src/v8/include/v8-platform.h - cobalt - Git at Google

 // Copyright 2013 the V8 project authors. All rights reserved.
 // Use of this source code is governed by a BSD-style license that can be
 // found in the LICENSE file.

 #ifndef V8_V8_PLATFORM_H_
 #define V8_V8_PLATFORM_H_

 #include <stddef.h>
 #include <stdint.h>
 #include <stdlib.h>  // For abort.
 #include <memory>
 #include <string>

 #include "v8config.h"  // NOLINT(build/include)

 namespace v8 {

 class Isolate;

 /**
  * A Task represents a unit of work.
  */
 class Task {
  public:
   virtual ~Task() = default;

   virtual void Run() = 0;
 };

 /**
  * An IdleTask represents a unit of work to be performed in idle time.
  * The Run method is invoked with an argument that specifies the deadline in
  * seconds returned by MonotonicallyIncreasingTime().
  * The idle task is expected to complete by this deadline.
  */
 class IdleTask {
  public:
   virtual ~IdleTask() = default;
   virtual void Run(double deadline_in_seconds) = 0;
 };

 /**
  * A TaskRunner allows scheduling of tasks. The TaskRunner may still be used to
  * post tasks after the isolate gets destructed, but these tasks may not get
  * executed anymore. All tasks posted to a given TaskRunner will be invoked in
  * sequence. Tasks can be posted from any thread.
  */
 class TaskRunner {
  public:
   /**
    * Schedules a task to be invoked by this TaskRunner. The TaskRunner
    * implementation takes ownership of |task|.
    */
   virtual void PostTask(std::unique_ptr<Task> task) = 0;

   /**
    * Schedules a task to be invoked by this TaskRunner. The TaskRunner
    * implementation takes ownership of |task|. The |task| cannot be nested
    * within other task executions.
    *
    * Requires that |TaskRunner::NonNestableTasksEnabled()| is true.
    */
   virtual void PostNonNestableTask(std::unique_ptr<Task> task) {}

   /**
    * Schedules a task to be invoked by this TaskRunner. The task is scheduled
    * after the given number of seconds |delay_in_seconds|. The TaskRunner
    * implementation takes ownership of |task|.
    */
   virtual void PostDelayedTask(std::unique_ptr<Task> task,
                                double delay_in_seconds) = 0;

   /**
    * Schedules a task to be invoked by this TaskRunner. The task is scheduled
    * after the given number of seconds |delay_in_seconds|. The TaskRunner
    * implementation takes ownership of |task|. The |task| cannot be nested
    * within other task executions.
    *
    * Requires that |TaskRunner::NonNestableDelayedTasksEnabled()| is true.
    */
   virtual void PostNonNestableDelayedTask(std::unique_ptr<Task> task,
                                           double delay_in_seconds) {}

   /**
    * Schedules an idle task to be invoked by this TaskRunner. The task is
    * scheduled when the embedder is idle. Requires that
    * |TaskRunner::IdleTasksEnabled()| is true. Idle tasks may be reordered
    * relative to other task types and may be starved for an arbitrarily long
    * time if no idle time is available. The TaskRunner implementation takes
    * ownership of |task|.
    */
   virtual void PostIdleTask(std::unique_ptr<IdleTask> task) = 0;

   /**
    * Returns true if idle tasks are enabled for this TaskRunner.
    */
   virtual bool IdleTasksEnabled() = 0;

   /**
    * Returns true if non-nestable tasks are enabled for this TaskRunner.
    */
   virtual bool NonNestableTasksEnabled() const { return false; }

   /**
    * Returns true if non-nestable delayed tasks are enabled for this TaskRunner.
    */
   virtual bool NonNestableDelayedTasksEnabled() const { return false; }

   TaskRunner() = default;
   virtual ~TaskRunner() = default;

   TaskRunner(const TaskRunner&) = delete;
   TaskRunner& operator=(const TaskRunner&) = delete;
 };

 /**
  * The interface represents complex arguments to trace events.
  */
 class ConvertableToTraceFormat {
  public:
   virtual ~ConvertableToTraceFormat() = default;

   /**
    * Append the class info to the provided |out| string. The appended
    * data must be a valid JSON object. Strings must be properly quoted, and
    * escaped. There is no processing applied to the content after it is
    * appended.
    */
   virtual void AppendAsTraceFormat(std::string* out) const = 0;
 };

 /**
  * V8 Tracing controller.
  *
  * Can be implemented by an embedder to record trace events from V8.
  */
 class TracingController {
  public:
   virtual ~TracingController() = default;

   /**
    * Called by TRACE_EVENT* macros, don't call this directly.
    * The name parameter is a category group for example:
    * TRACE_EVENT0("v8,parse", "V8.Parse")
    * The pointer returned points to a value with zero or more of the bits
    * defined in CategoryGroupEnabledFlags.
    **/
   virtual const uint8_t* GetCategoryGroupEnabled(const char* name) {
     static uint8_t no = 0;
     return &no;
   }

   /**
    * Adds a trace event to the platform tracing system. These function calls are
    * usually the result of a TRACE_* macro from trace_event_common.h when
    * tracing and the category of the particular trace are enabled. It is not
    * advisable to call these functions on their own; they are really only meant
    * to be used by the trace macros. The returned handle can be used by
    * UpdateTraceEventDuration to update the duration of COMPLETE events.
    */
   virtual uint64_t AddTraceEvent(
       char phase, const uint8_t* category_enabled_flag, const char* name,
       const char* scope, uint64_t id, uint64_t bind_id, int32_t num_args,
       const char** arg_names, const uint8_t* arg_types,
       const uint64_t* arg_values,
       std::unique_ptr<ConvertableToTraceFormat>* arg_convertables,
       unsigned int flags) {
     return 0;
   }
   virtual uint64_t AddTraceEventWithTimestamp(
       char phase, const uint8_t* category_enabled_flag, const char* name,
       const char* scope, uint64_t id, uint64_t bind_id, int32_t num_args,
       const char** arg_names, const uint8_t* arg_types,
       const uint64_t* arg_values,
       std::unique_ptr<ConvertableToTraceFormat>* arg_convertables,
       unsigned int flags, int64_t timestamp) {
     return 0;
   }

   /**
    * Sets the duration field of a COMPLETE trace event. It must be called with
    * the handle returned from AddTraceEvent().
    **/
   virtual void UpdateTraceEventDuration(const uint8_t* category_enabled_flag,
                                         const char* name, uint64_t handle) {}

   class TraceStateObserver {
    public:
     virtual ~TraceStateObserver() = default;
     virtual void OnTraceEnabled() = 0;
     virtual void OnTraceDisabled() = 0;
   };

   /** Adds tracing state change observer. */
   virtual void AddTraceStateObserver(TraceStateObserver*) {}

   /** Removes tracing state change observer. */
   virtual void RemoveTraceStateObserver(TraceStateObserver*) {}
 };

 /**
  * A V8 memory page allocator.
  *
  * Can be implemented by an embedder to manage large host OS allocations.
  */
 class PageAllocator {
  public:
   virtual ~PageAllocator() = default;

   /**
    * Gets the page granularity for AllocatePages and FreePages. Addresses and
    * lengths for those calls should be multiples of AllocatePageSize().
    */
   virtual size_t AllocatePageSize() = 0;

   /**
    * Gets the page granularity for SetPermissions and ReleasePages. Addresses
    * and lengths for those calls should be multiples of CommitPageSize().
    */
   virtual size_t CommitPageSize() = 0;

   /**
    * Sets the random seed so that GetRandomMmapAddr() will generate repeatable
    * sequences of random mmap addresses.
    */
   virtual void SetRandomMmapSeed(int64_t seed) = 0;

   /**
    * Returns a randomized address, suitable for memory allocation under ASLR.
    * The address will be aligned to AllocatePageSize.
    */
   virtual void* GetRandomMmapAddr() = 0;

   /**
    * Memory permissions.
    */
   enum Permission {
     kNoAccess,
     kRead,
     kReadWrite,
     // TODO(hpayer): Remove this flag. Memory should never be rwx.
     kReadWriteExecute,
     kReadExecute
   };

   /**
    * Allocates memory in range with the given alignment and permission.
    */
   virtual void* AllocatePages(void* address, size_t length, size_t alignment,
                               Permission permissions) = 0;

   /**
    * Frees memory in a range that was allocated by a call to AllocatePages.
    */
   virtual bool FreePages(void* address, size_t length) = 0;

   /**
    * Releases memory in a range that was allocated by a call to AllocatePages.
    */
   virtual bool ReleasePages(void* address, size_t length,
                             size_t new_length) = 0;

   /**
    * Sets permissions on pages in an allocated range.
    */
   virtual bool SetPermissions(void* address, size_t length,
                               Permission permissions) = 0;

   /**
    * Frees memory in the given [address, address + size) range. address and size
    * should be operating system page-aligned. The next write to this
    * memory area brings the memory transparently back.
    */
   virtual bool DiscardSystemPages(void* address, size_t size) { return true; }
 };

 /**
  * V8 Platform abstraction layer.
  *
  * The embedder has to provide an implementation of this interface before
  * initializing the rest of V8.
  */
 class Platform {
  public:
   virtual ~Platform() = default;

   /**
    * Allows the embedder to manage memory page allocations.
    */
   virtual PageAllocator* GetPageAllocator() {
     // TODO(bbudge) Make this abstract after all embedders implement this.
     return nullptr;
   }

   /**
    * Enables the embedder to respond in cases where V8 can't allocate large
    * blocks of memory. V8 retries the failed allocation once after calling this
    * method. On success, execution continues; otherwise V8 exits with a fatal
    * error.
    * Embedder overrides of this function must NOT call back into V8.
    */
   virtual void OnCriticalMemoryPressure() {
     // TODO(bbudge) Remove this when embedders override the following method.
     // See crbug.com/634547.
   }

   /**
    * Enables the embedder to respond in cases where V8 can't allocate large
    * memory regions. The |length| parameter is the amount of memory needed.
    * Returns true if memory is now available. Returns false if no memory could
    * be made available. V8 will retry allocations until this method returns
    * false.
    *
    * Embedder overrides of this function must NOT call back into V8.
    */
   virtual bool OnCriticalMemoryPressure(size_t length) { return false; }

   /**
    * Gets the number of worker threads used by
    * Call(BlockingTask)OnWorkerThread(). This can be used to estimate the number
    * of tasks a work package should be split into. A return value of 0 means
    * that there are no worker threads available. Note that a value of 0 won't
    * prohibit V8 from posting tasks using |CallOnWorkerThread|.
    */
   virtual int NumberOfWorkerThreads() = 0;

   /**
    * Returns a TaskRunner which can be used to post a task on the foreground.
    * This function should only be called from a foreground thread.
    */
   virtual std::shared_ptr<v8::TaskRunner> GetForegroundTaskRunner(
       Isolate* isolate) = 0;

   /**
    * Schedules a task to be invoked on a worker thread.
    */
   virtual void CallOnWorkerThread(std::unique_ptr<Task> task) = 0;

   /**
    * Schedules a task that blocks the main thread to be invoked with
    * high-priority on a worker thread.
    */
   virtual void CallBlockingTaskOnWorkerThread(std::unique_ptr<Task> task) {
     // Embedders may optionally override this to process these tasks in a high
     // priority pool.
     CallOnWorkerThread(std::move(task));
   }

   /**
    * Schedules a task to be invoked with low-priority on a worker thread.
    */
   virtual void CallLowPriorityTaskOnWorkerThread(std::unique_ptr<Task> task) {
     // Embedders may optionally override this to process these tasks in a low
     // priority pool.
     CallOnWorkerThread(std::move(task));
   }

   /**
    * Schedules a task to be invoked on a worker thread after |delay_in_seconds|
    * expires.
    */
   virtual void CallDelayedOnWorkerThread(std::unique_ptr<Task> task,
                                          double delay_in_seconds) = 0;

   /**
    * Schedules a task to be invoked on a foreground thread wrt a specific
    * |isolate|. Tasks posted for the same isolate should be execute in order of
    * scheduling. The definition of "foreground" is opaque to V8.
    */
   V8_DEPRECATE_SOON(
       "Use a taskrunner acquired by GetForegroundTaskRunner instead.",
       virtual void CallOnForegroundThread(Isolate* isolate, Task* task)) = 0;

   /**
    * Schedules a task to be invoked on a foreground thread wrt a specific
    * |isolate| after the given number of seconds |delay_in_seconds|.
    * Tasks posted for the same isolate should be execute in order of
    * scheduling. The definition of "foreground" is opaque to V8.
    */
   V8_DEPRECATE_SOON(
       "Use a taskrunner acquired by GetForegroundTaskRunner instead.",
       virtual void CallDelayedOnForegroundThread(Isolate* isolate, Task* task,
                                                  double delay_in_seconds)) = 0;

   /**
    * Schedules a task to be invoked on a foreground thread wrt a specific
    * |isolate| when the embedder is idle.
    * Requires that SupportsIdleTasks(isolate) is true.
    * Idle tasks may be reordered relative to other task types and may be
    * starved for an arbitrarily long time if no idle time is available.
    * The definition of "foreground" is opaque to V8.
    */
   V8_DEPRECATE_SOON(
       "Use a taskrunner acquired by GetForegroundTaskRunner instead.",
       virtual void CallIdleOnForegroundThread(Isolate* isolate,
                                               IdleTask* task)) {
     // This must be overriden if |IdleTasksEnabled()|.
     abort();
   }

   /**
    * Returns true if idle tasks are enabled for the given |isolate|.
    */
   virtual bool IdleTasksEnabled(Isolate* isolate) {
     return false;
   }

   /**
    * Monotonically increasing time in seconds from an arbitrary fixed point in
    * the past. This function is expected to return at least
    * millisecond-precision values. For this reason,
    * it is recommended that the fixed point be no further in the past than
    * the epoch.
    **/
   virtual double MonotonicallyIncreasingTime() = 0;

   /**
    * Current wall-clock time in milliseconds since epoch.
    * This function is expected to return at least millisecond-precision values.
    */
   virtual double CurrentClockTimeMillis() = 0;

   typedef void (*StackTracePrinter)();

   /**
    * Returns a function pointer that print a stack trace of the current stack
    * on invocation. Disables printing of the stack trace if nullptr.
    */
   virtual StackTracePrinter GetStackTracePrinter() { return nullptr; }

   /**
    * Returns an instance of a v8::TracingController. This must be non-nullptr.
    */
   virtual TracingController* GetTracingController() = 0;

   /**
    * Tells the embedder to generate and upload a crashdump during an unexpected
    * but non-critical scenario.
    */
   virtual void DumpWithoutCrashing() {}

   /**
    * Lets the embedder to add crash keys.
    */
   virtual void AddCrashKey(int id, const char* name, uintptr_t value) {
     // "noop" is a valid implementation if the embedder doesn't care to log
     // additional data for crashes.
   }

  protected:
   /**
    * Default implementation of current wall-clock time in milliseconds
    * since epoch. Useful for implementing |CurrentClockTimeMillis| if
    * nothing special needed.
    */
   V8_EXPORT static double SystemClockTimeMillis();
 };

 }  // namespace v8

 #endif  // V8_V8_PLATFORM_H_
	// Copyright 2013 the V8 project authors. All rights reserved.
	// Use of this source code is governed by a BSD-style license that can be
	// found in the LICENSE file.

	#ifndef V8_V8_PLATFORM_H_
	#define V8_V8_PLATFORM_H_

	#include <stddef.h>
	#include <stdint.h>
	#include <stdlib.h> // For abort.
	#include <memory>
	#include <string>

	#include "v8config.h" // NOLINT(build/include)

	namespace v8 {

	class Isolate;

	/**
	* A Task represents a unit of work.
	*/
	class Task {
	public:
	virtual ~Task() = default;

	virtual void Run() = 0;
	};

	/**
	* An IdleTask represents a unit of work to be performed in idle time.
	* The Run method is invoked with an argument that specifies the deadline in
	* seconds returned by MonotonicallyIncreasingTime().
	* The idle task is expected to complete by this deadline.
	*/
	class IdleTask {
	public:
	virtual ~IdleTask() = default;
	virtual void Run(double deadline_in_seconds) = 0;
	};

	/**
	* A TaskRunner allows scheduling of tasks. The TaskRunner may still be used to
	* post tasks after the isolate gets destructed, but these tasks may not get
	* executed anymore. All tasks posted to a given TaskRunner will be invoked in
	* sequence. Tasks can be posted from any thread.
	*/
	class TaskRunner {
	public:
	/**
	* Schedules a task to be invoked by this TaskRunner. The TaskRunner
	* implementation takes ownership of \|task\|.
	*/
	virtual void PostTask(std::unique_ptr<Task> task) = 0;

	/**
	* Schedules a task to be invoked by this TaskRunner. The TaskRunner
	* implementation takes ownership of \|task\|. The \|task\| cannot be nested
	* within other task executions.
	*
	* Requires that \|TaskRunner::NonNestableTasksEnabled()\| is true.
	*/
	virtual void PostNonNestableTask(std::unique_ptr<Task> task) {}

	/**
	* Schedules a task to be invoked by this TaskRunner. The task is scheduled
	* after the given number of seconds \|delay_in_seconds\|. The TaskRunner
	* implementation takes ownership of \|task\|.
	*/
	virtual void PostDelayedTask(std::unique_ptr<Task> task,
	double delay_in_seconds) = 0;

	/**
	* Schedules a task to be invoked by this TaskRunner. The task is scheduled
	* after the given number of seconds \|delay_in_seconds\|. The TaskRunner
	* implementation takes ownership of \|task\|. The \|task\| cannot be nested
	* within other task executions.
	*
	* Requires that \|TaskRunner::NonNestableDelayedTasksEnabled()\| is true.
	*/
	virtual void PostNonNestableDelayedTask(std::unique_ptr<Task> task,
	double delay_in_seconds) {}

	/**
	* Schedules an idle task to be invoked by this TaskRunner. The task is
	* scheduled when the embedder is idle. Requires that
	* \|TaskRunner::IdleTasksEnabled()\| is true. Idle tasks may be reordered
	* relative to other task types and may be starved for an arbitrarily long
	* time if no idle time is available. The TaskRunner implementation takes
	* ownership of \|task\|.
	*/
	virtual void PostIdleTask(std::unique_ptr<IdleTask> task) = 0;

	/**
	* Returns true if idle tasks are enabled for this TaskRunner.
	*/
	virtual bool IdleTasksEnabled() = 0;

	/**
	* Returns true if non-nestable tasks are enabled for this TaskRunner.
	*/
	virtual bool NonNestableTasksEnabled() const { return false; }

	/**
	* Returns true if non-nestable delayed tasks are enabled for this TaskRunner.
	*/
	virtual bool NonNestableDelayedTasksEnabled() const { return false; }

	TaskRunner() = default;
	virtual ~TaskRunner() = default;

	TaskRunner(const TaskRunner&) = delete;
	TaskRunner& operator=(const TaskRunner&) = delete;
	};

	/**
	* The interface represents complex arguments to trace events.
	*/
	class ConvertableToTraceFormat {
	public:
	virtual ~ConvertableToTraceFormat() = default;

	/**
	* Append the class info to the provided \|out\| string. The appended
	* data must be a valid JSON object. Strings must be properly quoted, and
	* escaped. There is no processing applied to the content after it is
	* appended.
	*/
	virtual void AppendAsTraceFormat(std::string* out) const = 0;
	};

	/**
	* V8 Tracing controller.
	*
	* Can be implemented by an embedder to record trace events from V8.
	*/
	class TracingController {
	public:
	virtual ~TracingController() = default;

	/**
	* Called by TRACE_EVENT* macros, don't call this directly.
	* The name parameter is a category group for example:
	* TRACE_EVENT0("v8,parse", "V8.Parse")
	* The pointer returned points to a value with zero or more of the bits
	* defined in CategoryGroupEnabledFlags.
	**/
	virtual const uint8_t* GetCategoryGroupEnabled(const char* name) {
	static uint8_t no = 0;
	return &no;
	}

	/**
	* Adds a trace event to the platform tracing system. These function calls are
	* usually the result of a TRACE_* macro from trace_event_common.h when
	* tracing and the category of the particular trace are enabled. It is not
	* advisable to call these functions on their own; they are really only meant
	* to be used by the trace macros. The returned handle can be used by
	* UpdateTraceEventDuration to update the duration of COMPLETE events.
	*/
	virtual uint64_t AddTraceEvent(
	char phase, const uint8_t* category_enabled_flag, const char* name,
	const char* scope, uint64_t id, uint64_t bind_id, int32_t num_args,
	const char** arg_names, const uint8_t* arg_types,
	const uint64_t* arg_values,
	std::unique_ptr<ConvertableToTraceFormat>* arg_convertables,
	unsigned int flags) {
	return 0;
	}
	virtual uint64_t AddTraceEventWithTimestamp(
	char phase, const uint8_t* category_enabled_flag, const char* name,
	const char* scope, uint64_t id, uint64_t bind_id, int32_t num_args,
	const char** arg_names, const uint8_t* arg_types,
	const uint64_t* arg_values,
	std::unique_ptr<ConvertableToTraceFormat>* arg_convertables,
	unsigned int flags, int64_t timestamp) {
	return 0;
	}

	/**
	* Sets the duration field of a COMPLETE trace event. It must be called with
	* the handle returned from AddTraceEvent().
	**/
	virtual void UpdateTraceEventDuration(const uint8_t* category_enabled_flag,
	const char* name, uint64_t handle) {}

	class TraceStateObserver {
	public:
	virtual ~TraceStateObserver() = default;
	virtual void OnTraceEnabled() = 0;
	virtual void OnTraceDisabled() = 0;
	};

	/** Adds tracing state change observer. */
	virtual void AddTraceStateObserver(TraceStateObserver*) {}

	/** Removes tracing state change observer. */
	virtual void RemoveTraceStateObserver(TraceStateObserver*) {}
	};

	/**
	* A V8 memory page allocator.
	*
	* Can be implemented by an embedder to manage large host OS allocations.
	*/
	class PageAllocator {
	public:
	virtual ~PageAllocator() = default;

	/**
	* Gets the page granularity for AllocatePages and FreePages. Addresses and
	* lengths for those calls should be multiples of AllocatePageSize().
	*/
	virtual size_t AllocatePageSize() = 0;

	/**
	* Gets the page granularity for SetPermissions and ReleasePages. Addresses
	* and lengths for those calls should be multiples of CommitPageSize().
	*/
	virtual size_t CommitPageSize() = 0;

	/**
	* Sets the random seed so that GetRandomMmapAddr() will generate repeatable
	* sequences of random mmap addresses.
	*/
	virtual void SetRandomMmapSeed(int64_t seed) = 0;

	/**
	* Returns a randomized address, suitable for memory allocation under ASLR.
	* The address will be aligned to AllocatePageSize.
	*/
	virtual void* GetRandomMmapAddr() = 0;

	/**
	* Memory permissions.
	*/
	enum Permission {
	kNoAccess,
	kRead,
	kReadWrite,
	// TODO(hpayer): Remove this flag. Memory should never be rwx.
	kReadWriteExecute,
	kReadExecute
	};

	/**
	* Allocates memory in range with the given alignment and permission.
	*/
	virtual void* AllocatePages(void* address, size_t length, size_t alignment,
	Permission permissions) = 0;

	/**
	* Frees memory in a range that was allocated by a call to AllocatePages.
	*/
	virtual bool FreePages(void* address, size_t length) = 0;

	/**
	* Releases memory in a range that was allocated by a call to AllocatePages.
	*/
	virtual bool ReleasePages(void* address, size_t length,
	size_t new_length) = 0;

	/**
	* Sets permissions on pages in an allocated range.
	*/
	virtual bool SetPermissions(void* address, size_t length,
	Permission permissions) = 0;

	/**
	* Frees memory in the given [address, address + size) range. address and size
	* should be operating system page-aligned. The next write to this
	* memory area brings the memory transparently back.
	*/
	virtual bool DiscardSystemPages(void* address, size_t size) { return true; }
	};

	/**
	* V8 Platform abstraction layer.
	*
	* The embedder has to provide an implementation of this interface before
	* initializing the rest of V8.
	*/
	class Platform {
	public:
	virtual ~Platform() = default;

	/**
	* Allows the embedder to manage memory page allocations.
	*/
	virtual PageAllocator* GetPageAllocator() {
	// TODO(bbudge) Make this abstract after all embedders implement this.
	return nullptr;
	}

	/**
	* Enables the embedder to respond in cases where V8 can't allocate large
	* blocks of memory. V8 retries the failed allocation once after calling this
	* method. On success, execution continues; otherwise V8 exits with a fatal
	* error.
	* Embedder overrides of this function must NOT call back into V8.
	*/
	virtual void OnCriticalMemoryPressure() {
	// TODO(bbudge) Remove this when embedders override the following method.
	// See crbug.com/634547.
	}

	/**
	* Enables the embedder to respond in cases where V8 can't allocate large
	* memory regions. The \|length\| parameter is the amount of memory needed.
	* Returns true if memory is now available. Returns false if no memory could
	* be made available. V8 will retry allocations until this method returns
	* false.
	*
	* Embedder overrides of this function must NOT call back into V8.
	*/
	virtual bool OnCriticalMemoryPressure(size_t length) { return false; }

	/**
	* Gets the number of worker threads used by
	* Call(BlockingTask)OnWorkerThread(). This can be used to estimate the number
	* of tasks a work package should be split into. A return value of 0 means
	* that there are no worker threads available. Note that a value of 0 won't
	* prohibit V8 from posting tasks using \|CallOnWorkerThread\|.
	*/
	virtual int NumberOfWorkerThreads() = 0;

	/**
	* Returns a TaskRunner which can be used to post a task on the foreground.
	* This function should only be called from a foreground thread.
	*/
	virtual std::shared_ptr<v8::TaskRunner> GetForegroundTaskRunner(
	Isolate* isolate) = 0;

	/**
	* Schedules a task to be invoked on a worker thread.
	*/
	virtual void CallOnWorkerThread(std::unique_ptr<Task> task) = 0;

	/**
	* Schedules a task that blocks the main thread to be invoked with
	* high-priority on a worker thread.
	*/
	virtual void CallBlockingTaskOnWorkerThread(std::unique_ptr<Task> task) {
	// Embedders may optionally override this to process these tasks in a high
	// priority pool.
	CallOnWorkerThread(std::move(task));
	}

	/**
	* Schedules a task to be invoked with low-priority on a worker thread.
	*/
	virtual void CallLowPriorityTaskOnWorkerThread(std::unique_ptr<Task> task) {
	// Embedders may optionally override this to process these tasks in a low
	// priority pool.
	CallOnWorkerThread(std::move(task));
	}

	/**
	* Schedules a task to be invoked on a worker thread after \|delay_in_seconds\|
	* expires.
	*/
	virtual void CallDelayedOnWorkerThread(std::unique_ptr<Task> task,
	double delay_in_seconds) = 0;

	/**
	* Schedules a task to be invoked on a foreground thread wrt a specific
	* \|isolate\|. Tasks posted for the same isolate should be execute in order of
	* scheduling. The definition of "foreground" is opaque to V8.
	*/
	V8_DEPRECATE_SOON(
	"Use a taskrunner acquired by GetForegroundTaskRunner instead.",
	virtual void CallOnForegroundThread(Isolate* isolate, Task* task)) = 0;

	/**
	* Schedules a task to be invoked on a foreground thread wrt a specific
	* \|isolate\| after the given number of seconds \|delay_in_seconds\|.
	* Tasks posted for the same isolate should be execute in order of
	* scheduling. The definition of "foreground" is opaque to V8.
	*/
	V8_DEPRECATE_SOON(
	"Use a taskrunner acquired by GetForegroundTaskRunner instead.",
	virtual void CallDelayedOnForegroundThread(Isolate* isolate, Task* task,
	double delay_in_seconds)) = 0;

	/**
	* Schedules a task to be invoked on a foreground thread wrt a specific
	* \|isolate\| when the embedder is idle.
	* Requires that SupportsIdleTasks(isolate) is true.
	* Idle tasks may be reordered relative to other task types and may be
	* starved for an arbitrarily long time if no idle time is available.
	* The definition of "foreground" is opaque to V8.
	*/
	V8_DEPRECATE_SOON(
	"Use a taskrunner acquired by GetForegroundTaskRunner instead.",
	virtual void CallIdleOnForegroundThread(Isolate* isolate,
	IdleTask* task)) {
	// This must be overriden if \|IdleTasksEnabled()\|.
	abort();
	}

	/**
	* Returns true if idle tasks are enabled for the given \|isolate\|.
	*/
	virtual bool IdleTasksEnabled(Isolate* isolate) {
	return false;
	}

	/**
	* Monotonically increasing time in seconds from an arbitrary fixed point in
	* the past. This function is expected to return at least
	* millisecond-precision values. For this reason,
	* it is recommended that the fixed point be no further in the past than
	* the epoch.
	**/
	virtual double MonotonicallyIncreasingTime() = 0;

	/**
	* Current wall-clock time in milliseconds since epoch.
	* This function is expected to return at least millisecond-precision values.
	*/
	virtual double CurrentClockTimeMillis() = 0;

	typedef void (*StackTracePrinter)();

	/**
	* Returns a function pointer that print a stack trace of the current stack
	* on invocation. Disables printing of the stack trace if nullptr.
	*/
	virtual StackTracePrinter GetStackTracePrinter() { return nullptr; }

	/**
	* Returns an instance of a v8::TracingController. This must be non-nullptr.
	*/
	virtual TracingController* GetTracingController() = 0;

	/**
	* Tells the embedder to generate and upload a crashdump during an unexpected
	* but non-critical scenario.
	*/
	virtual void DumpWithoutCrashing() {}

	/**
	* Lets the embedder to add crash keys.
	*/
	virtual void AddCrashKey(int id, const char* name, uintptr_t value) {
	// "noop" is a valid implementation if the embedder doesn't care to log
	// additional data for crashes.
	}

	protected:
	/**
	* Default implementation of current wall-clock time in milliseconds
	* since epoch. Useful for implementing \|CurrentClockTimeMillis\| if
	* nothing special needed.
	*/
	V8_EXPORT static double SystemClockTimeMillis();
	};

	} // namespace v8

	#endif // V8_V8_PLATFORM_H_