shell/platform/fuchsia/flutter/component.cc - mirrors/engine - Git at Google

 // Copyright 2013 The Flutter Authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #include "component.h"

 #include <dlfcn.h>
 #include <fuchsia/mem/cpp/fidl.h>
 #include <lib/async-loop/cpp/loop.h>
 #include <lib/async/cpp/task.h>
 #include <lib/async/default.h>
 #include <lib/fdio/directory.h>
 #include <lib/fdio/io.h>
 #include <lib/fdio/namespace.h>
 #include <lib/ui/scenic/cpp/view_ref_pair.h>
 #include <lib/ui/scenic/cpp/view_token_pair.h>
 #include <lib/vfs/cpp/composed_service_dir.h>
 #include <lib/vfs/cpp/remote_dir.h>
 #include <lib/vfs/cpp/service.h>
 #include <sys/stat.h>
 #include <zircon/dlfcn.h>
 #include <zircon/status.h>
 #include <zircon/types.h>

 #include <memory>
 #include <regex>
 #include <sstream>

 #include "flutter/fml/mapping.h"
 #include "flutter/fml/platform/fuchsia/task_observers.h"
 #include "flutter/fml/synchronization/waitable_event.h"
 #include "flutter/fml/unique_fd.h"
 #include "flutter/runtime/dart_vm_lifecycle.h"
 #include "flutter/shell/common/switches.h"
 #include "runtime/dart/utils/files.h"
 #include "runtime/dart/utils/handle_exception.h"
 #include "runtime/dart/utils/mapped_resource.h"
 #include "runtime/dart/utils/tempfs.h"
 #include "runtime/dart/utils/vmo.h"

 // TODO(kaushikiska): Use these constants from ::llcpp::fuchsia::io
 // Can read from target object.
 constexpr uint32_t OPEN_RIGHT_READABLE = 1u;

 // Connection can map target object executable.
 constexpr uint32_t OPEN_RIGHT_EXECUTABLE = 8u;

 namespace flutter_runner {
 namespace {

 constexpr char kDataKey[] = "data";
 constexpr char kAssetsKey[] = "assets";
 constexpr char kTmpPath[] = "/tmp";
 constexpr char kServiceRootPath[] = "/svc";
 constexpr char kRunnerConfigPath[] = "/config/data/flutter_runner_config";

 class FileInNamespaceBuffer final : public fml::Mapping {
  public:
   FileInNamespaceBuffer(int namespace_fd, const char* path, bool executable)
       : address_(nullptr), size_(0) {
     fuchsia::mem::Buffer buffer;
     if (!dart_utils::VmoFromFilenameAt(namespace_fd, path, executable,
                                        &buffer)) {
       return;
     }
     if (buffer.size == 0) {
       return;
     }

     uint32_t flags = ZX_VM_PERM_READ;
     if (executable) {
       flags |= ZX_VM_PERM_EXECUTE;
     }
     uintptr_t addr;
     zx_status_t status =
         zx::vmar::root_self()->map(flags, 0, buffer.vmo, 0, buffer.size, &addr);
     if (status != ZX_OK) {
       FML_LOG(FATAL) << "Failed to map " << path << ": "
                      << zx_status_get_string(status);
     }

     address_ = reinterpret_cast<void*>(addr);
     size_ = buffer.size;
   }

   ~FileInNamespaceBuffer() {
     if (address_ != nullptr) {
       zx::vmar::root_self()->unmap(reinterpret_cast<uintptr_t>(address_),
                                    size_);
       address_ = nullptr;
       size_ = 0;
     }
   }

   // |fml::Mapping|
   const uint8_t* GetMapping() const override {
     return reinterpret_cast<const uint8_t*>(address_);
   }

   // |fml::Mapping|
   size_t GetSize() const override { return size_; }

  private:
   void* address_;
   size_t size_;

   FML_DISALLOW_COPY_AND_ASSIGN(FileInNamespaceBuffer);
 };

 std::unique_ptr<fml::Mapping> CreateWithContentsOfFile(int namespace_fd,
                                                        const char* file_path,
                                                        bool executable) {
   FML_TRACE_EVENT("flutter", "LoadFile", "path", file_path);
   return std::make_unique<FileInNamespaceBuffer>(namespace_fd, file_path,
                                                  executable);
 }

 std::unique_ptr<fml::FileMapping> MakeFileMapping(const char* path,
                                                   bool executable) {
   uint32_t flags = OPEN_RIGHT_READABLE;
   if (executable) {
     flags |= OPEN_RIGHT_EXECUTABLE;
   }

   int fd = 0;
   // The returned file descriptor is compatible with standard posix operations
   // such as close, mmap, etc. We only need to treat open/open_at specially.
   zx_status_t status = fdio_open_fd(path, flags, &fd);

   if (status != ZX_OK) {
     return nullptr;
   }

   using Protection = fml::FileMapping::Protection;

   std::initializer_list<Protection> protection_execute = {Protection::kRead,
                                                           Protection::kExecute};
   std::initializer_list<Protection> protection_read = {Protection::kRead};
   auto mapping = std::make_unique<fml::FileMapping>(
       fml::UniqueFD{fd}, executable ? protection_execute : protection_read);

   if (!mapping->IsValid()) {
     return nullptr;
   }

   return mapping;
 }

 std::string DebugLabelForURL(const std::string& url) {
   auto found = url.rfind("/");
   if (found == std::string::npos) {
     return url;
   } else {
     return {url, found + 1};
   }
 }

 }  // namespace

 void Application::ParseProgramMetadata(
     const fidl::VectorPtr<fuchsia::sys::ProgramMetadata>& program_metadata,
     std::string* data_path,
     std::string* assets_path) {
   if (!program_metadata.has_value()) {
     return;
   }
   for (const auto& pg : *program_metadata) {
     if (pg.key.compare(kDataKey) == 0) {
       *data_path = "pkg/" + pg.value;
     } else if (pg.key.compare(kAssetsKey) == 0) {
       *assets_path = "pkg/" + pg.value;
     }
   }

   // assets_path defaults to the same as data_path if omitted.
   if (assets_path->empty()) {
     *assets_path = *data_path;
   }
 }

 ActiveApplication Application::Create(
     TerminationCallback termination_callback,
     fuchsia::sys::Package package,
     fuchsia::sys::StartupInfo startup_info,
     std::shared_ptr<sys::ServiceDirectory> runner_incoming_services,
     fidl::InterfaceRequest<fuchsia::sys::ComponentController> controller) {
   auto thread = std::make_unique<fml::Thread>();
   std::unique_ptr<Application> application;

   fml::AutoResetWaitableEvent latch;
   thread->GetTaskRunner()->PostTask([&]() mutable {
     application.reset(
         new Application(std::move(termination_callback), std::move(package),
                         std::move(startup_info), runner_incoming_services,
                         std::move(controller)));
     latch.Signal();
   });

   latch.Wait();
   return {.platform_thread = std::move(thread),
           .application = std::move(application)};
 }

 Application::Application(
     TerminationCallback termination_callback,
     fuchsia::sys::Package package,
     fuchsia::sys::StartupInfo startup_info,
     std::shared_ptr<sys::ServiceDirectory> runner_incoming_services,
     fidl::InterfaceRequest<fuchsia::sys::ComponentController>
         application_controller_request)
     : termination_callback_(std::move(termination_callback)),
       debug_label_(DebugLabelForURL(startup_info.launch_info.url)),
       application_controller_(this),
       outgoing_dir_(new vfs::PseudoDir()),
       runner_incoming_services_(runner_incoming_services),
       weak_factory_(this) {
   application_controller_.set_error_handler(
       [this](zx_status_t status) { Kill(); });

   FML_DCHECK(fdio_ns_.is_valid());
   // LaunchInfo::url non-optional.
   auto& launch_info = startup_info.launch_info;

   // LaunchInfo::arguments optional.
   if (auto& arguments = launch_info.arguments) {
     settings_.dart_entrypoint_args = arguments.value();
   }

   // Determine where data and assets are stored within /pkg.
   std::string data_path;
   std::string assets_path;
   ParseProgramMetadata(startup_info.program_metadata, &data_path, &assets_path);

   if (data_path.empty()) {
     FML_DLOG(ERROR) << "Could not find a /pkg/data directory for "
                     << package.resolved_url;
     return;
   }

   // Setup /tmp to be mapped to the process-local memfs.
   dart_utils::RunnerTemp::SetupComponent(fdio_ns_.get());

   // LaunchInfo::flat_namespace optional.
   for (size_t i = 0; i < startup_info.flat_namespace.paths.size(); ++i) {
     const auto& path = startup_info.flat_namespace.paths.at(i);
     if (path == kTmpPath) {
       continue;
     }

     zx::channel dir;
     if (path == kServiceRootPath) {
       svc_ = std::make_unique<sys::ServiceDirectory>(
           std::move(startup_info.flat_namespace.directories.at(i)));
       dir = svc_->CloneChannel().TakeChannel();
     } else {
       dir = std::move(startup_info.flat_namespace.directories.at(i));
     }

     zx_handle_t dir_handle = dir.release();
     if (fdio_ns_bind(fdio_ns_.get(), path.data(), dir_handle) != ZX_OK) {
       FML_DLOG(ERROR) << "Could not bind path to namespace: " << path;
       zx_handle_close(dir_handle);
     }
   }

   {
     fml::UniqueFD ns_fd(fdio_ns_opendir(fdio_ns_.get()));
     FML_DCHECK(ns_fd.is_valid());

     constexpr mode_t mode = O_RDONLY | O_DIRECTORY;

     application_assets_directory_.reset(
         openat(ns_fd.get(), assets_path.c_str(), mode));
     FML_DCHECK(application_assets_directory_.is_valid());

     application_data_directory_.reset(
         openat(ns_fd.get(), data_path.c_str(), mode));
     FML_DCHECK(application_data_directory_.is_valid());
   }

   // TODO: LaunchInfo::out.

   // TODO: LaunchInfo::err.

   // LaunchInfo::service_request optional.
   if (launch_info.directory_request) {
     outgoing_dir_->Serve(fuchsia::io::OPEN_RIGHT_READABLE |
                              fuchsia::io::OPEN_RIGHT_WRITABLE |
                              fuchsia::io::OPEN_FLAG_DIRECTORY,
                          std::move(launch_info.directory_request));
   }

   directory_request_ = directory_ptr_.NewRequest();

   fidl::InterfaceHandle<fuchsia::io::Directory> flutter_public_dir;
   // TODO(anmittal): when fixing enumeration using new c++ vfs, make sure that
   // flutter_public_dir is only accessed once we receive OnOpen Event.
   // That will prevent FL-175 for public directory
   auto request = flutter_public_dir.NewRequest().TakeChannel();
   fdio_service_connect_at(directory_ptr_.channel().get(), "svc",
                           request.release());

   auto composed_service_dir = std::make_unique<vfs::ComposedServiceDir>();
   composed_service_dir->set_fallback(std::move(flutter_public_dir));

   // Clone and check if client is servicing the directory.
   directory_ptr_->Clone(fuchsia::io::OPEN_FLAG_DESCRIBE |
                             fuchsia::io::OPEN_RIGHT_READABLE |
                             fuchsia::io::OPEN_RIGHT_WRITABLE,
                         cloned_directory_ptr_.NewRequest());

   cloned_directory_ptr_.events().OnOpen =
       [this](zx_status_t status, std::unique_ptr<fuchsia::io::NodeInfo> info) {
         cloned_directory_ptr_.Unbind();
         if (status != ZX_OK) {
           FML_LOG(ERROR) << "could not bind out directory for flutter app("
                          << debug_label_
                          << "): " << zx_status_get_string(status);
           return;
         }
         const char* other_dirs[] = {"debug", "ctrl", "diagnostics"};
         // add other directories as RemoteDirs.
         for (auto& dir_str : other_dirs) {
           fidl::InterfaceHandle<fuchsia::io::Directory> dir;
           auto request = dir.NewRequest().TakeChannel();
           auto status = fdio_service_connect_at(directory_ptr_.channel().get(),
                                                 dir_str, request.release());
           if (status == ZX_OK) {
             outgoing_dir_->AddEntry(
                 dir_str, std::make_unique<vfs::RemoteDir>(dir.TakeChannel()));
           } else {
             FML_LOG(ERROR) << "could not add out directory entry(" << dir_str
                            << ") for flutter app(" << debug_label_
                            << "): " << zx_status_get_string(status);
           }
         }
       };

   cloned_directory_ptr_.set_error_handler(
       [this](zx_status_t status) { cloned_directory_ptr_.Unbind(); });

   // TODO: LaunchInfo::additional_services optional.

   // All launch arguments have been read. Perform service binding and
   // final settings configuration. The next call will be to create a view
   // for this application.
   composed_service_dir->AddService(
       fuchsia::ui::app::ViewProvider::Name_,
       std::make_unique<vfs::Service>(
           [this](zx::channel channel, async_dispatcher_t* dispatcher) {
             shells_bindings_.AddBinding(
                 this, fidl::InterfaceRequest<fuchsia::ui::app::ViewProvider>(
                           std::move(channel)));
           }));

   outgoing_dir_->AddEntry("svc", std::move(composed_service_dir));

   // Setup the application controller binding.
   if (application_controller_request) {
     application_controller_.Bind(std::move(application_controller_request));
   }

   // Load and use runner-specific configuration, if it exists.
   std::string json_string;
   if (dart_utils::ReadFileToString(kRunnerConfigPath, &json_string)) {
     product_config_ = FlutterRunnerProductConfiguration(json_string);
     FML_LOG(INFO) << "Successfully loaded runner configuration: "
                   << json_string;
   } else {
     FML_LOG(WARNING) << "Failed to load runner configuration from "
                      << kRunnerConfigPath << "; using default config values.";
   }

   // Load VM and application bytecode.
   // For AOT, compare with flutter_aot_app in flutter_app.gni.
   // For JIT, compare flutter_jit_runner in BUILD.gn.
   if (flutter::DartVM::IsRunningPrecompiledCode()) {
     std::shared_ptr<dart_utils::ElfSnapshot> snapshot =
         std::make_shared<dart_utils::ElfSnapshot>();
     if (snapshot->Load(application_data_directory_.get(),
                        "app_aot_snapshot.so")) {
       const uint8_t* isolate_data = snapshot->IsolateData();
       const uint8_t* isolate_instructions = snapshot->IsolateInstrs();
       const uint8_t* vm_data = snapshot->VmData();
       const uint8_t* vm_instructions = snapshot->VmInstrs();
       if (isolate_data == nullptr || isolate_instructions == nullptr ||
           vm_data == nullptr || vm_instructions == nullptr) {
         FML_LOG(FATAL) << "ELF snapshot missing AOT symbols.";
         return;
       }
       auto hold_snapshot = [snapshot](const uint8_t* _, size_t __) {};
       settings_.vm_snapshot_data = [hold_snapshot, vm_data]() {
         return std::make_unique<fml::NonOwnedMapping>(vm_data, 0,
                                                       hold_snapshot);
       };
       settings_.vm_snapshot_instr = [hold_snapshot, vm_instructions]() {
         return std::make_unique<fml::NonOwnedMapping>(vm_instructions, 0,
                                                       hold_snapshot);
       };
       settings_.isolate_snapshot_data = [hold_snapshot, isolate_data]() {
         return std::make_unique<fml::NonOwnedMapping>(isolate_data, 0,
                                                       hold_snapshot);
       };
       settings_.isolate_snapshot_instr = [hold_snapshot,
                                           isolate_instructions]() {
         return std::make_unique<fml::NonOwnedMapping>(isolate_instructions, 0,
                                                       hold_snapshot);
       };
       isolate_snapshot_ = fml::MakeRefCounted<flutter::DartSnapshot>(
           std::make_shared<fml::NonOwnedMapping>(isolate_data, 0,
                                                  hold_snapshot),
           std::make_shared<fml::NonOwnedMapping>(isolate_instructions, 0,
                                                  hold_snapshot));
     } else {
       const int namespace_fd = application_data_directory_.get();
       settings_.vm_snapshot_data = [namespace_fd]() {
         return CreateWithContentsOfFile(namespace_fd, "vm_snapshot_data.bin",
                                         false);
       };
       settings_.vm_snapshot_instr = [namespace_fd]() {
         return CreateWithContentsOfFile(namespace_fd,
                                         "vm_snapshot_instructions.bin", true);
       };
       settings_.isolate_snapshot_data = [namespace_fd]() {
         return CreateWithContentsOfFile(namespace_fd,
                                         "isolate_snapshot_data.bin", false);
       };
       settings_.isolate_snapshot_instr = [namespace_fd]() {
         return CreateWithContentsOfFile(
             namespace_fd, "isolate_snapshot_instructions.bin", true);
       };
     }
   } else {
     settings_.vm_snapshot_data = []() {
       return MakeFileMapping("/pkg/data/vm_snapshot_data.bin", false);
     };
     settings_.vm_snapshot_instr = []() {
       return MakeFileMapping("/pkg/data/vm_snapshot_instructions.bin", true);
     };

     settings_.isolate_snapshot_data = []() {
       return MakeFileMapping("/pkg/data/isolate_core_snapshot_data.bin", false);
     };
     settings_.isolate_snapshot_instr = [] {
       return MakeFileMapping("/pkg/data/isolate_core_snapshot_instructions.bin",
                              true);
     };
   }

 #if defined(DART_PRODUCT)
   settings_.enable_observatory = false;
 #else
   settings_.enable_observatory = true;

   // TODO(cbracken): pass this in as a param to allow 0.0.0.0, ::1, etc.
   settings_.observatory_host = "127.0.0.1";
 #endif

   // Controls whether category "skia" trace events are enabled.
   settings_.trace_skia = true;

   settings_.verbose_logging = true;

   settings_.advisory_script_uri = debug_label_;

   settings_.advisory_script_entrypoint = debug_label_;

   settings_.icu_data_path = "";

   settings_.assets_dir = application_assets_directory_.get();

   // Compare flutter_jit_app in flutter_app.gni.
   settings_.application_kernel_list_asset = "app.dilplist";

   settings_.log_tag = debug_label_ + std::string{"(flutter)"};

   // No asserts in debug or release product.
   // No asserts in release with flutter_profile=true (non-product)
   // Yes asserts in non-product debug.
 #if !defined(DART_PRODUCT) && (!defined(FLUTTER_PROFILE) || !defined(NDEBUG))
   // Debug mode
   settings_.disable_dart_asserts = false;
 #else
   // Release mode
   settings_.disable_dart_asserts = true;
 #endif

   // Do not leak the VM; allow it to shut down normally when the last shell
   // terminates.
   settings_.leak_vm = false;

   settings_.task_observer_add =
       std::bind(&fml::CurrentMessageLoopAddAfterTaskObserver,
                 std::placeholders::_1, std::placeholders::_2);

   settings_.task_observer_remove = std::bind(
       &fml::CurrentMessageLoopRemoveAfterTaskObserver, std::placeholders::_1);

   settings_.log_message_callback = [](const std::string& tag,
                                       const std::string& message) {
     if (tag.size() > 0) {
       std::cout << tag << ": ";
     }
     std::cout << message << std::endl;
   };

   settings_.dart_flags = {"--lazy_async_stacks"};

   // Don't collect CPU samples from Dart VM C++ code.
   settings_.dart_flags.push_back("--no_profile_vm");

   // Scale back CPU profiler sampling period on ARM64 to avoid overloading
   // the tracing engine.
 #if defined(__aarch64__)
   settings_.dart_flags.push_back("--profile_period=10000");
 #endif  // defined(__aarch64__)

   auto weak_application = weak_factory_.GetWeakPtr();
   auto platform_task_runner = fml::MessageLoop::GetCurrent().GetTaskRunner();
   const std::string component_url = package.resolved_url;
   settings_.unhandled_exception_callback = [weak_application,
                                             platform_task_runner,
                                             runner_incoming_services,
                                             component_url](
                                                const std::string& error,
                                                const std::string& stack_trace) {
     if (weak_application) {
       // TODO(cbracken): unsafe. The above check and the PostTask below are
       // happening on the UI thread. If the Application dtor and thread
       // termination happen (on the platform thread) between the previous
       // line and the next line, a crash will occur since we'll be posting
       // to a dead thread. See Runner::OnApplicationTerminate() in
       // runner.cc.
       platform_task_runner->PostTask([weak_application,
                                       runner_incoming_services, component_url,
                                       error, stack_trace]() {
         if (weak_application) {
           dart_utils::HandleException(runner_incoming_services, component_url,
                                       error, stack_trace);
         } else {
           FML_LOG(WARNING)
               << "Exception was thrown which was not caught in Flutter app: "
               << error;
         }
       });
     } else {
       FML_LOG(WARNING)
           << "Exception was thrown which was not caught in Flutter app: "
           << error;
     }
     // Ideally we would return whether HandleException returned ZX_OK, but
     // short of knowing if the exception was correctly handled, we return
     // false to have the error and stack trace printed in the logs.
     return false;
   };
 }

 Application::~Application() = default;

 const std::string& Application::GetDebugLabel() const {
   return debug_label_;
 }

 void Application::Kill() {
   application_controller_.events().OnTerminated(
       last_return_code_.second, fuchsia::sys::TerminationReason::EXITED);

   termination_callback_(this);
   // WARNING: Don't do anything past this point as this instance may have been
   // collected.
 }

 void Application::Detach() {
   application_controller_.set_error_handler(nullptr);
 }

 void Application::OnEngineTerminate(const Engine* shell_holder) {
   auto found = std::find_if(shell_holders_.begin(), shell_holders_.end(),
                             [shell_holder](const auto& holder) {
                               return holder.get() == shell_holder;
                             });

   if (found == shell_holders_.end()) {
     return;
   }

   // We may launch multiple shell in this application. However, we will
   // terminate when the last shell goes away. The error code return to the
   // application controller will be the last isolate that had an error.
   auto return_code = shell_holder->GetEngineReturnCode();
   if (return_code.has_value()) {
     last_return_code_ = {true, return_code.value()};
   }

   shell_holders_.erase(found);

   if (shell_holders_.size() == 0) {
     Kill();
     // WARNING: Don't do anything past this point because the delegate may have
     // collected this instance via the termination callback.
   }
 }

 void Application::CreateView(
     zx::eventpair token,
     fidl::InterfaceRequest<fuchsia::sys::ServiceProvider> /*incoming_services*/,
     fidl::InterfaceHandle<
         fuchsia::sys::ServiceProvider> /*outgoing_services*/) {
   auto view_ref_pair = scenic::ViewRefPair::New();
   CreateViewWithViewRef(std::move(token), std::move(view_ref_pair.control_ref),
                         std::move(view_ref_pair.view_ref));
 }

 void Application::CreateViewWithViewRef(
     zx::eventpair view_token,
     fuchsia::ui::views::ViewRefControl control_ref,
     fuchsia::ui::views::ViewRef view_ref) {
   if (!svc_) {
     FML_DLOG(ERROR)
         << "Component incoming services was invalid when attempting to "
            "create a shell for a view provider request.";
     return;
   }

   shell_holders_.emplace(std::make_unique<Engine>(
       *this,                      // delegate
       debug_label_,               // thread label
       svc_,                       // Component incoming services
       runner_incoming_services_,  // Runner incoming services
       settings_,                  // settings
       scenic::ToViewToken(std::move(view_token)),  // view token
       scenic::ViewRefPair{
           .control_ref = std::move(control_ref),
           .view_ref = std::move(view_ref),
       },
       std::move(fdio_ns_),            // FDIO namespace
       std::move(directory_request_),  // outgoing request
       product_config_                 // product configuration
       ));
 }

 #if !defined(DART_PRODUCT)
 void Application::WriteProfileToTrace() const {
   for (const auto& engine : shell_holders_) {
     engine->WriteProfileToTrace();
   }
 }
 #endif  // !defined(DART_PRODUCT)

 }  // namespace flutter_runner
	// Copyright 2013 The Flutter Authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#include "component.h"

	#include <dlfcn.h>
	#include <fuchsia/mem/cpp/fidl.h>
	#include <lib/async-loop/cpp/loop.h>
	#include <lib/async/cpp/task.h>
	#include <lib/async/default.h>
	#include <lib/fdio/directory.h>
	#include <lib/fdio/io.h>
	#include <lib/fdio/namespace.h>
	#include <lib/ui/scenic/cpp/view_ref_pair.h>
	#include <lib/ui/scenic/cpp/view_token_pair.h>
	#include <lib/vfs/cpp/composed_service_dir.h>
	#include <lib/vfs/cpp/remote_dir.h>
	#include <lib/vfs/cpp/service.h>
	#include <sys/stat.h>
	#include <zircon/dlfcn.h>
	#include <zircon/status.h>
	#include <zircon/types.h>

	#include <memory>
	#include <regex>
	#include <sstream>

	#include "flutter/fml/mapping.h"
	#include "flutter/fml/platform/fuchsia/task_observers.h"
	#include "flutter/fml/synchronization/waitable_event.h"
	#include "flutter/fml/unique_fd.h"
	#include "flutter/runtime/dart_vm_lifecycle.h"
	#include "flutter/shell/common/switches.h"
	#include "runtime/dart/utils/files.h"
	#include "runtime/dart/utils/handle_exception.h"
	#include "runtime/dart/utils/mapped_resource.h"
	#include "runtime/dart/utils/tempfs.h"
	#include "runtime/dart/utils/vmo.h"

	// TODO(kaushikiska): Use these constants from ::llcpp::fuchsia::io
	// Can read from target object.
	constexpr uint32_t OPEN_RIGHT_READABLE = 1u;

	// Connection can map target object executable.
	constexpr uint32_t OPEN_RIGHT_EXECUTABLE = 8u;

	namespace flutter_runner {
	namespace {

	constexpr char kDataKey[] = "data";
	constexpr char kAssetsKey[] = "assets";
	constexpr char kTmpPath[] = "/tmp";
	constexpr char kServiceRootPath[] = "/svc";
	constexpr char kRunnerConfigPath[] = "/config/data/flutter_runner_config";

	class FileInNamespaceBuffer final : public fml::Mapping {
	public:
	FileInNamespaceBuffer(int namespace_fd, const char* path, bool executable)
	: address_(nullptr), size_(0) {
	fuchsia::mem::Buffer buffer;
	if (!dart_utils::VmoFromFilenameAt(namespace_fd, path, executable,
	&buffer)) {
	return;
	}
	if (buffer.size == 0) {
	return;
	}

	uint32_t flags = ZX_VM_PERM_READ;
	if (executable) {
	flags \|= ZX_VM_PERM_EXECUTE;
	}
	uintptr_t addr;
	zx_status_t status =
	zx::vmar::root_self()->map(flags, 0, buffer.vmo, 0, buffer.size, &addr);
	if (status != ZX_OK) {
	FML_LOG(FATAL) << "Failed to map " << path << ": "
	<< zx_status_get_string(status);
	}

	address_ = reinterpret_cast<void*>(addr);
	size_ = buffer.size;
	}

	~FileInNamespaceBuffer() {
	if (address_ != nullptr) {
	zx::vmar::root_self()->unmap(reinterpret_cast<uintptr_t>(address_),
	size_);
	address_ = nullptr;
	size_ = 0;
	}
	}

	// \|fml::Mapping\|
	const uint8_t* GetMapping() const override {
	return reinterpret_cast<const uint8_t*>(address_);
	}

	// \|fml::Mapping\|
	size_t GetSize() const override { return size_; }

	private:
	void* address_;
	size_t size_;

	FML_DISALLOW_COPY_AND_ASSIGN(FileInNamespaceBuffer);
	};

	std::unique_ptr<fml::Mapping> CreateWithContentsOfFile(int namespace_fd,
	const char* file_path,
	bool executable) {
	FML_TRACE_EVENT("flutter", "LoadFile", "path", file_path);
	return std::make_unique<FileInNamespaceBuffer>(namespace_fd, file_path,
	executable);
	}

	std::unique_ptr<fml::FileMapping> MakeFileMapping(const char* path,
	bool executable) {
	uint32_t flags = OPEN_RIGHT_READABLE;
	if (executable) {
	flags \|= OPEN_RIGHT_EXECUTABLE;
	}

	int fd = 0;
	// The returned file descriptor is compatible with standard posix operations
	// such as close, mmap, etc. We only need to treat open/open_at specially.
	zx_status_t status = fdio_open_fd(path, flags, &fd);

	if (status != ZX_OK) {
	return nullptr;
	}

	using Protection = fml::FileMapping::Protection;

	std::initializer_list<Protection> protection_execute = {Protection::kRead,
	Protection::kExecute};
	std::initializer_list<Protection> protection_read = {Protection::kRead};
	auto mapping = std::make_unique<fml::FileMapping>(
	fml::UniqueFD{fd}, executable ? protection_execute : protection_read);

	if (!mapping->IsValid()) {
	return nullptr;
	}

	return mapping;
	}

	std::string DebugLabelForURL(const std::string& url) {
	auto found = url.rfind("/");
	if (found == std::string::npos) {
	return url;
	} else {
	return {url, found + 1};
	}
	}

	} // namespace

	void Application::ParseProgramMetadata(
	const fidl::VectorPtr<fuchsia::sys::ProgramMetadata>& program_metadata,
	std::string* data_path,
	std::string* assets_path) {
	if (!program_metadata.has_value()) {
	return;
	}
	for (const auto& pg : *program_metadata) {
	if (pg.key.compare(kDataKey) == 0) {
	*data_path = "pkg/" + pg.value;
	} else if (pg.key.compare(kAssetsKey) == 0) {
	*assets_path = "pkg/" + pg.value;
	}
	}

	// assets_path defaults to the same as data_path if omitted.
	if (assets_path->empty()) {
	assets_path = data_path;
	}
	}

	ActiveApplication Application::Create(
	TerminationCallback termination_callback,
	fuchsia::sys::Package package,
	fuchsia::sys::StartupInfo startup_info,
	std::shared_ptr<sys::ServiceDirectory> runner_incoming_services,
	fidl::InterfaceRequest<fuchsia::sys::ComponentController> controller) {
	auto thread = std::make_unique<fml::Thread>();
	std::unique_ptr<Application> application;

	fml::AutoResetWaitableEvent latch;
	thread->GetTaskRunner()->PostTask([&]() mutable {
	application.reset(
	new Application(std::move(termination_callback), std::move(package),
	std::move(startup_info), runner_incoming_services,
	std::move(controller)));
	latch.Signal();
	});

	latch.Wait();
	return {.platform_thread = std::move(thread),
	.application = std::move(application)};
	}

	Application::Application(
	TerminationCallback termination_callback,
	fuchsia::sys::Package package,
	fuchsia::sys::StartupInfo startup_info,
	std::shared_ptr<sys::ServiceDirectory> runner_incoming_services,
	fidl::InterfaceRequest<fuchsia::sys::ComponentController>
	application_controller_request)
	: termination_callback_(std::move(termination_callback)),
	debug_label_(DebugLabelForURL(startup_info.launch_info.url)),
	application_controller_(this),
	outgoing_dir_(new vfs::PseudoDir()),
	runner_incoming_services_(runner_incoming_services),
	weak_factory_(this) {
	application_controller_.set_error_handler(
	[this](zx_status_t status) { Kill(); });

	FML_DCHECK(fdio_ns_.is_valid());
	// LaunchInfo::url non-optional.
	auto& launch_info = startup_info.launch_info;

	// LaunchInfo::arguments optional.
	if (auto& arguments = launch_info.arguments) {
	settings_.dart_entrypoint_args = arguments.value();
	}

	// Determine where data and assets are stored within /pkg.
	std::string data_path;
	std::string assets_path;
	ParseProgramMetadata(startup_info.program_metadata, &data_path, &assets_path);

	if (data_path.empty()) {
	FML_DLOG(ERROR) << "Could not find a /pkg/data directory for "
	<< package.resolved_url;
	return;
	}

	// Setup /tmp to be mapped to the process-local memfs.
	dart_utils::RunnerTemp::SetupComponent(fdio_ns_.get());

	// LaunchInfo::flat_namespace optional.
	for (size_t i = 0; i < startup_info.flat_namespace.paths.size(); ++i) {
	const auto& path = startup_info.flat_namespace.paths.at(i);
	if (path == kTmpPath) {
	continue;
	}

	zx::channel dir;
	if (path == kServiceRootPath) {
	svc_ = std::make_unique<sys::ServiceDirectory>(
	std::move(startup_info.flat_namespace.directories.at(i)));
	dir = svc_->CloneChannel().TakeChannel();
	} else {
	dir = std::move(startup_info.flat_namespace.directories.at(i));
	}

	zx_handle_t dir_handle = dir.release();
	if (fdio_ns_bind(fdio_ns_.get(), path.data(), dir_handle) != ZX_OK) {
	FML_DLOG(ERROR) << "Could not bind path to namespace: " << path;
	zx_handle_close(dir_handle);
	}
	}

	{
	fml::UniqueFD ns_fd(fdio_ns_opendir(fdio_ns_.get()));
	FML_DCHECK(ns_fd.is_valid());

	constexpr mode_t mode = O_RDONLY \| O_DIRECTORY;

	application_assets_directory_.reset(
	openat(ns_fd.get(), assets_path.c_str(), mode));
	FML_DCHECK(application_assets_directory_.is_valid());

	application_data_directory_.reset(
	openat(ns_fd.get(), data_path.c_str(), mode));
	FML_DCHECK(application_data_directory_.is_valid());
	}

	// TODO: LaunchInfo::out.

	// TODO: LaunchInfo::err.

	// LaunchInfo::service_request optional.
	if (launch_info.directory_request) {
	outgoing_dir_->Serve(fuchsia::io::OPEN_RIGHT_READABLE \|
	fuchsia::io::OPEN_RIGHT_WRITABLE \|
	fuchsia::io::OPEN_FLAG_DIRECTORY,
	std::move(launch_info.directory_request));
	}

	directory_request_ = directory_ptr_.NewRequest();

	fidl::InterfaceHandle<fuchsia::io::Directory> flutter_public_dir;
	// TODO(anmittal): when fixing enumeration using new c++ vfs, make sure that
	// flutter_public_dir is only accessed once we receive OnOpen Event.
	// That will prevent FL-175 for public directory
	auto request = flutter_public_dir.NewRequest().TakeChannel();
	fdio_service_connect_at(directory_ptr_.channel().get(), "svc",
	request.release());

	auto composed_service_dir = std::make_unique<vfs::ComposedServiceDir>();
	composed_service_dir->set_fallback(std::move(flutter_public_dir));

	// Clone and check if client is servicing the directory.
	directory_ptr_->Clone(fuchsia::io::OPEN_FLAG_DESCRIBE \|
	fuchsia::io::OPEN_RIGHT_READABLE \|
	fuchsia::io::OPEN_RIGHT_WRITABLE,
	cloned_directory_ptr_.NewRequest());

	cloned_directory_ptr_.events().OnOpen =
	[this](zx_status_t status, std::unique_ptr<fuchsia::io::NodeInfo> info) {
	cloned_directory_ptr_.Unbind();
	if (status != ZX_OK) {
	FML_LOG(ERROR) << "could not bind out directory for flutter app("
	<< debug_label_
	<< "): " << zx_status_get_string(status);
	return;
	}
	const char* other_dirs[] = {"debug", "ctrl", "diagnostics"};
	// add other directories as RemoteDirs.
	for (auto& dir_str : other_dirs) {
	fidl::InterfaceHandle<fuchsia::io::Directory> dir;
	auto request = dir.NewRequest().TakeChannel();
	auto status = fdio_service_connect_at(directory_ptr_.channel().get(),
	dir_str, request.release());
	if (status == ZX_OK) {
	outgoing_dir_->AddEntry(
	dir_str, std::make_unique<vfs::RemoteDir>(dir.TakeChannel()));
	} else {
	FML_LOG(ERROR) << "could not add out directory entry(" << dir_str
	<< ") for flutter app(" << debug_label_
	<< "): " << zx_status_get_string(status);
	}
	}
	};

	cloned_directory_ptr_.set_error_handler(
	[this](zx_status_t status) { cloned_directory_ptr_.Unbind(); });

	// TODO: LaunchInfo::additional_services optional.

	// All launch arguments have been read. Perform service binding and
	// final settings configuration. The next call will be to create a view
	// for this application.
	composed_service_dir->AddService(
	fuchsia::ui::app::ViewProvider::Name_,
	std::make_unique<vfs::Service>(
	[this](zx::channel channel, async_dispatcher_t* dispatcher) {
	shells_bindings_.AddBinding(
	this, fidl::InterfaceRequest<fuchsia::ui::app::ViewProvider>(
	std::move(channel)));
	}));

	outgoing_dir_->AddEntry("svc", std::move(composed_service_dir));

	// Setup the application controller binding.
	if (application_controller_request) {
	application_controller_.Bind(std::move(application_controller_request));
	}

	// Load and use runner-specific configuration, if it exists.
	std::string json_string;
	if (dart_utils::ReadFileToString(kRunnerConfigPath, &json_string)) {
	product_config_ = FlutterRunnerProductConfiguration(json_string);
	FML_LOG(INFO) << "Successfully loaded runner configuration: "
	<< json_string;
	} else {
	FML_LOG(WARNING) << "Failed to load runner configuration from "
	<< kRunnerConfigPath << "; using default config values.";
	}

	// Load VM and application bytecode.
	// For AOT, compare with flutter_aot_app in flutter_app.gni.
	// For JIT, compare flutter_jit_runner in BUILD.gn.
	if (flutter::DartVM::IsRunningPrecompiledCode()) {
	std::shared_ptr<dart_utils::ElfSnapshot> snapshot =
	std::make_shared<dart_utils::ElfSnapshot>();
	if (snapshot->Load(application_data_directory_.get(),
	"app_aot_snapshot.so")) {
	const uint8_t* isolate_data = snapshot->IsolateData();
	const uint8_t* isolate_instructions = snapshot->IsolateInstrs();
	const uint8_t* vm_data = snapshot->VmData();
	const uint8_t* vm_instructions = snapshot->VmInstrs();
	if (isolate_data == nullptr \|\| isolate_instructions == nullptr \|\|
	vm_data == nullptr \|\| vm_instructions == nullptr) {
	FML_LOG(FATAL) << "ELF snapshot missing AOT symbols.";
	return;
	}
	auto hold_snapshot = [snapshot](const uint8_t* _, size_t __) {};
	settings_.vm_snapshot_data = [hold_snapshot, vm_data]() {
	return std::make_unique<fml::NonOwnedMapping>(vm_data, 0,
	hold_snapshot);
	};
	settings_.vm_snapshot_instr = [hold_snapshot, vm_instructions]() {
	return std::make_unique<fml::NonOwnedMapping>(vm_instructions, 0,
	hold_snapshot);
	};
	settings_.isolate_snapshot_data = [hold_snapshot, isolate_data]() {
	return std::make_unique<fml::NonOwnedMapping>(isolate_data, 0,
	hold_snapshot);
	};
	settings_.isolate_snapshot_instr = [hold_snapshot,
	isolate_instructions]() {
	return std::make_unique<fml::NonOwnedMapping>(isolate_instructions, 0,
	hold_snapshot);
	};
	isolate_snapshot_ = fml::MakeRefCounted<flutter::DartSnapshot>(
	std::make_shared<fml::NonOwnedMapping>(isolate_data, 0,
	hold_snapshot),
	std::make_shared<fml::NonOwnedMapping>(isolate_instructions, 0,
	hold_snapshot));
	} else {
	const int namespace_fd = application_data_directory_.get();
	settings_.vm_snapshot_data = [namespace_fd]() {
	return CreateWithContentsOfFile(namespace_fd, "vm_snapshot_data.bin",
	false);
	};
	settings_.vm_snapshot_instr = [namespace_fd]() {
	return CreateWithContentsOfFile(namespace_fd,
	"vm_snapshot_instructions.bin", true);
	};
	settings_.isolate_snapshot_data = [namespace_fd]() {
	return CreateWithContentsOfFile(namespace_fd,
	"isolate_snapshot_data.bin", false);
	};
	settings_.isolate_snapshot_instr = [namespace_fd]() {
	return CreateWithContentsOfFile(
	namespace_fd, "isolate_snapshot_instructions.bin", true);
	};
	}
	} else {
	settings_.vm_snapshot_data = []() {
	return MakeFileMapping("/pkg/data/vm_snapshot_data.bin", false);
	};
	settings_.vm_snapshot_instr = []() {
	return MakeFileMapping("/pkg/data/vm_snapshot_instructions.bin", true);
	};

	settings_.isolate_snapshot_data = []() {
	return MakeFileMapping("/pkg/data/isolate_core_snapshot_data.bin", false);
	};
	settings_.isolate_snapshot_instr = [] {
	return MakeFileMapping("/pkg/data/isolate_core_snapshot_instructions.bin",
	true);
	};
	}

	#if defined(DART_PRODUCT)
	settings_.enable_observatory = false;
	#else
	settings_.enable_observatory = true;

	// TODO(cbracken): pass this in as a param to allow 0.0.0.0, ::1, etc.
	settings_.observatory_host = "127.0.0.1";
	#endif

	// Controls whether category "skia" trace events are enabled.
	settings_.trace_skia = true;

	settings_.verbose_logging = true;

	settings_.advisory_script_uri = debug_label_;

	settings_.advisory_script_entrypoint = debug_label_;

	settings_.icu_data_path = "";

	settings_.assets_dir = application_assets_directory_.get();

	// Compare flutter_jit_app in flutter_app.gni.
	settings_.application_kernel_list_asset = "app.dilplist";

	settings_.log_tag = debug_label_ + std::string{"(flutter)"};

	// No asserts in debug or release product.
	// No asserts in release with flutter_profile=true (non-product)
	// Yes asserts in non-product debug.
	#if !defined(DART_PRODUCT) && (!defined(FLUTTER_PROFILE) \|\| !defined(NDEBUG))
	// Debug mode
	settings_.disable_dart_asserts = false;
	#else
	// Release mode
	settings_.disable_dart_asserts = true;
	#endif

	// Do not leak the VM; allow it to shut down normally when the last shell
	// terminates.
	settings_.leak_vm = false;

	settings_.task_observer_add =
	std::bind(&fml::CurrentMessageLoopAddAfterTaskObserver,
	std::placeholders::_1, std::placeholders::_2);

	settings_.task_observer_remove = std::bind(
	&fml::CurrentMessageLoopRemoveAfterTaskObserver, std::placeholders::_1);

	settings_.log_message_callback = [](const std::string& tag,
	const std::string& message) {
	if (tag.size() > 0) {
	std::cout << tag << ": ";
	}
	std::cout << message << std::endl;
	};

	settings_.dart_flags = {"--lazy_async_stacks"};

	// Don't collect CPU samples from Dart VM C++ code.
	settings_.dart_flags.push_back("--no_profile_vm");

	// Scale back CPU profiler sampling period on ARM64 to avoid overloading
	// the tracing engine.
	#if defined(__aarch64__)
	settings_.dart_flags.push_back("--profile_period=10000");
	#endif // defined(__aarch64__)

	auto weak_application = weak_factory_.GetWeakPtr();
	auto platform_task_runner = fml::MessageLoop::GetCurrent().GetTaskRunner();
	const std::string component_url = package.resolved_url;
	settings_.unhandled_exception_callback = [weak_application,
	platform_task_runner,
	runner_incoming_services,
	component_url](
	const std::string& error,
	const std::string& stack_trace) {
	if (weak_application) {
	// TODO(cbracken): unsafe. The above check and the PostTask below are
	// happening on the UI thread. If the Application dtor and thread
	// termination happen (on the platform thread) between the previous
	// line and the next line, a crash will occur since we'll be posting
	// to a dead thread. See Runner::OnApplicationTerminate() in
	// runner.cc.
	platform_task_runner->PostTask([weak_application,
	runner_incoming_services, component_url,
	error, stack_trace]() {
	if (weak_application) {
	dart_utils::HandleException(runner_incoming_services, component_url,
	error, stack_trace);
	} else {
	FML_LOG(WARNING)
	<< "Exception was thrown which was not caught in Flutter app: "
	<< error;
	}
	});
	} else {
	FML_LOG(WARNING)
	<< "Exception was thrown which was not caught in Flutter app: "
	<< error;
	}
	// Ideally we would return whether HandleException returned ZX_OK, but
	// short of knowing if the exception was correctly handled, we return
	// false to have the error and stack trace printed in the logs.
	return false;
	};
	}

	Application::~Application() = default;

	const std::string& Application::GetDebugLabel() const {
	return debug_label_;
	}

	void Application::Kill() {
	application_controller_.events().OnTerminated(
	last_return_code_.second, fuchsia::sys::TerminationReason::EXITED);

	termination_callback_(this);
	// WARNING: Don't do anything past this point as this instance may have been
	// collected.
	}

	void Application::Detach() {
	application_controller_.set_error_handler(nullptr);
	}

	void Application::OnEngineTerminate(const Engine* shell_holder) {
	auto found = std::find_if(shell_holders_.begin(), shell_holders_.end(),
	[shell_holder](const auto& holder) {
	return holder.get() == shell_holder;
	});

	if (found == shell_holders_.end()) {
	return;
	}

	// We may launch multiple shell in this application. However, we will
	// terminate when the last shell goes away. The error code return to the
	// application controller will be the last isolate that had an error.
	auto return_code = shell_holder->GetEngineReturnCode();
	if (return_code.has_value()) {
	last_return_code_ = {true, return_code.value()};
	}

	shell_holders_.erase(found);

	if (shell_holders_.size() == 0) {
	Kill();
	// WARNING: Don't do anything past this point because the delegate may have
	// collected this instance via the termination callback.
	}
	}

	void Application::CreateView(
	zx::eventpair token,
	fidl::InterfaceRequest<fuchsia::sys::ServiceProvider> /incoming_services/,
	fidl::InterfaceHandle<
	fuchsia::sys::ServiceProvider> /outgoing_services/) {
	auto view_ref_pair = scenic::ViewRefPair::New();
	CreateViewWithViewRef(std::move(token), std::move(view_ref_pair.control_ref),
	std::move(view_ref_pair.view_ref));
	}

	void Application::CreateViewWithViewRef(
	zx::eventpair view_token,
	fuchsia::ui::views::ViewRefControl control_ref,
	fuchsia::ui::views::ViewRef view_ref) {
	if (!svc_) {
	FML_DLOG(ERROR)
	<< "Component incoming services was invalid when attempting to "
	"create a shell for a view provider request.";
	return;
	}

	shell_holders_.emplace(std::make_unique<Engine>(
	*this, // delegate
	debug_label_, // thread label
	svc_, // Component incoming services
	runner_incoming_services_, // Runner incoming services
	settings_, // settings
	scenic::ToViewToken(std::move(view_token)), // view token
	scenic::ViewRefPair{
	.control_ref = std::move(control_ref),
	.view_ref = std::move(view_ref),
	},
	std::move(fdio_ns_), // FDIO namespace
	std::move(directory_request_), // outgoing request
	product_config_ // product configuration
	));
	}

	#if !defined(DART_PRODUCT)
	void Application::WriteProfileToTrace() const {
	for (const auto& engine : shell_holders_) {
	engine->WriteProfileToTrace();
	}
	}
	#endif // !defined(DART_PRODUCT)

	} // namespace flutter_runner