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-rw-r--r--src/test/allocator_tests.cpp280
1 files changed, 192 insertions, 88 deletions
diff --git a/src/test/allocator_tests.cpp b/src/test/allocator_tests.cpp
index 613f6c12d7..f0e848655f 100644
--- a/src/test/allocator_tests.cpp
+++ b/src/test/allocator_tests.cpp
@@ -11,110 +11,214 @@
BOOST_FIXTURE_TEST_SUITE(allocator_tests, BasicTestingSetup)
-// Dummy memory page locker for platform independent tests
-static const void *last_lock_addr, *last_unlock_addr;
-static size_t last_lock_len, last_unlock_len;
-class TestLocker
+BOOST_AUTO_TEST_CASE(arena_tests)
{
-public:
- bool Lock(const void *addr, size_t len)
+ // Fake memory base address for testing
+ // without actually using memory.
+ void *synth_base = reinterpret_cast<void*>(0x08000000);
+ const size_t synth_size = 1024*1024;
+ Arena b(synth_base, synth_size, 16);
+ void *chunk = b.alloc(1000);
+#ifdef ARENA_DEBUG
+ b.walk();
+#endif
+ BOOST_CHECK(chunk != nullptr);
+ BOOST_CHECK(b.stats().used == 1008); // Aligned to 16
+ BOOST_CHECK(b.stats().total == synth_size); // Nothing has disappeared?
+ b.free(chunk);
+#ifdef ARENA_DEBUG
+ b.walk();
+#endif
+ BOOST_CHECK(b.stats().used == 0);
+ BOOST_CHECK(b.stats().free == synth_size);
+ try { // Test exception on double-free
+ b.free(chunk);
+ BOOST_CHECK(0);
+ } catch(std::runtime_error &)
{
- last_lock_addr = addr;
- last_lock_len = len;
- return true;
}
- bool Unlock(const void *addr, size_t len)
- {
- last_unlock_addr = addr;
- last_unlock_len = len;
- return true;
+
+ void *a0 = b.alloc(128);
+ BOOST_CHECK(a0 == synth_base); // first allocation must start at beginning
+ void *a1 = b.alloc(256);
+ void *a2 = b.alloc(512);
+ BOOST_CHECK(b.stats().used == 896);
+ BOOST_CHECK(b.stats().total == synth_size);
+#ifdef ARENA_DEBUG
+ b.walk();
+#endif
+ b.free(a0);
+#ifdef ARENA_DEBUG
+ b.walk();
+#endif
+ BOOST_CHECK(b.stats().used == 768);
+ b.free(a1);
+ BOOST_CHECK(b.stats().used == 512);
+ void *a3 = b.alloc(128);
+#ifdef ARENA_DEBUG
+ b.walk();
+#endif
+ BOOST_CHECK(b.stats().used == 640);
+ b.free(a2);
+ BOOST_CHECK(b.stats().used == 128);
+ b.free(a3);
+ BOOST_CHECK(b.stats().used == 0);
+ BOOST_CHECK(b.stats().total == synth_size);
+ BOOST_CHECK(b.stats().free == synth_size);
+
+ std::vector<void*> addr;
+ BOOST_CHECK(b.alloc(0) == nullptr); // allocating 0 always returns nullptr
+#ifdef ARENA_DEBUG
+ b.walk();
+#endif
+ // Sweeping allocate all memory
+ for (int x=0; x<1024; ++x)
+ addr.push_back(b.alloc(1024));
+ BOOST_CHECK(addr[0] == synth_base); // first allocation must start at beginning
+ BOOST_CHECK(b.stats().free == 0);
+ BOOST_CHECK(b.alloc(1024) == nullptr); // memory is full, this must return nullptr
+ BOOST_CHECK(b.alloc(0) == nullptr);
+ for (int x=0; x<1024; ++x)
+ b.free(addr[x]);
+ addr.clear();
+ BOOST_CHECK(b.stats().total == synth_size);
+ BOOST_CHECK(b.stats().free == synth_size);
+
+ // Now in the other direction...
+ for (int x=0; x<1024; ++x)
+ addr.push_back(b.alloc(1024));
+ for (int x=0; x<1024; ++x)
+ b.free(addr[1023-x]);
+ addr.clear();
+
+ // Now allocate in smaller unequal chunks, then deallocate haphazardly
+ // Not all the chunks will succeed allocating, but freeing nullptr is
+ // allowed so that is no problem.
+ for (int x=0; x<2048; ++x)
+ addr.push_back(b.alloc(x+1));
+ for (int x=0; x<2048; ++x)
+ b.free(addr[((x*23)%2048)^242]);
+ addr.clear();
+
+ // Go entirely wild: free and alloc interleaved,
+ // generate targets and sizes using pseudo-randomness.
+ for (int x=0; x<2048; ++x)
+ addr.push_back(0);
+ uint32_t s = 0x12345678;
+ for (int x=0; x<5000; ++x) {
+ int idx = s & (addr.size()-1);
+ if (s & 0x80000000) {
+ b.free(addr[idx]);
+ addr[idx] = 0;
+ } else if(!addr[idx]) {
+ addr[idx] = b.alloc((s >> 16) & 2047);
+ }
+ bool lsb = s & 1;
+ s >>= 1;
+ if (lsb)
+ s ^= 0xf00f00f0; // LFSR period 0xf7ffffe0
}
-};
+ for (void *ptr: addr)
+ b.free(ptr);
+ addr.clear();
-BOOST_AUTO_TEST_CASE(test_LockedPageManagerBase)
+ BOOST_CHECK(b.stats().total == synth_size);
+ BOOST_CHECK(b.stats().free == synth_size);
+}
+
+/** Mock LockedPageAllocator for testing */
+class TestLockedPageAllocator: public LockedPageAllocator
{
- const size_t test_page_size = 4096;
- LockedPageManagerBase<TestLocker> lpm(test_page_size);
- size_t addr;
- last_lock_addr = last_unlock_addr = 0;
- last_lock_len = last_unlock_len = 0;
-
- /* Try large number of small objects */
- addr = 0;
- for(int i=0; i<1000; ++i)
- {
- lpm.LockRange(reinterpret_cast<void*>(addr), 33);
- addr += 33;
- }
- /* Try small number of page-sized objects, straddling two pages */
- addr = test_page_size*100 + 53;
- for(int i=0; i<100; ++i)
- {
- lpm.LockRange(reinterpret_cast<void*>(addr), test_page_size);
- addr += test_page_size;
- }
- /* Try small number of page-sized objects aligned to exactly one page */
- addr = test_page_size*300;
- for(int i=0; i<100; ++i)
- {
- lpm.LockRange(reinterpret_cast<void*>(addr), test_page_size);
- addr += test_page_size;
- }
- /* one very large object, straddling pages */
- lpm.LockRange(reinterpret_cast<void*>(test_page_size*600+1), test_page_size*500);
- BOOST_CHECK(last_lock_addr == reinterpret_cast<void*>(test_page_size*(600+500)));
- /* one very large object, page aligned */
- lpm.LockRange(reinterpret_cast<void*>(test_page_size*1200), test_page_size*500-1);
- BOOST_CHECK(last_lock_addr == reinterpret_cast<void*>(test_page_size*(1200+500-1)));
-
- BOOST_CHECK(lpm.GetLockedPageCount() == (
- (1000*33+test_page_size-1)/test_page_size + // small objects
- 101 + 100 + // page-sized objects
- 501 + 500)); // large objects
- BOOST_CHECK((last_lock_len & (test_page_size-1)) == 0); // always lock entire pages
- BOOST_CHECK(last_unlock_len == 0); // nothing unlocked yet
-
- /* And unlock again */
- addr = 0;
- for(int i=0; i<1000; ++i)
+public:
+ TestLockedPageAllocator(int count_in, int lockedcount_in): count(count_in), lockedcount(lockedcount_in) {}
+ void* AllocateLocked(size_t len, bool *lockingSuccess)
{
- lpm.UnlockRange(reinterpret_cast<void*>(addr), 33);
- addr += 33;
+ *lockingSuccess = false;
+ if (count > 0) {
+ --count;
+
+ if (lockedcount > 0) {
+ --lockedcount;
+ *lockingSuccess = true;
+ }
+
+ return reinterpret_cast<void*>(0x08000000 + (count<<24)); // Fake address, do not actually use this memory
+ }
+ return 0;
}
- addr = test_page_size*100 + 53;
- for(int i=0; i<100; ++i)
+ void FreeLocked(void* addr, size_t len)
{
- lpm.UnlockRange(reinterpret_cast<void*>(addr), test_page_size);
- addr += test_page_size;
}
- addr = test_page_size*300;
- for(int i=0; i<100; ++i)
+ size_t GetLimit()
{
- lpm.UnlockRange(reinterpret_cast<void*>(addr), test_page_size);
- addr += test_page_size;
+ return std::numeric_limits<size_t>::max();
}
- lpm.UnlockRange(reinterpret_cast<void*>(test_page_size*600+1), test_page_size*500);
- lpm.UnlockRange(reinterpret_cast<void*>(test_page_size*1200), test_page_size*500-1);
+private:
+ int count;
+ int lockedcount;
+};
- /* Check that everything is released */
- BOOST_CHECK(lpm.GetLockedPageCount() == 0);
+BOOST_AUTO_TEST_CASE(lockedpool_tests_mock)
+{
+ // Test over three virtual arenas, of which one will succeed being locked
+ std::unique_ptr<LockedPageAllocator> x(new TestLockedPageAllocator(3, 1));
+ LockedPool pool(std::move(x));
+ BOOST_CHECK(pool.stats().total == 0);
+ BOOST_CHECK(pool.stats().locked == 0);
- /* A few and unlocks of size zero (should have no effect) */
- addr = 0;
- for(int i=0; i<1000; ++i)
- {
- lpm.LockRange(reinterpret_cast<void*>(addr), 0);
- addr += 1;
- }
- BOOST_CHECK(lpm.GetLockedPageCount() == 0);
- addr = 0;
- for(int i=0; i<1000; ++i)
+ void *a0 = pool.alloc(LockedPool::ARENA_SIZE / 2);
+ BOOST_CHECK(a0);
+ BOOST_CHECK(pool.stats().locked == LockedPool::ARENA_SIZE);
+ void *a1 = pool.alloc(LockedPool::ARENA_SIZE / 2);
+ BOOST_CHECK(a1);
+ void *a2 = pool.alloc(LockedPool::ARENA_SIZE / 2);
+ BOOST_CHECK(a2);
+ void *a3 = pool.alloc(LockedPool::ARENA_SIZE / 2);
+ BOOST_CHECK(a3);
+ void *a4 = pool.alloc(LockedPool::ARENA_SIZE / 2);
+ BOOST_CHECK(a4);
+ void *a5 = pool.alloc(LockedPool::ARENA_SIZE / 2);
+ BOOST_CHECK(a5);
+ // We've passed a count of three arenas, so this allocation should fail
+ void *a6 = pool.alloc(16);
+ BOOST_CHECK(!a6);
+
+ pool.free(a0);
+ pool.free(a2);
+ pool.free(a4);
+ pool.free(a1);
+ pool.free(a3);
+ pool.free(a5);
+ BOOST_CHECK(pool.stats().total == 3*LockedPool::ARENA_SIZE);
+ BOOST_CHECK(pool.stats().locked == LockedPool::ARENA_SIZE);
+ BOOST_CHECK(pool.stats().used == 0);
+}
+
+// These tests used the live LockedPoolManager object, this is also used
+// by other tests so the conditions are somewhat less controllable and thus the
+// tests are somewhat more error-prone.
+BOOST_AUTO_TEST_CASE(lockedpool_tests_live)
+{
+ LockedPoolManager &pool = LockedPoolManager::Instance();
+ LockedPool::Stats initial = pool.stats();
+
+ void *a0 = pool.alloc(16);
+ BOOST_CHECK(a0);
+ // Test reading and writing the allocated memory
+ *((uint32_t*)a0) = 0x1234;
+ BOOST_CHECK(*((uint32_t*)a0) == 0x1234);
+
+ pool.free(a0);
+ try { // Test exception on double-free
+ pool.free(a0);
+ BOOST_CHECK(0);
+ } catch(std::runtime_error &)
{
- lpm.UnlockRange(reinterpret_cast<void*>(addr), 0);
- addr += 1;
}
- BOOST_CHECK(lpm.GetLockedPageCount() == 0);
- BOOST_CHECK((last_unlock_len & (test_page_size-1)) == 0); // always unlock entire pages
+ // If more than one new arena was allocated for the above tests, something is wrong
+ BOOST_CHECK(pool.stats().total <= (initial.total + LockedPool::ARENA_SIZE));
+ // Usage must be back to where it started
+ BOOST_CHECK(pool.stats().used == initial.used);
}
BOOST_AUTO_TEST_SUITE_END()