/* ---------------------------------------------------------------------------- Copyright (c) 2018-2020, Microsoft Research, Daan Leijen This is free software; you can redistribute it and/or modify it under the terms of the MIT license. A copy of the license can be found in the file "LICENSE" at the root of this distribution. -----------------------------------------------------------------------------*/ #include "mimalloc.h" #include "mimalloc-types.h" #include "testhelper.h" // --------------------------------------------------------------------------- // Helper functions // --------------------------------------------------------------------------- bool check_zero_init(uint8_t* p, size_t size); #if MI_DEBUG >= 2 bool check_debug_fill_uninit(uint8_t* p, size_t size); bool check_debug_fill_freed(uint8_t* p, size_t size); #endif // --------------------------------------------------------------------------- // Main testing // --------------------------------------------------------------------------- int main(void) { mi_option_disable(mi_option_verbose); // --------------------------------------------------- // Zeroing allocation // --------------------------------------------------- CHECK_BODY("zeroinit-zalloc-small") { size_t zalloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_zalloc(zalloc_size); result = check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-zalloc-large") { size_t zalloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_zalloc(zalloc_size); result = check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-zalloc_small") { size_t zalloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_zalloc_small(zalloc_size); result = check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-calloc-small") { size_t calloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_calloc(calloc_size, 1); result = check_zero_init(p, calloc_size); mi_free(p); }; CHECK_BODY("zeroinit-calloc-large") { size_t calloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_calloc(calloc_size, 1); result = check_zero_init(p, calloc_size); mi_free(p); }; CHECK_BODY("zeroinit-rezalloc-small") { size_t zalloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_zalloc(zalloc_size); result = check_zero_init(p, zalloc_size); zalloc_size *= 3; p = (uint8_t*)mi_rezalloc(p, zalloc_size); result &= check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-rezalloc-large") { size_t zalloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_zalloc(zalloc_size); result = check_zero_init(p, zalloc_size); zalloc_size *= 3; p = (uint8_t*)mi_rezalloc(p, zalloc_size); result &= check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-recalloc-small") { size_t calloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_calloc(calloc_size, 1); result = check_zero_init(p, calloc_size); calloc_size *= 3; p = (uint8_t*)mi_recalloc(p, calloc_size, 1); result &= check_zero_init(p, calloc_size); mi_free(p); }; CHECK_BODY("zeroinit-recalloc-large") { size_t calloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_calloc(calloc_size, 1); result = check_zero_init(p, calloc_size); calloc_size *= 3; p = (uint8_t*)mi_recalloc(p, calloc_size, 1); result &= check_zero_init(p, calloc_size); mi_free(p); }; // --------------------------------------------------- // Zeroing in aligned API // --------------------------------------------------- CHECK_BODY("zeroinit-zalloc_aligned-small") { size_t zalloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_zalloc_aligned(zalloc_size, MI_MAX_ALIGN_SIZE * 2); result = check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-zalloc_aligned-large") { size_t zalloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_zalloc_aligned(zalloc_size, MI_MAX_ALIGN_SIZE * 2); result = check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-calloc_aligned-small") { size_t calloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_calloc_aligned(calloc_size, 1, MI_MAX_ALIGN_SIZE * 2); result = check_zero_init(p, calloc_size); mi_free(p); }; CHECK_BODY("zeroinit-calloc_aligned-large") { size_t calloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_calloc_aligned(calloc_size, 1, MI_MAX_ALIGN_SIZE * 2); result = check_zero_init(p, calloc_size); mi_free(p); }; CHECK_BODY("zeroinit-rezalloc_aligned-small") { size_t zalloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_zalloc_aligned(zalloc_size, MI_MAX_ALIGN_SIZE * 2); result = check_zero_init(p, zalloc_size); zalloc_size *= 3; p = (uint8_t*)mi_rezalloc_aligned(p, zalloc_size, MI_MAX_ALIGN_SIZE * 2); result &= check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-rezalloc_aligned-large") { size_t zalloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_zalloc_aligned(zalloc_size, MI_MAX_ALIGN_SIZE * 2); result = check_zero_init(p, zalloc_size); zalloc_size *= 3; p = (uint8_t*)mi_rezalloc_aligned(p, zalloc_size, MI_MAX_ALIGN_SIZE * 2); result &= check_zero_init(p, zalloc_size); mi_free(p); }; CHECK_BODY("zeroinit-recalloc_aligned-small") { size_t calloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_calloc_aligned(calloc_size, 1, MI_MAX_ALIGN_SIZE * 2); result = check_zero_init(p, calloc_size); calloc_size *= 3; p = (uint8_t*)mi_recalloc_aligned(p, calloc_size, 1, MI_MAX_ALIGN_SIZE * 2); result &= check_zero_init(p, calloc_size); mi_free(p); }; CHECK_BODY("zeroinit-recalloc_aligned-large") { size_t calloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_calloc_aligned(calloc_size, 1, MI_MAX_ALIGN_SIZE * 2); result = check_zero_init(p, calloc_size); calloc_size *= 3; p = (uint8_t*)mi_recalloc_aligned(p, calloc_size, 1, MI_MAX_ALIGN_SIZE * 2); result &= check_zero_init(p, calloc_size); mi_free(p); }; #if MI_DEBUG >= 2 // --------------------------------------------------- // Debug filling // --------------------------------------------------- CHECK_BODY("uninit-malloc-small") { size_t malloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_malloc(malloc_size); result = check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-malloc-large") { size_t malloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_malloc(malloc_size); result = check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-malloc_small") { size_t malloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_malloc_small(malloc_size); result = check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-realloc-small") { size_t malloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_malloc(malloc_size); result = check_debug_fill_uninit(p, malloc_size); malloc_size *= 3; p = (uint8_t*)mi_realloc(p, malloc_size); result &= check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-realloc-large") { size_t malloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_malloc(malloc_size); result = check_debug_fill_uninit(p, malloc_size); malloc_size *= 3; p = (uint8_t*)mi_realloc(p, malloc_size); result &= check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-mallocn-small") { size_t malloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_mallocn(malloc_size, 1); result = check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-mallocn-large") { size_t malloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_mallocn(malloc_size, 1); result = check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-reallocn-small") { size_t malloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_mallocn(malloc_size, 1); result = check_debug_fill_uninit(p, malloc_size); malloc_size *= 3; p = (uint8_t*)mi_reallocn(p, malloc_size, 1); result &= check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-reallocn-large") { size_t malloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_mallocn(malloc_size, 1); result = check_debug_fill_uninit(p, malloc_size); malloc_size *= 3; p = (uint8_t*)mi_reallocn(p, malloc_size, 1); result &= check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-malloc_aligned-small") { size_t malloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_malloc_aligned(malloc_size, MI_MAX_ALIGN_SIZE * 2); result = check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-malloc_aligned-large") { size_t malloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_malloc_aligned(malloc_size, MI_MAX_ALIGN_SIZE * 2); result = check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-realloc_aligned-small") { size_t malloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_malloc_aligned(malloc_size, MI_MAX_ALIGN_SIZE * 2); result = check_debug_fill_uninit(p, malloc_size); malloc_size *= 3; p = (uint8_t*)mi_realloc_aligned(p, malloc_size, MI_MAX_ALIGN_SIZE * 2); result &= check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("uninit-realloc_aligned-large") { size_t malloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_malloc_aligned(malloc_size, MI_MAX_ALIGN_SIZE * 2); result = check_debug_fill_uninit(p, malloc_size); malloc_size *= 3; p = (uint8_t*)mi_realloc_aligned(p, malloc_size, MI_MAX_ALIGN_SIZE * 2); result &= check_debug_fill_uninit(p, malloc_size); mi_free(p); }; CHECK_BODY("fill-freed-small") { size_t malloc_size = MI_SMALL_SIZE_MAX / 2; uint8_t* p = (uint8_t*)mi_malloc(malloc_size); mi_free(p); // First sizeof(void*) bytes will contain housekeeping data, skip these result = check_debug_fill_freed(p + sizeof(void*), malloc_size - sizeof(void*)); }; CHECK_BODY("fill-freed-large") { size_t malloc_size = MI_SMALL_SIZE_MAX * 2; uint8_t* p = (uint8_t*)mi_malloc(malloc_size); mi_free(p); // First sizeof(void*) bytes will contain housekeeping data, skip these result = check_debug_fill_freed(p + sizeof(void*), malloc_size - sizeof(void*)); }; #endif // --------------------------------------------------- // Done // ---------------------------------------------------[] return print_test_summary(); } // --------------------------------------------------------------------------- // Helper functions // --------------------------------------------------------------------------- bool check_zero_init(uint8_t* p, size_t size) { if(!p) return false; bool result = true; for (size_t i = 0; i < size; ++i) { result &= p[i] == 0; } return result; } #if MI_DEBUG >= 2 bool check_debug_fill_uninit(uint8_t* p, size_t size) { #if MI_VALGRIND (void)p; (void)size; return true; // when compiled with valgrind we don't init on purpose #else if(!p) return false; bool result = true; for (size_t i = 0; i < size; ++i) { result &= p[i] == MI_DEBUG_UNINIT; } return result; #endif } bool check_debug_fill_freed(uint8_t* p, size_t size) { #if MI_VALGRIND (void)p; (void)size; return true; // when compiled with valgrind we don't fill on purpose #else if(!p) return false; bool result = true; for (size_t i = 0; i < size; ++i) { result &= p[i] == MI_DEBUG_FREED; } return result; #endif } #endif