src/core/SkAutoMalloc.h - skia - Git at Google

 /*
  * Copyright 2016 Google Inc.
  *
  * Use of this source code is governed by a BSD-style license that can be
  * found in the LICENSE file.
  */

 #ifndef SkAutoMalloc_DEFINED
 #define SkAutoMalloc_DEFINED

 #include "include/core/SkTypes.h"
 #include "include/private/SkMacros.h"
 #include "include/private/SkMalloc.h"
 #include "include/private/SkNoncopyable.h"

 #include <memory>

 /**
  *  Manage an allocated block of heap memory. This object is the sole manager of
  *  the lifetime of the block, so the caller must not call sk_free() or delete
  *  on the block, unless release() was called.
  */
 class SkAutoMalloc : SkNoncopyable {
 public:
     explicit SkAutoMalloc(size_t size = 0)
         : fPtr(size ? sk_malloc_throw(size) : nullptr), fSize(size) {}

     /**
      *  Passed to reset to specify what happens if the requested size is smaller
      *  than the current size (and the current block was dynamically allocated).
      */
     enum OnShrink {
         /**
          *  If the requested size is smaller than the current size, and the
          *  current block is dynamically allocated, free the old block and
          *  malloc a new block of the smaller size.
          */
         kAlloc_OnShrink,

         /**
          *  If the requested size is smaller than the current size, and the
          *  current block is dynamically allocated, just return the old
          *  block.
          */
         kReuse_OnShrink
     };

     /**
      *  Reallocates the block to a new size. The ptr may or may not change.
      */
     void* reset(size_t size = 0, OnShrink shrink = kAlloc_OnShrink) {
         if (size != fSize && (size > fSize || kReuse_OnShrink != shrink)) {
             fPtr.reset(size ? sk_malloc_throw(size) : nullptr);
             fSize = size;
         }
         return fPtr.get();
     }

     /**
      *  Return the allocated block.
      */
     void* get() { return fPtr.get(); }
     const void* get() const { return fPtr.get(); }

    /** Transfer ownership of the current ptr to the caller, setting the
        internal reference to null. Note the caller is reponsible for calling
        sk_free on the returned address.
     */
     void* release() {
         fSize = 0;
         return fPtr.release();
     }

 private:
     struct WrapFree {
         void operator()(void* p) { sk_free(p); }
     };
     std::unique_ptr<void, WrapFree> fPtr;
     size_t fSize;  // can be larger than the requested size (see kReuse)
 };
 #define SkAutoMalloc(...) SK_REQUIRE_LOCAL_VAR(SkAutoMalloc)

 /**
  *  Manage an allocated block of memory. If the requested size is <= kSizeRequested (or slightly
  *  more), then the allocation will come from the stack rather than the heap. This object is the
  *  sole manager of the lifetime of the block, so the caller must not call sk_free() or delete on
  *  the block.
  */
 template <size_t kSizeRequested> class SkAutoSMalloc : SkNoncopyable {
 public:
     /**
      *  Creates initially empty storage. get() returns a ptr, but it is to a zero-byte allocation.
      *  Must call reset(size) to return an allocated block.
      */
     SkAutoSMalloc() {
         fPtr = fStorage;
         fSize = kSize;
     }

     /**
      *  Allocate a block of the specified size. If size <= kSizeRequested (or slightly more), then
      *  the allocation will come from the stack, otherwise it will be dynamically allocated.
      */
     explicit SkAutoSMalloc(size_t size) {
         fPtr = fStorage;
         fSize = kSize;
         this->reset(size);
     }

     /**
      *  Free the allocated block (if any). If the block was small enough to have been allocated on
      *  the stack, then this does nothing.
      */
     ~SkAutoSMalloc() {
         if (fPtr != (void*)fStorage) {
             sk_free(fPtr);
         }
     }

     /**
      *  Return the allocated block. May return non-null even if the block is of zero size. Since
      *  this may be on the stack or dynamically allocated, the caller must not call sk_free() on it,
      *  but must rely on SkAutoSMalloc to manage it.
      */
     void* get() const { return fPtr; }

     /**
      *  Return a new block of the requested size, freeing (as necessary) any previously allocated
      *  block. As with the constructor, if size <= kSizeRequested (or slightly more) then the return
      *  block may be allocated locally, rather than from the heap.
      */
     void* reset(size_t size,
                 SkAutoMalloc::OnShrink shrink = SkAutoMalloc::kAlloc_OnShrink,
                 bool* didChangeAlloc = nullptr) {
         size = (size < kSize) ? kSize : size;
         bool alloc = size != fSize && (SkAutoMalloc::kAlloc_OnShrink == shrink || size > fSize);
         if (didChangeAlloc) {
             *didChangeAlloc = alloc;
         }
         if (alloc) {
             if (fPtr != (void*)fStorage) {
                 sk_free(fPtr);
             }

             if (size == kSize) {
                 SkASSERT(fPtr != fStorage); // otherwise we lied when setting didChangeAlloc.
                 fPtr = fStorage;
             } else {
                 fPtr = sk_malloc_throw(size);
             }

             fSize = size;
         }
         SkASSERT(fSize >= size && fSize >= kSize);
         SkASSERT((fPtr == fStorage) || fSize > kSize);
         return fPtr;
     }

 private:
     // Align up to 32 bits.
     static const size_t kSizeAlign4 = SkAlign4(kSizeRequested);
 #if defined(SK_BUILD_FOR_GOOGLE3)
     // Stack frame size is limited for SK_BUILD_FOR_GOOGLE3. 4k is less than the actual max, but some functions
     // have multiple large stack allocations.
     static const size_t kMaxBytes = 4 * 1024;
     static const size_t kSize = kSizeRequested > kMaxBytes ? kMaxBytes : kSizeAlign4;
 #else
     static const size_t kSize = kSizeAlign4;
 #endif

     void*       fPtr;
     size_t      fSize;  // can be larger than the requested size (see kReuse)
     uint32_t    fStorage[kSize >> 2];
 };
 // Can't guard the constructor because it's a template class.

 #endif
	/*
	* Copyright 2016 Google Inc.
	*
	* Use of this source code is governed by a BSD-style license that can be
	* found in the LICENSE file.
	*/

	#ifndef SkAutoMalloc_DEFINED
	#define SkAutoMalloc_DEFINED

	#include "include/core/SkTypes.h"
	#include "include/private/SkMacros.h"
	#include "include/private/SkMalloc.h"
	#include "include/private/SkNoncopyable.h"

	#include <memory>

	/**
	* Manage an allocated block of heap memory. This object is the sole manager of
	* the lifetime of the block, so the caller must not call sk_free() or delete
	* on the block, unless release() was called.
	*/
	class SkAutoMalloc : SkNoncopyable {
	public:
	explicit SkAutoMalloc(size_t size = 0)
	: fPtr(size ? sk_malloc_throw(size) : nullptr), fSize(size) {}

	/**
	* Passed to reset to specify what happens if the requested size is smaller
	* than the current size (and the current block was dynamically allocated).
	*/
	enum OnShrink {
	/**
	* If the requested size is smaller than the current size, and the
	* current block is dynamically allocated, free the old block and
	* malloc a new block of the smaller size.
	*/
	kAlloc_OnShrink,

	/**
	* If the requested size is smaller than the current size, and the
	* current block is dynamically allocated, just return the old
	* block.
	*/
	kReuse_OnShrink
	};

	/**
	* Reallocates the block to a new size. The ptr may or may not change.
	*/
	void* reset(size_t size = 0, OnShrink shrink = kAlloc_OnShrink) {
	if (size != fSize && (size > fSize \|\| kReuse_OnShrink != shrink)) {
	fPtr.reset(size ? sk_malloc_throw(size) : nullptr);
	fSize = size;
	}
	return fPtr.get();
	}

	/**
	* Return the allocated block.
	*/
	void* get() { return fPtr.get(); }
	const void* get() const { return fPtr.get(); }

	/** Transfer ownership of the current ptr to the caller, setting the
	internal reference to null. Note the caller is reponsible for calling
	sk_free on the returned address.
	*/
	void* release() {
	fSize = 0;
	return fPtr.release();
	}

	private:
	struct WrapFree {
	void operator()(void* p) { sk_free(p); }
	};
	std::unique_ptr<void, WrapFree> fPtr;
	size_t fSize; // can be larger than the requested size (see kReuse)
	};
	#define SkAutoMalloc(...) SK_REQUIRE_LOCAL_VAR(SkAutoMalloc)

	/**
	* Manage an allocated block of memory. If the requested size is <= kSizeRequested (or slightly
	* more), then the allocation will come from the stack rather than the heap. This object is the
	* sole manager of the lifetime of the block, so the caller must not call sk_free() or delete on
	* the block.
	*/
	template <size_t kSizeRequested> class SkAutoSMalloc : SkNoncopyable {
	public:
	/**
	* Creates initially empty storage. get() returns a ptr, but it is to a zero-byte allocation.
	* Must call reset(size) to return an allocated block.
	*/
	SkAutoSMalloc() {
	fPtr = fStorage;
	fSize = kSize;
	}

	/**
	* Allocate a block of the specified size. If size <= kSizeRequested (or slightly more), then
	* the allocation will come from the stack, otherwise it will be dynamically allocated.
	*/
	explicit SkAutoSMalloc(size_t size) {
	fPtr = fStorage;
	fSize = kSize;
	this->reset(size);
	}

	/**
	* Free the allocated block (if any). If the block was small enough to have been allocated on
	* the stack, then this does nothing.
	*/
	~SkAutoSMalloc() {
	if (fPtr != (void*)fStorage) {
	sk_free(fPtr);
	}
	}

	/**
	* Return the allocated block. May return non-null even if the block is of zero size. Since
	* this may be on the stack or dynamically allocated, the caller must not call sk_free() on it,
	* but must rely on SkAutoSMalloc to manage it.
	*/
	void* get() const { return fPtr; }

	/**
	* Return a new block of the requested size, freeing (as necessary) any previously allocated
	* block. As with the constructor, if size <= kSizeRequested (or slightly more) then the return
	* block may be allocated locally, rather than from the heap.
	*/
	void* reset(size_t size,
	SkAutoMalloc::OnShrink shrink = SkAutoMalloc::kAlloc_OnShrink,
	bool* didChangeAlloc = nullptr) {
	size = (size < kSize) ? kSize : size;
	bool alloc = size != fSize && (SkAutoMalloc::kAlloc_OnShrink == shrink \|\| size > fSize);
	if (didChangeAlloc) {
	*didChangeAlloc = alloc;
	}
	if (alloc) {
	if (fPtr != (void*)fStorage) {
	sk_free(fPtr);
	}

	if (size == kSize) {
	SkASSERT(fPtr != fStorage); // otherwise we lied when setting didChangeAlloc.
	fPtr = fStorage;
	} else {
	fPtr = sk_malloc_throw(size);
	}

	fSize = size;
	}
	SkASSERT(fSize >= size && fSize >= kSize);
	SkASSERT((fPtr == fStorage) \|\| fSize > kSize);
	return fPtr;
	}

	private:
	// Align up to 32 bits.
	static const size_t kSizeAlign4 = SkAlign4(kSizeRequested);
	#if defined(SK_BUILD_FOR_GOOGLE3)
	// Stack frame size is limited for SK_BUILD_FOR_GOOGLE3. 4k is less than the actual max, but some functions
	// have multiple large stack allocations.
	static const size_t kMaxBytes = 4 * 1024;
	static const size_t kSize = kSizeRequested > kMaxBytes ? kMaxBytes : kSizeAlign4;
	#else
	static const size_t kSize = kSizeAlign4;
	#endif

	void* fPtr;
	size_t fSize; // can be larger than the requested size (see kReuse)
	uint32_t fStorage[kSize >> 2];
	};
	// Can't guard the constructor because it's a template class.

	#endif