AlkantarClanX12
Current Path : /opt/cpanel/ea-ruby27/src/passenger-release-6.0.23/test/cxx/MemoryKit/ |
Current File : //opt/cpanel/ea-ruby27/src/passenger-release-6.0.23/test/cxx/MemoryKit/PallocTest.cpp |
#include <TestSupport.h> #include <MemoryKit/palloc.h> #include <StaticString.h> #include <boost/static_assert.hpp> #include <boost/cstdint.hpp> using namespace Passenger; using namespace std; namespace tut { struct MemoryKit_PallocTest: public TestBase { psg_pool_t *pool; MemoryKit_PallocTest() : pool(NULL) { } ~MemoryKit_PallocTest() { if (pool != NULL) { psg_destroy_pool(pool); } } }; DEFINE_TEST_GROUP(MemoryKit_PallocTest); #define TEST_BASIC_ALLOCATIONS() \ do { \ volatile char *buf = (char *) psg_pnalloc(pool, 8); \ buf[0] = '1'; \ buf[1] = '2'; \ buf[2] = '3'; \ buf[3] = '4'; \ buf[4] = '5'; \ buf[5] = '6'; \ buf[6] = '7'; \ buf[7] = '\0'; \ ensure_equals("psg_pnalloc works", \ StaticString((const char *) buf), \ P_STATIC_STRING("1234567")); \ \ BOOST_STATIC_ASSERT(sizeof(void *) <= sizeof(boost::uintmax_t)); \ \ volatile int *i = (int *) psg_palloc(pool, sizeof(int)); \ ensure_equals<boost::uintmax_t>( \ "psg_palloc's alignment is suitable for integers", \ (boost::uintmax_t) i % sizeof(int), \ 0); \ *i = 1024; \ ensure_equals("psg_palloc on integers works", \ *i, 1024); \ \ volatile double *d = (double *) psg_palloc(pool, sizeof(double)); \ ensure_equals<boost::uintmax_t>( \ "psg_palloc's alignment is suitable for doubles", \ (boost::uintmax_t) i % sizeof(double), \ 0); \ *d = 1234.5; \ ensure_equals("psg_palloc on doubles works", \ *d, 1234.5); \ } while (false) #define TEST_LARGE_ALLOCATION() \ do { \ size_t size = PSG_MAX_ALLOC_FROM_POOL + 32; \ largebuf = (char *) psg_pnalloc(pool, size); \ for (unsigned i = 0; i < size; i++) { \ largebuf[i] = (char) i; \ } \ for (unsigned i = 0; i < size; i++) { \ ensure_equals("Testing buffer content", largebuf[i], (char) i); \ } \ } while (false) TEST_METHOD(1) { set_test_name("Initial state"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); ensure_equals<void *>("Only one pool data struct is allocated", pool->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); } TEST_METHOD(2) { set_test_name("Basic allocations that fit within one pool data struct"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); TEST_BASIC_ALLOCATIONS(); ensure_equals<void *>("Only one pool data struct is allocated", pool->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); } TEST_METHOD(3) { set_test_name("Basic allocations that require multiple pool data structs"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); size_t allocated = 0; while (allocated < PSG_DEFAULT_POOL_SIZE) { psg_palloc(pool, sizeof(double)); allocated += sizeof(double); } TEST_BASIC_ALLOCATIONS(); ensure("At least one pool data struct is allocated", pool->data.next != NULL); ensure_equals<void *>("Exactly two pool data struct are allocated", pool->data.next->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); } TEST_METHOD(4) { set_test_name("It allocates objects larger than" " PSG_MAX_ALLOC_FROM_POOL using malloc()"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); volatile char *largebuf; TEST_LARGE_ALLOCATION(); ensure_equals<void *>("Only one pool data struct is allocated", pool->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure("The buffer is allocated through the large list (1)", pool->large != NULL); ensure_equals<void *>("The buffer is allocated through the large list (2)", pool->large->alloc, (void *) largebuf); ensure_equals<void *>("There is only one item in the large list", pool->large->next, NULL); } TEST_METHOD(5) { set_test_name("It allows freeing" " objects larger than PSG_MAX_ALLOC_FROM_POOL"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); volatile char *largebuf; volatile char *largebuf1; TEST_LARGE_ALLOCATION(); largebuf1 = largebuf; volatile char *largebuf2; TEST_LARGE_ALLOCATION(); largebuf2 = largebuf; volatile char *largebuf3; TEST_LARGE_ALLOCATION(); largebuf3 = largebuf; ensure("Object 2 was freed", psg_pfree(pool, (void *) largebuf2)); ensure("Object 1 was freed", psg_pfree(pool, (void *) largebuf1)); ensure("Object 3 was freed", psg_pfree(pool, (void *) largebuf3)); ensure_equals<void *>("Only one pool data struct is allocated", pool->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); } TEST_METHOD(6) { set_test_name("It bumps the 'current' pointer to the next data struct" " after upon allocating the 8th data struct"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); while (pool->current == pool) { psg_pnalloc(pool, 32); } psg_pool_t *segment = pool; ensure_equals("(1) data.failed is 6", segment->data.failed, 6u); segment = segment->data.next; ensure("(2) data struct is not NULL", segment != NULL); ensure_equals("(2) data.failed is 5", segment->data.failed, 5u); ensure_equals("pool->current points to segment 2", pool->current, segment); segment = segment->data.next; ensure("(3) data struct is not NULL", segment != NULL); ensure_equals("(3) data.failed is 4", segment->data.failed, 4u); segment = segment->data.next; ensure("(4) data struct is not NULL", segment != NULL); ensure_equals("(4) data.failed is 3", segment->data.failed, 3u); segment = segment->data.next; ensure("(5) data struct is not NULL", segment != NULL); ensure_equals("(5) data.failed is 2", segment->data.failed, 2u); segment = segment->data.next; ensure("(6) data struct is not NULL", segment != NULL); ensure_equals("(6) data.failed is 1", segment->data.failed, 1u); segment = segment->data.next; ensure("(7) data struct is not NULL", segment != NULL); ensure_equals("(7) data.failed is 0", segment->data.failed, 0u); segment = segment->data.next; ensure("(8) data struct is not NULL", segment != NULL); ensure_equals("(8) data.failed is 0", segment->data.failed, 0u); ensure_equals<void *>("(8) This is the last data struct", segment->data.next, NULL); } TEST_METHOD(10) { set_test_name("psg_reset_pool() resets the pool for reuse if the pool" " only has one pool data struct"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); void *origLast1 = pool->data.last; volatile char *largebuf; TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); ensure("psg_reset_pool succeeds", psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); ensure_equals<void *>("pool->data.last is correctly reset", pool->data.last, origLast1); ensure_equals("pool->data.failed is 0", pool->data.failed, 0u); ensure_equals<void *>("Only one pool data struct is allocated", pool->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); } TEST_METHOD(11) { set_test_name("psg_reset_pool() fails to reset the pool for reuse if the pool" " has multiple pool data structs"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); void *origLast1 = pool->data.last; while (pool->data.next == NULL) { psg_pnalloc(pool, 32); } void *origLast2 = pool->data.next->data.last - 32; TEST_BASIC_ALLOCATIONS(); ensure("psg_reset_pool fails", !psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); ensure("At least one pool data struct is allocated", pool->data.next != NULL); ensure_equals<void *>("Exactly two pool data struct are allocated", pool->data.next->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals("pool->data.failed is 0", pool->data.failed, 0u); ensure_equals("pool->data.next->data.failed is 0", pool->data.next->data.failed, 0u); ensure_equals<void *>("pool->data.last is correctly reset", pool->data.last, origLast1); ensure_equals<void *>("pool->data.next->data.last is correctly reset", pool->data.next->data.last, origLast2); } TEST_METHOD(12) { set_test_name("psg_reset_pool() frees large allocations correctly" " if the pool only has one pool data struct"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); volatile char *largebuf; TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); ensure("psg_reset_pool succeeds", psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); ensure_equals<void *>("Only one pool data struct is allocated", pool->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); ensure_equals("pool->data.failed is 0", pool->data.failed, 0u); } TEST_METHOD(13) { set_test_name("psg_reset_pool() frees large allocations correctly" " if the pool has multiple pool data structs"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); while (pool->data.next == NULL) { psg_palloc(pool, sizeof(double)); } volatile char *largebuf; TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); ensure("psg_reset_pool fails", !psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); ensure("At least one pool data struct is allocated", pool->data.next != NULL); ensure_equals<void *>("Exactly two pool data struct are allocated", pool->data.next->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); ensure_equals("pool->data.failed is 0", pool->data.failed, 0u); } TEST_METHOD(14) { set_test_name("A pool that had 1 data struct can be reused after a reset"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); void *origLast1 = pool->data.last; volatile char *largebuf; TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); ensure("psg_reset_pool succeeds (1)", psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); ensure("psg_reset_pool succeeds (1)", psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); ensure_equals<void *>("pool->data.last is correctly reset", pool->data.last, origLast1); ensure_equals("pool->data.failed is 0", pool->data.failed, 0u); ensure_equals<void *>("Only one pool data struct is allocated", pool->data.next, NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); } TEST_METHOD(15) { set_test_name("A pool that had multiple data structs can be reused after a reset"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); void *origLast1 = pool->data.last; while (pool->data.next == NULL) { psg_pnalloc(pool, 32); } void *origLast2 = pool->data.next->data.last - 32; volatile char *largebuf; TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); ensure("(1) psg_reset_pool fails", !psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); ensure_equals<void *>("(1) pool->data.last is correctly reset", pool->data.last, origLast1); ensure_equals("(1) pool->data.failed is 0", pool->data.failed, 0u); ensure("(1) At least one pool data struct is allocated", pool->data.next != NULL); ensure_equals<void *>("(1) Exactly two pool data struct are allocated", pool->data.next->data.next, NULL); ensure_equals<void *>("(1) pool->data.next->data.last is correctly reset", pool->data.next->data.last, origLast2); ensure_equals<void *>("(1) pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("(1) Nothing is allocated through the large list", pool->large, NULL); TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); ensure("(2) psg_reset_pool fails", !psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); ensure_equals<void *>("(2) pool->data.last is correctly reset", pool->data.last, origLast1); ensure_equals("(2) pool->data.failed is 0", pool->data.failed, 0u); ensure("(2) At least one pool data struct is allocated", pool->data.next != NULL); ensure_equals<void *>("(2) Exactly two pool data struct are allocated", pool->data.next->data.next, NULL); ensure_equals<void *>("(2) pool->data.next->data.last is correctly reset", pool->data.next->data.last, origLast2); ensure_equals<void *>("(2) pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("(2) Nothing is allocated through the large list", pool->large, NULL); } TEST_METHOD(16) { set_test_name("A pool that had its 'current' pointer bumped" " can be reused after a reset"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); void *origLast1 = pool->data.last; while (pool->current == pool) { psg_palloc(pool, sizeof(double)); } ensure("psg_reset_pool fails", !psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); ensure_equals<void *>("pool->data.last is correctly reset", pool->data.last, origLast1); ensure_equals("pool->data.failed is 0", pool->data.failed, 0u); ensure("At least one pool data struct is allocated", pool->data.next != NULL); ensure_equals<void *>("pool->current points to the first pool data struct", pool->current, pool); ensure_equals<void *>("Nothing is allocated through the large list", pool->large, NULL); volatile char *largebuf; TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); } TEST_METHOD(20) { set_test_name("Miscellaneous stress test"); pool = psg_create_pool(PSG_DEFAULT_POOL_SIZE); for (unsigned i = 0; i < 1024; i++) { volatile char *largebuf; TEST_BASIC_ALLOCATIONS(); TEST_LARGE_ALLOCATION(); } ensure("psg_reset_pool fails", !psg_reset_pool(pool, PSG_DEFAULT_POOL_SIZE)); } }