third_party/v8/src/regexp/regexp-stack.h - cobalt - Git at Google

 // Copyright 2009 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_REGEXP_REGEXP_STACK_H_
 #define V8_REGEXP_REGEXP_STACK_H_

 #include "src/base/logging.h"
 #include "src/base/macros.h"
 #include "src/common/globals.h"

 namespace v8 {
 namespace internal {

 class RegExpStack;

 // Maintains a per-v8thread stack area that can be used by irregexp
 // implementation for its backtracking stack.
 // Since there is only one stack area, the Irregexp implementation is not
 // re-entrant. I.e., no regular expressions may be executed in the same thread
 // during a preempted Irregexp execution.
 class RegExpStackScope {
  public:
   // Create and delete an instance to control the life-time of a growing stack.

   // Initializes the stack memory area if necessary.
   explicit RegExpStackScope(Isolate* isolate);
   ~RegExpStackScope();  // Releases the stack if it has grown.
   RegExpStackScope(const RegExpStackScope&) = delete;
   RegExpStackScope& operator=(const RegExpStackScope&) = delete;

   RegExpStack* stack() const { return regexp_stack_; }

  private:
   RegExpStack* regexp_stack_;
 };


 class RegExpStack {
  public:
   RegExpStack();
   ~RegExpStack();
   RegExpStack(const RegExpStack&) = delete;
   RegExpStack& operator=(const RegExpStack&) = delete;

   // Number of allocated locations on the stack below the limit.
   // No sequence of pushes must be longer that this without doing a stack-limit
   // check.
   static constexpr int kStackLimitSlack = 32;

   // Gives the top of the memory used as stack.
   Address stack_base() {
     DCHECK_NE(0, thread_local_.memory_size_);
     DCHECK_EQ(thread_local_.memory_top_,
               thread_local_.memory_ + thread_local_.memory_size_);
     return reinterpret_cast<Address>(thread_local_.memory_top_);
   }

   // The total size of the memory allocated for the stack.
   size_t stack_capacity() { return thread_local_.memory_size_; }

   // If the stack pointer gets below the limit, we should react and
   // either grow the stack or report an out-of-stack exception.
   // There is only a limited number of locations below the stack limit,
   // so users of the stack should check the stack limit during any
   // sequence of pushes longer that this.
   Address* limit_address_address() { return &(thread_local_.limit_); }

   // Ensures that there is a memory area with at least the specified size.
   // If passing zero, the default/minimum size buffer is allocated.
   Address EnsureCapacity(size_t size);

   bool is_in_use() const { return thread_local_.is_in_use_; }
   void set_is_in_use(bool v) { thread_local_.is_in_use_ = v; }

   // Thread local archiving.
   static constexpr int ArchiveSpacePerThread() {
     return static_cast<int>(kThreadLocalSize);
   }
   char* ArchiveStack(char* to);
   char* RestoreStack(char* from);
   void FreeThreadResources() { thread_local_.ResetToStaticStack(this); }

   // Maximal size of allocated stack area.
   static constexpr size_t kMaximumStackSize = 64 * MB;

  private:
   // Artificial limit used when the thread-local state has been destroyed.
   static const Address kMemoryTop =
       static_cast<Address>(static_cast<uintptr_t>(-1));

   // Minimal size of dynamically-allocated stack area.
   static constexpr size_t kMinimumDynamicStackSize = 1 * KB;

   // In addition to dynamically-allocated, variable-sized stacks, we also have
   // a statically allocated and sized area that is used whenever no dynamic
   // stack is allocated. This guarantees that a stack is always available and
   // we can skip availability-checks later on.
   // It's double the slack size to ensure that we have a bit of breathing room
   // before NativeRegExpMacroAssembler::GrowStack must be called.
   static constexpr size_t kStaticStackSize =
       2 * kStackLimitSlack * kSystemPointerSize;
   byte static_stack_[kStaticStackSize] = {0};

   STATIC_ASSERT(kStaticStackSize <= kMaximumStackSize);

   // Structure holding the allocated memory, size and limit.
   struct ThreadLocal {
     explicit ThreadLocal(RegExpStack* regexp_stack) {
       ResetToStaticStack(regexp_stack);
     }

     // If memory_size_ > 0 then memory_ and memory_top_ must be non-nullptr
     // and memory_top_ = memory_ + memory_size_
     byte* memory_ = nullptr;
     byte* memory_top_ = nullptr;
     size_t memory_size_ = 0;
     Address limit_ = kNullAddress;
     bool owns_memory_ = false;  // Whether memory_ is owned and must be freed.
     bool is_in_use_ = false;    // To guard against reentrancy.

     void ResetToStaticStack(RegExpStack* regexp_stack);
     void FreeAndInvalidate();
   };
   static constexpr size_t kThreadLocalSize = sizeof(ThreadLocal);

   // Address of top of memory used as stack.
   Address memory_top_address_address() {
     return reinterpret_cast<Address>(&thread_local_.memory_top_);
   }

   // Resets the buffer if it has grown beyond the default/minimum size.
   // After this, the buffer is either the default size, or it is empty, so
   // you have to call EnsureCapacity before using it again.
   void Reset();

   ThreadLocal thread_local_;
   Isolate* isolate_;

   friend class ExternalReference;
   friend class Isolate;
   friend class RegExpStackScope;
 };

 }  // namespace internal
 }  // namespace v8

 #endif  // V8_REGEXP_REGEXP_STACK_H_
	// Copyright 2009 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_REGEXP_REGEXP_STACK_H_
	#define V8_REGEXP_REGEXP_STACK_H_

	#include "src/base/logging.h"
	#include "src/base/macros.h"
	#include "src/common/globals.h"

	namespace v8 {
	namespace internal {

	class RegExpStack;

	// Maintains a per-v8thread stack area that can be used by irregexp
	// implementation for its backtracking stack.
	// Since there is only one stack area, the Irregexp implementation is not
	// re-entrant. I.e., no regular expressions may be executed in the same thread
	// during a preempted Irregexp execution.
	class RegExpStackScope {
	public:
	// Create and delete an instance to control the life-time of a growing stack.

	// Initializes the stack memory area if necessary.
	explicit RegExpStackScope(Isolate* isolate);
	~RegExpStackScope(); // Releases the stack if it has grown.
	RegExpStackScope(const RegExpStackScope&) = delete;
	RegExpStackScope& operator=(const RegExpStackScope&) = delete;

	RegExpStack* stack() const { return regexp_stack_; }

	private:
	RegExpStack* regexp_stack_;
	};


	class RegExpStack {
	public:
	RegExpStack();
	~RegExpStack();
	RegExpStack(const RegExpStack&) = delete;
	RegExpStack& operator=(const RegExpStack&) = delete;

	// Number of allocated locations on the stack below the limit.
	// No sequence of pushes must be longer that this without doing a stack-limit
	// check.
	static constexpr int kStackLimitSlack = 32;

	// Gives the top of the memory used as stack.
	Address stack_base() {
	DCHECK_NE(0, thread_local_.memory_size_);
	DCHECK_EQ(thread_local_.memory_top_,
	thread_local_.memory_ + thread_local_.memory_size_);
	return reinterpret_cast<Address>(thread_local_.memory_top_);
	}

	// The total size of the memory allocated for the stack.
	size_t stack_capacity() { return thread_local_.memory_size_; }

	// If the stack pointer gets below the limit, we should react and
	// either grow the stack or report an out-of-stack exception.
	// There is only a limited number of locations below the stack limit,
	// so users of the stack should check the stack limit during any
	// sequence of pushes longer that this.
	Address* limit_address_address() { return &(thread_local_.limit_); }

	// Ensures that there is a memory area with at least the specified size.
	// If passing zero, the default/minimum size buffer is allocated.
	Address EnsureCapacity(size_t size);

	bool is_in_use() const { return thread_local_.is_in_use_; }
	void set_is_in_use(bool v) { thread_local_.is_in_use_ = v; }

	// Thread local archiving.
	static constexpr int ArchiveSpacePerThread() {
	return static_cast<int>(kThreadLocalSize);
	}
	char* ArchiveStack(char* to);
	char* RestoreStack(char* from);
	void FreeThreadResources() { thread_local_.ResetToStaticStack(this); }

	// Maximal size of allocated stack area.
	static constexpr size_t kMaximumStackSize = 64 * MB;

	private:
	// Artificial limit used when the thread-local state has been destroyed.
	static const Address kMemoryTop =
	static_cast<Address>(static_cast<uintptr_t>(-1));

	// Minimal size of dynamically-allocated stack area.
	static constexpr size_t kMinimumDynamicStackSize = 1 * KB;

	// In addition to dynamically-allocated, variable-sized stacks, we also have
	// a statically allocated and sized area that is used whenever no dynamic
	// stack is allocated. This guarantees that a stack is always available and
	// we can skip availability-checks later on.
	// It's double the slack size to ensure that we have a bit of breathing room
	// before NativeRegExpMacroAssembler::GrowStack must be called.
	static constexpr size_t kStaticStackSize =
	2 * kStackLimitSlack * kSystemPointerSize;
	byte static_stack_[kStaticStackSize] = {0};

	STATIC_ASSERT(kStaticStackSize <= kMaximumStackSize);

	// Structure holding the allocated memory, size and limit.
	struct ThreadLocal {
	explicit ThreadLocal(RegExpStack* regexp_stack) {
	ResetToStaticStack(regexp_stack);
	}

	// If memory_size_ > 0 then memory_ and memory_top_ must be non-nullptr
	// and memory_top_ = memory_ + memory_size_
	byte* memory_ = nullptr;
	byte* memory_top_ = nullptr;
	size_t memory_size_ = 0;
	Address limit_ = kNullAddress;
	bool owns_memory_ = false; // Whether memory_ is owned and must be freed.
	bool is_in_use_ = false; // To guard against reentrancy.

	void ResetToStaticStack(RegExpStack* regexp_stack);
	void FreeAndInvalidate();
	};
	static constexpr size_t kThreadLocalSize = sizeof(ThreadLocal);

	// Address of top of memory used as stack.
	Address memory_top_address_address() {
	return reinterpret_cast<Address>(&thread_local_.memory_top_);
	}

	// Resets the buffer if it has grown beyond the default/minimum size.
	// After this, the buffer is either the default size, or it is empty, so
	// you have to call EnsureCapacity before using it again.
	void Reset();

	ThreadLocal thread_local_;
	Isolate* isolate_;

	friend class ExternalReference;
	friend class Isolate;
	friend class RegExpStackScope;
	};

	} // namespace internal
	} // namespace v8

	#endif // V8_REGEXP_REGEXP_STACK_H_