/* $Id: tstRTBitOperations.cpp 87229 2021-01-12 16:11:02Z vboxsync $ */ /** @file * IPRT Testcase - Inlined Bit Operations. */ /* * Copyright (C) 2006-2020 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 /* * Test 2 - ID allocation using a bitmap. */ #define NIL_TEST2_ID 0 #define TEST2_ID_LAST ((RT_BIT_32(28) - 1) >> 8) struct TestMap2 { uint32_t idNil; uint32_t idLast; uint32_t idChunkPrev; uint32_t bmChunkId[(TEST2_ID_LAST + 1 + 31) / 32]; }; static uint32_t test2AllocId(struct TestMap2 *p2) { /* * Scan sequentially from the last one + 1. */ int32_t idChunk = ++p2->idChunkPrev; if ( (uint32_t)idChunk < TEST2_ID_LAST && idChunk > NIL_TEST2_ID) { idChunk = ASMBitNextClear(&p2->bmChunkId[0], TEST2_ID_LAST + 1, idChunk); if (idChunk > NIL_TEST2_ID) { if (ASMAtomicBitTestAndSet(&p2->bmChunkId[0], idChunk)) { RTTestFailed(NIL_RTTEST, "line %d: idChunk=%#x", __LINE__, idChunk); return NIL_TEST2_ID; } return p2->idChunkPrev = idChunk; } } /* * Ok, scan from the start. */ idChunk = ASMBitFirstClear(&p2->bmChunkId[0], TEST2_ID_LAST + 1); if (idChunk <= NIL_TEST2_ID) { RTTestFailed(NIL_RTTEST, "line %d: idChunk=%#x", __LINE__, idChunk); return NIL_TEST2_ID; } if (ASMAtomicBitTestAndSet(&p2->bmChunkId[0], idChunk)) { RTTestFailed(NIL_RTTEST, "line %d: idChunk=%#x", __LINE__, idChunk); return NIL_TEST2_ID; } return p2->idChunkPrev = idChunk; } static void test2(RTTEST hTest) { struct TestMap2 *p2 = (struct TestMap2 *)RTTestGuardedAllocTail(hTest, sizeof(TestMap2)); p2->idNil = NIL_TEST2_ID; p2->idLast = TEST2_ID_LAST; /* Some simple tests first. */ RT_ZERO(p2->bmChunkId); RTTEST_CHECK(hTest, ASMBitFirstSet(&p2->bmChunkId[0], TEST2_ID_LAST + 1) == -1); for (uint32_t iBit = 0; iBit <= TEST2_ID_LAST; iBit++) RTTEST_CHECK(hTest, !ASMBitTest(&p2->bmChunkId[0], iBit)); memset(&p2->bmChunkId[0], 0xff, sizeof(p2->bmChunkId)); RTTEST_CHECK(hTest, ASMBitFirstClear(&p2->bmChunkId[0], TEST2_ID_LAST + 1) == -1); for (uint32_t iBit = 0; iBit <= TEST2_ID_LAST; iBit++) RTTEST_CHECK(hTest, ASMBitTest(&p2->bmChunkId[0], iBit)); /* The real test. */ p2->idChunkPrev = 0; RT_ZERO(p2->bmChunkId); ASMBitSet(p2->bmChunkId, NIL_TEST2_ID); uint32_t cLeft = TEST2_ID_LAST; while (cLeft-- > 0) test2AllocId(p2); RTTEST_CHECK(hTest, ASMBitFirstClear(&p2->bmChunkId[0], TEST2_ID_LAST + 1) == -1); } int main() { /* * Init the runtime and stuff. */ RTTEST hTest; int rc = RTTestInitAndCreate("tstRTBitOperations", &hTest); if (rc) return rc; RTTestBanner(hTest); int i; int j; int k; /* * Tests */ struct TestMap { uint32_t au32[4]; }; #if 0 struct TestMap sTest; struct TestMap *p = &sTest; #else struct TestMap *p = (struct TestMap *)RTTestGuardedAllocTail(hTest, sizeof(*p)); #endif #define DUMP() RTTestPrintf(hTest, RTTESTLVL_INFO, "au32={%08x,%08x,%08x,%08x}", p->au32[0], p->au32[1], p->au32[2], p->au32[3]) #define CHECK(expr) do { if (!(expr)) { RTTestFailed(hTest, "line %d: %s", __LINE__, #expr); DUMP(); } CHECK_GUARD(s); } while (0) #define CHECK_BIT(expr, b1) do { if (!(expr)) { RTTestFailed(hTest, "line %d, b1=%d: %s", __LINE__, b1, #expr); } CHECK_GUARD(s); } while (0) #define CHECK_BIT2(expr, b1, b2) do { if (!(expr)) { RTTestFailed(hTest, "line %d, b1=%d b2=%d: %s", __LINE__, b1, b2, #expr); } CHECK_GUARD(s); } while (0) #define CHECK_BIT3(expr, b1, b2, b3) do { if (!(expr)) { RTTestFailed(hTest, "line %d, b1=%d b2=%d b3=%d: %s", __LINE__, b1, b2, b3, #expr); } CHECK_GUARD(s); } while (0) #define CHECK_VAL(a_RetType, a_Fmt, a_ValueExpr, a_Expect) \ do { a_RetType rcCheckRet = (a_ValueExpr); \ if (RT_LIKELY((rcCheckRet) == (a_Expect))) {} \ else RTTestFailed(hTest, "line %d: %s -> " a_Fmt ", expected " a_Fmt "", \ __LINE__, #a_ValueExpr, rcCheckRet, a_Expect); \ CHECK_GUARD(s); \ } while (0) #define GUARD_MAP(p) do { } while (0) #define CHECK_GUARD(p) do { } while (0) #define MAP_CLEAR(p) do { RT_ZERO(*(p)); GUARD_MAP(p); } while (0) #define MAP_SET(p) do { memset(p, 0xff, sizeof(*(p))); GUARD_MAP(p); } while (0) /* self check. */ MAP_CLEAR(p); CHECK_GUARD(p); /* * Check the primitives first: */ CHECK_VAL(unsigned, "%u", ASMBitLastSetU32(0), 0); CHECK(ASMBitLastSetU32(1) == 1); CHECK(ASMBitLastSetU32(0x80000000) == 32); CHECK(ASMBitLastSetU32(0xffffffff) == 32); CHECK(ASMBitLastSetU32(RT_BIT(23) | RT_BIT(11)) == 24); for (i = 0; i < 32; i++) CHECK(ASMBitLastSetU32(1 << i) == (unsigned)i + 1); CHECK(ASMBitFirstSetU32(0) == 0); CHECK(ASMBitFirstSetU32(1) == 1); CHECK(ASMBitFirstSetU32(0x80000000) == 32); CHECK(ASMBitFirstSetU32(0xffffffff) == 1); CHECK(ASMBitFirstSetU32(RT_BIT(23) | RT_BIT(11)) == 12); for (i = 0; i < 32; i++) CHECK(ASMBitFirstSetU32(1 << i) == (unsigned)i + 1); CHECK(ASMBitLastSetU64(UINT64_C(0)) == 0); CHECK(ASMBitLastSetU64(UINT64_C(1)) == 1); CHECK(ASMBitLastSetU64(UINT64_C(0x80000000)) == 32); CHECK(ASMBitLastSetU64(UINT64_C(0xffffffff)) == 32); CHECK(ASMBitLastSetU64(RT_BIT_64(33) | RT_BIT_64(11)) == 34); for (i = 0; i < 64; i++) CHECK(ASMBitLastSetU64(UINT64_C(1) << i) == (unsigned)i + 1); CHECK(ASMBitFirstSetU64(UINT64_C(0)) == 0); CHECK(ASMBitFirstSetU64(UINT64_C(1)) == 1); CHECK(ASMBitFirstSetU64(UINT64_C(0x80000000)) == 32); CHECK(ASMBitFirstSetU64(UINT64_C(0x800000000000)) == 48); CHECK(ASMBitFirstSetU64(UINT64_C(0x8000000000000000)) == 64); CHECK(ASMBitFirstSetU64(UINT64_C(0xffffffff)) == 1); CHECK(ASMBitFirstSetU64(UINT64_C(0xffffffffffffffff)) == 1); CHECK(ASMBitFirstSetU64(RT_BIT_64(33) | RT_BIT_64(11)) == 12); for (i = 0; i < 64; i++) CHECK(ASMBitFirstSetU64(UINT64_C(1) << i) == (unsigned)i + 1); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU32(0), 0); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU32(UINT32_C(0x84210000)), 16+1); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU32(UINT32_C(0xffffffff)), 0+1); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU32(UINT32_C(0x80000000)), 31+1); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU64(0), 0); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU64(UINT64_C(0xffffeeee84210000)), 16+1); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU64(UINT64_C(0xffffeeee00000000)), 33+1); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU64(UINT64_C(0x8000000000000000)), 63+1); CHECK_VAL(unsigned, "%u", ASMBitFirstSetU64(UINT64_C(0xffffffffffffffff)), 0+1); CHECK_VAL(unsigned, "%u", ASMBitLastSetU32(0), 0); CHECK_VAL(unsigned, "%u", ASMBitLastSetU32(UINT32_C(0xffffffff)), 31+1); CHECK_VAL(unsigned, "%u", ASMBitLastSetU32(UINT32_C(0x00000001)), 0+1); CHECK_VAL(unsigned, "%u", ASMBitLastSetU32(UINT32_C(0x0001ffff)), 16+1); CHECK_VAL(unsigned, "%u", ASMBitLastSetU32(UINT32_C(0x01234567)), 24+1); CHECK_VAL(unsigned, "%u", ASMBitLastSetU64(0), 0); CHECK_VAL(unsigned, "%u", ASMBitLastSetU64(UINT64_C(0x0000807060504030)), 47+1); CHECK_VAL(uint16_t, "%#x", ASMByteSwapU16(UINT16_C(0x1234)), UINT16_C(0x3412)); CHECK_VAL(uint32_t, "%#x", ASMByteSwapU32(UINT32_C(0x12345678)), UINT32_C(0x78563412)); CHECK_VAL(uint64_t, "%#llx", ASMByteSwapU64(UINT64_C(0x1122334455667788)), UINT64_C(0x8877665544332211)); CHECK_VAL(uint32_t, "%#x", ASMRotateLeftU32(UINT32_C(0x12345678), 4), UINT32_C(0x23456781)); CHECK_VAL(uint32_t, "%#x", ASMRotateLeftU32(UINT32_C(0x12345678), 16), UINT32_C(0x56781234)); CHECK_VAL(uint32_t, "%#x", ASMRotateLeftU32(UINT32_C(0x82868080), 29), UINT32_C(0x1050d010)); CHECK_VAL(uint32_t, "%#x", ASMRotateLeftU32(UINT32_C(0xfedcba89), 1), UINT32_C(0xfdb97513)); CHECK_VAL(uint32_t, "%#x", ASMRotateRightU32(UINT32_C(0x12345678), 4), UINT32_C(0x81234567)); CHECK_VAL(uint32_t, "%#x", ASMRotateRightU32(UINT32_C(0x12345678), 16), UINT32_C(0x56781234)); CHECK_VAL(uint32_t, "%#x", ASMRotateRightU32(UINT32_C(0x82868080), 29), UINT32_C(0x14340404)); CHECK_VAL(uint32_t, "%#x", ASMRotateRightU32(UINT32_C(0xfedcba89), 1), UINT32_C(0xff6e5d44)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x123456789abcdef0), 4), UINT64_C(0x23456789abcdef01)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x123456789abcdef0), 16), UINT64_C(0x56789abcdef01234)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x123456789abcdef0), 32), UINT64_C(0x9abcdef012345678)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x123456789abcdef0), 48), UINT64_C(0xdef0123456789abc)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x123456789abcdef0), 56), UINT64_C(0xf0123456789abcde)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x123456789abcdef0), 60), UINT64_C(0x0123456789abcdef)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x8182838485868788), 63), UINT64_C(0x40c141c242c343c4)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x8182838485868788), 1), UINT64_C(0x030507090b0d0f11)); CHECK_VAL(uint64_t, "%#llx", ASMRotateLeftU64(UINT64_C(0x8182838485868788), 29), UINT64_C(0x90b0d0f110305070)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x123456789abcdef0), 4), UINT64_C(0x0123456789abcdef)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x123456789abcdef0), 16), UINT64_C(0xdef0123456789abc)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x123456789abcdef0), 32), UINT64_C(0x9abcdef012345678)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x123456789abcdef0), 48), UINT64_C(0x56789abcdef01234)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x123456789abcdef0), 56), UINT64_C(0x3456789abcdef012)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x123456789abcdef0), 60), UINT64_C(0x23456789abcdef01)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x8182838485868788), 63), UINT64_C(0x030507090b0d0f11)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x8182838485868788), 1), UINT64_C(0x40c141c242c343c4)); CHECK_VAL(uint64_t, "%#llx", ASMRotateRightU64(UINT64_C(0x8182838485868788), 29), UINT64_C(0x2c343c440c141c24)); /* * Variable sized bitmaps: */ /* bit set */ MAP_CLEAR(p); ASMBitSet(&p->au32[0], 0); ASMBitSet(&p->au32[0], 31); ASMBitSet(&p->au32[0], 65); CHECK(p->au32[0] == 0x80000001U); CHECK(p->au32[2] == 0x00000002U); CHECK(ASMBitTestAndSet(&p->au32[0], 0) && p->au32[0] == 0x80000001U); CHECK(!ASMBitTestAndSet(&p->au32[0], 16) && p->au32[0] == 0x80010001U); CHECK(ASMBitTestAndSet(&p->au32[0], 16) && p->au32[0] == 0x80010001U); CHECK(!ASMBitTestAndSet(&p->au32[0], 80) && p->au32[2] == 0x00010002U); MAP_CLEAR(p); ASMAtomicBitSet(&p->au32[0], 0); ASMAtomicBitSet(&p->au32[0], 30); ASMAtomicBitSet(&p->au32[0], 64); CHECK(p->au32[0] == 0x40000001U); CHECK(p->au32[2] == 0x00000001U); CHECK(ASMAtomicBitTestAndSet(&p->au32[0], 0) && p->au32[0] == 0x40000001U); CHECK(!ASMAtomicBitTestAndSet(&p->au32[0], 16) && p->au32[0] == 0x40010001U); CHECK(ASMAtomicBitTestAndSet(&p->au32[0], 16) && p->au32[0] == 0x40010001U); CHECK(!ASMAtomicBitTestAndSet(&p->au32[0], 80) && p->au32[2] == 0x00010001U); /* bit clear */ MAP_SET(p); ASMBitClear(&p->au32[0], 0); ASMBitClear(&p->au32[0], 31); ASMBitClear(&p->au32[0], 65); CHECK(p->au32[0] == ~0x80000001U); CHECK(p->au32[2] == ~0x00000002U); CHECK(!ASMBitTestAndClear(&p->au32[0], 0) && p->au32[0] == ~0x80000001U); CHECK(ASMBitTestAndClear(&p->au32[0], 16) && p->au32[0] == ~0x80010001U); CHECK(!ASMBitTestAndClear(&p->au32[0], 16) && p->au32[0] == ~0x80010001U); CHECK(ASMBitTestAndClear(&p->au32[0], 80) && p->au32[2] == ~0x00010002U); MAP_SET(p); ASMAtomicBitClear(&p->au32[0], 0); ASMAtomicBitClear(&p->au32[0], 30); ASMAtomicBitClear(&p->au32[0], 64); CHECK(p->au32[0] == ~0x40000001U); CHECK(p->au32[2] == ~0x00000001U); CHECK(!ASMAtomicBitTestAndClear(&p->au32[0], 0) && p->au32[0] == ~0x40000001U); CHECK(ASMAtomicBitTestAndClear(&p->au32[0], 16) && p->au32[0] == ~0x40010001U); CHECK(!ASMAtomicBitTestAndClear(&p->au32[0], 16) && p->au32[0] == ~0x40010001U); CHECK(ASMAtomicBitTestAndClear(&p->au32[0], 80) && p->au32[2] == ~0x00010001U); /* toggle */ MAP_SET(p); ASMBitToggle(&p->au32[0], 0); ASMBitToggle(&p->au32[0], 31); ASMBitToggle(&p->au32[0], 65); ASMBitToggle(&p->au32[0], 47); ASMBitToggle(&p->au32[0], 47); CHECK(p->au32[0] == ~0x80000001U); CHECK(p->au32[2] == ~0x00000002U); CHECK(!ASMBitTestAndToggle(&p->au32[0], 0) && p->au32[0] == ~0x80000000U); CHECK(ASMBitTestAndToggle(&p->au32[0], 0) && p->au32[0] == ~0x80000001U); CHECK(ASMBitTestAndToggle(&p->au32[0], 16) && p->au32[0] == ~0x80010001U); CHECK(!ASMBitTestAndToggle(&p->au32[0], 16) && p->au32[0] == ~0x80000001U); CHECK(ASMBitTestAndToggle(&p->au32[0], 80) && p->au32[2] == ~0x00010002U); MAP_SET(p); ASMAtomicBitToggle(&p->au32[0], 0); ASMAtomicBitToggle(&p->au32[0], 30); ASMAtomicBitToggle(&p->au32[0], 64); ASMAtomicBitToggle(&p->au32[0], 47); ASMAtomicBitToggle(&p->au32[0], 47); CHECK(p->au32[0] == ~0x40000001U); CHECK(p->au32[2] == ~0x00000001U); CHECK(!ASMAtomicBitTestAndToggle(&p->au32[0], 0) && p->au32[0] == ~0x40000000U); CHECK(ASMAtomicBitTestAndToggle(&p->au32[0], 0) && p->au32[0] == ~0x40000001U); CHECK(ASMAtomicBitTestAndToggle(&p->au32[0], 16) && p->au32[0] == ~0x40010001U); CHECK(!ASMAtomicBitTestAndToggle(&p->au32[0], 16) && p->au32[0] == ~0x40000001U); CHECK(ASMAtomicBitTestAndToggle(&p->au32[0], 80) && p->au32[2] == ~0x00010001U); /* test bit. */ for (i = 0; i < 128; i++) { MAP_SET(p); CHECK_BIT(ASMBitTest(&p->au32[0], i), i); ASMBitToggle(&p->au32[0], i); CHECK_BIT(!ASMBitTest(&p->au32[0], i), i); CHECK_BIT(!ASMBitTestAndToggle(&p->au32[0], i), i); CHECK_BIT(ASMBitTest(&p->au32[0], i), i); CHECK_BIT(ASMBitTestAndToggle(&p->au32[0], i), i); CHECK_BIT(!ASMBitTest(&p->au32[0], i), i); MAP_SET(p); CHECK_BIT(ASMBitTest(&p->au32[0], i), i); ASMAtomicBitToggle(&p->au32[0], i); CHECK_BIT(!ASMBitTest(&p->au32[0], i), i); CHECK_BIT(!ASMAtomicBitTestAndToggle(&p->au32[0], i), i); CHECK_BIT(ASMBitTest(&p->au32[0], i), i); CHECK_BIT(ASMAtomicBitTestAndToggle(&p->au32[0], i), i); CHECK_BIT(!ASMBitTest(&p->au32[0], i), i); } /* bit searching */ MAP_SET(p); CHECK_VAL(int32_t, "%d", ASMBitFirstClear(&p->au32[0], sizeof(p->au32) * 8), -1); CHECK_VAL(int32_t, "%d", ASMBitFirstSet(&p->au32[0], sizeof(p->au32) * 8), 0); ASMBitClear(&p->au32[0], 1); CHECK_VAL(int32_t, "%d", ASMBitFirstClear(&p->au32[0], sizeof(p->au32) * 8), 1); CHECK_VAL(int32_t, "%d", ASMBitFirstSet(&p->au32[0], sizeof(p->au32) * 8), 0); MAP_SET(p); ASMBitClear(&p->au32[0], 95); CHECK_VAL(int32_t, "%d", ASMBitFirstClear(&p->au32[0], sizeof(p->au32) * 8), 95); CHECK_VAL(int32_t, "%d", ASMBitFirstSet(&p->au32[0], sizeof(p->au32) * 8), 0); MAP_SET(p); ASMBitClear(&p->au32[0], 127); CHECK(ASMBitFirstClear(&p->au32[0], sizeof(p->au32) * 8) == 127); CHECK(ASMBitFirstSet(&p->au32[0], sizeof(p->au32) * 8) == 0); CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, 0) == 1); CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, 1) == 2); CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, 2) == 3); MAP_SET(p); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 0) == -1); ASMBitClear(&p->au32[0], 32); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 32) == -1); ASMBitClear(&p->au32[0], 88); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 57) == 88); MAP_SET(p); ASMBitClear(&p->au32[0], 31); ASMBitClear(&p->au32[0], 57); ASMBitClear(&p->au32[0], 88); ASMBitClear(&p->au32[0], 101); ASMBitClear(&p->au32[0], 126); ASMBitClear(&p->au32[0], 127); CHECK(ASMBitFirstClear(&p->au32[0], sizeof(p->au32) * 8) == 31); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 31) == 57); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 57) == 88); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 88) == 101); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 101) == 126); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 126) == 127); CHECK(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, 127) == -1); CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, 29) == 30); CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, 30) == 32); MAP_CLEAR(p); for (i = 1; i < 128; i++) CHECK_BIT(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, i - 1) == i, i); for (i = 0; i < 128; i++) { MAP_SET(p); ASMBitClear(&p->au32[0], i); CHECK_BIT(ASMBitFirstClear(&p->au32[0], sizeof(p->au32) * 8) == i, i); for (j = 0; j < i; j++) CHECK_BIT(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, j) == i, i); for (j = i; j < 128; j++) CHECK_BIT(ASMBitNextClear(&p->au32[0], sizeof(p->au32) * 8, j) == -1, i); } /* clear range. */ MAP_SET(p); ASMBitClearRange(&p->au32, 0, 128); CHECK(!p->au32[0] && !p->au32[1] && !p->au32[2] && !p->au32[3]); for (i = 0; i < 128; i++) { for (j = i + 1; j <= 128; j++) { MAP_SET(p); ASMBitClearRange(&p->au32, i, j); for (k = 0; k < i; k++) CHECK_BIT3(ASMBitTest(&p->au32[0], k), i, j, k); for (k = i; k < j; k++) CHECK_BIT3(!ASMBitTest(&p->au32[0], k), i, j, k); for (k = j; k < 128; k++) CHECK_BIT3(ASMBitTest(&p->au32[0], k), i, j, k); } } /* set range. */ MAP_CLEAR(p); ASMBitSetRange(&p->au32[0], 0, 5); ASMBitSetRange(&p->au32[0], 6, 44); ASMBitSetRange(&p->au32[0], 64, 65); CHECK(p->au32[0] == UINT32_C(0xFFFFFFDF)); CHECK(p->au32[1] == UINT32_C(0x00000FFF)); CHECK(p->au32[2] == UINT32_C(0x00000001)); MAP_CLEAR(p); ASMBitSetRange(&p->au32[0], 0, 1); ASMBitSetRange(&p->au32[0], 62, 63); ASMBitSetRange(&p->au32[0], 63, 64); ASMBitSetRange(&p->au32[0], 127, 128); CHECK(p->au32[0] == UINT32_C(0x00000001) && p->au32[1] == UINT32_C(0xC0000000)); CHECK(p->au32[2] == UINT32_C(0x00000000) && p->au32[3] == UINT32_C(0x80000000)); MAP_CLEAR(p); ASMBitSetRange(&p->au32, 0, 128); CHECK(!~p->au32[0] && !~p->au32[1] && !~p->au32[2] && !~p->au32[3]); for (i = 0; i < 128; i++) { for (j = i + 1; j <= 128; j++) { MAP_CLEAR(p); ASMBitSetRange(&p->au32, i, j); for (k = 0; k < i; k++) CHECK_BIT3(!ASMBitTest(&p->au32[0], k), i, j, k); for (k = i; k < j; k++) CHECK_BIT3(ASMBitTest(&p->au32[0], k), i, j, k); for (k = j; k < 128; k++) CHECK_BIT3(!ASMBitTest(&p->au32[0], k), i, j, k); } } /* searching for set bits. */ MAP_CLEAR(p); CHECK(ASMBitFirstSet(&p->au32[0], sizeof(p->au32) * 8) == -1); ASMBitSet(&p->au32[0], 65); CHECK(ASMBitFirstSet(&p->au32[0], sizeof(p->au32) * 8) == 65); CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, 65) == -1); for (i = 0; i < 65; i++) CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, i) == 65); for (i = 65; i < 128; i++) CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, i) == -1); ASMBitSet(&p->au32[0], 17); CHECK(ASMBitFirstSet(&p->au32[0], sizeof(p->au32) * 8) == 17); CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, 17) == 65); for (i = 0; i < 16; i++) CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, i) == 17); for (i = 17; i < 65; i++) CHECK(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, i) == 65); MAP_SET(p); for (i = 1; i < 128; i++) CHECK_BIT(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, i - 1) == i, i); for (i = 0; i < 128; i++) { MAP_CLEAR(p); ASMBitSet(&p->au32[0], i); CHECK_BIT(ASMBitFirstSet(&p->au32[0], sizeof(p->au32) * 8) == i, i); for (j = 0; j < i; j++) CHECK_BIT(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, j) == i, i); for (j = i; j < 128; j++) CHECK_BIT(ASMBitNextSet(&p->au32[0], sizeof(p->au32) * 8, j) == -1, i); } /* * Special tests. */ test2(hTest); /* * Summary */ return RTTestSummaryAndDestroy(hTest); }