/* $Id: tstMemAutoPtr.cpp 44528 2013-02-04 14:27:54Z vboxsync $ */ /** @file * IPRT - Testcase the RTCMemAutoPtr template. */ /* * Copyright (C) 2008-2011 Oracle Corporation * * This file is part of VirtualBox Open Source Edition (OSE), as * available from http://www.virtualbox.org. This file is free software; * you can redistribute it and/or modify it under the terms of the GNU * General Public License (GPL) as published by the Free Software * Foundation, in version 2 as it comes in the "COPYING" file of the * VirtualBox OSE distribution. VirtualBox OSE is distributed in the * hope that it will be useful, but WITHOUT ANY WARRANTY of any kind. * * The contents of this file may alternatively be used under the terms * of the Common Development and Distribution License Version 1.0 * (CDDL) only, as it comes in the "COPYING.CDDL" file of the * VirtualBox OSE distribution, in which case the provisions of the * CDDL are applicable instead of those of the GPL. * * You may elect to license modified versions of this file under the * terms and conditions of either the GPL or the CDDL or both. */ /******************************************************************************* * Header Files * *******************************************************************************/ #include #include #include #include #include /******************************************************************************* * Structures and Typedefs * *******************************************************************************/ typedef struct TSTMEMAUTOPTRSTRUCT { uint32_t a; uint32_t b; uint32_t c; } TSTMEMAUTOPTRSTRUCT; /******************************************************************************* * Global Variables * *******************************************************************************/ #ifndef TST_MEM_AUTO_PTR_ONLY_DISAS static unsigned g_cErrors = 0; static unsigned g_cFrees; #endif /* * Feel free to inspect with gdb / objdump / whatever / g++ -fverbose-asm in * a release build and compare with tstMemAutoPtrDisas1PureC. */ extern "C" int tstMemAutoPtrDisas1(void **ppv) { RTCMemAutoPtr Handle(1); if (!Handle) { Handle->a = RTRandU32(); if (Handle->a < UINT32_MAX / 2) { *ppv = Handle.release(); return VINF_SUCCESS; } } return VERR_TRY_AGAIN; } /* * For comparing to tstMemAutoPtrDisas1. */ extern "C" int tstMemAutoPtrDisas1PureC(void **ppv) { TSTMEMAUTOPTRSTRUCT *pHandle = (TSTMEMAUTOPTRSTRUCT *)RTMemRealloc(NULL, sizeof(*pHandle)); if (pHandle) { pHandle->a = RTRandU32(); if (pHandle->a < UINT32_MAX / 2) { *ppv = pHandle; return VINF_SUCCESS; } RTMemFree(pHandle); } return VERR_TRY_AGAIN; } #ifndef TST_MEM_AUTO_PTR_ONLY_DISAS template void tstMemAutoPtrDestructorCounter(T *aMem) { if (aMem == NULL) { RTPrintf("tstMemAutoPtr(%d): Destructor called with NILL handle!\n"); g_cErrors++; } else if (!VALID_PTR(aMem)) { RTPrintf("tstMemAutoPtr(%d): Destructor called with a bad handle %p\n", aMem); g_cErrors++; } RTMemEfFreeNP(aMem); g_cFrees++; } void *tstMemAutoPtrAllocatorNoZero(void *pvOld, size_t cbNew, const char *pszTag) { void *pvNew = RTMemReallocTag(pvOld, cbNew, pszTag); if (pvNew) memset(pvNew, 0xfe, cbNew); return pvNew; } int main() { RTR3InitExeNoArguments(0); RTPrintf("tstMemAutoPtr: TESTING...\n"); #define CHECK_EXPR(expr) \ do { bool const f = !!(expr); if (!f) { RTPrintf("tstMemAutoPtr(%d): %s!\n", __LINE__, #expr); g_cErrors++; } } while (0) /* * Some simple stuff. */ { RTCMemAutoPtr NilObj; CHECK_EXPR(!NilObj); CHECK_EXPR(NilObj.get() == NULL); CHECK_EXPR(NilObj.release() == NULL); NilObj.reset(); } { RTCMemAutoPtr Alloc(10); CHECK_EXPR(Alloc.get() != NULL); char *pch = Alloc.release(); CHECK_EXPR(pch != NULL); CHECK_EXPR(Alloc.get() == NULL); RTCMemAutoPtr Manage(pch); CHECK_EXPR(Manage.get() == pch); CHECK_EXPR(&Manage[0] == pch); CHECK_EXPR(&Manage[1] == &pch[1]); CHECK_EXPR(&Manage[9] == &pch[9]); } /* * Use the electric fence memory API to check alternative template * arguments and also check some subscript / reference limit thing. */ { RTCMemAutoPtr, RTMemEfReallocNP> Electric(10); CHECK_EXPR(Electric.get() != NULL); Electric[0] = '0'; CHECK_EXPR(Electric[0] == '0'); CHECK_EXPR(*Electric == '0'); //CHECK_EXPR(Electric == '0'); Electric[9] = '1'; CHECK_EXPR(Electric[9] == '1'); /* Electric[10] = '2'; - this will crash (of course) */ } /* * Check that memory is actually free when it should be and isn't when it shouldn't. * Use the electric heap to get some extra checks. */ g_cFrees = 0; { RTCMemAutoPtr FreeIt(128); FreeIt[127] = '0'; } CHECK_EXPR(g_cFrees == 1); g_cFrees = 0; { RTCMemAutoPtr FreeIt2(128); FreeIt2[127] = '1'; FreeIt2.reset(); FreeIt2.alloc(128); FreeIt2[127] = '2'; FreeIt2.reset(FreeIt2.get()); /* this one is weird, but it's how things works... */ } CHECK_EXPR(g_cFrees == 2); g_cFrees = 0; { RTCMemAutoPtr DontFreeIt(256); DontFreeIt[255] = '0'; RTMemEfFreeNP(DontFreeIt.release()); } CHECK_EXPR(g_cFrees == 0); g_cFrees = 0; { RTCMemAutoPtr FreeIt3(128); FreeIt3[127] = '0'; CHECK_EXPR(FreeIt3.realloc(128)); FreeIt3[127] = '0'; CHECK_EXPR(FreeIt3.realloc(256)); FreeIt3[255] = '0'; CHECK_EXPR(FreeIt3.realloc(64)); FreeIt3[63] = '0'; CHECK_EXPR(FreeIt3.realloc(32)); FreeIt3[31] = '0'; } CHECK_EXPR(g_cFrees == 1); g_cFrees = 0; { RTCMemAutoPtr FreeIt4; CHECK_EXPR(FreeIt4.alloc(123)); CHECK_EXPR(FreeIt4.realloc(543)); FreeIt4 = (char *)NULL; CHECK_EXPR(FreeIt4.get() == NULL); } CHECK_EXPR(g_cFrees == 1); /* * Check the ->, [] and * (unary) operators with some useful struct. */ { RTCMemAutoPtr Struct1(1); Struct1->a = 0x11223344; Struct1->b = 0x55667788; Struct1->c = 0x99aabbcc; CHECK_EXPR(Struct1->a == 0x11223344); CHECK_EXPR(Struct1->b == 0x55667788); CHECK_EXPR(Struct1->c == 0x99aabbcc); Struct1[0].a = 0x11223344; Struct1[0].b = 0x55667788; Struct1[0].c = 0x99aabbcc; CHECK_EXPR(Struct1[0].a == 0x11223344); CHECK_EXPR(Struct1[0].b == 0x55667788); CHECK_EXPR(Struct1[0].c == 0x99aabbcc); (*Struct1).a = 0x11223344; (*Struct1).b = 0x55667788; (*Struct1).c = 0x99aabbcc; CHECK_EXPR((*Struct1).a == 0x11223344); CHECK_EXPR((*Struct1).b == 0x55667788); CHECK_EXPR((*Struct1).c == 0x99aabbcc); /* since at it... */ Struct1.get()->a = 0x11223344; Struct1.get()->b = 0x55667788; Struct1.get()->c = 0x99aabbcc; CHECK_EXPR(Struct1.get()->a == 0x11223344); CHECK_EXPR(Struct1.get()->b == 0x55667788); CHECK_EXPR(Struct1.get()->c == 0x99aabbcc); } /* * Check the zeroing of memory. */ { RTCMemAutoPtr, tstMemAutoPtrAllocatorNoZero> Zeroed1(1, true); CHECK_EXPR(*Zeroed1 == 0); } { RTCMemAutoPtr, tstMemAutoPtrAllocatorNoZero> Zeroed2; Zeroed2.alloc(5, true); CHECK_EXPR(Zeroed2[0] == 0); CHECK_EXPR(Zeroed2[1] == 0); CHECK_EXPR(Zeroed2[2] == 0); CHECK_EXPR(Zeroed2[3] == 0); CHECK_EXPR(Zeroed2[4] == 0); } /* * Summary. */ if (!g_cErrors) RTPrintf("tstMemAutoPtr: SUCCESS\n"); else RTPrintf("tstMemAutoPtr: FAILED - %d errors\n", g_cErrors); return !!g_cErrors; } #endif /* TST_MEM_AUTO_PTR_ONLY_DISAS */