/* $Id: tstRTAvl.cpp 33540 2010-10-28 09:27:05Z vboxsync $ */ /** @file * IPRT Testcase - AVL trees. */ /* * Copyright (C) 2006-2009 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 #include #include #include /******************************************************************************* * Structures and Typedefs * *******************************************************************************/ typedef struct TRACKER { /** The max key value (exclusive). */ uint32_t MaxKey; /** The last allocated key. */ uint32_t LastAllocatedKey; /** The number of set bits in the bitmap. */ uint32_t cSetBits; /** The bitmap size. */ uint32_t cbBitmap; /** Bitmap containing the allocated nodes. */ uint8_t abBitmap[1]; } TRACKER, *PTRACKER; /******************************************************************************* * Global Variables * *******************************************************************************/ static RTTEST g_hTest; static RTRAND g_hRand; /** * Creates a new tracker. * * @returns Pointer to the new tracker. * @param MaxKey The max key value for the tracker. (exclusive) */ static PTRACKER TrackerCreate(uint32_t MaxKey) { uint32_t cbBitmap = (MaxKey + sizeof(uint32_t) * sizeof(uint8_t) - 1) / sizeof(uint8_t); PTRACKER pTracker = (PTRACKER)RTMemAllocZ(RT_OFFSETOF(TRACKER, abBitmap[cbBitmap])); if (pTracker) { pTracker->MaxKey = MaxKey; pTracker->LastAllocatedKey = MaxKey; pTracker->cbBitmap = cbBitmap; Assert(pTracker->cSetBits == 0); } return pTracker; } /** * Destroys a tracker. * * @param pTracker The tracker. */ static void TrackerDestroy(PTRACKER pTracker) { RTMemFree(pTracker); } /** * Inserts a key range into the tracker. * * @returns success indicator. * @param pTracker The tracker. * @param Key The first key in the range. * @param KeyLast The last key in the range. (inclusive) */ static bool TrackerInsert(PTRACKER pTracker, uint32_t Key, uint32_t KeyLast) { bool fRc = !ASMBitTestAndSet(pTracker->abBitmap, Key); if (fRc) pTracker->cSetBits++; while (KeyLast != Key) { if (!ASMBitTestAndSet(pTracker->abBitmap, KeyLast)) pTracker->cSetBits++; else fRc = false; KeyLast--; } return fRc; } /** * Removes a key range from the tracker. * * @returns success indicator. * @param pTracker The tracker. * @param Key The first key in the range. * @param KeyLast The last key in the range. (inclusive) */ static bool TrackerRemove(PTRACKER pTracker, uint32_t Key, uint32_t KeyLast) { bool fRc = ASMBitTestAndClear(pTracker->abBitmap, Key); if (fRc) pTracker->cSetBits--; while (KeyLast != Key) { if (ASMBitTestAndClear(pTracker->abBitmap, KeyLast)) pTracker->cSetBits--; else fRc = false; KeyLast--; } return fRc; } /** * Random key range allocation. * * @returns success indicator. * @param pTracker The tracker. * @param pKey Where to store the first key in the allocated range. * @param pKeyLast Where to store the first key in the allocated range. * @param cMaxKey The max range length. * @remark The caller has to call TrackerInsert. */ static bool TrackerNewRandomEx(PTRACKER pTracker, uint32_t *pKey, uint32_t *pKeyLast, uint32_t cMaxKeys) { /* * Find a key. */ uint32_t Key = RTRandAdvU32Ex(g_hRand, 0, pTracker->MaxKey - 1); if (ASMBitTest(pTracker->abBitmap, Key)) { if (pTracker->cSetBits >= pTracker->MaxKey) return false; int Key2 = ASMBitNextClear(pTracker->abBitmap, pTracker->MaxKey, Key); if (Key2 > 0) Key = Key2; else { /* we're missing a ASMBitPrevClear function, so just try another, lower, value.*/ for (;;) { const uint32_t KeyPrev = Key; Key = RTRandAdvU32Ex(g_hRand, 0, KeyPrev - 1); if (!ASMBitTest(pTracker->abBitmap, Key)) break; Key2 = ASMBitNextClear(pTracker->abBitmap, RT_ALIGN_32(KeyPrev, 32), Key); if (Key2 > 0) { Key = Key2; break; } } } } /* * Determine the range. */ uint32_t KeyLast; if (cMaxKeys == 1 || !pKeyLast) KeyLast = Key; else { uint32_t cKeys = RTRandAdvU32Ex(g_hRand, 0, RT_MIN(pTracker->MaxKey - Key, cMaxKeys - 1)); KeyLast = Key + cKeys; int Key2 = ASMBitNextSet(pTracker->abBitmap, RT_ALIGN_32(KeyLast, 32), Key); if ( Key2 > 0 && (unsigned)Key2 <= KeyLast) KeyLast = Key2 - 1; } /* * Return. */ *pKey = Key; if (pKeyLast) *pKeyLast = KeyLast; return true; } /** * Random single key allocation. * * @returns success indicator. * @param pTracker The tracker. * @param pKey Where to store the allocated key. * @remark The caller has to call TrackerInsert. */ static bool TrackerNewRandom(PTRACKER pTracker, uint32_t *pKey) { return TrackerNewRandomEx(pTracker, pKey, NULL, 1); } /** * Random single key 'lookup'. * * @returns success indicator. * @param pTracker The tracker. * @param pKey Where to store the allocated key. * @remark The caller has to call TrackerRemove. */ static bool TrackerFindRandom(PTRACKER pTracker, uint32_t *pKey) { uint32_t Key = RTRandAdvU32Ex(g_hRand, 0, pTracker->MaxKey - 1); if (!ASMBitTest(pTracker->abBitmap, Key)) { if (!pTracker->cSetBits) return false; int Key2 = ASMBitNextSet(pTracker->abBitmap, pTracker->MaxKey, Key); if (Key2 > 0) Key = Key2; else { /* we're missing a ASMBitPrevSet function, so here's a quick replacement hack. */ uint32_t *pu32Start = (uint32_t *)&pTracker->abBitmap[0]; uint32_t *pu32Cur = (uint32_t *)&pTracker->abBitmap[Key >> 8]; while (pu32Cur >= pu32Start) { if (*pu32Cur) { *pKey = ASMBitLastSetU32(*pu32Cur) - 1 + (uint32_t)((pu32Cur - pu32Start) * 32); return true; } pu32Cur--; } Key2 = ASMBitFirstSet(pTracker->abBitmap, pTracker->MaxKey); if (Key2 == -1) { RTTestIFailed("cSetBits=%u - but ASMBitFirstSet failed to find any", pTracker->cSetBits); return false; } Key = Key2; } } *pKey = Key; return true; } /* bool TrackerAllocSeq(PTRACKER pTracker, uint32_t *pKey, uint32_t *pKeyLast, uint32_t cMaxKeys) { return false; }*/ /** * Prints an unbuffered char. * @param ch The char. */ static void ProgressChar(char ch) { //RTTestIPrintf(RTTESTLVL_INFO, "%c", ch); RTTestIPrintf(RTTESTLVL_SUB_TEST, "%c", ch); } /** * Prints a progress indicator label. * @param cMax The max number of operations (exclusive). * @param pszFormat The format string. * @param ... The arguments to the format string. */ DECLINLINE(void) ProgressPrintf(unsigned cMax, const char *pszFormat, ...) { if (cMax < 10000) return; va_list va; va_start(va, pszFormat); //RTTestIPrintfV(RTTESTLVL_INFO, pszFormat, va); RTTestIPrintfV(RTTESTLVL_SUB_TEST, pszFormat, va); va_end(va); } /** * Prints a progress indicator dot. * @param iCur The current operation. (can be descending too) * @param cMax The max number of operations (exclusive). */ DECLINLINE(void) Progress(unsigned iCur, unsigned cMax) { if (cMax < 10000) return; if (!(iCur % (cMax / 20))) ProgressChar('.'); } static int avlogcphys(unsigned cMax) { /* * Simple linear insert and remove. */ if (cMax >= 10000) RTTestISubF("oGCPhys(%d): linear left", cMax); PAVLOGCPHYSTREE pTree = (PAVLOGCPHYSTREE)RTMemAllocZ(sizeof(*pTree)); unsigned i; for (i = 0; i < cMax; i++) { Progress(i, cMax); PAVLOGCPHYSNODECORE pNode = (PAVLOGCPHYSNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = i; if (!RTAvloGCPhysInsert(pTree, pNode)) { RTTestIFailed("linear left insert i=%d\n", i); return 1; } /* negative. */ AVLOGCPHYSNODECORE Node = *pNode; if (RTAvloGCPhysInsert(pTree, &Node)) { RTTestIFailed("linear left negative insert i=%d\n", i); return 1; } } ProgressPrintf(cMax, "~"); for (i = 0; i < cMax; i++) { Progress(i, cMax); PAVLOGCPHYSNODECORE pNode = RTAvloGCPhysRemove(pTree, i); if (!pNode) { RTTestIFailed("linear left remove i=%d\n", i); return 1; } memset(pNode, 0xcc, sizeof(*pNode)); RTMemFree(pNode); /* negative */ pNode = RTAvloGCPhysRemove(pTree, i); if (pNode) { RTTestIFailed("linear left negative remove i=%d\n", i); return 1; } } /* * Simple linear insert and remove from the right. */ if (cMax >= 10000) RTTestISubF("oGCPhys(%d): linear right", cMax); for (i = 0; i < cMax; i++) { Progress(i, cMax); PAVLOGCPHYSNODECORE pNode = (PAVLOGCPHYSNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = i; if (!RTAvloGCPhysInsert(pTree, pNode)) { RTTestIFailed("linear right insert i=%d\n", i); return 1; } /* negative. */ AVLOGCPHYSNODECORE Node = *pNode; if (RTAvloGCPhysInsert(pTree, &Node)) { RTTestIFailed("linear right negative insert i=%d\n", i); return 1; } } ProgressPrintf(cMax, "~"); while (i-- > 0) { Progress(i, cMax); PAVLOGCPHYSNODECORE pNode = RTAvloGCPhysRemove(pTree, i); if (!pNode) { RTTestIFailed("linear right remove i=%d\n", i); return 1; } memset(pNode, 0xcc, sizeof(*pNode)); RTMemFree(pNode); /* negative */ pNode = RTAvloGCPhysRemove(pTree, i); if (pNode) { RTTestIFailed("linear right negative remove i=%d\n", i); return 1; } } /* * Linear insert but root based removal. */ if (cMax >= 10000) RTTestISubF("oGCPhys(%d): linear root", cMax); for (i = 0; i < cMax; i++) { Progress(i, cMax); PAVLOGCPHYSNODECORE pNode = (PAVLOGCPHYSNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = i; if (!RTAvloGCPhysInsert(pTree, pNode)) { RTTestIFailed("linear root insert i=%d\n", i); return 1; } /* negative. */ AVLOGCPHYSNODECORE Node = *pNode; if (RTAvloGCPhysInsert(pTree, &Node)) { RTTestIFailed("linear root negative insert i=%d\n", i); return 1; } } ProgressPrintf(cMax, "~"); while (i-- > 0) { Progress(i, cMax); PAVLOGCPHYSNODECORE pNode = (PAVLOGCPHYSNODECORE)((intptr_t)pTree + *pTree); RTGCPHYS Key = pNode->Key; pNode = RTAvloGCPhysRemove(pTree, Key); if (!pNode) { RTTestIFailed("linear root remove i=%d Key=%d\n", i, (unsigned)Key); return 1; } memset(pNode, 0xcc, sizeof(*pNode)); RTMemFree(pNode); /* negative */ pNode = RTAvloGCPhysRemove(pTree, Key); if (pNode) { RTTestIFailed("linear root negative remove i=%d Key=%d\n", i, (unsigned)Key); return 1; } } if (*pTree) { RTTestIFailed("sparse remove didn't remove it all!\n"); return 1; } /* * Make a sparsely populated tree and remove the nodes using best fit in 5 cycles. */ const unsigned cMaxSparse = RT_ALIGN(cMax, 32); if (cMaxSparse >= 10000) RTTestISubF("oGCPhys(%d): sparse", cMax); for (i = 0; i < cMaxSparse; i += 8) { Progress(i, cMaxSparse); PAVLOGCPHYSNODECORE pNode = (PAVLOGCPHYSNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = i; if (!RTAvloGCPhysInsert(pTree, pNode)) { RTTestIFailed("sparse insert i=%d\n", i); return 1; } /* negative. */ AVLOGCPHYSNODECORE Node = *pNode; if (RTAvloGCPhysInsert(pTree, &Node)) { RTTestIFailed("sparse negative insert i=%d\n", i); return 1; } } /* Remove using best fit in 5 cycles. */ ProgressPrintf(cMaxSparse, "~"); unsigned j; for (j = 0; j < 4; j++) { for (i = 0; i < cMaxSparse; i += 8 * 4) { Progress(i, cMax); // good enough PAVLOGCPHYSNODECORE pNode = RTAvloGCPhysRemoveBestFit(pTree, i, true); if (!pNode) { RTTestIFailed("sparse remove i=%d j=%d\n", i, j); return 1; } if (pNode->Key - (unsigned long)i >= 8 * 4) { RTTestIFailed("sparse remove i=%d j=%d Key=%d\n", i, j, (unsigned)pNode->Key); return 1; } memset(pNode, 0xdd, sizeof(*pNode)); RTMemFree(pNode); } } if (*pTree) { RTTestIFailed("sparse remove didn't remove it all!\n"); return 1; } RTMemFree(pTree); ProgressPrintf(cMaxSparse, "\n"); return 0; } int avlogcphysRand(unsigned cMax, unsigned cMax2) { PAVLOGCPHYSTREE pTree = (PAVLOGCPHYSTREE)RTMemAllocZ(sizeof(*pTree)); unsigned i; /* * Random tree. */ if (cMax >= 10000) RTTestISubF("oGCPhys(%d, %d): random", cMax, cMax2); PTRACKER pTracker = TrackerCreate(cMax2); if (!pTracker) { RTTestIFailed("failed to create %d tracker!\n", cMax2); return 1; } /* Insert a number of nodes in random order. */ for (i = 0; i < cMax; i++) { Progress(i, cMax); uint32_t Key; if (!TrackerNewRandom(pTracker, &Key)) { RTTestIFailed("failed to allocate node no. %d\n", i); TrackerDestroy(pTracker); return 1; } PAVLOGCPHYSNODECORE pNode = (PAVLOGCPHYSNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = Key; if (!RTAvloGCPhysInsert(pTree, pNode)) { RTTestIFailed("random insert i=%d Key=%#x\n", i, Key); return 1; } /* negative. */ AVLOGCPHYSNODECORE Node = *pNode; if (RTAvloGCPhysInsert(pTree, &Node)) { RTTestIFailed("linear negative insert i=%d Key=%#x\n", i, Key); return 1; } TrackerInsert(pTracker, Key, Key); } /* delete the nodes in random order. */ ProgressPrintf(cMax, "~"); while (i-- > 0) { Progress(i, cMax); uint32_t Key; if (!TrackerFindRandom(pTracker, &Key)) { RTTestIFailed("failed to find free node no. %d\n", i); TrackerDestroy(pTracker); return 1; } PAVLOGCPHYSNODECORE pNode = RTAvloGCPhysRemove(pTree, Key); if (!pNode) { RTTestIFailed("random remove i=%d Key=%#x\n", i, Key); return 1; } if (pNode->Key != Key) { RTTestIFailed("random remove i=%d Key=%#x pNode->Key=%#x\n", i, Key, (unsigned)pNode->Key); return 1; } TrackerRemove(pTracker, Key, Key); memset(pNode, 0xdd, sizeof(*pNode)); RTMemFree(pNode); } if (*pTree) { RTTestIFailed("random remove didn't remove it all!\n"); return 1; } ProgressPrintf(cMax, "\n"); TrackerDestroy(pTracker); RTMemFree(pTree); return 0; } int avlrogcphys(void) { unsigned i; unsigned j; unsigned k; PAVLROGCPHYSTREE pTree = (PAVLROGCPHYSTREE)RTMemAllocZ(sizeof(*pTree)); AssertCompileSize(AVLOGCPHYSNODECORE, 24); AssertCompileSize(AVLROGCPHYSNODECORE, 32); RTTestISubF("RTAvlroGCPhys"); /* * Simple linear insert, get and remove. */ /* insert */ for (i = 0; i < 65536; i += 4) { PAVLROGCPHYSNODECORE pNode = (PAVLROGCPHYSNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = i; pNode->KeyLast = i + 3; if (!RTAvlroGCPhysInsert(pTree, pNode)) { RTTestIFailed("linear insert i=%d\n", (unsigned)i); return 1; } /* negative. */ AVLROGCPHYSNODECORE Node = *pNode; for (j = i + 3; j > i - 32; j--) { for (k = i; k < i + 32; k++) { Node.Key = RT_MIN(j, k); Node.KeyLast = RT_MAX(k, j); if (RTAvlroGCPhysInsert(pTree, &Node)) { RTTestIFailed("linear negative insert i=%d j=%d k=%d\n", i, j, k); return 1; } } } } /* do gets. */ for (i = 0; i < 65536; i += 4) { PAVLROGCPHYSNODECORE pNode = RTAvlroGCPhysGet(pTree, i); if (!pNode) { RTTestIFailed("linear get i=%d\n", i); return 1; } if (pNode->Key > i || pNode->KeyLast < i) { RTTestIFailed("linear get i=%d Key=%d KeyLast=%d\n", i, (unsigned)pNode->Key, (unsigned)pNode->KeyLast); return 1; } for (j = 0; j < 4; j++) { if (RTAvlroGCPhysRangeGet(pTree, i + j) != pNode) { RTTestIFailed("linear range get i=%d j=%d\n", i, j); return 1; } } /* negative. */ if ( RTAvlroGCPhysGet(pTree, i + 1) || RTAvlroGCPhysGet(pTree, i + 2) || RTAvlroGCPhysGet(pTree, i + 3)) { RTTestIFailed("linear negative get i=%d + n\n", i); return 1; } } /* remove */ for (i = 0; i < 65536; i += 4) { PAVLROGCPHYSNODECORE pNode = RTAvlroGCPhysRemove(pTree, i); if (!pNode) { RTTestIFailed("linear remove i=%d\n", i); return 1; } memset(pNode, 0xcc, sizeof(*pNode)); RTMemFree(pNode); /* negative */ if ( RTAvlroGCPhysRemove(pTree, i) || RTAvlroGCPhysRemove(pTree, i + 1) || RTAvlroGCPhysRemove(pTree, i + 2) || RTAvlroGCPhysRemove(pTree, i + 3)) { RTTestIFailed("linear negative remove i=%d + n\n", i); return 1; } } /* * Make a sparsely populated tree. */ for (i = 0; i < 65536; i += 8) { PAVLROGCPHYSNODECORE pNode = (PAVLROGCPHYSNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = i; pNode->KeyLast = i + 3; if (!RTAvlroGCPhysInsert(pTree, pNode)) { RTTestIFailed("sparse insert i=%d\n", i); return 1; } /* negative. */ AVLROGCPHYSNODECORE Node = *pNode; const RTGCPHYS jMin = i > 32 ? i - 32 : 1; const RTGCPHYS kMax = i + 32; for (j = pNode->KeyLast; j >= jMin; j--) { for (k = pNode->Key; k < kMax; k++) { Node.Key = RT_MIN(j, k); Node.KeyLast = RT_MAX(k, j); if (RTAvlroGCPhysInsert(pTree, &Node)) { RTTestIFailed("sparse negative insert i=%d j=%d k=%d\n", i, j, k); return 1; } } } } /* * Get and Remove using range matching in 5 cycles. */ for (j = 0; j < 4; j++) { for (i = 0; i < 65536; i += 8 * 4) { /* gets */ RTGCPHYS KeyBase = i + j * 8; PAVLROGCPHYSNODECORE pNode = RTAvlroGCPhysGet(pTree, KeyBase); if (!pNode) { RTTestIFailed("sparse get i=%d j=%d KeyBase=%d\n", i, j, (unsigned)KeyBase); return 1; } if (pNode->Key > KeyBase || pNode->KeyLast < KeyBase) { RTTestIFailed("sparse get i=%d j=%d KeyBase=%d pNode->Key=%d\n", i, j, (unsigned)KeyBase, (unsigned)pNode->Key); return 1; } for (k = KeyBase; k < KeyBase + 4; k++) { if (RTAvlroGCPhysRangeGet(pTree, k) != pNode) { RTTestIFailed("sparse range get i=%d j=%d k=%d\n", i, j, k); return 1; } } /* negative gets */ for (k = i + j; k < KeyBase + 8; k++) { if ( k != KeyBase && RTAvlroGCPhysGet(pTree, k)) { RTTestIFailed("sparse negative get i=%d j=%d k=%d\n", i, j, k); return 1; } } for (k = i + j; k < KeyBase; k++) { if (RTAvlroGCPhysRangeGet(pTree, k)) { RTTestIFailed("sparse negative range get i=%d j=%d k=%d\n", i, j, k); return 1; } } for (k = KeyBase + 4; k < KeyBase + 8; k++) { if (RTAvlroGCPhysRangeGet(pTree, k)) { RTTestIFailed("sparse negative range get i=%d j=%d k=%d\n", i, j, k); return 1; } } /* remove */ RTGCPHYS Key = KeyBase + ((i / 19) % 4); if (RTAvlroGCPhysRangeRemove(pTree, Key) != pNode) { RTTestIFailed("sparse remove i=%d j=%d Key=%d\n", i, j, (unsigned)Key); return 1; } memset(pNode, 0xdd, sizeof(*pNode)); RTMemFree(pNode); } } if (*pTree) { RTTestIFailed("sparse remove didn't remove it all!\n"); return 1; } /* * Realworld testcase. */ struct { AVLROGCPHYSTREE Tree; AVLROGCPHYSNODECORE aNode[4]; } s1, s2, s3; RT_ZERO(s1); RT_ZERO(s2); RT_ZERO(s3); s1.aNode[0].Key = 0x00030000; s1.aNode[0].KeyLast = 0x00030fff; s1.aNode[1].Key = 0x000a0000; s1.aNode[1].KeyLast = 0x000bffff; s1.aNode[2].Key = 0xe0000000; s1.aNode[2].KeyLast = 0xe03fffff; s1.aNode[3].Key = 0xfffe0000; s1.aNode[3].KeyLast = 0xfffe0ffe; for (i = 0; i < RT_ELEMENTS(s1.aNode); i++) { PAVLROGCPHYSNODECORE pNode = &s1.aNode[i]; if (!RTAvlroGCPhysInsert(&s1.Tree, pNode)) { RTTestIFailed("real insert i=%d\n", i); return 1; } if (RTAvlroGCPhysInsert(&s1.Tree, pNode)) { RTTestIFailed("real negative insert i=%d\n", i); return 1; } if (RTAvlroGCPhysGet(&s1.Tree, pNode->Key) != pNode) { RTTestIFailed("real get (1) i=%d\n", i); return 1; } if (RTAvlroGCPhysGet(&s1.Tree, pNode->KeyLast) != NULL) { RTTestIFailed("real negative get (2) i=%d\n", i); return 1; } if (RTAvlroGCPhysRangeGet(&s1.Tree, pNode->Key) != pNode) { RTTestIFailed("real range get (1) i=%d\n", i); return 1; } if (RTAvlroGCPhysRangeGet(&s1.Tree, pNode->Key + 1) != pNode) { RTTestIFailed("real range get (2) i=%d\n", i); return 1; } if (RTAvlroGCPhysRangeGet(&s1.Tree, pNode->KeyLast) != pNode) { RTTestIFailed("real range get (3) i=%d\n", i); return 1; } } s3 = s1; s1 = s2; for (i = 0; i < RT_ELEMENTS(s3.aNode); i++) { PAVLROGCPHYSNODECORE pNode = &s3.aNode[i]; if (RTAvlroGCPhysGet(&s3.Tree, pNode->Key) != pNode) { RTTestIFailed("real get (10) i=%d\n", i); return 1; } if (RTAvlroGCPhysRangeGet(&s3.Tree, pNode->Key) != pNode) { RTTestIFailed("real range get (10) i=%d\n", i); return 1; } j = pNode->Key + 1; do { if (RTAvlroGCPhysGet(&s3.Tree, j) != NULL) { RTTestIFailed("real negative get (11) i=%d j=%#x\n", i, j); return 1; } if (RTAvlroGCPhysRangeGet(&s3.Tree, j) != pNode) { RTTestIFailed("real range get (11) i=%d j=%#x\n", i, j); return 1; } } while (j++ < pNode->KeyLast); } return 0; } int avlul(void) { RTTestISubF("RTAvlUL"); /* * Simple linear insert and remove. */ PAVLULNODECORE pTree = 0; unsigned i; /* insert */ for (i = 0; i < 65536; i++) { PAVLULNODECORE pNode = (PAVLULNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = i; if (!RTAvlULInsert(&pTree, pNode)) { RTTestIFailed("linear insert i=%d\n", i); return 1; } /* negative. */ AVLULNODECORE Node = *pNode; if (RTAvlULInsert(&pTree, &Node)) { RTTestIFailed("linear negative insert i=%d\n", i); return 1; } } for (i = 0; i < 65536; i++) { PAVLULNODECORE pNode = RTAvlULRemove(&pTree, i); if (!pNode) { RTTestIFailed("linear remove i=%d\n", i); return 1; } pNode->pLeft = (PAVLULNODECORE)0xaaaaaaaa; pNode->pRight = (PAVLULNODECORE)0xbbbbbbbb; pNode->uchHeight = 'e'; RTMemFree(pNode); /* negative */ pNode = RTAvlULRemove(&pTree, i); if (pNode) { RTTestIFailed("linear negative remove i=%d\n", i); return 1; } } /* * Make a sparsely populated tree. */ for (i = 0; i < 65536; i += 8) { PAVLULNODECORE pNode = (PAVLULNODECORE)RTMemAlloc(sizeof(*pNode)); pNode->Key = i; if (!RTAvlULInsert(&pTree, pNode)) { RTTestIFailed("linear insert i=%d\n", i); return 1; } /* negative. */ AVLULNODECORE Node = *pNode; if (RTAvlULInsert(&pTree, &Node)) { RTTestIFailed("linear negative insert i=%d\n", i); return 1; } } /* * Remove using best fit in 5 cycles. */ unsigned j; for (j = 0; j < 4; j++) { for (i = 0; i < 65536; i += 8 * 4) { PAVLULNODECORE pNode = RTAvlULRemoveBestFit(&pTree, i, true); //PAVLULNODECORE pNode = RTAvlULRemove(&pTree, i + j * 8); if (!pNode) { RTTestIFailed("sparse remove i=%d j=%d\n", i, j); return 1; } pNode->pLeft = (PAVLULNODECORE)0xdddddddd; pNode->pRight = (PAVLULNODECORE)0xcccccccc; pNode->uchHeight = 'E'; RTMemFree(pNode); } } return 0; } int main() { /* * Init. */ RTTEST hTest; int rc = RTTestInitAndCreate("tstRTAvl", &hTest); if (rc) return rc; RTTestBanner(hTest); g_hTest = hTest; rc = RTRandAdvCreateParkMiller(&g_hRand); if (RT_FAILURE(rc)) { RTTestIFailed("RTRandAdvCreateParkMiller -> %Rrc", rc); return RTTestSummaryAndDestroy(hTest); } /* * Testing. */ unsigned i; RTTestSub(hTest, "oGCPhys(32..2048)"); for (i = 32; i < 2048; i++) if (avlogcphys(i)) break; avlogcphys(_64K); avlogcphys(_512K); avlogcphys(_4M); RTTestISubF("oGCPhys(32..2048, *1K)"); for (i = 32; i < 4096; i++) if (avlogcphysRand(i, i + _1K)) break; for (; i <= _4M; i *= 2) if (avlogcphysRand(i, i * 8)) break; avlrogcphys(); avlul(); /* * Done. */ return RTTestSummaryAndDestroy(hTest); }