/* * Copyright (c) 2000-2014 Apple Inc. All rights reserved. * * @APPLE_OSREFERENCE_LICENSE_HEADER_START@ * * This file contains Original Code and/or Modifications of Original Code * as defined in and that are subject to the Apple Public Source License * Version 2.0 (the 'License'). You may not use this file except in * compliance with the License. The rights granted to you under the License * may not be used to create, or enable the creation or redistribution of, * unlawful or unlicensed copies of an Apple operating system, or to * circumvent, violate, or enable the circumvention or violation of, any * terms of an Apple operating system software license agreement. * * Please obtain a copy of the License at * http://www.opensource.apple.com/apsl/ and read it before using this file. * * The Original Code and all software distributed under the License are * distributed on an 'AS IS' basis, WITHOUT WARRANTY OF ANY KIND, EITHER * EXPRESS OR IMPLIED, AND APPLE HEREBY DISCLAIMS ALL SUCH WARRANTIES, * INCLUDING WITHOUT LIMITATION, ANY WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE, QUIET ENJOYMENT OR NON-INFRINGEMENT. * Please see the License for the specific language governing rights and * limitations under the License. * * @APPLE_OSREFERENCE_LICENSE_HEADER_END@ */ /* * hfs_endian.c * * This file implements endian swapping routines for the HFS/HFS Plus * volume format. */ #include "hfs_endian.h" #include "hfs_dbg.h" #include "hfscommon/headers/BTreesPrivate.h" #undef ENDIAN_DEBUG /* * Internal swapping routines * * These routines handle swapping the records of leaf and index nodes. The * layout of the keys and records varies depending on the kind of B-tree * (determined by fileID). * * The direction parameter must be kSwapBTNodeBigToHost or kSwapBTNodeHostToBig. * The kSwapBTNodeHeaderRecordOnly "direction" is not valid for these routines. */ int hfs_swap_HFSPlusBTInternalNode (BlockDescriptor *src, HFSCatalogNodeID fileID, enum HFSBTSwapDirection direction); void hfs_swap_HFSPlusForkData (HFSPlusForkData *src); #if CONFIG_HFS_STD int hfs_swap_HFSBTInternalNode (BlockDescriptor *src, HFSCatalogNodeID fileID, enum HFSBTSwapDirection direction); #endif /* * hfs_swap_HFSPlusForkData */ void hfs_swap_HFSPlusForkData ( HFSPlusForkData *src ) { int i; src->logicalSize = SWAP_BE64 (src->logicalSize); src->clumpSize = SWAP_BE32 (src->clumpSize); src->totalBlocks = SWAP_BE32 (src->totalBlocks); for (i = 0; i < kHFSPlusExtentDensity; i++) { src->extents[i].startBlock = SWAP_BE32 (src->extents[i].startBlock); src->extents[i].blockCount = SWAP_BE32 (src->extents[i].blockCount); } } /* * hfs_swap_BTNode * * NOTE: This operation is not naturally symmetric. * We have to determine which way we're swapping things. */ int hfs_swap_BTNode ( BlockDescriptor *src, vnode_t vp, enum HFSBTSwapDirection direction, u_int8_t allow_empty_node ) { BTNodeDescriptor *srcDesc = src->buffer; u_int16_t *srcOffs = NULL; BTreeControlBlockPtr btcb = (BTreeControlBlockPtr)VTOF(vp)->fcbBTCBPtr; u_int16_t i; /* index to match srcDesc->numRecords */ int error = 0; #ifdef ENDIAN_DEBUG if (direction == kSwapBTNodeBigToHost) { printf ("hfs: BE -> Native Swap\n"); } else if (direction == kSwapBTNodeHostToBig) { printf ("hfs: Native -> BE Swap\n"); } else if (direction == kSwapBTNodeHeaderRecordOnly) { printf ("hfs: Not swapping descriptors\n"); } else { panic ("hfs_swap_BTNode: This is impossible"); } #endif /* * If we are doing a swap from on-disk to in-memory, then swap the node * descriptor and record offsets before we need to use them. */ if (direction == kSwapBTNodeBigToHost) { srcDesc->fLink = SWAP_BE32 (srcDesc->fLink); srcDesc->bLink = SWAP_BE32 (srcDesc->bLink); /* * When first opening a BTree, we have to read the header node before the * control block is initialized. In this case, totalNodes will be zero, * so skip the bounds checking. Also, we should ignore the header node when * checking for invalid forwards and backwards links, since the header node's * links can point back to itself legitimately. */ if (btcb->totalNodes != 0) { if (srcDesc->fLink >= btcb->totalNodes) { printf("hfs_swap_BTNode: invalid forward link (0x%08x >= 0x%08x)\n", srcDesc->fLink, btcb->totalNodes); error = fsBTInvalidHeaderErr; goto fail; } if (srcDesc->bLink >= btcb->totalNodes) { printf("hfs_swap_BTNode: invalid backward link (0x%08x >= 0x%08x)\n", srcDesc->bLink, btcb->totalNodes); error = fsBTInvalidHeaderErr; goto fail; } if ((src->blockNum != 0) && (srcDesc->fLink == (u_int32_t) src->blockNum)) { printf("hfs_swap_BTNode: invalid forward link (0x%08x == 0x%08x)\n", srcDesc->fLink, (u_int32_t) src->blockNum); error = fsBTInvalidHeaderErr; goto fail; } if ((src->blockNum != 0) && (srcDesc->bLink == (u_int32_t) src->blockNum)) { printf("hfs_swap_BTNode: invalid backward link (0x%08x == 0x%08x)\n", srcDesc->bLink, (u_int32_t) src->blockNum); error = fsBTInvalidHeaderErr; goto fail; } } /* * Check srcDesc->kind. Don't swap it because it's only one byte. */ if (srcDesc->kind < kBTLeafNode || srcDesc->kind > kBTMapNode) { printf("hfs_swap_BTNode: invalid node kind (%d)\n", srcDesc->kind); error = fsBTInvalidHeaderErr; goto fail; } /* * Check srcDesc->height. Don't swap it because it's only one byte. */ if (srcDesc->height > kMaxTreeDepth) { printf("hfs_swap_BTNode: invalid node height (%d)\n", srcDesc->height); error = fsBTInvalidHeaderErr; goto fail; } /* Don't swap srcDesc->reserved */ srcDesc->numRecords = SWAP_BE16 (srcDesc->numRecords); /* * Swap the node offsets (including the free space one!). */ srcOffs = (u_int16_t *)((char *)src->buffer + (src->blockSize - ((srcDesc->numRecords + 1) * sizeof (u_int16_t)))); /* * Sanity check that the record offsets are within the node itself. */ if ((char *)srcOffs > ((char *)src->buffer + src->blockSize) || (char *)srcOffs < ((char *)src->buffer + sizeof(BTNodeDescriptor))) { printf("hfs_swap_BTNode: invalid record count (0x%04X)\n", srcDesc->numRecords); error = fsBTInvalidHeaderErr; goto fail; } /* * Swap and sanity check each of the record offsets. */ for (i = 0; i <= srcDesc->numRecords; i++) { srcOffs[i] = SWAP_BE16 (srcOffs[i]); /* * Sanity check: must be even, and within the node itself. * * We may be called to swap an unused node, which contains all zeroes. * Unused nodes are expected only when allow_empty_node is true. * If it is false and record offset is zero, return error. */ if ((srcOffs[i] & 1) || ( (allow_empty_node == false) && (srcOffs[i] == 0)) || (srcOffs[i] < sizeof(BTNodeDescriptor) && srcOffs[i] != 0) || (srcOffs[i] >= src->blockSize)) { printf("hfs_swap_BTNode: record #%d invalid offset (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); error = fsBTInvalidHeaderErr; goto fail; } /* * Make sure the offsets are strictly increasing. Note that we're looping over * them backwards, hence the order in the comparison. */ if ((i != 0) && (srcOffs[i] >= srcOffs[i-1])) { printf("hfs_swap_BTNode: offsets %d and %d out of order (0x%04X, 0x%04X)\n", srcDesc->numRecords-i-1, srcDesc->numRecords-i, srcOffs[i], srcOffs[i-1]); error = fsBTInvalidHeaderErr; goto fail; } } } /* * Swap the records (ordered by frequency of access) */ if ((srcDesc->kind == kBTIndexNode) || (srcDesc-> kind == kBTLeafNode)) { if (VTOVCB(vp)->vcbSigWord == kHFSPlusSigWord) { error = hfs_swap_HFSPlusBTInternalNode (src, VTOC(vp)->c_fileid, direction); } #if CONFIG_HFS_STD else { error = hfs_swap_HFSBTInternalNode (src, VTOC(vp)->c_fileid, direction); } #endif if (error) goto fail; } else if (srcDesc-> kind == kBTMapNode) { /* Don't swap the bitmaps, they'll be done in the bitmap routines */ } else if (srcDesc-> kind == kBTHeaderNode) { /* The header's offset is hard-wired because we cannot trust the offset pointers. */ BTHeaderRec *srcHead = (BTHeaderRec *)((char *)src->buffer + sizeof(BTNodeDescriptor)); srcHead->treeDepth = SWAP_BE16 (srcHead->treeDepth); srcHead->rootNode = SWAP_BE32 (srcHead->rootNode); srcHead->leafRecords = SWAP_BE32 (srcHead->leafRecords); srcHead->firstLeafNode = SWAP_BE32 (srcHead->firstLeafNode); srcHead->lastLeafNode = SWAP_BE32 (srcHead->lastLeafNode); srcHead->nodeSize = SWAP_BE16 (srcHead->nodeSize); srcHead->maxKeyLength = SWAP_BE16 (srcHead->maxKeyLength); srcHead->totalNodes = SWAP_BE32 (srcHead->totalNodes); srcHead->freeNodes = SWAP_BE32 (srcHead->freeNodes); srcHead->clumpSize = SWAP_BE32 (srcHead->clumpSize); srcHead->attributes = SWAP_BE32 (srcHead->attributes); /* Don't swap srcHead->reserved1 */ /* Don't swap srcHead->btreeType; it's only one byte */ /* Don't swap srcHead->reserved2 */ /* Don't swap srcHead->reserved3 */ /* Don't swap bitmap */ } /* * If we are doing a swap from in-memory to on-disk, then swap the node * descriptor and record offsets after we're done using them. */ if (direction == kSwapBTNodeHostToBig) { /* * Sanity check and swap the forward and backward links. * Ignore the header node since its forward and backwards links can legitimately * point to itself. */ if (srcDesc->fLink >= btcb->totalNodes) { panic("hfs_UNswap_BTNode: invalid forward link (0x%08X)\n", srcDesc->fLink); error = fsBTInvalidHeaderErr; goto fail; } if ((src->blockNum != 0) && (srcDesc->fLink == (u_int32_t) src->blockNum)) { panic ("hfs_UNswap_BTNode: invalid forward link (0x%08x == 0x%08x)\n", srcDesc->fLink, (u_int32_t) src->blockNum); error = fsBTInvalidHeaderErr; goto fail; } if (srcDesc->bLink >= btcb->totalNodes) { panic("hfs_UNswap_BTNode: invalid backward link (0x%08X)\n", srcDesc->bLink); error = fsBTInvalidHeaderErr; goto fail; } if ((src->blockNum != 0) && (srcDesc->bLink == (u_int32_t) src->blockNum)) { panic ("hfs_UNswap_BTNode: invalid backward link (0x%08x == 0x%08x)\n", srcDesc->bLink, (u_int32_t) src->blockNum); error = fsBTInvalidHeaderErr; goto fail; } srcDesc->fLink = SWAP_BE32 (srcDesc->fLink); srcDesc->bLink = SWAP_BE32 (srcDesc->bLink); /* * Check srcDesc->kind. Don't swap it because it's only one byte. */ if (srcDesc->kind < kBTLeafNode || srcDesc->kind > kBTMapNode) { panic("hfs_UNswap_BTNode: invalid node kind (%d)\n", srcDesc->kind); error = fsBTInvalidHeaderErr; goto fail; } /* * Check srcDesc->height. Don't swap it because it's only one byte. */ if (srcDesc->height > kMaxTreeDepth) { panic("hfs_UNswap_BTNode: invalid node height (%d)\n", srcDesc->height); error = fsBTInvalidHeaderErr; goto fail; } /* Don't swap srcDesc->reserved */ /* * Swap the node offsets (including the free space one!). */ srcOffs = (u_int16_t *)((char *)src->buffer + (src->blockSize - ((srcDesc->numRecords + 1) * sizeof (u_int16_t)))); /* * Sanity check that the record offsets are within the node itself. */ if ((char *)srcOffs > ((char *)src->buffer + src->blockSize) || (char *)srcOffs < ((char *)src->buffer + sizeof(BTNodeDescriptor))) { panic("hfs_UNswap_BTNode: invalid record count (0x%04X)\n", srcDesc->numRecords); error = fsBTInvalidHeaderErr; goto fail; } /* * Swap and sanity check each of the record offsets. */ for (i = 0; i <= srcDesc->numRecords; i++) { /* * Sanity check: must be even, and within the node itself. * * We may be called to swap an unused node, which contains all zeroes. * This can happen when the last record from a node gets deleted. * This is why we allow the record offset to be zero. * Unused nodes are expected only when allow_empty_node is true * (the caller should set it to true for kSwapBTNodeBigToHost). */ if ((srcOffs[i] & 1) || ((allow_empty_node == false) && (srcOffs[i] == 0)) || (srcOffs[i] < sizeof(BTNodeDescriptor) && srcOffs[i] != 0) || (srcOffs[i] >= src->blockSize)) { panic("hfs_UNswap_BTNode: record #%d invalid offset (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); error = fsBTInvalidHeaderErr; goto fail; } /* * Make sure the offsets are strictly increasing. Note that we're looping over * them backwards, hence the order in the comparison. */ if ((i < srcDesc->numRecords) && (srcOffs[i+1] >= srcOffs[i])) { panic("hfs_UNswap_BTNode: offsets %d and %d out of order (0x%04X, 0x%04X)\n", srcDesc->numRecords-i-2, srcDesc->numRecords-i-1, srcOffs[i+1], srcOffs[i]); error = fsBTInvalidHeaderErr; goto fail; } srcOffs[i] = SWAP_BE16 (srcOffs[i]); } srcDesc->numRecords = SWAP_BE16 (srcDesc->numRecords); } fail: if (error) { /* * Log some useful information about where the corrupt node is. */ printf("hfs: node=%lld fileID=%u volume=%s device=%s\n", src->blockNum, VTOC(vp)->c_fileid, VTOVCB(vp)->vcbVN, vfs_statfs(vnode_mount(vp))->f_mntfromname); hfs_mark_inconsistent(VTOVCB(vp), HFS_INCONSISTENCY_DETECTED); } return (error); } int hfs_swap_HFSPlusBTInternalNode ( BlockDescriptor *src, HFSCatalogNodeID fileID, enum HFSBTSwapDirection direction ) { BTNodeDescriptor *srcDesc = src->buffer; u_int16_t *srcOffs = (u_int16_t *)((char *)src->buffer + (src->blockSize - (srcDesc->numRecords * sizeof (u_int16_t)))); char *nextRecord; /* Points to start of record following current one */ /* * i is an int32 because it needs to be negative to index the offset to free space. * srcDesc->numRecords is a u_int16_t and is unlikely to become 32-bit so this should be ok. */ int32_t i; u_int32_t j; if (fileID == kHFSExtentsFileID) { HFSPlusExtentKey *srcKey; HFSPlusExtentDescriptor *srcRec; size_t recordSize; /* Size of the data part of the record, or node number for index nodes */ if (srcDesc->kind == kBTIndexNode) recordSize = sizeof(u_int32_t); else recordSize = sizeof(HFSPlusExtentDescriptor); for (i = 0; i < srcDesc->numRecords; i++) { /* Point to the start of the record we're currently checking. */ srcKey = (HFSPlusExtentKey *)((char *)src->buffer + srcOffs[i]); /* * Point to start of next (larger offset) record. We'll use this * to be sure the current record doesn't overflow into the next * record. */ nextRecord = (char *)src->buffer + srcOffs[i-1]; /* * Make sure the key and data are within the buffer. Since both key * and data are fixed size, this is relatively easy. Note that this * relies on the keyLength being a constant; we verify the keyLength * below. */ if ((char *)srcKey + sizeof(HFSPlusExtentKey) + recordSize > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: extents key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } else { printf("hfs_swap_HFSPlusBTInternalNode: extents key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } return fsBTInvalidNodeErr; } if (direction == kSwapBTNodeBigToHost) srcKey->keyLength = SWAP_BE16 (srcKey->keyLength); if (srcKey->keyLength != sizeof(*srcKey) - sizeof(srcKey->keyLength)) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: extents key #%d invalid length (%d)\n", srcDesc->numRecords-i-1, srcKey->keyLength); } else { printf("hfs_swap_HFSPlusBTInternalNode: extents key #%d invalid length (%d)\n", srcDesc->numRecords-i-1, srcKey->keyLength); } return fsBTInvalidNodeErr; } srcRec = (HFSPlusExtentDescriptor *)((char *)srcKey + srcKey->keyLength + sizeof(srcKey->keyLength)); if (direction == kSwapBTNodeHostToBig) srcKey->keyLength = SWAP_BE16 (srcKey->keyLength); /* Don't swap srcKey->forkType; it's only one byte */ /* Don't swap srcKey->pad */ srcKey->fileID = SWAP_BE32 (srcKey->fileID); srcKey->startBlock = SWAP_BE32 (srcKey->startBlock); if (srcDesc->kind == kBTIndexNode) { /* For index nodes, the record data is just a child node number. */ *((u_int32_t *)srcRec) = SWAP_BE32 (*((u_int32_t *)srcRec)); } else { /* Swap the extent data */ for (j = 0; j < kHFSPlusExtentDensity; j++) { srcRec[j].startBlock = SWAP_BE32 (srcRec[j].startBlock); srcRec[j].blockCount = SWAP_BE32 (srcRec[j].blockCount); } } } } else if (fileID == kHFSCatalogFileID) { HFSPlusCatalogKey *srcKey; int16_t *srcPtr; u_int16_t keyLength; for (i = 0; i < srcDesc->numRecords; i++) { /* Point to the start of the record we're currently checking. */ srcKey = (HFSPlusCatalogKey *)((char *)src->buffer + srcOffs[i]); /* * Point to start of next (larger offset) record. We'll use this * to be sure the current record doesn't overflow into the next * record. */ nextRecord = (char *)src->buffer + (uintptr_t)(srcOffs[i-1]); /* * Make sure we can safely dereference the keyLength and parentID fields. */ if ((char *)srcKey + offsetof(HFSPlusCatalogKey, nodeName.unicode[0]) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: catalog key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } else { printf("hfs_swap_HFSPlusBTInternalNode: catalog key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } return fsBTInvalidNodeErr; } /* * Swap and sanity check the key length */ if (direction == kSwapBTNodeBigToHost) srcKey->keyLength = SWAP_BE16 (srcKey->keyLength); keyLength = srcKey->keyLength; /* Put it in a local (native order) because we use it several times */ if (direction == kSwapBTNodeHostToBig) srcKey->keyLength = SWAP_BE16 (keyLength); /* Sanity check the key length */ if (keyLength < kHFSPlusCatalogKeyMinimumLength || keyLength > kHFSPlusCatalogKeyMaximumLength) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: catalog key #%d invalid length (%d)\n", srcDesc->numRecords-i-1, keyLength); } else { printf("hfs_swap_HFSPlusBTInternalNode: catalog key #%d invalid length (%d)\n", srcDesc->numRecords-i-1, keyLength); } return fsBTInvalidNodeErr; } /* * Make sure that we can safely dereference the record's type field or * an index node's child node number. */ srcPtr = (int16_t *)((char *)srcKey + keyLength + sizeof(srcKey->keyLength)); if ((char *)srcPtr + sizeof(u_int32_t) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: catalog key #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: catalog key #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } srcKey->parentID = SWAP_BE32 (srcKey->parentID); /* * Swap and sanity check the key's node name */ if (direction == kSwapBTNodeBigToHost) srcKey->nodeName.length = SWAP_BE16 (srcKey->nodeName.length); /* Make sure name length is consistent with key length */ if (keyLength < sizeof(srcKey->parentID) + sizeof(srcKey->nodeName.length) + srcKey->nodeName.length*sizeof(srcKey->nodeName.unicode[0])) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: catalog record #%d keyLength=%d expected=%lu\n", srcDesc->numRecords-i, keyLength, sizeof(srcKey->parentID) + sizeof(srcKey->nodeName.length) + srcKey->nodeName.length*sizeof(srcKey->nodeName.unicode[0])); } else { printf("hfs_swap_HFSPlusBTInternalNode: catalog record #%d keyLength=%d expected=%lu\n", srcDesc->numRecords-i, keyLength, sizeof(srcKey->parentID) + sizeof(srcKey->nodeName.length) + srcKey->nodeName.length*sizeof(srcKey->nodeName.unicode[0])); } return fsBTInvalidNodeErr; } for (j = 0; j < srcKey->nodeName.length; j++) { srcKey->nodeName.unicode[j] = SWAP_BE16 (srcKey->nodeName.unicode[j]); } if (direction == kSwapBTNodeHostToBig) srcKey->nodeName.length = SWAP_BE16 (srcKey->nodeName.length); /* * For index nodes, the record data is just the child's node number. * Skip over swapping the various types of catalog record. */ if (srcDesc->kind == kBTIndexNode) { *((u_int32_t *)srcPtr) = SWAP_BE32 (*((u_int32_t *)srcPtr)); continue; } /* Make sure the recordType is in native order before using it. */ if (direction == kSwapBTNodeBigToHost) srcPtr[0] = SWAP_BE16 (srcPtr[0]); if (srcPtr[0] == kHFSPlusFolderRecord) { HFSPlusCatalogFolder *srcRec = (HFSPlusCatalogFolder *)srcPtr; if ((char *)srcRec + sizeof(*srcRec) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: catalog folder record #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: catalog folder record #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } srcRec->flags = SWAP_BE16 (srcRec->flags); srcRec->valence = SWAP_BE32 (srcRec->valence); srcRec->folderID = SWAP_BE32 (srcRec->folderID); srcRec->createDate = SWAP_BE32 (srcRec->createDate); srcRec->contentModDate = SWAP_BE32 (srcRec->contentModDate); srcRec->attributeModDate = SWAP_BE32 (srcRec->attributeModDate); srcRec->accessDate = SWAP_BE32 (srcRec->accessDate); srcRec->backupDate = SWAP_BE32 (srcRec->backupDate); srcRec->bsdInfo.ownerID = SWAP_BE32 (srcRec->bsdInfo.ownerID); srcRec->bsdInfo.groupID = SWAP_BE32 (srcRec->bsdInfo.groupID); /* Don't swap srcRec->bsdInfo.adminFlags; it's only one byte */ /* Don't swap srcRec->bsdInfo.ownerFlags; it's only one byte */ srcRec->bsdInfo.fileMode = SWAP_BE16 (srcRec->bsdInfo.fileMode); srcRec->bsdInfo.special.iNodeNum = SWAP_BE32 (srcRec->bsdInfo.special.iNodeNum); srcRec->textEncoding = SWAP_BE32 (srcRec->textEncoding); /* Don't swap srcRec->userInfo */ /* Don't swap srcRec->finderInfo */ srcRec->folderCount = SWAP_BE32 (srcRec->folderCount); } else if (srcPtr[0] == kHFSPlusFileRecord) { HFSPlusCatalogFile *srcRec = (HFSPlusCatalogFile *)srcPtr; if ((char *)srcRec + sizeof(*srcRec) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: catalog file record #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: catalog file record #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } srcRec->flags = SWAP_BE16 (srcRec->flags); srcRec->fileID = SWAP_BE32 (srcRec->fileID); srcRec->createDate = SWAP_BE32 (srcRec->createDate); srcRec->contentModDate = SWAP_BE32 (srcRec->contentModDate); srcRec->attributeModDate = SWAP_BE32 (srcRec->attributeModDate); srcRec->accessDate = SWAP_BE32 (srcRec->accessDate); srcRec->backupDate = SWAP_BE32 (srcRec->backupDate); srcRec->bsdInfo.ownerID = SWAP_BE32 (srcRec->bsdInfo.ownerID); srcRec->bsdInfo.groupID = SWAP_BE32 (srcRec->bsdInfo.groupID); /* Don't swap srcRec->bsdInfo.adminFlags; it's only one byte */ /* Don't swap srcRec->bsdInfo.ownerFlags; it's only one byte */ srcRec->bsdInfo.fileMode = SWAP_BE16 (srcRec->bsdInfo.fileMode); srcRec->bsdInfo.special.iNodeNum = SWAP_BE32 (srcRec->bsdInfo.special.iNodeNum); srcRec->textEncoding = SWAP_BE32 (srcRec->textEncoding); /* If kHFSHasLinkChainBit is set, reserved1 is hl_FirstLinkID. * In all other context, it is expected to be zero. */ srcRec->reserved1 = SWAP_BE32 (srcRec->reserved1); /* Don't swap srcRec->userInfo */ /* Don't swap srcRec->finderInfo */ /* Don't swap srcRec->reserved2 */ hfs_swap_HFSPlusForkData (&srcRec->dataFork); hfs_swap_HFSPlusForkData (&srcRec->resourceFork); } else if ((srcPtr[0] == kHFSPlusFolderThreadRecord) || (srcPtr[0] == kHFSPlusFileThreadRecord)) { /* * Make sure there is room for parentID and name length. */ HFSPlusCatalogThread *srcRec = (HFSPlusCatalogThread *)srcPtr; if ((char *) &srcRec->nodeName.unicode[0] > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: catalog thread record #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: catalog thread record #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } /* Don't swap srcRec->reserved */ srcRec->parentID = SWAP_BE32 (srcRec->parentID); if (direction == kSwapBTNodeBigToHost) srcRec->nodeName.length = SWAP_BE16 (srcRec->nodeName.length); /* * Make sure there is room for the name in the buffer. * Then swap the characters of the name itself. */ if ((char *) &srcRec->nodeName.unicode[srcRec->nodeName.length] > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: catalog thread record #%d name too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: catalog thread record #%d name too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } for (j = 0; j < srcRec->nodeName.length; j++) { srcRec->nodeName.unicode[j] = SWAP_BE16 (srcRec->nodeName.unicode[j]); } if (direction == kSwapBTNodeHostToBig) srcRec->nodeName.length = SWAP_BE16 (srcRec->nodeName.length); } else { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: unrecognized catalog record type (0x%04X; record #%d)\n", srcPtr[0], srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: unrecognized catalog record type (0x%04X; record #%d)\n", srcPtr[0], srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } /* We can swap the record type now that we're done using it. */ if (direction == kSwapBTNodeHostToBig) srcPtr[0] = SWAP_BE16 (srcPtr[0]); } } else if (fileID == kHFSAttributesFileID) { HFSPlusAttrKey *srcKey; HFSPlusAttrRecord *srcRec; u_int16_t keyLength; u_int32_t attrSize = 0; for (i = 0; i < srcDesc->numRecords; i++) { /* Point to the start of the record we're currently checking. */ srcKey = (HFSPlusAttrKey *)((char *)src->buffer + srcOffs[i]); /* * Point to start of next (larger offset) record. We'll use this * to be sure the current record doesn't overflow into the next * record. */ nextRecord = (char *)src->buffer + srcOffs[i-1]; /* Make sure there is room in the buffer for a minimal key */ if ((char *) &srcKey->attrName[1] > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: attr key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } else { printf("hfs_swap_HFSPlusBTInternalNode: attr key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } return fsBTInvalidNodeErr; } /* Swap the key length field */ if (direction == kSwapBTNodeBigToHost) srcKey->keyLength = SWAP_BE16(srcKey->keyLength); keyLength = srcKey->keyLength; /* Keep a copy in native order */ if (direction == kSwapBTNodeHostToBig) srcKey->keyLength = SWAP_BE16(srcKey->keyLength); /* * Make sure that we can safely dereference the record's type field or * an index node's child node number. */ srcRec = (HFSPlusAttrRecord *)((char *)srcKey + keyLength + sizeof(srcKey->keyLength)); if ((char *)srcRec + sizeof(u_int32_t) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: attr key #%d too big (%d)\n", srcDesc->numRecords-i-1, keyLength); } else { printf("hfs_swap_HFSPlusBTInternalNode: attr key #%d too big (%d)\n", srcDesc->numRecords-i-1, keyLength); } return fsBTInvalidNodeErr; } srcKey->fileID = SWAP_BE32(srcKey->fileID); srcKey->startBlock = SWAP_BE32(srcKey->startBlock); /* * Swap and check the attribute name */ if (direction == kSwapBTNodeBigToHost) srcKey->attrNameLen = SWAP_BE16(srcKey->attrNameLen); /* Sanity check the attribute name length */ if (srcKey->attrNameLen > kHFSMaxAttrNameLen || keyLength < (kHFSPlusAttrKeyMinimumLength + sizeof(u_int16_t)*srcKey->attrNameLen)) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: attr key #%d keyLength=%d attrNameLen=%d\n", srcDesc->numRecords-i-1, keyLength, srcKey->attrNameLen); } else { printf("hfs_swap_HFSPlusBTInternalNode: attr key #%d keyLength=%d attrNameLen=%d\n", srcDesc->numRecords-i-1, keyLength, srcKey->attrNameLen); } return fsBTInvalidNodeErr; } for (j = 0; j < srcKey->attrNameLen; j++) srcKey->attrName[j] = SWAP_BE16(srcKey->attrName[j]); if (direction == kSwapBTNodeHostToBig) srcKey->attrNameLen = SWAP_BE16(srcKey->attrNameLen); /* * For index nodes, the record data is just the child's node number. * Skip over swapping the various types of attribute record. */ if (srcDesc->kind == kBTIndexNode) { *((u_int32_t *)srcRec) = SWAP_BE32 (*((u_int32_t *)srcRec)); continue; } /* Swap the record data */ if (direction == kSwapBTNodeBigToHost) srcRec->recordType = SWAP_BE32(srcRec->recordType); switch (srcRec->recordType) { case kHFSPlusAttrInlineData: /* Is there room for the inline data header? */ if ((char *) &srcRec->attrData.attrData[0] > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: attr inline #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: attr inline #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } /* We're not swapping the reserved fields */ /* Swap the attribute size */ if (direction == kSwapBTNodeHostToBig) attrSize = srcRec->attrData.attrSize; srcRec->attrData.attrSize = SWAP_BE32(srcRec->attrData.attrSize); if (direction == kSwapBTNodeBigToHost) attrSize = srcRec->attrData.attrSize; /* Is there room for the inline attribute data? */ if ((char *) &srcRec->attrData.attrData[attrSize] > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: attr inline #%d too big (attrSize=%u)\n", srcDesc->numRecords-i-1, attrSize); } else { printf("hfs_swap_HFSPlusBTInternalNode: attr inline #%d too big (attrSize=%u)\n", srcDesc->numRecords-i-1, attrSize); } return fsBTInvalidNodeErr; } /* Not swapping the attribute data itself */ break; case kHFSPlusAttrForkData: /* Is there room for the fork data record? */ if ((char *)srcRec + sizeof(HFSPlusAttrForkData) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: attr fork data #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: attr fork data #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } /* We're not swapping the reserved field */ hfs_swap_HFSPlusForkData(&srcRec->forkData.theFork); break; case kHFSPlusAttrExtents: /* Is there room for an extent record? */ if ((char *)srcRec + sizeof(HFSPlusAttrExtents) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: attr extents #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSPlusBTInternalNode: attr extents #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } /* We're not swapping the reserved field */ for (j = 0; j < kHFSPlusExtentDensity; j++) { srcRec->overflowExtents.extents[j].startBlock = SWAP_BE32(srcRec->overflowExtents.extents[j].startBlock); srcRec->overflowExtents.extents[j].blockCount = SWAP_BE32(srcRec->overflowExtents.extents[j].blockCount); } break; } if (direction == kSwapBTNodeHostToBig) srcRec->recordType = SWAP_BE32(srcRec->recordType); } } else if (fileID > kHFSFirstUserCatalogNodeID) { /* The only B-tree with a non-system CNID that we use is the hotfile B-tree */ HotFileKey *srcKey; u_int32_t *srcRec; for (i = 0; i < srcDesc->numRecords; i++) { /* Point to the start of the record we're currently checking. */ srcKey = (HotFileKey *)((char *)src->buffer + srcOffs[i]); /* * Point to start of next (larger offset) record. We'll use this * to be sure the current record doesn't overflow into the next * record. */ nextRecord = (char *)src->buffer + srcOffs[i-1]; /* Make sure there is room for the key (HotFileKey) and data (u_int32_t) */ if ((char *)srcKey + sizeof(HotFileKey) + sizeof(u_int32_t) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: hotfile #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } else { printf("hfs_swap_HFSPlusBTInternalNode: hotfile #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } return fsBTInvalidNodeErr; } /* Swap and sanity check the key length field */ if (direction == kSwapBTNodeBigToHost) srcKey->keyLength = SWAP_BE16 (srcKey->keyLength); if (srcKey->keyLength != sizeof(*srcKey) - sizeof(srcKey->keyLength)) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSPlusBTInternalNode: hotfile #%d incorrect keyLength %d\n", srcDesc->numRecords-i-1, srcKey->keyLength); } else { printf("hfs_swap_HFSPlusBTInternalNode: hotfile #%d incorrect keyLength %d\n", srcDesc->numRecords-i-1, srcKey->keyLength); } return fsBTInvalidNodeErr; } srcRec = (u_int32_t *)((char *)srcKey + srcKey->keyLength + sizeof(srcKey->keyLength)); if (direction == kSwapBTNodeHostToBig) srcKey->keyLength = SWAP_BE16 (srcKey->keyLength); /* Don't swap srcKey->forkType */ /* Don't swap srcKey->pad */ srcKey->temperature = SWAP_BE32 (srcKey->temperature); srcKey->fileID = SWAP_BE32 (srcKey->fileID); *((u_int32_t *)srcRec) = SWAP_BE32 (*((u_int32_t *)srcRec)); } } else { panic ("hfs_swap_HFSPlusBTInternalNode: fileID %u is not a system B-tree\n", fileID); } return (0); } #if CONFIG_HFS_STD int hfs_swap_HFSBTInternalNode ( BlockDescriptor *src, HFSCatalogNodeID fileID, enum HFSBTSwapDirection direction ) { BTNodeDescriptor *srcDesc = src->buffer; u_int16_t *srcOffs = (u_int16_t *)((char *)src->buffer + (src->blockSize - (srcDesc->numRecords * sizeof (u_int16_t)))); char *nextRecord; /* Points to start of record following current one */ /* * i is an int32 because it needs to be negative to index the offset to free space. * srcDesc->numRecords is a u_int16_t and is unlikely to become 32-bit so this should be ok. */ int32_t i; u_int32_t j; if (fileID == kHFSExtentsFileID) { HFSExtentKey *srcKey; HFSExtentDescriptor *srcRec; size_t recordSize; /* Size of the data part of the record, or node number for index nodes */ if (srcDesc->kind == kBTIndexNode) recordSize = sizeof(u_int32_t); else recordSize = sizeof(HFSExtentDescriptor); for (i = 0; i < srcDesc->numRecords; i++) { /* Point to the start of the record we're currently checking. */ srcKey = (HFSExtentKey *)((char *)src->buffer + srcOffs[i]); /* * Point to start of next (larger offset) record. We'll use this * to be sure the current record doesn't overflow into the next * record. */ nextRecord = (char *)src->buffer + srcOffs[i-1]; /* * Make sure the key and data are within the buffer. Since both key * and data are fixed size, this is relatively easy. Note that this * relies on the keyLength being a constant; we verify the keyLength * below. */ if ((char *)srcKey + sizeof(HFSExtentKey) + recordSize > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: extents key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } else { printf("hfs_swap_HFSBTInternalNode: extents key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } return fsBTInvalidNodeErr; } /* Don't swap srcKey->keyLength (it's only one byte), but do sanity check it */ if (srcKey->keyLength != sizeof(*srcKey) - sizeof(srcKey->keyLength)) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: extents key #%d invalid length (%d)\n", srcDesc->numRecords-i-1, srcKey->keyLength); } else { printf("hfs_swap_HFSBTInternalNode: extents key #%d invalid length (%d)\n", srcDesc->numRecords-i-1, srcKey->keyLength); } return fsBTInvalidNodeErr; } /* Don't swap srcKey->forkType; it's only one byte */ srcKey->fileID = SWAP_BE32 (srcKey->fileID); srcKey->startBlock = SWAP_BE16 (srcKey->startBlock); /* Point to record data (round up to even byte boundary) */ srcRec = (HFSExtentDescriptor *)((char *)srcKey + ((srcKey->keyLength + 2) & ~1)); if (srcDesc->kind == kBTIndexNode) { /* For index nodes, the record data is just a child node number. */ *((u_int32_t *)srcRec) = SWAP_BE32 (*((u_int32_t *)srcRec)); } else { /* Swap the extent data */ for (j = 0; j < kHFSExtentDensity; j++) { srcRec[j].startBlock = SWAP_BE16 (srcRec[j].startBlock); srcRec[j].blockCount = SWAP_BE16 (srcRec[j].blockCount); } } } } else if (fileID == kHFSCatalogFileID) { HFSCatalogKey *srcKey; int16_t *srcPtr; unsigned expectedKeyLength; for (i = 0; i < srcDesc->numRecords; i++) { /* Point to the start of the record we're currently checking. */ srcKey = (HFSCatalogKey *)((char *)src->buffer + srcOffs[i]); /* * Point to start of next (larger offset) record. We'll use this * to be sure the current record doesn't overflow into the next * record. */ nextRecord = (char *)src->buffer + srcOffs[i-1]; /* * Make sure we can safely dereference the keyLength and parentID fields. * The value 8 below is 1 bytes for keyLength + 1 byte reserved + 4 bytes * for parentID + 1 byte for nodeName's length + 1 byte to round up the * record start to an even offset, which forms a minimal key. */ if ((char *)srcKey + 8 > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: catalog key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } else { printf("hfs_swap_HFSBTInternalNode: catalog key #%d offset too big (0x%04X)\n", srcDesc->numRecords-i-1, srcOffs[i]); } return fsBTInvalidNodeErr; } /* Don't swap srcKey->keyLength (it's only one byte), but do sanity check it */ if (srcKey->keyLength < kHFSCatalogKeyMinimumLength || srcKey->keyLength > kHFSCatalogKeyMaximumLength) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: catalog key #%d invalid length (%d)\n", srcDesc->numRecords-i-1, srcKey->keyLength); } else { printf("hfs_swap_HFSBTInternalNode: catalog key #%d invalid length (%d)\n", srcDesc->numRecords-i-1, srcKey->keyLength); } return fsBTInvalidNodeErr; } /* Don't swap srcKey->reserved */ srcKey->parentID = SWAP_BE32 (srcKey->parentID); /* Don't swap srcKey->nodeName */ /* Make sure the keyLength is big enough for the key's content */ if (srcDesc->kind == kBTIndexNode) expectedKeyLength = sizeof(*srcKey) - sizeof(srcKey->keyLength); else expectedKeyLength = srcKey->nodeName[0] + kHFSCatalogKeyMinimumLength; if (srcKey->keyLength < expectedKeyLength) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: catalog record #%d keyLength=%u expected=%u\n", srcDesc->numRecords-i, srcKey->keyLength, expectedKeyLength); } else { printf("hfs_swap_HFSBTInternalNode: catalog record #%d keyLength=%u expected=%u\n", srcDesc->numRecords-i, srcKey->keyLength, expectedKeyLength); } return fsBTInvalidNodeErr; } /* Point to record data (round up to even byte boundary) */ srcPtr = (int16_t *)((char *)srcKey + ((srcKey->keyLength + 2) & ~1)); /* * Make sure that we can safely dereference the record's type field or * and index node's child node number. */ if ((char *)srcPtr + sizeof(u_int32_t) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: catalog key #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSBTInternalNode: catalog key #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } /* * For index nodes, the record data is just the child's node number. * Skip over swapping the various types of catalog record. */ if (srcDesc->kind == kBTIndexNode) { *((u_int32_t *)srcPtr) = SWAP_BE32 (*((u_int32_t *)srcPtr)); continue; } /* Make sure the recordType is in native order before using it. */ if (direction == kSwapBTNodeBigToHost) srcPtr[0] = SWAP_BE16 (srcPtr[0]); if (srcPtr[0] == kHFSFolderRecord) { HFSCatalogFolder *srcRec = (HFSCatalogFolder *)srcPtr; if ((char *)srcRec + sizeof(*srcRec) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: catalog folder record #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSBTInternalNode: catalog folder record #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } srcRec->flags = SWAP_BE16 (srcRec->flags); srcRec->valence = SWAP_BE16 (srcRec->valence); srcRec->folderID = SWAP_BE32 (srcRec->folderID); srcRec->createDate = SWAP_BE32 (srcRec->createDate); srcRec->modifyDate = SWAP_BE32 (srcRec->modifyDate); srcRec->backupDate = SWAP_BE32 (srcRec->backupDate); /* Don't swap srcRec->userInfo */ /* Don't swap srcRec->finderInfo */ /* Don't swap resserved array */ } else if (srcPtr[0] == kHFSFileRecord) { HFSCatalogFile *srcRec = (HFSCatalogFile *)srcPtr; if ((char *)srcRec + sizeof(*srcRec) > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: catalog file record #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSBTInternalNode: catalog file record #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } srcRec->flags = srcRec->flags; srcRec->fileType = srcRec->fileType; /* Don't swap srcRec->userInfo */ srcRec->fileID = SWAP_BE32 (srcRec->fileID); srcRec->dataStartBlock = SWAP_BE16 (srcRec->dataStartBlock); srcRec->dataLogicalSize = SWAP_BE32 (srcRec->dataLogicalSize); srcRec->dataPhysicalSize = SWAP_BE32 (srcRec->dataPhysicalSize); srcRec->rsrcStartBlock = SWAP_BE16 (srcRec->rsrcStartBlock); srcRec->rsrcLogicalSize = SWAP_BE32 (srcRec->rsrcLogicalSize); srcRec->rsrcPhysicalSize = SWAP_BE32 (srcRec->rsrcPhysicalSize); srcRec->createDate = SWAP_BE32 (srcRec->createDate); srcRec->modifyDate = SWAP_BE32 (srcRec->modifyDate); srcRec->backupDate = SWAP_BE32 (srcRec->backupDate); /* Don't swap srcRec->finderInfo */ srcRec->clumpSize = SWAP_BE16 (srcRec->clumpSize); /* Swap the two sets of extents as an array of six (three each) u_int16_t */ for (j = 0; j < kHFSExtentDensity * 2; j++) { srcRec->dataExtents[j].startBlock = SWAP_BE16 (srcRec->dataExtents[j].startBlock); srcRec->dataExtents[j].blockCount = SWAP_BE16 (srcRec->dataExtents[j].blockCount); } /* Don't swap srcRec->reserved */ } else if ((srcPtr[0] == kHFSFolderThreadRecord) || (srcPtr[0] == kHFSFileThreadRecord)) { HFSCatalogThread *srcRec = (HFSCatalogThread *)srcPtr; /* Make sure there is room for parentID and name length */ if ((char *) &srcRec->nodeName[1] > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: catalog thread record #%d too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSBTInternalNode: catalog thread record #%d too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } /* Don't swap srcRec->reserved array */ srcRec->parentID = SWAP_BE32 (srcRec->parentID); /* Don't swap srcRec->nodeName */ /* Make sure there is room for the name in the buffer */ if ((char *) &srcRec->nodeName[srcRec->nodeName[0]] > nextRecord) { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: catalog thread record #%d name too big\n", srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSBTInternalNode: catalog thread record #%d name too big\n", srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } } else { if (direction == kSwapBTNodeHostToBig) { panic("hfs_swap_HFSBTInternalNode: unrecognized catalog record type (0x%04X; record #%d)\n", srcPtr[0], srcDesc->numRecords-i-1); } else { printf("hfs_swap_HFSBTInternalNode: unrecognized catalog record type (0x%04X; record #%d)\n", srcPtr[0], srcDesc->numRecords-i-1); } return fsBTInvalidNodeErr; } /* We can swap the record type now that we're done using it */ if (direction == kSwapBTNodeHostToBig) srcPtr[0] = SWAP_BE16 (srcPtr[0]); } } else { panic ("hfs_swap_HFSBTInternalNode: fileID %u is not a system B-tree\n", fileID); } return (0); } #endif