6613cc5186
This is more consistent with our other SK_BUILD_FOR_... macros, and less likely to collide with other preprocessor logic. (Luckily, this was defined in public.bzl, so we can do this all in one CL in the Skia repo.) Change-Id: I5f232888288c9c53fad445545d983d0fb0b4add8 Reviewed-on: https://skia-review.googlesource.com/86940 Reviewed-by: Mike Klein <mtklein@chromium.org> Commit-Queue: Mike Klein <mtklein@chromium.org>
498 lines
14 KiB
C++
498 lines
14 KiB
C++
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/*
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* Copyright 2006 The Android Open Source Project
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*
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* Use of this source code is governed by a BSD-style license that can be
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* found in the LICENSE file.
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*/
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#ifndef SkTemplates_DEFINED
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#define SkTemplates_DEFINED
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#include "SkMath.h"
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#include "SkMalloc.h"
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#include "SkTLogic.h"
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#include "SkTypes.h"
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#include <limits.h>
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#include <memory>
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#include <new>
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/** \file SkTemplates.h
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This file contains light-weight template classes for type-safe and exception-safe
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resource management.
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*/
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/**
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* Marks a local variable as known to be unused (to avoid warnings).
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* Note that this does *not* prevent the local variable from being optimized away.
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*/
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template<typename T> inline void sk_ignore_unused_variable(const T&) { }
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/**
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* Returns a pointer to a D which comes immediately after S[count].
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*/
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template <typename D, typename S> static D* SkTAfter(S* ptr, size_t count = 1) {
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return reinterpret_cast<D*>(ptr + count);
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}
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/**
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* Returns a pointer to a D which comes byteOffset bytes after S.
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*/
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template <typename D, typename S> static D* SkTAddOffset(S* ptr, size_t byteOffset) {
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// The intermediate char* has the same cv-ness as D as this produces better error messages.
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// This relies on the fact that reinterpret_cast can add constness, but cannot remove it.
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return reinterpret_cast<D*>(reinterpret_cast<sknonstd::same_cv_t<char, D>*>(ptr) + byteOffset);
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}
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template <typename R, typename T, R (*P)(T*)> struct SkFunctionWrapper {
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R operator()(T* t) { return P(t); }
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};
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/** \class SkAutoTCallVProc
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Call a function when this goes out of scope. The template uses two
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parameters, the object, and a function that is to be called in the destructor.
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If release() is called, the object reference is set to null. If the object
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reference is null when the destructor is called, we do not call the
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function.
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*/
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template <typename T, void (*P)(T*)> class SkAutoTCallVProc
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: public std::unique_ptr<T, SkFunctionWrapper<void, T, P>> {
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public:
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SkAutoTCallVProc(T* obj): std::unique_ptr<T, SkFunctionWrapper<void, T, P>>(obj) {}
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operator T*() const { return this->get(); }
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};
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/** \class SkAutoTCallIProc
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Call a function when this goes out of scope. The template uses two
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parameters, the object, and a function that is to be called in the destructor.
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If release() is called, the object reference is set to null. If the object
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reference is null when the destructor is called, we do not call the
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function.
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*/
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template <typename T, int (*P)(T*)> class SkAutoTCallIProc
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: public std::unique_ptr<T, SkFunctionWrapper<int, T, P>> {
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public:
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SkAutoTCallIProc(T* obj): std::unique_ptr<T, SkFunctionWrapper<int, T, P>>(obj) {}
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operator T*() const { return this->get(); }
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};
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/** Allocate an array of T elements, and free the array in the destructor
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*/
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template <typename T> class SkAutoTArray : SkNoncopyable {
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public:
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SkAutoTArray() {
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fArray = nullptr;
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SkDEBUGCODE(fCount = 0;)
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}
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/** Allocate count number of T elements
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*/
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explicit SkAutoTArray(int count) {
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SkASSERT(count >= 0);
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fArray = nullptr;
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if (count) {
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fArray = new T[count];
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}
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SkDEBUGCODE(fCount = count;)
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}
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/** Reallocates given a new count. Reallocation occurs even if new count equals old count.
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*/
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void reset(int count) {
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delete[] fArray;
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SkASSERT(count >= 0);
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fArray = nullptr;
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if (count) {
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fArray = new T[count];
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}
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SkDEBUGCODE(fCount = count;)
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}
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~SkAutoTArray() { delete[] fArray; }
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/** Return the array of T elements. Will be NULL if count == 0
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*/
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T* get() const { return fArray; }
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/** Return the nth element in the array
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*/
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T& operator[](int index) const {
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SkASSERT((unsigned)index < (unsigned)fCount);
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return fArray[index];
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}
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void swap(SkAutoTArray& other) {
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SkTSwap(fArray, other.fArray);
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SkDEBUGCODE(SkTSwap(fCount, other.fCount));
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}
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private:
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T* fArray;
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SkDEBUGCODE(int fCount;)
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};
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/** Wraps SkAutoTArray, with room for kCountRequested elements preallocated.
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*/
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template <int kCountRequested, typename T> class SkAutoSTArray : SkNoncopyable {
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public:
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/** Initialize with no objects */
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SkAutoSTArray() {
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fArray = nullptr;
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fCount = 0;
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}
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/** Allocate count number of T elements
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*/
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SkAutoSTArray(int count) {
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fArray = nullptr;
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fCount = 0;
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this->reset(count);
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}
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~SkAutoSTArray() {
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this->reset(0);
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}
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/** Destroys previous objects in the array and default constructs count number of objects */
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void reset(int count) {
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T* start = fArray;
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T* iter = start + fCount;
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while (iter > start) {
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(--iter)->~T();
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}
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SkASSERT(count >= 0);
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if (fCount != count) {
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if (fCount > kCount) {
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// 'fArray' was allocated last time so free it now
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SkASSERT((T*) fStorage != fArray);
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sk_free(fArray);
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}
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if (count > kCount) {
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const uint64_t size64 = sk_64_mul(count, sizeof(T));
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const size_t size = static_cast<size_t>(size64);
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if (size != size64) {
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sk_out_of_memory();
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}
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fArray = (T*) sk_malloc_throw(size);
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} else if (count > 0) {
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fArray = (T*) fStorage;
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} else {
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fArray = nullptr;
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}
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fCount = count;
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}
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iter = fArray;
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T* stop = fArray + count;
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while (iter < stop) {
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new (iter++) T;
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}
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}
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/** Return the number of T elements in the array
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*/
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int count() const { return fCount; }
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/** Return the array of T elements. Will be NULL if count == 0
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*/
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T* get() const { return fArray; }
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T* begin() { return fArray; }
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const T* begin() const { return fArray; }
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T* end() { return fArray + fCount; }
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const T* end() const { return fArray + fCount; }
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/** Return the nth element in the array
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*/
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T& operator[](int index) const {
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SkASSERT(index < fCount);
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return fArray[index];
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}
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private:
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#if defined(SK_BUILD_FOR_GOOGLE3)
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// Stack frame size is limited for SK_BUILD_FOR_GOOGLE3. 4k is less than the actual max, but some functions
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// have multiple large stack allocations.
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static const int kMaxBytes = 4 * 1024;
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static const int kCount = kCountRequested * sizeof(T) > kMaxBytes
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? kMaxBytes / sizeof(T)
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: kCountRequested;
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#else
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static const int kCount = kCountRequested;
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#endif
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int fCount;
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T* fArray;
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// since we come right after fArray, fStorage should be properly aligned
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char fStorage[kCount * sizeof(T)];
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};
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/** Manages an array of T elements, freeing the array in the destructor.
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* Does NOT call any constructors/destructors on T (T must be POD).
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*/
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template <typename T> class SkAutoTMalloc : SkNoncopyable {
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public:
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/** Takes ownership of the ptr. The ptr must be a value which can be passed to sk_free. */
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explicit SkAutoTMalloc(T* ptr = nullptr) {
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fPtr = ptr;
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}
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/** Allocates space for 'count' Ts. */
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explicit SkAutoTMalloc(size_t count) {
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fPtr = count ? (T*)sk_malloc_flags(count * sizeof(T), SK_MALLOC_THROW) : nullptr;
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}
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SkAutoTMalloc(SkAutoTMalloc<T>&& that) : fPtr(that.release()) {}
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~SkAutoTMalloc() {
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sk_free(fPtr);
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}
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/** Resize the memory area pointed to by the current ptr preserving contents. */
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void realloc(size_t count) {
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if (count) {
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fPtr = reinterpret_cast<T*>(sk_realloc_throw(fPtr, count * sizeof(T)));
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} else {
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this->reset(0);
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}
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}
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/** Resize the memory area pointed to by the current ptr without preserving contents. */
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T* reset(size_t count = 0) {
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sk_free(fPtr);
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fPtr = count ? (T*)sk_malloc_flags(count * sizeof(T), SK_MALLOC_THROW) : nullptr;
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return fPtr;
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}
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T* get() const { return fPtr; }
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operator T*() {
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return fPtr;
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}
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operator const T*() const {
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return fPtr;
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}
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T& operator[](int index) {
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return fPtr[index];
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}
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const T& operator[](int index) const {
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return fPtr[index];
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}
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SkAutoTMalloc& operator=(SkAutoTMalloc<T>&& that) {
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if (this != &that) {
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sk_free(fPtr);
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fPtr = that.release();
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}
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return *this;
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}
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/**
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* Transfer ownership of the ptr to the caller, setting the internal
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* pointer to NULL. Note that this differs from get(), which also returns
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* the pointer, but it does not transfer ownership.
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*/
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T* release() {
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T* ptr = fPtr;
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fPtr = nullptr;
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return ptr;
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}
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private:
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T* fPtr;
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};
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template <size_t kCountRequested, typename T> class SkAutoSTMalloc : SkNoncopyable {
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public:
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SkAutoSTMalloc() : fPtr(fTStorage) {}
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SkAutoSTMalloc(size_t count) {
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if (count > kCount) {
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fPtr = (T*)sk_malloc_flags(count * sizeof(T), SK_MALLOC_THROW | SK_MALLOC_TEMP);
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} else if (count) {
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fPtr = fTStorage;
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} else {
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fPtr = nullptr;
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}
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}
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~SkAutoSTMalloc() {
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if (fPtr != fTStorage) {
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sk_free(fPtr);
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}
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}
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// doesn't preserve contents
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T* reset(size_t count) {
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if (fPtr != fTStorage) {
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sk_free(fPtr);
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}
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if (count > kCount) {
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fPtr = (T*)sk_malloc_throw(count * sizeof(T));
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} else if (count) {
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fPtr = fTStorage;
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} else {
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fPtr = nullptr;
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}
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return fPtr;
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}
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T* get() const { return fPtr; }
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operator T*() {
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return fPtr;
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}
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operator const T*() const {
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return fPtr;
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}
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T& operator[](int index) {
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return fPtr[index];
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}
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const T& operator[](int index) const {
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return fPtr[index];
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}
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// Reallocs the array, can be used to shrink the allocation. Makes no attempt to be intelligent
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void realloc(size_t count) {
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if (count > kCount) {
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if (fPtr == fTStorage) {
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fPtr = (T*)sk_malloc_throw(count * sizeof(T));
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memcpy(fPtr, fTStorage, kCount * sizeof(T));
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} else {
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fPtr = (T*)sk_realloc_throw(fPtr, count * sizeof(T));
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}
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} else if (count) {
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if (fPtr != fTStorage) {
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fPtr = (T*)sk_realloc_throw(fPtr, count * sizeof(T));
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}
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} else {
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this->reset(0);
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}
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}
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private:
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// Since we use uint32_t storage, we might be able to get more elements for free.
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static const size_t kCountWithPadding = SkAlign4(kCountRequested*sizeof(T)) / sizeof(T);
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#if defined(SK_BUILD_FOR_GOOGLE3)
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// Stack frame size is limited for SK_BUILD_FOR_GOOGLE3. 4k is less than the actual max, but some functions
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// have multiple large stack allocations.
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static const size_t kMaxBytes = 4 * 1024;
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static const size_t kCount = kCountRequested * sizeof(T) > kMaxBytes
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? kMaxBytes / sizeof(T)
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: kCountWithPadding;
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#else
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static const size_t kCount = kCountWithPadding;
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#endif
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T* fPtr;
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union {
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uint32_t fStorage32[SkAlign4(kCount*sizeof(T)) >> 2];
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T fTStorage[1]; // do NOT want to invoke T::T()
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};
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};
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//////////////////////////////////////////////////////////////////////////////////////////////////
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/**
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* Pass the object and the storage that was offered during SkInPlaceNewCheck, and this will
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* safely destroy (and free if it was dynamically allocated) the object.
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*/
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template <typename T> void SkInPlaceDeleteCheck(T* obj, void* storage) {
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if (storage == obj) {
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obj->~T();
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} else {
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delete obj;
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}
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}
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/**
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* Allocates T, using storage if it is large enough, and allocating on the heap (via new) if
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* storage is not large enough.
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*
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* obj = SkInPlaceNewCheck<Type>(storage, size);
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* ...
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* SkInPlaceDeleteCheck(obj, storage);
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*/
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template <typename T> T* SkInPlaceNewCheck(void* storage, size_t size) {
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return (sizeof(T) <= size) ? new (storage) T : new T;
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}
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template <typename T, typename A1, typename A2, typename A3>
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T* SkInPlaceNewCheck(void* storage, size_t size, const A1& a1, const A2& a2, const A3& a3) {
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return (sizeof(T) <= size) ? new (storage) T(a1, a2, a3) : new T(a1, a2, a3);
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}
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template <typename T, typename A1, typename A2, typename A3, typename A4>
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T* SkInPlaceNewCheck(void* storage, size_t size,
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const A1& a1, const A2& a2, const A3& a3, const A4& a4) {
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return (sizeof(T) <= size) ? new (storage) T(a1, a2, a3, a4) : new T(a1, a2, a3, a4);
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}
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/**
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* Reserves memory that is aligned on double and pointer boundaries.
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* Hopefully this is sufficient for all practical purposes.
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*/
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template <size_t N> class SkAlignedSStorage : SkNoncopyable {
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public:
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size_t size() const { return N; }
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void* get() { return fData; }
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const void* get() const { return fData; }
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private:
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union {
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void* fPtr;
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double fDouble;
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char fData[N];
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};
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};
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/**
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* Reserves memory that is aligned on double and pointer boundaries.
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* Hopefully this is sufficient for all practical purposes. Otherwise,
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* we have to do some arcane trickery to determine alignment of non-POD
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* types. Lifetime of the memory is the lifetime of the object.
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*/
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template <int N, typename T> class SkAlignedSTStorage : SkNoncopyable {
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public:
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/**
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* Returns void* because this object does not initialize the
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* memory. Use placement new for types that require a cons.
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*/
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void* get() { return fStorage.get(); }
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const void* get() const { return fStorage.get(); }
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private:
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SkAlignedSStorage<sizeof(T)*N> fStorage;
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};
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using SkAutoFree = std::unique_ptr<void, SkFunctionWrapper<void, void, sk_free>>;
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template<typename C, std::size_t... Is>
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constexpr auto SkMakeArrayFromIndexSequence(C c, skstd::index_sequence<Is...>)
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-> std::array<skstd::result_of_t<C(std::size_t)>, sizeof...(Is)> {
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return {{ c(Is)... }};
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}
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template<size_t N, typename C> constexpr auto SkMakeArray(C c)
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-> std::array<skstd::result_of_t<C(std::size_t)>, N> {
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return SkMakeArrayFromIndexSequence(c, skstd::make_index_sequence<N>{});
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}
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#endif
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