9519d4f05a
Change-Id: I8d37dfa3a5f0af4741eb6f1c10e13065d20b0ccb Reviewed-on: https://skia-review.googlesource.com/132829 Reviewed-by: Brian Salomon <bsalomon@google.com> Commit-Queue: Robert Phillips <robertphillips@google.com>
321 lines
9.1 KiB
C++
321 lines
9.1 KiB
C++
/*
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* Copyright 2011 Google Inc.
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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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#include "Test.h"
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#include "GrMemoryPool.h"
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#include "SkRandom.h"
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#include "SkTArray.h"
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#include "SkTDArray.h"
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#include "SkTemplates.h"
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// A is the top of an inheritance tree of classes that overload op new and
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// and delete to use a GrMemoryPool. The objects have values of different types
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// that can be set and checked.
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class A {
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public:
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A() {}
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virtual void setValues(int v) {
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fChar = static_cast<char>(v);
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}
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virtual bool checkValues(int v) {
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return fChar == static_cast<char>(v);
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}
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virtual ~A() {}
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void* operator new(size_t size) {
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if (!gPool.get()) {
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return ::operator new(size);
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} else {
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return gPool->allocate(size);
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}
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}
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void operator delete(void* p) {
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if (!gPool.get()) {
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::operator delete(p);
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} else {
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return gPool->release(p);
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}
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}
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static A* Create(SkRandom* r);
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static void SetAllocator(size_t preallocSize, size_t minAllocSize) {
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GrMemoryPool* pool = new GrMemoryPool(preallocSize, minAllocSize);
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gPool.reset(pool);
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}
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static void ResetAllocator() {
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gPool.reset(nullptr);
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}
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private:
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static std::unique_ptr<GrMemoryPool> gPool;
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char fChar;
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};
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std::unique_ptr<GrMemoryPool> A::gPool;
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class B : public A {
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public:
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B() {}
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virtual void setValues(int v) {
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fDouble = static_cast<double>(v);
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this->INHERITED::setValues(v);
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}
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virtual bool checkValues(int v) {
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return fDouble == static_cast<double>(v) &&
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this->INHERITED::checkValues(v);
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}
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virtual ~B() {}
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private:
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double fDouble;
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typedef A INHERITED;
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};
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class C : public A {
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public:
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C() {}
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virtual void setValues(int v) {
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fInt64 = static_cast<int64_t>(v);
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this->INHERITED::setValues(v);
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}
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virtual bool checkValues(int v) {
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return fInt64 == static_cast<int64_t>(v) &&
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this->INHERITED::checkValues(v);
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}
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virtual ~C() {}
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private:
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int64_t fInt64;
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typedef A INHERITED;
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};
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// D derives from C and owns a dynamically created B
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class D : public C {
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public:
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D() {
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fB = new B();
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}
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virtual void setValues(int v) {
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fVoidStar = reinterpret_cast<void*>(static_cast<intptr_t>(v));
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this->INHERITED::setValues(v);
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fB->setValues(v);
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}
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virtual bool checkValues(int v) {
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return fVoidStar == reinterpret_cast<void*>(static_cast<intptr_t>(v)) &&
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fB->checkValues(v) &&
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this->INHERITED::checkValues(v);
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}
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virtual ~D() {
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delete fB;
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}
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private:
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void* fVoidStar;
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B* fB;
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typedef C INHERITED;
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};
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class E : public A {
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public:
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E() {}
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virtual void setValues(int v) {
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for (size_t i = 0; i < SK_ARRAY_COUNT(fIntArray); ++i) {
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fIntArray[i] = v;
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}
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this->INHERITED::setValues(v);
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}
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virtual bool checkValues(int v) {
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bool ok = true;
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for (size_t i = 0; ok && i < SK_ARRAY_COUNT(fIntArray); ++i) {
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if (fIntArray[i] != v) {
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ok = false;
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}
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}
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return ok && this->INHERITED::checkValues(v);
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}
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virtual ~E() {}
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private:
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int fIntArray[20];
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typedef A INHERITED;
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};
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A* A::Create(SkRandom* r) {
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switch (r->nextRangeU(0, 4)) {
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case 0:
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return new A;
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case 1:
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return new B;
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case 2:
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return new C;
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case 3:
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return new D;
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case 4:
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return new E;
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default:
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// suppress warning
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return nullptr;
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}
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}
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struct Rec {
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A* fInstance;
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int fValue;
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};
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DEF_TEST(GrMemoryPool, reporter) {
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// prealloc and min alloc sizes for the pool
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static const size_t gSizes[][2] = {
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{0, 0},
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{10 * sizeof(A), 20 * sizeof(A)},
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{100 * sizeof(A), 100 * sizeof(A)},
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{500 * sizeof(A), 500 * sizeof(A)},
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{10000 * sizeof(A), 0},
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{1, 100 * sizeof(A)},
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};
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// different percentages of creation vs deletion
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static const float gCreateFraction[] = {1.f, .95f, 0.75f, .5f};
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// number of create/destroys per test
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static const int kNumIters = 20000;
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// check that all the values stored in A objects are correct after this
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// number of iterations
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static const int kCheckPeriod = 500;
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SkRandom r;
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for (size_t s = 0; s < SK_ARRAY_COUNT(gSizes); ++s) {
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A::SetAllocator(gSizes[s][0], gSizes[s][1]);
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for (size_t c = 0; c < SK_ARRAY_COUNT(gCreateFraction); ++c) {
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SkTDArray<Rec> instanceRecs;
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for (int i = 0; i < kNumIters; ++i) {
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float createOrDestroy = r.nextUScalar1();
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if (createOrDestroy < gCreateFraction[c] ||
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0 == instanceRecs.count()) {
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Rec* rec = instanceRecs.append();
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rec->fInstance = A::Create(&r);
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rec->fValue = static_cast<int>(r.nextU());
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rec->fInstance->setValues(rec->fValue);
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} else {
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int d = r.nextRangeU(0, instanceRecs.count() - 1);
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Rec& rec = instanceRecs[d];
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REPORTER_ASSERT(reporter, rec.fInstance->checkValues(rec.fValue));
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delete rec.fInstance;
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instanceRecs.removeShuffle(d);
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}
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if (0 == i % kCheckPeriod) {
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for (int r = 0; r < instanceRecs.count(); ++r) {
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Rec& rec = instanceRecs[r];
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REPORTER_ASSERT(reporter, rec.fInstance->checkValues(rec.fValue));
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}
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}
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}
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for (int i = 0; i < instanceRecs.count(); ++i) {
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Rec& rec = instanceRecs[i];
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REPORTER_ASSERT(reporter, rec.fInstance->checkValues(rec.fValue));
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delete rec.fInstance;
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}
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}
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}
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}
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// GrMemoryPool requires that it's empty at the point of destruction. This helps
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// achieving that by releasing all added memory in the destructor.
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class AutoPoolReleaser {
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public:
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AutoPoolReleaser(GrMemoryPool& pool): fPool(pool) {
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}
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~AutoPoolReleaser() {
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for (void* ptr: fAllocated) {
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fPool.release(ptr);
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}
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}
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void add(void* ptr) {
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fAllocated.push_back(ptr);
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}
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private:
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GrMemoryPool& fPool;
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SkTArray<void*> fAllocated;
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};
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DEF_TEST(GrMemoryPoolAPI, reporter) {
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constexpr size_t kSmallestMinAllocSize = GrMemoryPool::kSmallestMinAllocSize;
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// Allocates memory until pool adds a new block (pool.size() changes).
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auto allocateMemory = [](GrMemoryPool& pool, AutoPoolReleaser& r) {
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size_t origPoolSize = pool.size();
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while (pool.size() == origPoolSize) {
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r.add(pool.allocate(31));
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}
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};
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// Effective prealloc space capacity is >= kSmallestMinAllocSize.
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{
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GrMemoryPool pool(0, 0);
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REPORTER_ASSERT(reporter, pool.preallocSize() == kSmallestMinAllocSize);
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}
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// Effective prealloc space capacity is >= minAllocSize.
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{
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constexpr size_t kMinAllocSize = kSmallestMinAllocSize * 2;
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GrMemoryPool pool(kSmallestMinAllocSize, kMinAllocSize);
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REPORTER_ASSERT(reporter, pool.preallocSize() == kMinAllocSize);
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}
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// Effective block size capacity >= kSmallestMinAllocSize.
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{
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GrMemoryPool pool(kSmallestMinAllocSize, kSmallestMinAllocSize / 2);
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AutoPoolReleaser r(pool);
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allocateMemory(pool, r);
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REPORTER_ASSERT(reporter, pool.size() == kSmallestMinAllocSize);
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}
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// Pool allocates exactly preallocSize on creation.
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{
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constexpr size_t kPreallocSize = kSmallestMinAllocSize * 5;
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GrMemoryPool pool(kPreallocSize, 0);
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REPORTER_ASSERT(reporter, pool.preallocSize() == kPreallocSize);
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}
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// Pool allocates exactly minAllocSize when it expands.
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{
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constexpr size_t kMinAllocSize = kSmallestMinAllocSize * 7;
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GrMemoryPool pool(0, kMinAllocSize);
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AutoPoolReleaser r(pool);
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allocateMemory(pool, r);
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REPORTER_ASSERT(reporter, pool.size() == kMinAllocSize);
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allocateMemory(pool, r);
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REPORTER_ASSERT(reporter, pool.size() == 2 * kMinAllocSize);
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}
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// When asked to allocate amount > minAllocSize, pool allocates larger block
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// to accommodate all internal structures.
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{
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constexpr size_t kMinAllocSize = kSmallestMinAllocSize * 2;
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GrMemoryPool pool(kSmallestMinAllocSize, kMinAllocSize);
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AutoPoolReleaser r(pool);
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REPORTER_ASSERT(reporter, pool.size() == 0);
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constexpr size_t hugeSize = 10 * kMinAllocSize;
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r.add(pool.allocate(hugeSize));
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REPORTER_ASSERT(reporter, pool.size() > hugeSize);
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// Block size allocated to accommodate huge request doesn't include any extra
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// space, so next allocation request allocates a new block.
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size_t hugeBlockSize = pool.size();
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r.add(pool.allocate(0));
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REPORTER_ASSERT(reporter, pool.size() == hugeBlockSize + kMinAllocSize);
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}
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}
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