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