hacks/dump-imessages/iphone-dataprotection/emf_decrypter/hfs/btree.c

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#include <stdlib.h>
#include <hfs/hfsplus.h>
BTNodeDescriptor* readBTNodeDescriptor(uint32_t num, BTree* tree) {
BTNodeDescriptor* descriptor;
descriptor = (BTNodeDescriptor*) malloc(sizeof(BTNodeDescriptor));
if(!READ(tree->io, num * tree->headerRec->nodeSize, sizeof(BTNodeDescriptor), descriptor))
return NULL;
FLIPENDIAN(descriptor->fLink);
FLIPENDIAN(descriptor->bLink);
FLIPENDIAN(descriptor->numRecords);
return descriptor;
}
static int writeBTNodeDescriptor(BTNodeDescriptor* descriptor, uint32_t num, BTree* tree) {
BTNodeDescriptor myDescriptor;
myDescriptor = *descriptor;
FLIPENDIAN(myDescriptor.fLink);
FLIPENDIAN(myDescriptor.bLink);
FLIPENDIAN(myDescriptor.numRecords);
if(!WRITE(tree->io, num * tree->headerRec->nodeSize, sizeof(BTNodeDescriptor), &myDescriptor))
return FALSE;
return TRUE;
}
BTHeaderRec* readBTHeaderRec(io_func* io) {
BTHeaderRec* headerRec;
headerRec = (BTHeaderRec*) malloc(sizeof(BTHeaderRec));
if(!READ(io, sizeof(BTNodeDescriptor), sizeof(BTHeaderRec), headerRec)) {
free(headerRec);
return NULL;
}
FLIPENDIAN(headerRec->treeDepth);
FLIPENDIAN(headerRec->rootNode);
FLIPENDIAN(headerRec->leafRecords);
FLIPENDIAN(headerRec->firstLeafNode);
FLIPENDIAN(headerRec->lastLeafNode);
FLIPENDIAN(headerRec->nodeSize);
FLIPENDIAN(headerRec->maxKeyLength);
FLIPENDIAN(headerRec->totalNodes);
FLIPENDIAN(headerRec->freeNodes);
FLIPENDIAN(headerRec->clumpSize);
FLIPENDIAN(headerRec->attributes);
/*printf("treeDepth: %d\n", headerRec->treeDepth);
printf("rootNode: %d\n", headerRec->rootNode);
printf("leafRecords: %d\n", headerRec->leafRecords);
printf("firstLeafNode: %d\n", headerRec->firstLeafNode);
printf("lastLeafNode: %d\n", headerRec->lastLeafNode);
printf("nodeSize: %d\n", headerRec->nodeSize);
printf("maxKeyLength: %d\n", headerRec->maxKeyLength);
printf("totalNodes: %d\n", headerRec->totalNodes);
printf("freeNodes: %d\n", headerRec->freeNodes);
printf("clumpSize: %d\n", headerRec->clumpSize);
printf("bTreeType: 0x%x\n", headerRec->btreeType);
printf("keyCompareType: 0x%x\n", headerRec->keyCompareType);
printf("attributes: 0x%x\n", headerRec->attributes);
fflush(stdout);*/
return headerRec;
}
static int writeBTHeaderRec(BTree* tree) {
BTHeaderRec headerRec;
headerRec = *tree->headerRec;
FLIPENDIAN(headerRec.treeDepth);
FLIPENDIAN(headerRec.rootNode);
FLIPENDIAN(headerRec.leafRecords);
FLIPENDIAN(headerRec.firstLeafNode);
FLIPENDIAN(headerRec.lastLeafNode);
FLIPENDIAN(headerRec.nodeSize);
FLIPENDIAN(headerRec.maxKeyLength);
FLIPENDIAN(headerRec.totalNodes);
FLIPENDIAN(headerRec.freeNodes);
FLIPENDIAN(headerRec.clumpSize);
FLIPENDIAN(headerRec.attributes);
if(!WRITE(tree->io, sizeof(BTNodeDescriptor), sizeof(BTHeaderRec), &headerRec))
return FALSE;
return TRUE;
}
BTree* openBTree(io_func* io, compareFunc compare, dataReadFunc keyRead, keyWriteFunc keyWrite, keyPrintFunc keyPrint, dataReadFunc dataRead) {
BTree* tree;
tree = (BTree*) malloc(sizeof(BTree));
tree->io = io;
tree->headerRec = readBTHeaderRec(tree->io);
if(tree->headerRec == NULL) {
free(tree);
return NULL;
}
tree->compare = compare;
tree->keyRead = keyRead;
tree->keyWrite = keyWrite;
tree->keyPrint = keyPrint;
tree->dataRead = dataRead;
return tree;
}
void closeBTree(BTree* tree) {
(*tree->io->close)(tree->io);
free(tree->headerRec);
free(tree);
}
off_t getRecordOffset(int num, uint32_t nodeNum, BTree* tree) {
uint16_t offset;
off_t nodeOffset;
nodeOffset = nodeNum * tree->headerRec->nodeSize;
if(!READ(tree->io, nodeOffset + tree->headerRec->nodeSize - (sizeof(uint16_t) * (num + 1)), sizeof(uint16_t), &offset)) {
hfs_panic("cannot get record offset!");
}
FLIPENDIAN(offset);
//printf("%d: %d %d\n", nodeOffset + tree->headerRec->nodeSize - (sizeof(uint16_t) * (num + 1)), nodeOffset + offset, offset);
return (nodeOffset + offset);
}
static off_t getFreeSpace(uint32_t nodeNum, BTNodeDescriptor* descriptor, BTree* tree) {
uint16_t num;
off_t nodeOffset;
off_t freespaceOffsetOffset;
uint16_t offset;
off_t freespaceOffset;
num = descriptor->numRecords;
nodeOffset = nodeNum * tree->headerRec->nodeSize;
freespaceOffsetOffset = nodeOffset + tree->headerRec->nodeSize - (sizeof(uint16_t) * (num + 1));
if(!READ(tree->io, freespaceOffsetOffset, sizeof(uint16_t), &offset)) {
hfs_panic("cannot get record offset!");
}
FLIPENDIAN(offset);
freespaceOffset = nodeOffset + offset;
return (freespaceOffsetOffset - freespaceOffset);
}
off_t getNodeNumberFromPointerRecord(off_t offset, io_func* io) {
uint32_t nodeNum;
if(!READ(io, offset, sizeof(uint32_t), &nodeNum)) {
hfs_panic("cannot get node number from pointer record!");
}
FLIPENDIAN(nodeNum);
return nodeNum;
}
static void* searchNode(BTree* tree, uint32_t root, BTKey* searchKey, int *exact, uint32_t *nodeNumber, int *recordNumber) {
BTNodeDescriptor* descriptor;
BTKey* key;
off_t recordOffset;
off_t recordDataOffset;
off_t lastRecordDataOffset;
int res;
int i;
descriptor = readBTNodeDescriptor(root, tree);
if(descriptor == NULL)
return NULL;
lastRecordDataOffset = 0;
for(i = 0; i < descriptor->numRecords; i++) {
recordOffset = getRecordOffset(i, root, tree);
key = READ_KEY(tree, recordOffset, tree->io);
recordDataOffset = recordOffset + key->keyLength + sizeof(key->keyLength);
res = COMPARE(tree, key, searchKey);
free(key);
if(res == 0) {
if(descriptor->kind == kBTLeafNode) {
if(nodeNumber != NULL)
*nodeNumber = root;
if(recordNumber != NULL)
*recordNumber = i;
if(exact != NULL)
*exact = TRUE;
free(descriptor);
return READ_DATA(tree, recordDataOffset, tree->io);
} else {
free(descriptor);
return searchNode(tree, getNodeNumberFromPointerRecord(recordDataOffset, tree->io), searchKey, exact, nodeNumber, recordNumber);
}
} else if(res > 0) {
break;
}
lastRecordDataOffset = recordDataOffset;
}
if(lastRecordDataOffset == 0) {
hfs_panic("BTree inconsistent!");
return NULL;
}
if(descriptor->kind == kBTLeafNode) {
if(nodeNumber != NULL)
*nodeNumber = root;
if(recordNumber != NULL)
*recordNumber = i;
if(exact != NULL)
*exact = FALSE;
free(descriptor);
return READ_DATA(tree, lastRecordDataOffset, tree->io);
} else if(descriptor->kind == kBTIndexNode) {
free(descriptor);
return searchNode(tree, getNodeNumberFromPointerRecord(lastRecordDataOffset, tree->io), searchKey, exact, nodeNumber, recordNumber);
} else {
if(nodeNumber != NULL)
*nodeNumber = root;
if(recordNumber != NULL)
*recordNumber = i;
if(exact != NULL)
*exact = FALSE;
free(descriptor);
return NULL;
}
}
void* search(BTree* tree, BTKey* searchKey, int *exact, uint32_t *nodeNumber, int *recordNumber) {
return searchNode(tree, tree->headerRec->rootNode, searchKey, exact, nodeNumber, recordNumber);
}
static uint32_t linearCheck(uint32_t* heightTable, unsigned char* map, BTree* tree, uint32_t *errCount) {
uint8_t i;
uint8_t j;
uint32_t node;
uint32_t count;
uint32_t leafRecords;
BTNodeDescriptor* descriptor;
uint32_t prevNode;
off_t recordOffset;
BTKey* key;
BTKey* previousKey;
count = 0;
leafRecords = 0;
for(i = 0; i <= tree->headerRec->treeDepth; i++) {
node = heightTable[i];
if(node != 0) {
descriptor = readBTNodeDescriptor(node, tree);
while(descriptor->bLink != 0) {
node = descriptor->bLink;
free(descriptor);
descriptor = readBTNodeDescriptor(node, tree);
}
free(descriptor);
prevNode = 0;
previousKey = NULL;
if(i == 1) {
if(node != tree->headerRec->firstLeafNode) {
printf("BTREE CONSISTENCY ERROR: First leaf node (%d) is not correct. Should be: %d\n", tree->headerRec->firstLeafNode, node);
(*errCount)++;
}
}
while(node != 0) {
descriptor = readBTNodeDescriptor(node, tree);
if(descriptor->bLink != prevNode) {
printf("BTREE CONSISTENCY ERROR: Node %d is not properly linked with previous node %d\n", node, prevNode);
(*errCount)++;
}
if(descriptor->height != i) {
printf("BTREE CONSISTENCY ERROR: Node %d (%d) is not properly linked with nodes of the same height %d\n", node, descriptor->height, i);
(*errCount)++;
}
if((map[node / 8] & (1 << (7 - (node % 8)))) == 0) {
printf("BTREE CONSISTENCY ERROR: Node %d not marked allocated\n", node);
(*errCount)++;
}
/*if(descriptor->kind == kBTIndexNode && descriptor->numRecords < 2) {
printf("BTREE CONSISTENCY ERROR: Node %d does not have at least two children\n", node);
(*errCount)++;
}*/
for(j = 0; j < descriptor->numRecords; j++) {
recordOffset = getRecordOffset(j, node, tree);
key = READ_KEY(tree, recordOffset, tree->io);
if(previousKey != NULL) {
if(COMPARE(tree, key, previousKey) < 0) {
printf("BTREE CONSISTENCY ERROR: Ordering not preserved during linear check for record %d node %d: ", j, node);
(*errCount)++;
tree->keyPrint(previousKey);
printf(" < ");
tree->keyPrint(key);
printf("\n");
}
free(previousKey);
}
if(i == 1) {
leafRecords++;
}
previousKey = key;
}
count++;
prevNode = node;
node = descriptor->fLink;
free(descriptor);
}
if(i == 1) {
if(prevNode != tree->headerRec->lastLeafNode) {
printf("BTREE CONSISTENCY ERROR: Last leaf node (%d) is not correct. Should be: %d\n", tree->headerRec->lastLeafNode, node);
(*errCount)++;
}
}
free(previousKey);
}
}
if(leafRecords != tree->headerRec->leafRecords) {
printf("BTREE CONSISTENCY ERROR: leafRecords (%d) is not correct. Should be: %d\n", tree->headerRec->leafRecords, leafRecords);
(*errCount)++;
}
return count;
}
static uint32_t traverseNode(uint32_t nodeNum, BTree* tree, unsigned char* map, int parentHeight, BTKey** firstKey, BTKey** lastKey,
uint32_t* heightTable, uint32_t* errCount, int displayTree) {
BTNodeDescriptor* descriptor;
BTKey* key;
BTKey* previousKey;
BTKey* retFirstKey;
BTKey* retLastKey;
int i, j;
int res;
uint32_t count;
off_t recordOffset;
off_t recordDataOffset;
off_t lastrecordDataOffset;
descriptor = readBTNodeDescriptor(nodeNum, tree);
previousKey = NULL;
count = 1;
if(displayTree) {
for(i = 0; i < descriptor->height; i++) {
printf(" ");
}
}
if(descriptor->kind == kBTLeafNode) {
if(displayTree)
printf("Leaf %d: %d", nodeNum, descriptor->numRecords);
if(descriptor->height != 1) {
printf("BTREE CONSISTENCY ERROR: Leaf node %d does not have height 1\n", nodeNum); fflush(stdout);
(*errCount)++;
}
} else if(descriptor->kind == kBTIndexNode) {
if(displayTree)
printf("Index %d: %d", nodeNum, descriptor->numRecords);
} else {
printf("BTREE CONSISTENCY ERROR: Unexpected node %d has kind %d\n", nodeNum, descriptor->kind); fflush(stdout);
(*errCount)++;
}
if(displayTree) {
printf("\n"); fflush(stdout);
}
if((map[nodeNum / 8] & (1 << (7 - (nodeNum % 8)))) == 0) {
printf("BTREE CONSISTENCY ERROR: Node %d not marked allocated\n", nodeNum); fflush(stdout);
(*errCount)++;
}
if(nodeNum == tree->headerRec->rootNode) {
if(descriptor->height != tree->headerRec->treeDepth) {
printf("BTREE CONSISTENCY ERROR: Root node %d (%d) does not have the proper height (%d)\n", nodeNum,
descriptor->height, tree->headerRec->treeDepth); fflush(stdout);
(*errCount)++;
}
} else {
if(descriptor->height != (parentHeight - 1)) {
printf("BTREE CONSISTENCY ERROR: Node %d does not have the proper height\n", nodeNum); fflush(stdout);
(*errCount)++;
}
}
/*if(descriptor->kind == kBTIndexNode && descriptor->numRecords < 2) {
printf("BTREE CONSISTENCY ERROR: Node %d does not have at least two children\n", nodeNum);
(*errCount)++;
}*/
heightTable[descriptor->height] = nodeNum;
lastrecordDataOffset = 0;
for(i = 0; i < descriptor->numRecords; i++) {
recordOffset = getRecordOffset(i, nodeNum, tree);
key = READ_KEY(tree, recordOffset, tree->io);
recordDataOffset = recordOffset + key->keyLength + sizeof(key->keyLength);
if((recordDataOffset - (nodeNum * tree->headerRec->nodeSize)) > (tree->headerRec->nodeSize - (sizeof(uint16_t) * (descriptor->numRecords + 1)))) {
printf("BTREE CONSISTENCY ERROR: Record data extends past offsets in node %d record %d\n", nodeNum, i); fflush(stdout);
(*errCount)++;
}
if(i == 0) {
*firstKey = READ_KEY(tree, recordOffset, tree->io);
}
if(i == (descriptor->numRecords - 1)) {
*lastKey = READ_KEY(tree, recordOffset, tree->io);
}
if(previousKey != NULL) {
res = COMPARE(tree, key, previousKey);
if(res < 0) {
printf("BTREE CONSISTENCY ERROR(traverse): Ordering between records within node not preserved in record %d node %d for ", i, nodeNum);
(*errCount)++;
tree->keyPrint(previousKey);
printf(" < ");
tree->keyPrint(key);
printf("\n"); fflush(stdout);
}
free(previousKey);
previousKey = NULL;
}
if(displayTree) {
for(j = 0; j < (descriptor->height - 1); j++) {
printf(" ");
}
tree->keyPrint(key);
printf("\n");
}
if(descriptor->kind == kBTIndexNode) {
count += traverseNode(getNodeNumberFromPointerRecord(recordDataOffset, tree->io),
tree, map, descriptor->height, &retFirstKey, &retLastKey, heightTable, errCount, displayTree);
if(COMPARE(tree, retFirstKey, key) != 0) {
printf("BTREE CONSISTENCY ERROR: Index node key does not match first key in record %d node %d\n", i, nodeNum); fflush(stdout);
(*errCount)++;
}
if(COMPARE(tree, retLastKey, key) < 0) {
printf("BTREE CONSISTENCY ERROR: Last key is less than the index node key in record %d node %d\n", i, nodeNum); fflush(stdout);
(*errCount)++;
}
free(retFirstKey);
free(key);
previousKey = retLastKey;
} else {
previousKey = key;
}
if(recordOffset < lastrecordDataOffset) {
printf("BTREE CONSISTENCY ERROR: Record offsets are not in order in node %d starting at record %d\n", nodeNum, i); fflush(stdout);
(*errCount)++;
}
lastrecordDataOffset = recordDataOffset;
}
if(previousKey != NULL) free(previousKey);
free(descriptor);
return count;
}
static unsigned char* mapNodes(BTree* tree, uint32_t* numMapNodes, uint32_t* errCount) {
unsigned char *map;
BTNodeDescriptor* descriptor;
unsigned char byte;
uint32_t totalNodes;
uint32_t freeNodes;
uint32_t byteNumber;
uint32_t byteTracker;
uint32_t mapNode;
off_t mapRecordStart;
off_t mapRecordLength;
int i;
map = (unsigned char *)malloc(tree->headerRec->totalNodes/8 + 1);
byteTracker = 0;
freeNodes = 0;
totalNodes = 0;
mapRecordStart = getRecordOffset(2, 0, tree);
mapRecordLength = tree->headerRec->nodeSize - 256;
byteNumber = 0;
mapNode = 0;
*numMapNodes = 0;
while(TRUE) {
while(byteNumber < mapRecordLength) {
READ(tree->io, mapRecordStart + byteNumber, 1, &byte);
map[byteTracker] = byte;
byteTracker++;
byteNumber++;
for(i = 0; i < 8; i++) {
if((byte & (1 << (7 - i))) == 0) {
freeNodes++;
}
totalNodes++;
if(totalNodes == tree->headerRec->totalNodes)
goto done;
}
}
descriptor = readBTNodeDescriptor(mapNode, tree);
mapNode = descriptor->fLink;
free(descriptor);
(*numMapNodes)++;
if(mapNode == 0) {
printf("BTREE CONSISTENCY ERROR: Not enough map nodes allocated! Allocated for: %d, needed: %d\n", totalNodes, tree->headerRec->totalNodes);
(*errCount)++;
break;
}
mapRecordStart = mapNode * tree->headerRec->nodeSize + 14;
mapRecordLength = tree->headerRec->nodeSize - 20;
byteNumber = 0;
}
done:
if(freeNodes != tree->headerRec->freeNodes) {
printf("BTREE CONSISTENCY ERROR: Free nodes %d differ from actually allocated %d\n", tree->headerRec->freeNodes, freeNodes);
(*errCount)++;
}
return map;
}
int debugBTree(BTree* tree, int displayTree) {
unsigned char* map;
uint32_t *heightTable;
BTKey* retFirstKey;
BTKey* retLastKey;
uint32_t numMapNodes;
uint32_t traverseCount;
uint32_t linearCount;
uint32_t errorCount;
uint8_t i;
errorCount = 0;
printf("Mapping nodes...\n"); fflush(stdout);
map = mapNodes(tree, &numMapNodes, &errorCount);
printf("Initializing height table...\n"); fflush(stdout);
heightTable = (uint32_t*) malloc(sizeof(uint32_t) * (tree->headerRec->treeDepth + 1));
for(i = 0; i <= tree->headerRec->treeDepth; i++) {
heightTable[i] = 0;
}
if(tree->headerRec->rootNode == 0) {
if(tree->headerRec->firstLeafNode == 0 && tree->headerRec->lastLeafNode == 0) {
traverseCount = 0;
linearCount = 0;
} else {
printf("BTREE CONSISTENCY ERROR: First leaf node (%d) and last leaf node (%d) inconsistent with empty BTree\n",
tree->headerRec->firstLeafNode, tree->headerRec->lastLeafNode);
// Try to see if we can get a linear count
if(tree->headerRec->firstLeafNode != 0)
heightTable[1] = tree->headerRec->firstLeafNode;
else
heightTable[1] = tree->headerRec->lastLeafNode;
linearCount = linearCheck(heightTable, map, tree, &errorCount);
}
} else {
printf("Performing tree traversal...\n"); fflush(stdout);
traverseCount = traverseNode(tree->headerRec->rootNode, tree, map, 0, &retFirstKey, &retLastKey, heightTable, &errorCount, displayTree);
free(retFirstKey);
free(retLastKey);
printf("Performing linear traversal...\n"); fflush(stdout);
linearCount = linearCheck(heightTable, map, tree, &errorCount);
}
printf("Total traverse nodes: %d\n", traverseCount); fflush(stdout);
printf("Total linear nodes: %d\n", linearCount); fflush(stdout);
printf("Error count: %d\n", errorCount); fflush(stdout);
if(traverseCount != linearCount) {
printf("BTREE CONSISTENCY ERROR: Linear count and traverse count are inconsistent\n");
}
if(traverseCount != (tree->headerRec->totalNodes - tree->headerRec->freeNodes - numMapNodes - 1)) {
printf("BTREE CONSISTENCY ERROR: Free nodes and total nodes (%d) and traverse count are inconsistent\n",
tree->headerRec->totalNodes - tree->headerRec->freeNodes);
}
free(heightTable);
free(map);
return errorCount;
}
static uint32_t findFree(BTree* tree) {
unsigned char byte;
uint32_t byteNumber;
uint32_t mapNode;
BTNodeDescriptor* descriptor;
off_t mapRecordStart;
off_t mapRecordLength;
int i;
mapRecordStart = getRecordOffset(2, 0, tree);
mapRecordLength = tree->headerRec->nodeSize - 256;
mapNode = 0;
byteNumber = 0;
while(TRUE) {
while(byteNumber < mapRecordLength) {
READ(tree->io, mapRecordStart + byteNumber, 1, &byte);
if(byte != 0xFF) {
for(i = 0; i < 8; i++) {
if((byte & (1 << (7 - i))) == 0) {
byte |= (1 << (7 - i));
tree->headerRec->freeNodes--;
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderRec");
ASSERT(WRITE(tree->io, mapRecordStart + byteNumber, 1, &byte), "WRITE");
return ((byteNumber * 8) + i);
}
}
}
byteNumber++;
}
descriptor = readBTNodeDescriptor(mapNode, tree);
mapNode = descriptor->fLink;
free(descriptor);
if(mapNode == 0) {
return 0;
}
mapRecordStart = mapNode * tree->headerRec->nodeSize + 14;
mapRecordLength = tree->headerRec->nodeSize - 20;
byteNumber = 0;
}
}
static int markUsed(uint32_t node, BTree* tree) {
BTNodeDescriptor* descriptor;
uint32_t mapNode;
uint32_t byteNumber;
unsigned char byte;
mapNode = 0;
byteNumber = node / 8;
if(byteNumber >= (tree->headerRec->nodeSize - 256)) {
while(TRUE) {
descriptor = readBTNodeDescriptor(mapNode, tree);
mapNode = descriptor->fLink;
free(descriptor);
if(byteNumber > (tree->headerRec->nodeSize - 20)) {
byteNumber -= tree->headerRec->nodeSize - 20;
} else {
break;
}
}
}
ASSERT(READ(tree->io, mapNode * tree->headerRec->nodeSize + 14 + byteNumber, 1, &byte), "READ");
byte |= (1 << (7 - (node % 8)));
ASSERT(WRITE(tree->io, mapNode * tree->headerRec->nodeSize + 14 + byteNumber, 1, &byte), "WRITE");
return TRUE;
}
static int growBTree(BTree* tree) {
int i;
unsigned char* buffer;
uint16_t offset;
uint32_t byteNumber;
uint32_t mapNode;
int increasedNodes;
off_t newNodeOffset;
uint32_t newNodesStart;
BTNodeDescriptor* descriptor;
BTNodeDescriptor newDescriptor;
allocate((RawFile*)(tree->io->data), ((RawFile*)(tree->io->data))->forkData->logicalSize + ((RawFile*)(tree->io->data))->forkData->clumpSize);
increasedNodes = (((RawFile*)(tree->io->data))->forkData->logicalSize/tree->headerRec->nodeSize) - tree->headerRec->totalNodes;
newNodesStart = tree->headerRec->totalNodes / tree->headerRec->nodeSize;
tree->headerRec->freeNodes += increasedNodes;
tree->headerRec->totalNodes += increasedNodes;
byteNumber = tree->headerRec->totalNodes / 8;
mapNode = 0;
buffer = (unsigned char*) malloc(tree->headerRec->nodeSize - 20);
for(i = 0; i < (tree->headerRec->nodeSize - 20); i++) {
buffer[i] = 0;
}
if(byteNumber < (tree->headerRec->nodeSize - 256)) {
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderREc");
free(buffer);
return TRUE;
} else {
byteNumber -= tree->headerRec->nodeSize - 256;
while(TRUE) {
descriptor = readBTNodeDescriptor(mapNode, tree);
if(descriptor->fLink == 0) {
descriptor->fLink = newNodesStart;
ASSERT(writeBTNodeDescriptor(descriptor, mapNode, tree), "writeBTNodeDescriptor");
newDescriptor.fLink = 0;
newDescriptor.bLink = 0;
newDescriptor.kind = kBTMapNode;
newDescriptor.height = 0;
newDescriptor.numRecords = 1;
newDescriptor.reserved = 0;
ASSERT(writeBTNodeDescriptor(&newDescriptor, descriptor->fLink, tree), "writeBTNodeDescriptor");
newNodeOffset = descriptor->fLink * tree->headerRec->nodeSize;
ASSERT(WRITE(tree->io, newNodeOffset + 14, tree->headerRec->nodeSize - 20, buffer), "WRITE");
offset = 14;
FLIPENDIAN(offset);
ASSERT(WRITE(tree->io, newNodeOffset + tree->headerRec->nodeSize - 2, sizeof(offset), &offset), "WRITE");
offset = 14 + tree->headerRec->nodeSize - 20;
FLIPENDIAN(offset);
ASSERT(WRITE(tree->io, newNodeOffset + tree->headerRec->nodeSize - 4, sizeof(offset), &offset), "WRITE");
// mark the map node as being used
ASSERT(markUsed(newNodesStart, tree), "markUsed");
tree->headerRec->freeNodes--;
newNodesStart++;
}
mapNode = descriptor->fLink;
if(byteNumber > (tree->headerRec->nodeSize - 20)) {
byteNumber -= tree->headerRec->nodeSize - 20;
} else {
free(buffer);
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderRec");
return TRUE;
}
}
}
return FALSE;
}
static uint32_t getNewNode(BTree* tree) {
if(tree->headerRec->freeNodes == 0) {
growBTree(tree);
}
return findFree(tree);
}
static uint32_t removeNode(BTree* tree, uint32_t node) {
unsigned char byte;
off_t mapRecordStart;
uint32_t mapNode;
size_t mapRecordLength;
BTNodeDescriptor *descriptor;
BTNodeDescriptor *oDescriptor;
mapRecordStart = getRecordOffset(2, 0, tree);
mapRecordLength = tree->headerRec->nodeSize - 256;
mapNode = 0;
while((node / 8) >= mapRecordLength) {
descriptor = readBTNodeDescriptor(mapNode, tree);
mapNode = descriptor->fLink;
free(descriptor);
if(mapNode == 0) {
hfs_panic("Cannot remove node because I can't map it!");
return 0;
}
mapRecordStart = mapNode * tree->headerRec->nodeSize + 14;
mapRecordLength = tree->headerRec->nodeSize - 20;
node -= mapRecordLength * 8;
}
READ(tree->io, mapRecordStart + (node / 8), 1, &byte);
byte &= ~(1 << (7 - (node % 8)));
tree->headerRec->freeNodes++;
descriptor = readBTNodeDescriptor(node, tree);
if(tree->headerRec->firstLeafNode == node) {
tree->headerRec->firstLeafNode = descriptor->fLink;
}
if(tree->headerRec->lastLeafNode == node) {
tree->headerRec->lastLeafNode = descriptor->bLink;
}
if(node == tree->headerRec->rootNode) {
tree->headerRec->rootNode = 0;
}
if(descriptor->bLink != 0) {
oDescriptor = readBTNodeDescriptor(descriptor->bLink, tree);
oDescriptor->fLink = descriptor->fLink;
ASSERT(writeBTNodeDescriptor(oDescriptor, descriptor->bLink, tree), "writeBTNodeDescriptor");
free(oDescriptor);
}
if(descriptor->fLink != 0) {
oDescriptor = readBTNodeDescriptor(descriptor->fLink, tree);
oDescriptor->bLink = descriptor->bLink;
ASSERT(writeBTNodeDescriptor(oDescriptor, descriptor->fLink, tree), "writeBTNodeDescriptor");
free(oDescriptor);
}
free(descriptor);
ASSERT(WRITE(tree->io, mapRecordStart + (node / 8), 1, &byte), "WRITE");
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderRec");
return TRUE;
}
static uint32_t splitNode(uint32_t node, BTNodeDescriptor* descriptor, BTree* tree) {
int nodesToMove;
int i;
off_t internalOffset;
BTNodeDescriptor* fDescriptor;
BTNodeDescriptor newDescriptor;
uint32_t newNodeNum;
off_t newNodeOffset;
off_t toMove;
size_t toMoveLength;
unsigned char *buffer;
off_t offsetsToMove;
size_t offsetsToMoveLength;
uint16_t *offsetsBuffer;
nodesToMove = descriptor->numRecords - (descriptor->numRecords/2);
toMove = getRecordOffset(descriptor->numRecords/2, node, tree);
toMoveLength = getRecordOffset(descriptor->numRecords, node, tree) - toMove;
buffer = (unsigned char *)malloc(toMoveLength);
ASSERT(READ(tree->io, toMove, toMoveLength, buffer), "READ");
offsetsToMove = (node * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * (descriptor->numRecords + 1));
offsetsToMoveLength = sizeof(uint16_t) * (nodesToMove + 1);
offsetsBuffer = (uint16_t *)malloc(offsetsToMoveLength);
ASSERT(READ(tree->io, offsetsToMove, offsetsToMoveLength, offsetsBuffer), "READ");
for(i = 0; i < (nodesToMove + 1); i++) {
FLIPENDIAN(offsetsBuffer[i]);
}
internalOffset = offsetsBuffer[nodesToMove] - 14;
for(i = 0; i < (nodesToMove + 1); i++) {
offsetsBuffer[i] -= internalOffset;
FLIPENDIAN(offsetsBuffer[i]);
}
newNodeNum = getNewNode(tree);
newNodeOffset = newNodeNum * tree->headerRec->nodeSize;
newDescriptor.fLink = descriptor->fLink;
newDescriptor.bLink = node;
newDescriptor.kind = descriptor->kind;
newDescriptor.height = descriptor->height;
newDescriptor.numRecords = nodesToMove;
newDescriptor.reserved = 0;
ASSERT(writeBTNodeDescriptor(&newDescriptor, newNodeNum, tree), "writeBTNodeDescriptor");
if(newDescriptor.fLink != 0) {
fDescriptor = readBTNodeDescriptor(newDescriptor.fLink, tree);
fDescriptor->bLink = newNodeNum;
ASSERT(writeBTNodeDescriptor(fDescriptor, newDescriptor.fLink, tree), "writeBTNodeDescriptor");
free(fDescriptor);
}
descriptor->fLink = newNodeNum;
descriptor->numRecords = descriptor->numRecords/2;
ASSERT(writeBTNodeDescriptor(descriptor, node, tree), "writeBTNodeDescriptor");
ASSERT(WRITE(tree->io, newNodeOffset + 14, toMoveLength, buffer), "WRITE");
ASSERT(WRITE(tree->io, newNodeOffset + tree->headerRec->nodeSize - (sizeof(uint16_t) * (nodesToMove + 1)), offsetsToMoveLength, offsetsBuffer), "WRITE");
// The offset for the existing descriptor's new numRecords will happen to be where the old data was, which is now where the free space starts
// So we don't have to manually set the free space offset
free(buffer);
free(offsetsBuffer);
if(descriptor->kind == kBTLeafNode && node == tree->headerRec->lastLeafNode) {
tree->headerRec->lastLeafNode = newNodeNum;
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderRec");
}
return newNodeNum;
}
static int moveRecordsDown(BTree* tree, BTNodeDescriptor* descriptor, int record, uint32_t node, int length, int moveOffsets) {
off_t firstRecordStart;
off_t lastRecordEnd;
unsigned char* records;
off_t firstOffsetStart;
off_t lastOffsetEnd;
uint16_t* offsets;
int i;
firstRecordStart = getRecordOffset(record, node, tree);
lastRecordEnd = getRecordOffset(descriptor->numRecords, node, tree);
records = (unsigned char*)malloc(lastRecordEnd - firstRecordStart);
ASSERT(READ(tree->io, firstRecordStart, lastRecordEnd - firstRecordStart, records), "READ");
firstOffsetStart = (node * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * (descriptor->numRecords + 1));
lastOffsetEnd = (node * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * record);
offsets = (uint16_t*)malloc(lastOffsetEnd - firstOffsetStart);
ASSERT(READ(tree->io, firstOffsetStart, lastOffsetEnd - firstOffsetStart, offsets), "READ");
for(i = 0; i < (lastOffsetEnd - firstOffsetStart)/sizeof(uint16_t); i++) {
FLIPENDIAN(offsets[i]);
offsets[i] += length;
FLIPENDIAN(offsets[i]);
}
ASSERT(WRITE(tree->io, firstRecordStart + length, lastRecordEnd - firstRecordStart, records), "WRITE");
if(moveOffsets > 0) {
ASSERT(WRITE(tree->io, firstOffsetStart - sizeof(uint16_t), lastOffsetEnd - firstOffsetStart, offsets), "WRITE");
} else if(moveOffsets < 0) {
ASSERT(WRITE(tree->io, firstOffsetStart + sizeof(uint16_t), lastOffsetEnd - firstOffsetStart, offsets), "WRITE");
} else {
ASSERT(WRITE(tree->io, firstOffsetStart, lastOffsetEnd - firstOffsetStart, offsets), "WRITE");
}
free(records);
free(offsets);
return TRUE;
}
static int doAddRecord(BTree* tree, uint32_t root, BTKey* searchKey, size_t length, unsigned char* content) {
BTNodeDescriptor* descriptor;
BTKey* key;
off_t recordOffset;
off_t recordDataOffset;
off_t lastRecordDataOffset;
uint16_t offset;
int res;
int i;
descriptor = readBTNodeDescriptor(root, tree);
if(descriptor == NULL)
return FALSE;
lastRecordDataOffset = 0;
for(i = 0; i < descriptor->numRecords; i++) {
recordOffset = getRecordOffset(i, root, tree);
key = READ_KEY(tree, recordOffset, tree->io);
recordDataOffset = recordOffset + key->keyLength + sizeof(key->keyLength);
res = COMPARE(tree, key, searchKey);
if(res == 0) {
free(key);
free(descriptor);
return FALSE;
} else if(res > 0) {
free(key);
break;
}
free(key);
lastRecordDataOffset = recordDataOffset;
}
if(i != descriptor->numRecords) {
// first, move everyone else down
moveRecordsDown(tree, descriptor, i, root, sizeof(searchKey->keyLength) + searchKey->keyLength + length, 1);
// then insert ourself
ASSERT(WRITE_KEY(tree, recordOffset, searchKey, tree->io), "WRITE_KEY");
ASSERT(WRITE(tree->io, recordOffset + sizeof(searchKey->keyLength) + searchKey->keyLength, length, content), "WRITE");
offset = recordOffset - (root * tree->headerRec->nodeSize);
FLIPENDIAN(offset);
ASSERT(WRITE(tree->io, (root * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * (i + 1)),
sizeof(uint16_t), &offset), "WRITE");
} else {
// just insert ourself at the end
recordOffset = getRecordOffset(i, root, tree);
ASSERT(WRITE_KEY(tree, recordOffset, searchKey, tree->io), "WRITE_KEY");
ASSERT(WRITE(tree->io, recordOffset + sizeof(uint16_t) + searchKey->keyLength, length, content), "WRITE");
// write the new free offset
offset = (recordOffset + sizeof(searchKey->keyLength) + searchKey->keyLength + length) - (root * tree->headerRec->nodeSize);
FLIPENDIAN(offset);
ASSERT(WRITE(tree->io, (root * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * (descriptor->numRecords + 2)),
sizeof(uint16_t), &offset), "WRITE");
}
descriptor->numRecords++;
if(descriptor->height == 1) {
tree->headerRec->leafRecords++;
}
ASSERT(writeBTNodeDescriptor(descriptor, root, tree), "writeBTNodeDescriptor");
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderRec");
free(descriptor);
return TRUE;
}
static int addRecord(BTree* tree, uint32_t root, BTKey* searchKey, size_t length, unsigned char* content, int* callAgain) {
BTNodeDescriptor* descriptor;
BTKey* key;
off_t recordOffset;
off_t recordDataOffset;
off_t lastRecordDataOffset;
size_t freeSpace;
int res;
int i;
uint32_t newNode;
uint32_t newNodeBigEndian;
uint32_t nodeBigEndian;
descriptor = readBTNodeDescriptor(root, tree);
if(descriptor == NULL)
return 0;
freeSpace = getFreeSpace(root, descriptor, tree);
lastRecordDataOffset = 0;
for(i = 0; i < descriptor->numRecords; i++) {
recordOffset = getRecordOffset(i, root, tree);
key = READ_KEY(tree, recordOffset, tree->io);
recordDataOffset = recordOffset + key->keyLength + sizeof(key->keyLength);
res = COMPARE(tree, key, searchKey);
if(res == 0) {
free(key);
free(descriptor);
return 0;
} else if(res > 0) {
free(key);
break;
}
free(key);
lastRecordDataOffset = recordDataOffset;
}
if(descriptor->kind == kBTLeafNode) {
if(freeSpace < (sizeof(searchKey->keyLength) + searchKey->keyLength + length + sizeof(uint16_t))) {
newNode = splitNode(root, descriptor, tree);
if(i < descriptor->numRecords) {
doAddRecord(tree, root, searchKey, length, content);
} else {
doAddRecord(tree, newNode, searchKey, length, content);
}
free(descriptor);
return newNode;
} else {
doAddRecord(tree, root, searchKey, length, content);
free(descriptor);
return 0;
}
} else {
if(lastRecordDataOffset == 0) {
if(descriptor->numRecords == 0) {
hfs_panic("empty index node in btree");
return 0;
}
key = READ_KEY(tree, (root * tree->headerRec->nodeSize) + 14, tree->io);
recordDataOffset = recordOffset + key->keyLength + sizeof(key->keyLength);
nodeBigEndian = getNodeNumberFromPointerRecord(recordDataOffset, tree->io);
FLIPENDIAN(nodeBigEndian);
free(key);
key = READ_KEY(tree, (root * tree->headerRec->nodeSize) + 14, tree->io);
recordDataOffset = recordOffset + key->keyLength + sizeof(key->keyLength);
if(searchKey->keyLength != key->keyLength) {
if(searchKey->keyLength > key->keyLength && freeSpace < (searchKey->keyLength - key->keyLength)) {
// very unlikely. We need to split this node before we can resize the key of this index. Do that first, and tell them to call again.
*callAgain = TRUE;
return splitNode(root, descriptor, tree);
}
moveRecordsDown(tree, descriptor, 1, root, searchKey->keyLength - key->keyLength, 0);
}
free(key);
ASSERT(WRITE_KEY(tree, recordOffset, searchKey, tree->io), "WRITE_KEY");
ASSERT(WRITE(tree->io, recordOffset + sizeof(uint16_t) + searchKey->keyLength, sizeof(uint32_t), &nodeBigEndian), "WRITE");
FLIPENDIAN(nodeBigEndian);
newNode = addRecord(tree, nodeBigEndian, searchKey, length, content, callAgain);
} else {
newNode = addRecord(tree, getNodeNumberFromPointerRecord(lastRecordDataOffset, tree->io), searchKey, length, content, callAgain);
}
if(newNode == 0) {
free(descriptor);
return 0;
} else {
newNodeBigEndian = newNode;
key = READ_KEY(tree, newNode * tree->headerRec->nodeSize + 14, tree->io);
FLIPENDIAN(newNodeBigEndian);
if(freeSpace < (sizeof(key->keyLength) + key->keyLength + sizeof(newNodeBigEndian) + sizeof(uint16_t))) {
newNode = splitNode(root, descriptor, tree);
if(i < descriptor->numRecords) {
doAddRecord(tree, root, key, sizeof(newNodeBigEndian), (unsigned char*)(&newNodeBigEndian));
} else {
doAddRecord(tree, newNode, key, sizeof(newNodeBigEndian), (unsigned char*)(&newNodeBigEndian));
}
free(key);
free(descriptor);
return newNode;
} else {
doAddRecord(tree, root, key, sizeof(newNodeBigEndian), (unsigned char*)(&newNodeBigEndian));
free(key);
free(descriptor);
return 0;
}
}
}
}
static int increaseHeight(BTree* tree, uint32_t newNode) {
uint32_t oldRoot;
uint32_t newRoot;
BTNodeDescriptor newDescriptor;
BTKey* oldRootKey;
BTKey* newNodeKey;
uint16_t oldRootOffset;
uint16_t newNodeOffset;
uint16_t freeOffset;
oldRoot = tree->headerRec->rootNode;
oldRootKey = READ_KEY(tree, (oldRoot * tree->headerRec->nodeSize) + 14, tree->io);
newNodeKey = READ_KEY(tree, (newNode * tree->headerRec->nodeSize) + 14, tree->io);
newRoot = getNewNode(tree);
newDescriptor.fLink = 0;
newDescriptor.bLink = 0;
newDescriptor.kind = kBTIndexNode;
newDescriptor.height = tree->headerRec->treeDepth + 1;
newDescriptor.numRecords = 2;
newDescriptor.reserved = 0;
oldRootOffset = 14;
newNodeOffset = oldRootOffset + sizeof(oldRootKey->keyLength) + oldRootKey->keyLength + sizeof(uint32_t);
freeOffset = newNodeOffset + sizeof(newNodeKey->keyLength) + newNodeKey->keyLength + sizeof(uint32_t);
tree->headerRec->rootNode = newRoot;
tree->headerRec->treeDepth = newDescriptor.height;
ASSERT(WRITE_KEY(tree, newRoot * tree->headerRec->nodeSize + oldRootOffset, oldRootKey, tree->io), "WRITE_KEY");
FLIPENDIAN(oldRoot);
ASSERT(WRITE(tree->io, newRoot * tree->headerRec->nodeSize + oldRootOffset + sizeof(oldRootKey->keyLength) + oldRootKey->keyLength,
sizeof(uint32_t), &oldRoot), "WRITE");
ASSERT(WRITE_KEY(tree, newRoot * tree->headerRec->nodeSize + newNodeOffset, newNodeKey, tree->io), "WRITE_KEY");
FLIPENDIAN(newNode);
ASSERT(WRITE(tree->io, newRoot * tree->headerRec->nodeSize + newNodeOffset + sizeof(newNodeKey->keyLength) + newNodeKey->keyLength,
sizeof(uint32_t), &newNode), "WRITE");
FLIPENDIAN(oldRootOffset);
ASSERT(WRITE(tree->io, (newRoot * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * 1),
sizeof(uint16_t), &oldRootOffset), "WRITE");
FLIPENDIAN(newNodeOffset);
ASSERT(WRITE(tree->io, (newRoot * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * 2),
sizeof(uint16_t), &newNodeOffset), "WRITE");
FLIPENDIAN(freeOffset);
ASSERT(WRITE(tree->io, (newRoot * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * 3),
sizeof(uint16_t), &freeOffset), "WRITE");
ASSERT(writeBTNodeDescriptor(&newDescriptor, tree->headerRec->rootNode, tree), "writeBTNodeDescriptor");
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderRec");
free(oldRootKey);
free(newNodeKey);
return TRUE;
}
int addToBTree(BTree* tree, BTKey* searchKey, size_t length, unsigned char* content) {
int callAgain;
BTNodeDescriptor newDescriptor;
uint16_t offset;
uint16_t freeOffset;
uint32_t newNode;
if(tree->headerRec->rootNode != 0) {
do {
callAgain = FALSE;
newNode = addRecord(tree, tree->headerRec->rootNode, searchKey, length, content, &callAgain);
if(newNode != 0) {
increaseHeight(tree, newNode);
}
} while(callAgain);
} else {
// add the first leaf node
tree->headerRec->rootNode = getNewNode(tree);
tree->headerRec->firstLeafNode = tree->headerRec->rootNode;
tree->headerRec->lastLeafNode = tree->headerRec->rootNode;
tree->headerRec->leafRecords = 1;
tree->headerRec->treeDepth = 1;
newDescriptor.fLink = 0;
newDescriptor.bLink = 0;
newDescriptor.kind = kBTLeafNode;
newDescriptor.height = 1;
newDescriptor.numRecords = 1;
newDescriptor.reserved = 0;
offset = 14;
freeOffset = offset + sizeof(searchKey->keyLength) + searchKey->keyLength + length;
ASSERT(WRITE_KEY(tree, tree->headerRec->rootNode * tree->headerRec->nodeSize + offset, searchKey, tree->io), "WRITE_KEY");
ASSERT(WRITE(tree->io, tree->headerRec->rootNode * tree->headerRec->nodeSize + offset + sizeof(searchKey->keyLength) + searchKey->keyLength,
length, content), "WRITE");
FLIPENDIAN(offset);
ASSERT(WRITE(tree->io, (tree->headerRec->rootNode * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * 1),
sizeof(uint16_t), &offset), "WRITE");
FLIPENDIAN(freeOffset);
ASSERT(WRITE(tree->io, (tree->headerRec->rootNode * tree->headerRec->nodeSize) + tree->headerRec->nodeSize - (sizeof(uint16_t) * 2),
sizeof(uint16_t), &freeOffset), "WRITE");
ASSERT(writeBTNodeDescriptor(&newDescriptor, tree->headerRec->rootNode, tree), "writeBTNodeDescriptor");
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderRec");
}
return TRUE;
}
static uint32_t removeRecord(BTree* tree, uint32_t root, BTKey* searchKey, int* callAgain, int* gone) {
BTNodeDescriptor* descriptor;
int length;
int i;
int res;
uint32_t newNode;
uint32_t nodeToTraverse;
uint32_t newNodeBigEndian;
BTKey* key;
off_t recordOffset;
off_t recordDataOffset;
off_t lastRecordDataOffset;
int childGone;
int checkForChangedKey ;
size_t freeSpace;
descriptor = readBTNodeDescriptor(root, tree);
freeSpace = getFreeSpace(root, descriptor, tree);
nodeToTraverse = 0;
lastRecordDataOffset = 0;
newNode = 0;
(*gone) = FALSE;
checkForChangedKey = FALSE;
for(i = 0; i < descriptor->numRecords; i++) {
recordOffset = getRecordOffset(i, root, tree);
key = READ_KEY(tree, recordOffset, tree->io);
recordDataOffset = recordOffset + key->keyLength + sizeof(key->keyLength);
res = COMPARE(tree, key, searchKey);
if(res == 0) {
free(key);
if(descriptor->kind == kBTLeafNode) {
if(i != (descriptor->numRecords - 1)) {
length = getRecordOffset(i + 1, root, tree) - recordOffset;
moveRecordsDown(tree, descriptor, i + 1, root, -length, -1);
} // don't need to do that if we're the last record, because our old offset pointer will be the new free space pointer
descriptor->numRecords--;
tree->headerRec->leafRecords--;
ASSERT(writeBTNodeDescriptor(descriptor, root, tree), "writeBTNodeDescriptor");
ASSERT(writeBTHeaderRec(tree), "writeBTHeaderRec");
if(descriptor->numRecords >= 1) {
free(descriptor);
return 0;
} else {
free(descriptor);
removeNode(tree, root);
(*gone) = TRUE;
return 0;
}
} else {
nodeToTraverse = getNodeNumberFromPointerRecord(recordDataOffset, tree->io);
checkForChangedKey = TRUE;
break;
}
} else if(res > 0) {
free(key);
if(lastRecordDataOffset == 0 || descriptor->kind == kBTLeafNode) {
// not found;
free(descriptor);
return 0;
} else {
nodeToTraverse = getNodeNumberFromPointerRecord(lastRecordDataOffset, tree->io);
break;
}
}
lastRecordDataOffset = recordDataOffset;
free(key);
}
if(nodeToTraverse == 0) {
nodeToTraverse = getNodeNumberFromPointerRecord(lastRecordDataOffset, tree->io);
}
if(i == descriptor->numRecords) {
i = descriptor->numRecords - 1;
}
newNode = removeRecord(tree, nodeToTraverse, searchKey, callAgain, &childGone);
if(childGone) {
if(i != (descriptor->numRecords - 1)) {
length = getRecordOffset(i + 1, root, tree) - recordOffset;
moveRecordsDown(tree, descriptor, i + 1, root, -length, -1);
} // don't need to do that if we're the last record, because our old offset pointer will be the new free space pointer
descriptor->numRecords--;
ASSERT(writeBTNodeDescriptor(descriptor, root, tree), "writeBTNodeDescriptor");
} else {
if(checkForChangedKey) {
// we will remove the first item in the child node, so our index has to change
key = READ_KEY(tree, getRecordOffset(0, nodeToTraverse, tree), tree->io);
if(searchKey->keyLength != key->keyLength) {
if(key->keyLength > searchKey->keyLength && freeSpace < (key->keyLength - searchKey->keyLength)) {
// very unlikely. We need to split this node before we can resize the key of this index. Do that first, and tell them to call again.
*callAgain = TRUE;
return splitNode(root, descriptor, tree);
}
moveRecordsDown(tree, descriptor, i + 1, root, key->keyLength - searchKey->keyLength, 0);
}
ASSERT(WRITE_KEY(tree, recordOffset, key, tree->io), "WRITE_KEY");
FLIPENDIAN(nodeToTraverse);
ASSERT(WRITE(tree->io, recordOffset + sizeof(uint16_t) + key->keyLength, sizeof(uint32_t), &nodeToTraverse), "WRITE");
FLIPENDIAN(nodeToTraverse);
free(key);
}
}
if(newNode == 0) {
if(descriptor->numRecords == 0) {
removeNode(tree, root);
(*gone) = TRUE;
}
free(descriptor);
return 0;
} else {
newNodeBigEndian = newNode;
key = READ_KEY(tree, newNode * tree->headerRec->nodeSize + 14, tree->io);
FLIPENDIAN(newNodeBigEndian);
if(freeSpace < (sizeof(key->keyLength) + key->keyLength + sizeof(newNodeBigEndian) + sizeof(uint16_t))) {
newNode = splitNode(root, descriptor, tree);
if(i < descriptor->numRecords) {
doAddRecord(tree, root, key, sizeof(newNodeBigEndian), (unsigned char*)(&newNodeBigEndian));
} else {
doAddRecord(tree, newNode, key, sizeof(newNodeBigEndian), (unsigned char*)(&newNodeBigEndian));
}
if(descriptor->numRecords == 0) {
removeNode(tree, root);
(*gone) = TRUE;
}
free(key);
free(descriptor);
return newNode;
} else {
doAddRecord(tree, root, key, sizeof(newNodeBigEndian), (unsigned char*)(&newNodeBigEndian));
free(key);
free(descriptor);
return 0;
}
}
return FALSE;
}
int removeFromBTree(BTree* tree, BTKey* searchKey) {
int callAgain;
int gone;
uint32_t newNode;
do {
callAgain = FALSE;
newNode = removeRecord(tree, tree->headerRec->rootNode, searchKey, &callAgain, &gone);
if(newNode != 0) {
increaseHeight(tree, newNode);
}
} while(callAgain);
return TRUE;
}