/* * Copyright 2015 Google Inc. * * Use of this source code is governed by a BSD-style license that can be * found in the LICENSE file. */ #include "include/core/SkRefCnt.h" #include "include/core/SkString.h" #include "include/private/SkChecksum.h" #include "include/private/SkTHash.h" #include "tests/Test.h" #include // Tests use of const foreach(). map.count() is of course the better way to do this. static int count(const SkTHashMap& map) { int n = 0; map.foreach([&n](int, double) { n++; }); return n; } DEF_TEST(HashMap, r) { SkTHashMap map; map.set(3, 4.0); REPORTER_ASSERT(r, map.count() == 1); REPORTER_ASSERT(r, map.approxBytesUsed() > 0); double* found = map.find(3); REPORTER_ASSERT(r, found); REPORTER_ASSERT(r, *found == 4.0); map.foreach([](int key, double* d){ *d = -key; }); REPORTER_ASSERT(r, count(map) == 1); found = map.find(3); REPORTER_ASSERT(r, found); REPORTER_ASSERT(r, *found == -3.0); REPORTER_ASSERT(r, !map.find(2)); const int N = 20; for (int i = 0; i < N; i++) { map.set(i, 2.0*i); } // Test walking the map with iterators, using preincrement (++iter). for (SkTHashMap::Iter iter = map.begin(); iter != map.end(); ++iter) { REPORTER_ASSERT(r, iter->first * 2 == (*iter).second); } // Test walking the map with range-based for. for (auto& entry : map) { REPORTER_ASSERT(r, entry.first * 2 == entry.second); } // Ensure that iteration works equally well on a const map, using postincrement (iter++). const auto& cmap = map; for (SkTHashMap::Iter iter = cmap.begin(); iter != cmap.end(); iter++) { REPORTER_ASSERT(r, iter->first * 2 == (*iter).second); } // Ensure that range-based for works equally well on a const map. for (const auto& entry : cmap) { REPORTER_ASSERT(r, entry.first * 2 == entry.second); } // Ensure that structured bindings work. for (const auto& [number, timesTwo] : cmap) { REPORTER_ASSERT(r, number * 2 == timesTwo); } SkTHashMap clone = map; for (int i = 0; i < N; i++) { double* found = map.find(i); REPORTER_ASSERT(r, found); REPORTER_ASSERT(r, *found == i*2.0); found = clone.find(i); REPORTER_ASSERT(r, found); REPORTER_ASSERT(r, *found == i*2.0); } for (int i = N; i < 2*N; i++) { REPORTER_ASSERT(r, !map.find(i)); REPORTER_ASSERT(r, !clone.find(i)); } REPORTER_ASSERT(r, map.count() == N); REPORTER_ASSERT(r, clone.count() == N); for (int i = 0; i < N/2; i++) { map.remove(i); } for (int i = 0; i < N; i++) { double* found = map.find(i); REPORTER_ASSERT(r, (found == nullptr) == (i < N/2)); found = clone.find(i); REPORTER_ASSERT(r, *found == i*2.0); } REPORTER_ASSERT(r, map.count() == N/2); REPORTER_ASSERT(r, clone.count() == N); map.reset(); REPORTER_ASSERT(r, map.count() == 0); REPORTER_ASSERT(r, clone.count() == N); clone = map; REPORTER_ASSERT(r, clone.count() == 0); { // Test that we don't leave dangling values in empty slots. SkTHashMap> refMap; auto ref = sk_make_sp(); REPORTER_ASSERT(r, ref->unique()); refMap.set(0, ref); REPORTER_ASSERT(r, refMap.count() == 1); REPORTER_ASSERT(r, !ref->unique()); refMap.remove(0); REPORTER_ASSERT(r, refMap.count() == 0); REPORTER_ASSERT(r, ref->unique()); } } DEF_TEST(HashSet, r) { SkTHashSet set; set.add(SkString("Hello")); set.add(SkString("World")); REPORTER_ASSERT(r, set.count() == 2); REPORTER_ASSERT(r, set.contains(SkString("Hello"))); REPORTER_ASSERT(r, set.contains(SkString("World"))); REPORTER_ASSERT(r, !set.contains(SkString("Goodbye"))); REPORTER_ASSERT(r, set.find(SkString("Hello"))); REPORTER_ASSERT(r, *set.find(SkString("Hello")) == SkString("Hello")); // Test walking the set with iterators, using preincrement (++iter). for (SkTHashSet::Iter iter = set.begin(); iter != set.end(); ++iter) { REPORTER_ASSERT(r, iter->equals("Hello") || (*iter).equals("World")); } // Test walking the set with iterators, using postincrement (iter++). for (SkTHashSet::Iter iter = set.begin(); iter != set.end(); iter++) { REPORTER_ASSERT(r, iter->equals("Hello") || (*iter).equals("World")); } // Test walking the set with range-based for. for (auto& entry : set) { REPORTER_ASSERT(r, entry.equals("Hello") || entry.equals("World")); } // Ensure that iteration works equally well on a const set. const auto& cset = set; for (SkTHashSet::Iter iter = cset.begin(); iter != cset.end(); iter++) { REPORTER_ASSERT(r, iter->equals("Hello") || (*iter).equals("World")); } // Ensure that range-based for works equally well on a const set. for (auto& entry : cset) { REPORTER_ASSERT(r, entry.equals("Hello") || entry.equals("World")); } SkTHashSet clone = set; REPORTER_ASSERT(r, clone.count() == 2); REPORTER_ASSERT(r, clone.contains(SkString("Hello"))); REPORTER_ASSERT(r, clone.contains(SkString("World"))); REPORTER_ASSERT(r, !clone.contains(SkString("Goodbye"))); REPORTER_ASSERT(r, clone.find(SkString("Hello"))); REPORTER_ASSERT(r, *clone.find(SkString("Hello")) == SkString("Hello")); set.remove(SkString("Hello")); REPORTER_ASSERT(r, !set.contains(SkString("Hello"))); REPORTER_ASSERT(r, set.count() == 1); REPORTER_ASSERT(r, clone.contains(SkString("Hello"))); REPORTER_ASSERT(r, clone.count() == 2); set.reset(); REPORTER_ASSERT(r, set.count() == 0); clone = set; REPORTER_ASSERT(r, clone.count() == 0); } namespace { class CopyCounter { public: CopyCounter() : fID(0), fCounter(nullptr) {} CopyCounter(uint32_t id, uint32_t* counter) : fID(id), fCounter(counter) {} CopyCounter(const CopyCounter& other) : fID(other.fID) , fCounter(other.fCounter) { SkASSERT(fCounter); *fCounter += 1; } void operator=(const CopyCounter& other) { fID = other.fID; fCounter = other.fCounter; *fCounter += 1; } CopyCounter(CopyCounter&& other) { *this = std::move(other); } void operator=(CopyCounter&& other) { fID = other.fID; fCounter = other.fCounter; } bool operator==(const CopyCounter& other) const { return fID == other.fID; } private: uint32_t fID; uint32_t* fCounter; }; struct HashCopyCounter { uint32_t operator()(const CopyCounter&) const { return 0; // let them collide, what do we care? } }; } // namespace DEF_TEST(HashSetCopyCounter, r) { SkTHashSet set; uint32_t globalCounter = 0; CopyCounter copyCounter1(1, &globalCounter); CopyCounter copyCounter2(2, &globalCounter); REPORTER_ASSERT(r, globalCounter == 0); set.add(copyCounter1); REPORTER_ASSERT(r, globalCounter == 1); REPORTER_ASSERT(r, set.contains(copyCounter1)); REPORTER_ASSERT(r, globalCounter == 1); set.add(copyCounter1); // We allow copies for same-value adds for now. REPORTER_ASSERT(r, globalCounter == 2); set.add(copyCounter2); REPORTER_ASSERT(r, globalCounter == 3); REPORTER_ASSERT(r, set.contains(copyCounter1)); REPORTER_ASSERT(r, set.contains(copyCounter2)); REPORTER_ASSERT(r, globalCounter == 3); set.add(copyCounter1); set.add(copyCounter2); // We allow copies for same-value adds for now. REPORTER_ASSERT(r, globalCounter == 5); } DEF_TEST(HashFindOrNull, r) { struct Entry { int key = 0; int val = 0; }; struct HashTraits { static int GetKey(const Entry* e) { return e->key; } static uint32_t Hash(int key) { return key; } }; SkTHashTable table; REPORTER_ASSERT(r, nullptr == table.findOrNull(7)); Entry seven = { 7, 24 }; table.set(&seven); REPORTER_ASSERT(r, &seven == table.findOrNull(7)); } DEF_TEST(HashTableGrowsAndShrinks, r) { SkTHashSet s; auto check_count_cap = [&](int count, int cap) { REPORTER_ASSERT(r, s.count() == count); REPORTER_ASSERT(r, s.approxBytesUsed() == (sizeof(int) + sizeof(uint32_t)) * cap); }; // Add and remove some elements to test basic growth and shrink patterns. check_count_cap(0,0); s.add(1); check_count_cap(1,4); s.add(2); check_count_cap(2,4); s.add(3); check_count_cap(3,4); s.add(4); check_count_cap(4,8); s.remove(4); check_count_cap(3,8); s.remove(3); check_count_cap(2,4); s.remove(2); check_count_cap(1,4); s.remove(1); check_count_cap(0,4); s.add(1); check_count_cap(1,4); s.add(2); check_count_cap(2,4); s.add(3); check_count_cap(3,4); s.add(4); check_count_cap(4,8); // Add and remove single elements repeatedly to test hysteresis // avoids reallocating these small tables all the time. for (int i = 0; i < 10; i++) { s. add(5); check_count_cap(5,8); s.remove(5); check_count_cap(4,8); } s.remove(4); check_count_cap(3,8); for (int i = 0; i < 10; i++) { s. add(4); check_count_cap(4,8); s.remove(4); check_count_cap(3,8); } s.remove(3); check_count_cap(2,4); for (int i = 0; i < 10; i++) { s. add(4); check_count_cap(3,4); s.remove(4); check_count_cap(2,4); } s.remove(2); check_count_cap(1,4); for (int i = 0; i < 10; i++) { s. add(2); check_count_cap(2,4); s.remove(2); check_count_cap(1,4); } }