if (w_memory == nullptr) {
	return nullptr;
	}
	uint8_t* x_memory = GetExecutableAddress(w_memory);
	// Ensure the header ends up at expected instruction alignment.
	DCHECK_ALIGNED_PARAM(reinterpret_cast<uintptr_t>(w_memory + header_size), alignment);
	used_memory_for_code_ += mspace_usable_size(w_memory);
	const uint8_t* result = x_memory + header_size;

	// Write the code.
	std::copy(code, code + code_size, w_memory + header_size);

	// Write the header.
	OatQuickMethodHeader* method_header =
	OatQuickMethodHeader::FromCodePointer(w_memory + header_size);
	new (method_header) OatQuickMethodHeader(
	(stack_map != nullptr) ? result - stack_map : 0u,
	code_size);
	if (has_should_deoptimize_flag) {
	method_header->SetHasShouldDeoptimizeFlag();
	}

	// Both instruction and data caches need flushing to the point of unification where both share
	// a common view of memory. Flushing the data cache ensures the dirty cachelines from the
	// newly added code are written out to the point of unification. Flushing the instruction
	// cache ensures the newly written code will be fetched from the point of unification before
	// use. Memory in the code cache is re-cycled as code is added and removed. The flushes
	// prevent stale code from residing in the instruction cache.
	//
	// Caches are flushed before write permission is removed because some ARMv8 Qualcomm kernels
	// may trigger a segfault if a page fault occurs when requesting a cache maintenance
	// operation. This is a kernel bug that we need to work around until affected devices
	// (e.g. Nexus 5X and 6P) stop being supported or their kernels are fixed.
	//
	// For reference, this behavior is caused by this commit:
	// https://android.googlesource.com/kernel/msm/+/3fbe6bc28a6b9939d0650f2f17eb5216c719950c
	//
	bool cache_flush_success = true;
	if (HasDualCodeMapping()) {
	// Flush d-cache for the non-executable mapping.
	cache_flush_success = FlushCpuCaches(w_memory, w_memory + total_size);
	}

	// Invalidate i-cache for the executable mapping.
	if (cache_flush_success) {
	cache_flush_success = FlushCpuCaches(x_memory, x_memory + total_size);
	}

	// If flushing the cache has failed, reject the allocation because we can't guarantee
	// correctness of the instructions present in the processor caches.
	if (!cache_flush_success) {
	PLOG(ERROR) << "Cache flush failed triggering code allocation failure";
	FreeCode(x_memory);
	return nullptr;
	}

	// Ensure CPU instruction pipelines are flushed for all cores. This is necessary for
	// correctness as code may still be in instruction pipelines despite the i-cache flush. It is
	// not safe to assume that changing permissions with mprotect (RX->RWX->RX) will cause a TLB
	// shootdown (incidentally invalidating the CPU pipelines by sending an IPI to all cores to
	// notify them of the TLB invalidation). Some architectures, notably ARM and ARM64, have
	// hardware support that broadcasts TLB invalidations and so their kernels have no software
	// based TLB shootdown. The sync-core flavor of membarrier was introduced in Linux 4.16 to
	// address this (see mbarrier(2)). The membarrier here will fail on prior kernels and on
	// platforms lacking the appropriate support.
	art::membarrier(art::MembarrierCommand::kPrivateExpeditedSyncCore);

	return result;
	}

	static void FillRootTable(uint8_t* roots_data, const std::vector<Handle<mirror::Object>>& roots)
	REQUIRES(Locks::jit_lock_)
	REQUIRES_SHARED(Locks::mutator_lock_) {
	GcRoot<mirror::Object>* gc_roots = reinterpret_cast<GcRoot<mirror::Object>*>(roots_data);
	const uint32_t length = roots.size();
	// Put all roots in `roots_data`.
	for (uint32_t i = 0; i < length; ++i) {
	ObjPtr<mirror::Object> object = roots[i].Get();
	gc_roots[i] = GcRoot<mirror::Object>(object);
	}
	// Store the length of the table at the end. This will allow fetching it from a stack_map
	// pointer.
	reinterpret_cast<uint32_t*>(roots_data)[length] = length;
	}

	bool JitMemoryRegion::CommitData(uint8_t* roots_data,
	const std::vector<Handle<mirror::Object>>& roots,
	const uint8_t* stack_map,
	size_t stack_map_size) {
	roots_data = GetWritableDataAddress(roots_data);
	size_t root_table_size = ComputeRootTableSize(roots.size());
	uint8_t* stack_map_data = roots_data + root_table_size;
	FillRootTable(roots_data, roots);
	memcpy(stack_map_data, stack_map, stack_map_size);
	// Flush data cache, as compiled code references literals in it.
	// TODO(oth): establish whether this is necessary.
	if (UNLIKELY(!FlushCpuCaches(roots_data, roots_data + root_table_size + stack_map_size))) {
	VLOG(jit) << "Failed to flush data in CommitData";
	return false;
	}
	return true;
	}

	void JitMemoryRegion::FreeCode(const uint8_t* code) {
	code = GetNonExecutableAddress(code);
	used_memory_for_code_ -= mspace_usable_size(code);
	mspace_free(exec_mspace_, const_cast<uint8_t*>(code));
	}

	uint8_t* JitMemoryRegion::AllocateData(size_t data_size) {
	void* result = mspace_malloc(data_mspace_, data_size);
	used_memory_for_data_ += mspace_usable_size(result);
	return reinterpret_cast<uint8_t*>(GetNonWritableDataAddress(result));
	}

	void JitMemoryRegion::FreeData(uint8_t* data) {
	data = GetWritableDataAddress(data);
	used_memory_for_data_ -= mspace_usable_size(data);
	mspace_free(data_mspace_, data);
	}

	#if defined(__BIONIC__)

	int JitMemoryRegion::CreateZygoteMemory(size_t capacity, std::string* error_msg) {
	/* Check if kernel support exists, otherwise fall back to ashmem */
	static const char* kRegionName = "/jit-zygote-cache";
	if (art::IsSealFutureWriteSupported()) {
	int fd = art::memfd_create(kRegionName, MFD_ALLOW_SEALING);
	if (fd == -1) {
	std::ostringstream oss;
	oss << "Failed to create zygote mapping: " << strerror(errno);
	*error_msg = oss.str();
	return -1;
	}

	if (ftruncate(fd, capacity) != 0) {
	std::ostringstream oss;
	oss << "Failed to create zygote mapping: " << strerror(errno);
	*error_msg = oss.str();
	return -1;
	}

	return fd;
	}

	LOG(INFO) << "Falling back to ashmem implementation for JIT zygote mapping";

	int fd;
	PaletteStatus status = PaletteAshmemCreateRegion(kRegionName, capacity, &fd);
	if (status != PaletteStatus::kOkay) {
	CHECK_EQ(status, PaletteStatus::kCheckErrno);
	std::ostringstream oss;
	oss << "Failed to create zygote mapping: " << strerror(errno);
	*error_msg = oss.str();
	return -1;
	}
	return fd;
	}

	bool JitMemoryRegion::ProtectZygoteMemory(int fd, std::string* error_msg) {
	if (art::IsSealFutureWriteSupported()) {
	if (fcntl(fd, F_ADD_SEALS, F_SEAL_SHRINK \| F_SEAL_GROW \| F_SEAL_SEAL \| F_SEAL_FUTURE_WRITE)
	== -1) {
	std::ostringstream oss;
	oss << "Failed to protect zygote mapping: " << strerror(errno);
	*error_msg = oss.str();
	return false;
	}
	} else {
	PaletteStatus status = PaletteAshmemSetProtRegion(fd, PROT_READ);
	if (status != PaletteStatus::kOkay) {
	CHECK_EQ(status, PaletteStatus::kCheckErrno);
	std::ostringstream oss;
	oss << "Failed to protect zygote mapping: " << strerror(errno);
	*error_msg = oss.str();
	return false;
	}
	}
	return true;
	}

	#else

	// When running on non-bionic configuration, this is not supported.
	int JitMemoryRegion::CreateZygoteMemory(size_t capacity ATTRIBUTE_UNUSED,
	std::string* error_msg ATTRIBUTE_UNUSED) {
	return -1;
	}

	bool JitMemoryRegion::ProtectZygoteMemory(int fd ATTRIBUTE_UNUSED,
	std::string* error_msg ATTRIBUTE_UNUSED) {
	return true;
	}

	#endif

	} // namespace jit
	} // namespace art