runtime/vm/zone.h - sdk - Git at Google

 // Copyright (c) 2012, the Dart project authors.  Please see the AUTHORS file
 // for details. All rights reserved. Use of this source code is governed by a
 // BSD-style license that can be found in the LICENSE file.

 #ifndef RUNTIME_VM_ZONE_H_
 #define RUNTIME_VM_ZONE_H_

 #include "platform/utils.h"
 #include "vm/allocation.h"
 #include "vm/handles.h"
 #include "vm/memory_region.h"
 #include "vm/thread_state.h"

 namespace dart {

 // Zones support very fast allocation of small chunks of memory. The
 // chunks cannot be deallocated individually, but instead zones
 // support deallocating all chunks in one fast operation.

 class Zone {
  public:
   // Allocate an array sized to hold 'len' elements of type
   // 'ElementType'.  Checks for integer overflow when performing the
   // size computation.
   template <class ElementType>
   inline ElementType* Alloc(intptr_t len);

   // Allocates an array sized to hold 'len' elements of type
   // 'ElementType'.  The new array is initialized from the memory of
   // 'old_array' up to 'old_len'.
   template <class ElementType>
   inline ElementType* Realloc(ElementType* old_array,
                               intptr_t old_len,
                               intptr_t new_len);

   // Allocates 'size' bytes of memory in the zone; expands the zone by
   // allocating new segments of memory on demand using 'new'.
   //
   // It is preferred to use Alloc<T>() instead, as that function can
   // check for integer overflow.  If you use AllocUnsafe, you are
   // responsible for avoiding integer overflow yourself.
   inline uword AllocUnsafe(intptr_t size);

   // Make a copy of the string in the zone allocated area.
   char* MakeCopyOfString(const char* str);

   // Make a copy of the first n characters of a string in the zone
   // allocated area.
   char* MakeCopyOfStringN(const char* str, intptr_t len);

   // Concatenate strings |a| and |b|. |a| may be NULL. If |a| is not NULL,
   // |join| will be inserted between |a| and |b|.
   char* ConcatStrings(const char* a, const char* b, char join = ',');

   // TODO(zra): Remove these calls and replace them with calls to OS::SCreate
   // and OS::VSCreate.
   // These calls are deprecated. Do not add further calls to these functions.
   // instead use OS::SCreate and OS::VSCreate.
   // Make a zone-allocated string based on printf format and args.
   char* PrintToString(const char* format, ...) PRINTF_ATTRIBUTE(2, 3);
   char* VPrint(const char* format, va_list args);

   // Compute the total size of this zone. This includes wasted space that is
   // due to internal fragmentation in the segments.
   uintptr_t SizeInBytes() const;

   // Computes the amount of space used in the zone.
   uintptr_t CapacityInBytes() const;

   // Structure for managing handles allocation.
   VMHandles* handles() { return &handles_; }

   void VisitObjectPointers(ObjectPointerVisitor* visitor);

   Zone* previous() const { return previous_; }

   bool ContainsNestedZone(Zone* other) const {
     while (other != NULL) {
       if (this == other) return true;
       other = other->previous_;
     }
     return false;
   }

  private:
   Zone();
   ~Zone();  // Delete all memory associated with the zone.

   // All pointers returned from AllocateUnsafe() and New() have this alignment.
   static const intptr_t kAlignment = kDoubleSize;

   // Default initial chunk size.
   static const intptr_t kInitialChunkSize = 1 * KB;

   // Default segment size.
   static const intptr_t kSegmentSize = 64 * KB;

   // Zap value used to indicate deleted zone area (debug purposes).
   static const unsigned char kZapDeletedByte = 0x42;

   // Zap value used to indicate uninitialized zone area (debug purposes).
   static const unsigned char kZapUninitializedByte = 0xab;

   // Expand the zone to accommodate an allocation of 'size' bytes.
   uword AllocateExpand(intptr_t size);

   // Allocate a large segment.
   uword AllocateLargeSegment(intptr_t size);

   // Insert zone into zone chain, after current_zone.
   void Link(Zone* current_zone) { previous_ = current_zone; }

   // Delete all objects and free all memory allocated in the zone.
   void DeleteAll();

   // Does not actually free any memory. Enables templated containers like
   // BaseGrowableArray to use different allocators.
   template <class ElementType>
   void Free(ElementType* old_array, intptr_t len) {
 #ifdef DEBUG
     if (len > 0) {
       memset(old_array, kZapUninitializedByte, len * sizeof(ElementType));
     }
 #endif
   }

   // Dump the current allocated sizes in the zone object.
   void DumpZoneSizes();

   // Overflow check (FATAL) for array length.
   template <class ElementType>
   static inline void CheckLength(intptr_t len);

   // This buffer is used for allocation before any segments.
   // This would act as the initial stack allocated chunk so that we don't
   // end up calling malloc/free on zone scopes that allocate less than
   // kChunkSize
   COMPILE_ASSERT(kAlignment <= 8);
   ALIGN8 uint8_t buffer_[kInitialChunkSize];
   MemoryRegion initial_buffer_;

   // The free region in the current (head) segment or the initial buffer is
   // represented as the half-open interval [position, limit). The 'position'
   // variable is guaranteed to be aligned as dictated by kAlignment.
   uword position_;
   uword limit_;

   // Zone segments are internal data structures used to hold information
   // about the memory segmentations that constitute a zone. The entire
   // implementation is in zone.cc.
   class Segment;

   // The current head segment; may be NULL.
   Segment* head_;

   // List of large segments allocated in this zone; may be NULL.
   Segment* large_segments_;

   // Structure for managing handles allocation.
   VMHandles handles_;

   // Used for chaining zones in order to allow unwinding of stacks.
   Zone* previous_;

   friend class StackZone;
   friend class ApiZone;
   template <typename T, typename B, typename Allocator>
   friend class BaseGrowableArray;
   template <typename T, typename B, typename Allocator>
   friend class BaseDirectChainedHashMap;
   DISALLOW_COPY_AND_ASSIGN(Zone);
 };

 class StackZone : public StackResource {
  public:
   // Create an empty zone and set is at the current zone for the Thread.
   explicit StackZone(ThreadState* thread);

   // Delete all memory associated with the zone.
   ~StackZone();

   // Compute the total size of this zone. This includes wasted space that is
   // due to internal fragmentation in the segments.
   uintptr_t SizeInBytes() const { return zone_.SizeInBytes(); }

   // Computes the used space in the zone.
   intptr_t CapacityInBytes() const { return zone_.CapacityInBytes(); }

   Zone* GetZone() { return &zone_; }

  private:
   Zone zone_;

   template <typename T>
   friend class GrowableArray;
   template <typename T>
   friend class ZoneGrowableArray;

   DISALLOW_IMPLICIT_CONSTRUCTORS(StackZone);
 };

 inline uword Zone::AllocUnsafe(intptr_t size) {
   ASSERT(size >= 0);
   // Round up the requested size to fit the alignment.
   if (size > (kIntptrMax - kAlignment)) {
     FATAL1("Zone::Alloc: 'size' is too large: size=%" Pd "", size);
   }
   size = Utils::RoundUp(size, kAlignment);

   // Check if the requested size is available without expanding.
   uword result;
   intptr_t free_size = (limit_ - position_);
   if (free_size >= size) {
     result = position_;
     position_ += size;
   } else {
     result = AllocateExpand(size);
   }

   // Check that the result has the proper alignment and return it.
   ASSERT(Utils::IsAligned(result, kAlignment));
   return result;
 }

 template <class ElementType>
 inline void Zone::CheckLength(intptr_t len) {
   const intptr_t kElementSize = sizeof(ElementType);
   if (len > (kIntptrMax / kElementSize)) {
     FATAL2("Zone::Alloc: 'len' is too large: len=%" Pd ", kElementSize=%" Pd,
            len, kElementSize);
   }
 }

 template <class ElementType>
 inline ElementType* Zone::Alloc(intptr_t len) {
   CheckLength<ElementType>(len);
   return reinterpret_cast<ElementType*>(AllocUnsafe(len * sizeof(ElementType)));
 }

 template <class ElementType>
 inline ElementType* Zone::Realloc(ElementType* old_data,
                                   intptr_t old_len,
                                   intptr_t new_len) {
   CheckLength<ElementType>(new_len);
   const intptr_t kElementSize = sizeof(ElementType);
   uword old_end = reinterpret_cast<uword>(old_data) + (old_len * kElementSize);
   // Resize existing allocation if nothing was allocated in between...
   if (Utils::RoundUp(old_end, kAlignment) == position_) {
     uword new_end =
         reinterpret_cast<uword>(old_data) + (new_len * kElementSize);
     // ...and there is sufficient space.
     if (new_end <= limit_) {
       ASSERT(new_len >= old_len);
       position_ = Utils::RoundUp(new_end, kAlignment);
       return old_data;
     }
   }
   if (new_len <= old_len) {
     return old_data;
   }
   ElementType* new_data = Alloc<ElementType>(new_len);
   if (old_data != 0) {
     memmove(reinterpret_cast<void*>(new_data),
             reinterpret_cast<void*>(old_data), old_len * kElementSize);
   }
   return new_data;
 }

 }  // namespace dart

 #endif  // RUNTIME_VM_ZONE_H_
	// Copyright (c) 2012, the Dart project authors. Please see the AUTHORS file
	// for details. All rights reserved. Use of this source code is governed by a
	// BSD-style license that can be found in the LICENSE file.

	#ifndef RUNTIME_VM_ZONE_H_
	#define RUNTIME_VM_ZONE_H_

	#include "platform/utils.h"
	#include "vm/allocation.h"
	#include "vm/handles.h"
	#include "vm/memory_region.h"
	#include "vm/thread_state.h"

	namespace dart {

	// Zones support very fast allocation of small chunks of memory. The
	// chunks cannot be deallocated individually, but instead zones
	// support deallocating all chunks in one fast operation.

	class Zone {
	public:
	// Allocate an array sized to hold 'len' elements of type
	// 'ElementType'. Checks for integer overflow when performing the
	// size computation.
	template <class ElementType>
	inline ElementType* Alloc(intptr_t len);

	// Allocates an array sized to hold 'len' elements of type
	// 'ElementType'. The new array is initialized from the memory of
	// 'old_array' up to 'old_len'.
	template <class ElementType>
	inline ElementType* Realloc(ElementType* old_array,
	intptr_t old_len,
	intptr_t new_len);

	// Allocates 'size' bytes of memory in the zone; expands the zone by
	// allocating new segments of memory on demand using 'new'.
	//
	// It is preferred to use Alloc<T>() instead, as that function can
	// check for integer overflow. If you use AllocUnsafe, you are
	// responsible for avoiding integer overflow yourself.
	inline uword AllocUnsafe(intptr_t size);

	// Make a copy of the string in the zone allocated area.
	char* MakeCopyOfString(const char* str);

	// Make a copy of the first n characters of a string in the zone
	// allocated area.
	char* MakeCopyOfStringN(const char* str, intptr_t len);

	// Concatenate strings \|a\| and \|b\|. \|a\| may be NULL. If \|a\| is not NULL,
	// \|join\| will be inserted between \|a\| and \|b\|.
	char* ConcatStrings(const char* a, const char* b, char join = ',');

	// TODO(zra): Remove these calls and replace them with calls to OS::SCreate
	// and OS::VSCreate.
	// These calls are deprecated. Do not add further calls to these functions.
	// instead use OS::SCreate and OS::VSCreate.
	// Make a zone-allocated string based on printf format and args.
	char* PrintToString(const char* format, ...) PRINTF_ATTRIBUTE(2, 3);
	char* VPrint(const char* format, va_list args);

	// Compute the total size of this zone. This includes wasted space that is
	// due to internal fragmentation in the segments.
	uintptr_t SizeInBytes() const;

	// Computes the amount of space used in the zone.
	uintptr_t CapacityInBytes() const;

	// Structure for managing handles allocation.
	VMHandles* handles() { return &handles_; }

	void VisitObjectPointers(ObjectPointerVisitor* visitor);

	Zone* previous() const { return previous_; }

	bool ContainsNestedZone(Zone* other) const {
	while (other != NULL) {
	if (this == other) return true;
	other = other->previous_;
	}
	return false;
	}

	private:
	Zone();
	~Zone(); // Delete all memory associated with the zone.

	// All pointers returned from AllocateUnsafe() and New() have this alignment.
	static const intptr_t kAlignment = kDoubleSize;

	// Default initial chunk size.
	static const intptr_t kInitialChunkSize = 1 * KB;

	// Default segment size.
	static const intptr_t kSegmentSize = 64 * KB;

	// Zap value used to indicate deleted zone area (debug purposes).
	static const unsigned char kZapDeletedByte = 0x42;

	// Zap value used to indicate uninitialized zone area (debug purposes).
	static const unsigned char kZapUninitializedByte = 0xab;

	// Expand the zone to accommodate an allocation of 'size' bytes.
	uword AllocateExpand(intptr_t size);

	// Allocate a large segment.
	uword AllocateLargeSegment(intptr_t size);

	// Insert zone into zone chain, after current_zone.
	void Link(Zone* current_zone) { previous_ = current_zone; }

	// Delete all objects and free all memory allocated in the zone.
	void DeleteAll();

	// Does not actually free any memory. Enables templated containers like
	// BaseGrowableArray to use different allocators.
	template <class ElementType>
	void Free(ElementType* old_array, intptr_t len) {
	#ifdef DEBUG
	if (len > 0) {
	memset(old_array, kZapUninitializedByte, len * sizeof(ElementType));
	}
	#endif
	}

	// Dump the current allocated sizes in the zone object.
	void DumpZoneSizes();

	// Overflow check (FATAL) for array length.
	template <class ElementType>
	static inline void CheckLength(intptr_t len);

	// This buffer is used for allocation before any segments.
	// This would act as the initial stack allocated chunk so that we don't
	// end up calling malloc/free on zone scopes that allocate less than
	// kChunkSize
	COMPILE_ASSERT(kAlignment <= 8);
	ALIGN8 uint8_t buffer_[kInitialChunkSize];
	MemoryRegion initial_buffer_;

	// The free region in the current (head) segment or the initial buffer is
	// represented as the half-open interval [position, limit). The 'position'
	// variable is guaranteed to be aligned as dictated by kAlignment.
	uword position_;
	uword limit_;

	// Zone segments are internal data structures used to hold information
	// about the memory segmentations that constitute a zone. The entire
	// implementation is in zone.cc.
	class Segment;

	// The current head segment; may be NULL.
	Segment* head_;

	// List of large segments allocated in this zone; may be NULL.
	Segment* large_segments_;

	// Structure for managing handles allocation.
	VMHandles handles_;

	// Used for chaining zones in order to allow unwinding of stacks.
	Zone* previous_;

	friend class StackZone;
	friend class ApiZone;
	template <typename T, typename B, typename Allocator>
	friend class BaseGrowableArray;
	template <typename T, typename B, typename Allocator>
	friend class BaseDirectChainedHashMap;
	DISALLOW_COPY_AND_ASSIGN(Zone);
	};

	class StackZone : public StackResource {
	public:
	// Create an empty zone and set is at the current zone for the Thread.
	explicit StackZone(ThreadState* thread);

	// Delete all memory associated with the zone.
	~StackZone();

	// Compute the total size of this zone. This includes wasted space that is
	// due to internal fragmentation in the segments.
	uintptr_t SizeInBytes() const { return zone_.SizeInBytes(); }

	// Computes the used space in the zone.
	intptr_t CapacityInBytes() const { return zone_.CapacityInBytes(); }

	Zone* GetZone() { return &zone_; }

	private:
	Zone zone_;

	template <typename T>
	friend class GrowableArray;
	template <typename T>
	friend class ZoneGrowableArray;

	DISALLOW_IMPLICIT_CONSTRUCTORS(StackZone);
	};

	inline uword Zone::AllocUnsafe(intptr_t size) {
	ASSERT(size >= 0);
	// Round up the requested size to fit the alignment.
	if (size > (kIntptrMax - kAlignment)) {
	FATAL1("Zone::Alloc: 'size' is too large: size=%" Pd "", size);
	}
	size = Utils::RoundUp(size, kAlignment);

	// Check if the requested size is available without expanding.
	uword result;
	intptr_t free_size = (limit_ - position_);
	if (free_size >= size) {
	result = position_;
	position_ += size;
	} else {
	result = AllocateExpand(size);
	}

	// Check that the result has the proper alignment and return it.
	ASSERT(Utils::IsAligned(result, kAlignment));
	return result;
	}

	template <class ElementType>
	inline void Zone::CheckLength(intptr_t len) {
	const intptr_t kElementSize = sizeof(ElementType);
	if (len > (kIntptrMax / kElementSize)) {
	FATAL2("Zone::Alloc: 'len' is too large: len=%" Pd ", kElementSize=%" Pd,
	len, kElementSize);
	}
	}

	template <class ElementType>
	inline ElementType* Zone::Alloc(intptr_t len) {
	CheckLength<ElementType>(len);
	return reinterpret_cast<ElementType>(AllocUnsafe(len sizeof(ElementType)));
	}

	template <class ElementType>
	inline ElementType* Zone::Realloc(ElementType* old_data,
	intptr_t old_len,
	intptr_t new_len) {
	CheckLength<ElementType>(new_len);
	const intptr_t kElementSize = sizeof(ElementType);
	uword old_end = reinterpret_cast<uword>(old_data) + (old_len * kElementSize);
	// Resize existing allocation if nothing was allocated in between...
	if (Utils::RoundUp(old_end, kAlignment) == position_) {
	uword new_end =
	reinterpret_cast<uword>(old_data) + (new_len * kElementSize);
	// ...and there is sufficient space.
	if (new_end <= limit_) {
	ASSERT(new_len >= old_len);
	position_ = Utils::RoundUp(new_end, kAlignment);
	return old_data;
	}
	}
	if (new_len <= old_len) {
	return old_data;
	}
	ElementType* new_data = Alloc<ElementType>(new_len);
	if (old_data != 0) {
	memmove(reinterpret_cast<void*>(new_data),
	reinterpret_cast<void>(old_data), old_len kElementSize);
	}
	return new_data;
	}

	} // namespace dart

	#endif // RUNTIME_VM_ZONE_H_