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d71d446104
archie/tk3.6/tkTextBTree.c
Mario Fetka d71d446104 Intial commit
2024-05-27 16:13:40 +02:00

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/*
* tkTextBTree.c --
*
* This file contains code that manages the B-tree representation
* of text for Tk's text widget. The B-tree holds both the text
* and tag information related to the text.
*
* Copyright (c) 1992-1993 The Regents of the University of California.
* All rights reserved.
*
* Permission is hereby granted, without written agreement and without
* license or royalty fees, to use, copy, modify, and distribute this
* software and its documentation for any purpose, provided that the
* above copyright notice and the following two paragraphs appear in
* all copies of this software.
*
* IN NO EVENT SHALL THE UNIVERSITY OF CALIFORNIA BE LIABLE TO ANY PARTY FOR
* DIRECT, INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES ARISING OUT
* OF THE USE OF THIS SOFTWARE AND ITS DOCUMENTATION, EVEN IF THE UNIVERSITY OF
* CALIFORNIA HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
*
* THE UNIVERSITY OF CALIFORNIA SPECIFICALLY DISCLAIMS ANY WARRANTIES,
* INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY
* AND FITNESS FOR A PARTICULAR PURPOSE. THE SOFTWARE PROVIDED HEREUNDER IS
* ON AN "AS IS" BASIS, AND THE UNIVERSITY OF CALIFORNIA HAS NO OBLIGATION TO
* PROVIDE MAINTENANCE, SUPPORT, UPDATES, ENHANCEMENTS, OR MODIFICATIONS.
*/
#ifndef lint
static char rcsid[] = "$Header: /user6/ouster/wish/RCS/tkTextBTree.c,v 1.19 93/10/11 16:55:21 ouster Exp $ SPRITE (Berkeley)";
#endif /* not lint */
#include "tkInt.h"
#include "tkConfig.h"
#include "tkText.h"
/*
* The data structure below keeps summary information about one tag as part
* of the tag information in a node.
*/
typedef struct Summary {
TkTextTag *tagPtr; /* Handle for tag. */
int toggleCount; /* Number of transitions into or
* out of this tag that occur in
* the subtree rooted at this node. */
struct Summary *nextPtr; /* Next in list of all tags for same
* node, or NULL if at end of list. */
} Summary;
/*
* The data structure below defines a node in the B-tree representing
* all of the lines in a text widget.
*/
typedef struct Node {
struct Node *parentPtr; /* Pointer to parent node, or NULL if
* this is the root. */
struct Node *nextPtr; /* Next in list of children of the
* same parent node, or NULL for end
* of list. */
Summary *summaryPtr; /* First in malloc-ed list of info
* about tags in this subtree (NULL if
* no tag info in the subtree). */
int level; /* Level of this node in the B-tree.
* 0 refers to the bottom of the tree
* (children are lines, not nodes). */
union { /* First in linked list of children. */
struct Node *nodePtr; /* Used if level > 0. */
TkTextLine *linePtr; /* Used if level == 0. */
} children;
int numChildren; /* Number of children of this node. */
int numLines; /* Total number of lines (leaves) in
* the subtree rooted here. */
} Node;
/*
* Upper and lower bounds on how many children a node may have:
* rebalance when either of these limits is exceeded. MAX_CHILDREN
* should be twice MIN_CHILDREN and MIN_CHILDREN must be >= 2.
*/
#define MAX_CHILDREN 12
#define MIN_CHILDREN 6
/*
* The data structure below defines an entire B-tree.
*/
typedef struct BTree {
Node *rootPtr; /* Pointer to root of B-tree. */
} BTree;
/*
* The structure below is used to pass information between
* TkBTreeGetTags and IncCount:
*/
typedef struct TagInfo {
int numTags; /* Number of tags for which there
* is currently information in
* tags and counts. */
int arraySize; /* Number of entries allocated for
* tags and counts. */
TkTextTag **tagPtrs; /* Array of tags seen so far.
* Malloc-ed. */
int *counts; /* Toggle count (so far) for each
* entry in tags. Malloc-ed. */
} TagInfo;
/*
* Macro to compute the space needed for a line that holds n non-null
* characters:
*/
#define LINE_SIZE(n) ((unsigned) (sizeof(TkTextLine) - 3 + (n)))
/*
* Variable that indicates whether to enable consistency checks for
* debugging.
*/
int tkBTreeDebug = 0;
/*
* Forward declarations for procedures defined in this file:
*/
static void AddToggleToLine _ANSI_ARGS_((TkTextLine *linePtr,
int index, TkTextTag *tagPtr));
static void ChangeNodeToggleCount _ANSI_ARGS_((Node *nodePtr,
TkTextTag *tagPtr, int delta));
static void CheckNodeConsistency _ANSI_ARGS_((Node *nodePtr));
static void DeleteSummaries _ANSI_ARGS_((Summary *tagPtr));
static void DestroyNode _ANSI_ARGS_((Node *nodePtr));
static void IncCount _ANSI_ARGS_((TkTextTag *tagPtr, int inc,
TagInfo *tagInfoPtr));
static void Rebalance _ANSI_ARGS_((BTree *treePtr, Node *nodePtr));
static void RecomputeNodeCounts _ANSI_ARGS_((Node *nodePtr));
/*
*----------------------------------------------------------------------
*
* TkBTreeCreate --
*
* This procedure is called to create a new text B-tree.
*
* Results:
* The return value is a pointer to a new B-tree containing
* one line with nothing but a newline character.
*
* Side effects:
* Memory is allocated and initialized.
*
*----------------------------------------------------------------------
*/
TkTextBTree
TkBTreeCreate()
{
register BTree *treePtr;
register Node *rootPtr;
register TkTextLine *linePtr;
rootPtr = (Node *) ckalloc(sizeof(Node));
linePtr = (TkTextLine *) ckalloc(LINE_SIZE(1));
rootPtr->parentPtr = NULL;
rootPtr->nextPtr = NULL;
rootPtr->summaryPtr = NULL;
rootPtr->level = 0;
rootPtr->children.linePtr = linePtr;
rootPtr->numChildren = 1;
rootPtr->numLines = 1;
linePtr->parentPtr = rootPtr;
linePtr->nextPtr = NULL;
linePtr->annotPtr = NULL;
linePtr->numBytes = 1;
linePtr->bytes[0] = '\n';
linePtr->bytes[1] = 0;
treePtr = (BTree *) ckalloc(sizeof(BTree));
treePtr->rootPtr = rootPtr;
return (TkTextBTree) treePtr;
}
/*
*----------------------------------------------------------------------
*
* TkBTreeDestroy --
*
* Delete a B-tree, recycling all of the storage it contains.
*
* Results:
* The tree given by treePtr is deleted. TreePtr should never
* again be used.
*
* Side effects:
* Memory is freed.
*
*----------------------------------------------------------------------
*/
void
TkBTreeDestroy(tree)
TkTextBTree tree; /* Pointer to tree to delete. */
{
BTree *treePtr = (BTree *) tree;
DestroyNode(treePtr->rootPtr);
ckfree((char *) treePtr);
}
/*
*----------------------------------------------------------------------
*
* DestroyNode --
*
* This is a recursive utility procedure used during the deletion
* of a B-tree.
*
* Results:
* None.
*
* Side effects:
* All the storage for nodePtr and its descendants is freed.
*
*----------------------------------------------------------------------
*/
static void
DestroyNode(nodePtr)
register Node *nodePtr;
{
if (nodePtr->level == 0) {
register TkTextLine *curPtr, *nextLinePtr;
register TkAnnotation *annotPtr, *nextAnnotPtr;
for (curPtr = nodePtr->children.linePtr; curPtr != NULL; ) {
nextLinePtr = curPtr->nextPtr;
for (annotPtr = curPtr->annotPtr; annotPtr != NULL; ) {
nextAnnotPtr = annotPtr->nextPtr;
if (annotPtr->type == TK_ANNOT_TOGGLE) {
ckfree((char *) annotPtr);
}
annotPtr = nextAnnotPtr;
}
ckfree((char *) curPtr);
curPtr = nextLinePtr;
}
} else {
register Node *curPtr, *nextPtr;
for (curPtr = nodePtr->children.nodePtr; curPtr != NULL; ) {
nextPtr = curPtr->nextPtr;
DestroyNode(curPtr);
curPtr = nextPtr;
}
}
DeleteSummaries(nodePtr->summaryPtr);
ckfree((char *) nodePtr);
}
/*
*----------------------------------------------------------------------
*
* DeleteSummaries --
*
* Free up all of the memory in a list of tag summaries associated
* with a node.
*
* Results:
* None.
*
* Side effects:
* Storage is released.
*
*----------------------------------------------------------------------
*/
static void
DeleteSummaries(summaryPtr)
register Summary *summaryPtr; /* First in list of node's tag
* summaries. */
{
register Summary *nextPtr;
while (summaryPtr != NULL) {
nextPtr = summaryPtr->nextPtr;
ckfree((char *) summaryPtr);
summaryPtr = nextPtr;
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeInsertChars --
*
* Insert characters at a given position in a B-tree.
*
* Results:
* None.
*
* Side effects:
* NumBytes characters are added to the B-tree at the given
* character position. This can cause the structure of the
* B-tree to change.
*
*----------------------------------------------------------------------
*/
void
TkBTreeInsertChars(tree, linePtr, ch, string)
TkTextBTree tree; /* B-tree in which to insert. */
register TkTextLine *linePtr; /* Pointer to line in which to
* insert. */
int ch; /* Index of character before which
* to insert. Must not be after
* last character in line.*/
char *string; /* Pointer to bytes to insert (may
* contain newlines, must be null-
* terminated). */
{
BTree *treePtr = (BTree *) tree;
register Node *nodePtr;
register TkAnnotation *annotPtr;
TkTextLine *prevPtr;
int newChunkLength; /* # chars in current line being
* inserted. */
register char *eol; /* Pointer to last character in
* current line being inserted. */
int changeToLineCount; /* Counts change to total number of
* lines in file. */
TkAnnotation *afterPtr; /* List of annotations that occur
* at or after the insertion point
* in the line of the insertion. */
int prefixLength, suffixLength, totalLength;
register TkTextLine *newPtr;
/*
* Find the line just before the one where the insertion will occur
* but with the same parent node (if there is one). This is needed
* so we can replace the insertion line with a new one. Remove this
* line from the list for its parent, since it's going to be discarded
* when we're all done).
*/
nodePtr = linePtr->parentPtr;
prevPtr = nodePtr->children.linePtr;
if (prevPtr == linePtr) {
prevPtr = NULL;
nodePtr->children.linePtr = linePtr->nextPtr;
} else {
for ( ; prevPtr->nextPtr != linePtr; prevPtr = prevPtr->nextPtr) {
/* Empty loop body. */
}
prevPtr->nextPtr = linePtr->nextPtr;
}
/*
* Break up the annotations for the insertion line into two pieces:
* those before the insertion point, and those at or after the insertion
* point.
*/
afterPtr = NULL;
if ((linePtr->annotPtr != NULL) && (linePtr->annotPtr->ch >= ch)) {
afterPtr = linePtr->annotPtr;
linePtr->annotPtr = NULL;
} else {
for (annotPtr = linePtr->annotPtr; annotPtr != NULL;
annotPtr = annotPtr->nextPtr) {
if ((annotPtr->nextPtr != NULL)
&& (annotPtr->nextPtr->ch >= ch)) {
afterPtr = annotPtr->nextPtr;
annotPtr->nextPtr = NULL;
break;
}
}
}
/*
* Chop the string up into lines and insert each line individually.
*/
changeToLineCount = -1;
prefixLength = ch;
while (1) {
for (newChunkLength = 0, eol = string; *eol != 0; eol++) {
newChunkLength++;
if (*eol == '\n') {
break;
}
}
/*
* Create a new line consisting of up to three parts: a prefix
* from linePtr, some material from string, and a suffix from
* linePtr.
*/
if ((newChunkLength == 0) || (*eol != '\n')) {
suffixLength = linePtr->numBytes - ch;
} else {
suffixLength = 0;
}
totalLength = prefixLength + newChunkLength + suffixLength;
newPtr = (TkTextLine *) ckalloc(LINE_SIZE(totalLength));
newPtr->parentPtr = nodePtr;
if (prevPtr == NULL) {
newPtr->nextPtr = nodePtr->children.linePtr;
nodePtr->children.linePtr = newPtr;
} else {
newPtr->nextPtr = prevPtr->nextPtr;
prevPtr->nextPtr = newPtr;
}
if (linePtr->annotPtr != NULL) {
newPtr->annotPtr = linePtr->annotPtr;
for (annotPtr = newPtr->annotPtr; annotPtr != NULL;
annotPtr = annotPtr->nextPtr) {
annotPtr->linePtr = newPtr;
}
linePtr->annotPtr = NULL;
} else {
newPtr->annotPtr = NULL;
}
newPtr->numBytes = totalLength;
if (prefixLength != 0) {
memcpy((VOID *) newPtr->bytes, (VOID *) linePtr->bytes,
prefixLength);
}
if (newChunkLength != 0) {
memcpy((VOID *) (newPtr->bytes + prefixLength), (VOID *) string,
newChunkLength);
}
if (suffixLength != 0) {
memcpy((VOID *) (newPtr->bytes + prefixLength + newChunkLength),
(VOID *) (linePtr->bytes + ch), suffixLength);
}
newPtr->bytes[totalLength] = 0;
changeToLineCount += 1;
/*
* Quit after the suffix has been output (there is always at least
* one character of suffix: the newline). Before jumping out of the
* loop, put back the annotations that pertain to the suffix.
* Careful! If no newlines were inserted, there could already be
* annotations at the beginning of the line; add back to the end.
*/
if (suffixLength != 0) {
if (newPtr->annotPtr == NULL) {
newPtr->annotPtr = afterPtr;
} else {
for (annotPtr = newPtr->annotPtr; annotPtr->nextPtr != NULL;
annotPtr = annotPtr->nextPtr) {
/* Empty loop body. */
}
annotPtr->nextPtr = afterPtr;
}
for (annotPtr = afterPtr; annotPtr != NULL;
annotPtr = annotPtr->nextPtr) {
annotPtr->linePtr = newPtr;
annotPtr->ch += prefixLength+newChunkLength-ch;
}
break;
}
/*
* Advance to insert the next line chunk.
*/
string += newChunkLength;
prefixLength = 0;
prevPtr = newPtr;
}
/*
* Increment the line counts in all the parent nodes of the insertion
* point, then rebalance the tree if necessary.
*/
for ( ; nodePtr != NULL; nodePtr = nodePtr->parentPtr) {
nodePtr->numLines += changeToLineCount;
}
nodePtr = linePtr->parentPtr;
nodePtr->numChildren += changeToLineCount;
if (nodePtr->numChildren > MAX_CHILDREN) {
Rebalance(treePtr, nodePtr);
}
ckfree((char *) linePtr);
if (tkBTreeDebug) {
TkBTreeCheck(tree);
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeDeleteChars --
*
* Delete a range of characters from a B-tree.
*
* Results:
* None.
*
* Side effects:
* Information is deleted from the B-tree. This can cause the
* internal structure of the B-tree to change. Note: the two
* lines given by line1Ptr and line2Ptr will be replaced with
* a single line containing the undeleted parts of the original
* lines. This could potentially result in an empty line;
* normally the caller should adjust the deletion range to prevent
* this sort of behavior.
*
*----------------------------------------------------------------------
*/
void
TkBTreeDeleteChars(tree, line1Ptr, ch1, line2Ptr, ch2)
TkTextBTree tree; /* B-tree in which to delete. */
register TkTextLine *line1Ptr; /* Line containing first character
* to delete. */
int ch1; /* Index within linePtr1 of first
* character to delete. */
register TkTextLine *line2Ptr; /* Line containing character just
* after last one to delete. */
int ch2; /* Index within linePtr2 of character
* just after last one to delete. */
{
BTree *treePtr = (BTree *) tree;
TkTextLine *linePtr, *nextPtr, *prevLinePtr;
Node *nodePtr, *parentPtr, *nextNodePtr;
TkAnnotation *annotPtr, *annotPtr2;
int ch;
int linesDeleted; /* Counts lines deleted from current
* level-0 node. */
/*
* Work through the tree deleting all of the lines between line1Ptr
* and line2Ptr (but don't delete line1Ptr or line2Ptr yet). Also
* delete any nodes in the B-tree that become empty because of
* this process.
*/
linePtr = line1Ptr->nextPtr;
nodePtr = line1Ptr->parentPtr;
if (line1Ptr == line2Ptr) {
goto middleLinesDeleted;
}
while (1) {
/*
* Delete all relevant lines within the same level-0 node.
*/
linesDeleted = 0;
while ((linePtr != line2Ptr) && (linePtr != NULL)) {
/*
* Move any annotations in this line to the end of the
* deletion range. If both the starting and ending toggle
* for a tagged range get moved, they'll cancel each other
* automatically and be dropped, which is the right behavior.
*/
for (annotPtr = linePtr->annotPtr, linePtr->annotPtr = NULL;
annotPtr != NULL; annotPtr = annotPtr2) {
if (annotPtr->type == TK_ANNOT_TOGGLE) {
AddToggleToLine(line2Ptr, ch2, annotPtr->info.tagPtr);
ChangeNodeToggleCount(nodePtr, annotPtr->info.tagPtr, -1);
annotPtr2 = annotPtr->nextPtr;
ckfree((char *) annotPtr);
} else {
annotPtr2 = annotPtr->nextPtr;
annotPtr->linePtr = line2Ptr;
annotPtr->ch = ch2;
TkBTreeAddAnnotation(annotPtr);
}
}
nextPtr = linePtr->nextPtr;
ckfree((char *) linePtr);
linesDeleted++;
linePtr = nextPtr;
}
if (nodePtr == line1Ptr->parentPtr) {
line1Ptr->nextPtr = linePtr;
} else {
nodePtr->children.linePtr = linePtr;
}
for (parentPtr = nodePtr; parentPtr != NULL;
parentPtr = parentPtr->parentPtr) {
parentPtr->numLines -= linesDeleted;
}
nodePtr->numChildren -= linesDeleted;
if (linePtr == line2Ptr) {
break;
}
/*
* Find the next level-0 node to visit, and its first line (but
* remember the current node so we can come back to delete it if
* it's empty).
*/
nextNodePtr = nodePtr;
while (nextNodePtr->nextPtr == NULL) {
nextNodePtr = nextNodePtr->parentPtr;
}
nextNodePtr = nextNodePtr->nextPtr;
while (nextNodePtr->level > 0) {
nextNodePtr = nextNodePtr->children.nodePtr;
}
linePtr = nextNodePtr->children.linePtr;
/*
* Now go back to the node we just left and delete it if
* it's empty, along with any of its ancestors that are
* empty. It may seem funny to go back like this, but it's
* simpler to find the next place to visit before modifying
* the tree structure.
*/
while (nodePtr->numChildren == 0) {
parentPtr = nodePtr->parentPtr;
if (parentPtr->children.nodePtr == nodePtr) {
parentPtr->children.nodePtr = nodePtr->nextPtr;
} else {
Node *prevPtr;
for (prevPtr = parentPtr->children.nodePtr;
prevPtr->nextPtr != nodePtr;
prevPtr = prevPtr->nextPtr) {
}
prevPtr->nextPtr = nodePtr->nextPtr;
}
parentPtr->numChildren--;
DeleteSummaries(nodePtr->summaryPtr);
ckfree((char *) nodePtr);
nodePtr = parentPtr;
}
nodePtr = nextNodePtr;
}
/*
* Make a new line that consists of the first part of the first
* line of the deletion range and the last part of the last line
* of the deletion range.
*/
middleLinesDeleted:
nodePtr = line1Ptr->parentPtr;
linePtr = (TkTextLine *) ckalloc(LINE_SIZE(ch1 + line2Ptr->numBytes - ch2));
linePtr->parentPtr = nodePtr;
linePtr->nextPtr = line1Ptr->nextPtr;
linePtr->annotPtr = NULL;
linePtr->numBytes = ch1 + line2Ptr->numBytes - ch2;
if (ch1 != 0) {
memcpy((VOID *) linePtr->bytes, (VOID *) line1Ptr->bytes, ch1);
}
strcpy(linePtr->bytes + ch1, line2Ptr->bytes + ch2);
/*
* Process the annotations for the starting and ending lines. Enter
* a new annotation on linePtr (the joined line) for each of these
* annotations, then delete the originals. The code below is a little
* tricky (e.g. the "break" in the first loop) to handle the case where
* the starting and ending lines are the same.
*/
for (annotPtr = line1Ptr->annotPtr; annotPtr != NULL;
annotPtr = line1Ptr->annotPtr) {
if (annotPtr->ch <= ch1) {
ch = annotPtr->ch;
} else {
if (line1Ptr == line2Ptr) {
break;
}
ch = ch1;
}
line1Ptr->annotPtr = annotPtr->nextPtr;
if (annotPtr->type == TK_ANNOT_TOGGLE) {
AddToggleToLine(linePtr, ch, annotPtr->info.tagPtr);
ChangeNodeToggleCount(line1Ptr->parentPtr, annotPtr->info.tagPtr,
-1);
ckfree((char *) annotPtr);
} else {
annotPtr->linePtr = linePtr;
annotPtr->ch = ch;
TkBTreeAddAnnotation(annotPtr);
}
}
for (annotPtr = line2Ptr->annotPtr; annotPtr != NULL;
annotPtr = line2Ptr->annotPtr) {
if (annotPtr->ch >= ch2) {
ch = annotPtr->ch - ch2 + ch1;
} else {
ch = ch1;
}
line2Ptr->annotPtr = annotPtr->nextPtr;
if (annotPtr->type == TK_ANNOT_TOGGLE) {
AddToggleToLine(linePtr, ch, annotPtr->info.tagPtr);
ChangeNodeToggleCount(line2Ptr->parentPtr, annotPtr->info.tagPtr,
-1);
ckfree((char *) annotPtr);
} else {
annotPtr->linePtr = linePtr;
annotPtr->ch = ch;
TkBTreeAddAnnotation(annotPtr);
}
}
/*
* Delete the original starting and stopping lines (don't forget
* that the annotations have already been deleted) and insert the
* new line in place of line1Ptr.
*/
nodePtr = line1Ptr->parentPtr;
if (nodePtr->children.linePtr == line1Ptr) {
nodePtr->children.linePtr = linePtr;
} else {
for (prevLinePtr = nodePtr->children.linePtr;
prevLinePtr->nextPtr != line1Ptr;
prevLinePtr = prevLinePtr->nextPtr) {
/* Empty loop body. */
}
prevLinePtr->nextPtr = linePtr;
}
ckfree((char *) line1Ptr);
if (line2Ptr != line1Ptr) {
nodePtr = line2Ptr->parentPtr;
if (nodePtr->children.linePtr == line2Ptr) {
nodePtr->children.linePtr = line2Ptr->nextPtr;
} else {
for (prevLinePtr = nodePtr->children.linePtr;
prevLinePtr->nextPtr != line2Ptr;
prevLinePtr = prevLinePtr->nextPtr) {
/* Empty loop body. */
}
prevLinePtr->nextPtr = line2Ptr->nextPtr;
}
ckfree((char *) line2Ptr);
for (parentPtr = nodePtr; parentPtr != NULL;
parentPtr = parentPtr->parentPtr) {
parentPtr->numLines--;
}
nodePtr->numChildren--;
}
/*
* Rebalance the tree, starting from each of the endpoints of the
* deletion range. This code is a tricky, because the act of
* rebalancing the parent of one endpoint can cause the parent of
* the other endpoint to be reallocated. The only thing it's safe
* to hold onto is a pointer to a line. Thus, rebalance line2Ptr's
* parent first, then use linePtr find the second parent to rebalance
* second.
*/
if (nodePtr != linePtr->parentPtr) {
Rebalance(treePtr, nodePtr);
}
Rebalance(treePtr, linePtr->parentPtr);
if (tkBTreeDebug) {
TkBTreeCheck(tree);
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeTag --
*
* Turn a given tag on or off for a given range of characters in
* a B-tree of text.
*
* Results:
* None.
*
* Side effects:
* The given tag is added to the given range of characters
* in the tree or removed from all those characters, depending
* on the "add" argument.
*
*----------------------------------------------------------------------
*/
void
TkBTreeTag(tree, line1, ch1, line2, ch2, tagPtr, add)
TkTextBTree tree; /* B-tree in which to add tag
* information. */
int line1, ch1; /* Position of first character to
* tag. */
int line2, ch2; /* Position of character just after
* last one to tag. */
TkTextTag *tagPtr; /* Tag to associate with the range
* of characters. */
int add; /* One means add tag to the given
* range of characters; zero means
* remove the tag from the range. */
{
BTree *treePtr = (BTree *) tree;
register TkTextLine *line1Ptr, *line2Ptr;
TkTextSearch search;
int oldState;
/*
* Find the lines containing the first and last characters to be tagged,
* and adjust the starting and stopping locations if they don't already
* point within lines. If the range would have started or stopped at the
* end of a line, round it up to the beginning of the next line (right
* now this restriction keeps the final newline from being tagged).
*/
if (line1 < 0) {
line1 = 0;
ch1 = 0;
}
line1Ptr = TkBTreeFindLine(tree, line1);
if (line1Ptr == NULL) {
return;
}
if (ch1 >= line1Ptr->numBytes) {
TkTextLine *nextLinePtr;
nextLinePtr = TkBTreeNextLine(line1Ptr);
if (nextLinePtr == NULL) {
return;
} else {
line1Ptr = nextLinePtr;
line1++;
ch1 = 0;
}
}
if (line2 < 0) {
return;
}
line2Ptr = TkBTreeFindLine(tree, line2);
if (line2Ptr == NULL) {
line2Ptr = TkBTreeFindLine(tree, treePtr->rootPtr->numLines-1);
ch2 = line2Ptr->numBytes-1;
}
if (ch2 >= line2Ptr->numBytes) {
TkTextLine *nextLinePtr;
nextLinePtr = TkBTreeNextLine(line2Ptr);
if (nextLinePtr == NULL) {
ch2 = line2Ptr->numBytes-1;
} else {
line2Ptr = nextLinePtr;
line2++;
ch2 = 0;
}
}
/*
* See if the tag is already present or absent at the start of the
* range. If the state doesn't already match what we want then add
* a toggle there.
*/
oldState = TkBTreeCharTagged(line1Ptr, ch1, tagPtr);
if ((add != 0) ^ oldState) {
AddToggleToLine(line1Ptr, ch1, tagPtr);
}
/*
* Scan the range of characters covered by the change and delete
* any existing tag transitions except those on the first and
* last characters. Keep track of whether the old state just before
* the last character (not including any tags on it) is what we
* want now; if not, then add a tag toggle there.
*/
TkBTreeStartSearch(tree, line1, ch1+1, line2, ch2, tagPtr, &search);
while (TkBTreeNextTag(&search)) {
if ((search.linePtr == line2Ptr) && (search.ch1 == ch2)) {
break;
}
oldState ^= 1;
AddToggleToLine(search.linePtr, search.ch1, tagPtr);
}
if ((add != 0) ^ oldState) {
AddToggleToLine(line2Ptr, ch2, tagPtr);
}
if (tkBTreeDebug) {
TkBTreeCheck(tree);
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeAddAnnotation --
*
* Given a filled in annotation, this procedure links it into
* a B-tree structure so that it will track changes to the B-tree.
*
* Results:
* None.
*
* Side effects:
* AnnotPtr will be linked into its tree. Note: the storage for
* annotPtr is assumed to have been malloc'ed by the caller.
*
*----------------------------------------------------------------------
*/
/* ARGSUSED */
void
TkBTreeAddAnnotation(annotPtr)
TkAnnotation *annotPtr; /* Pointer to annotation. The caller must
* have filled in all the fields except the
* "nextPtr" field. The type should NOT be
* TK_ANNOT_TOGGLE; these annotations are
* managed by the TkBTreeTag procedure. */
{
register TkAnnotation *annotPtr2, *prevPtr;
for (prevPtr = NULL, annotPtr2 = annotPtr->linePtr->annotPtr;
annotPtr2 != NULL;
prevPtr = annotPtr2, annotPtr2 = annotPtr2->nextPtr) {
if (annotPtr2->ch > annotPtr->ch) {
break;
}
}
if (prevPtr == NULL) {
annotPtr->nextPtr = annotPtr->linePtr->annotPtr;
annotPtr->linePtr->annotPtr = annotPtr;
} else {
annotPtr->nextPtr = prevPtr->nextPtr;
prevPtr->nextPtr = annotPtr;
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeRemoveAnnotation --
*
* This procedure unlinks an annotation from a B-tree so that
* the annotation will no longer be managed by the B-tree code.
*
* Results:
* None.
*
* Side effects:
* AnnotPtr will be unlinked from its tree. Note: it is up to the
* caller to free the storage for annotPtr, if that is desired.
*
*----------------------------------------------------------------------
*/
/* ARGSUSED */
void
TkBTreeRemoveAnnotation(annotPtr)
TkAnnotation *annotPtr; /* Pointer to annotation, which must
* have been linked into tree by a previous
* call to TkBTreeAddAnnotation. */
{
register TkAnnotation *prevPtr;
if (annotPtr->linePtr->annotPtr == annotPtr) {
annotPtr->linePtr->annotPtr = annotPtr->nextPtr;
} else {
for (prevPtr = annotPtr->linePtr->annotPtr;
prevPtr->nextPtr != annotPtr;
prevPtr = prevPtr->nextPtr) {
/* Empty loop body. */
}
prevPtr->nextPtr = annotPtr->nextPtr;
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeFindLine --
*
* Find a particular line in a B-tree based on its line number.
*
* Results:
* The return value is a pointer to the line structure for the
* line whose index is "line", or NULL if no such line exists.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
TkTextLine *
TkBTreeFindLine(tree, line)
TkTextBTree tree; /* B-tree in which to find line. */
int line; /* Index of desired line. */
{
BTree *treePtr = (BTree *) tree;
register Node *nodePtr;
register TkTextLine *linePtr;
int linesLeft;
nodePtr = treePtr->rootPtr;
linesLeft = line;
if ((line < 0) || (line >= nodePtr->numLines)) {
return NULL;
}
/*
* Work down through levels of the tree until a node is found at
* level 0.
*/
while (nodePtr->level != 0) {
for (nodePtr = nodePtr->children.nodePtr;
nodePtr->numLines <= linesLeft;
nodePtr = nodePtr->nextPtr) {
if (nodePtr == NULL) {
panic("TkBTreeFindLine ran out of nodes");
}
linesLeft -= nodePtr->numLines;
}
}
/*
* Work through the lines attached to the level-0 node.
*/
for (linePtr = nodePtr->children.linePtr; linesLeft > 0;
linePtr = linePtr->nextPtr) {
if (linePtr == NULL) {
panic("TkBTreeFindLine ran out of lines");
}
linesLeft -= 1;
}
return linePtr;
}
/*
*----------------------------------------------------------------------
*
* TkBTreeNextLine --
*
* Given an existing line in a B-tree, this procedure locates the
* next line in the B-tree. This procedure is used for scanning
* through the B-tree.
*
* Results:
* The return value is a pointer to the line that immediately
* follows linePtr, or NULL if there is no such line.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
TkTextLine *
TkBTreeNextLine(linePtr)
register TkTextLine *linePtr; /* Pointer to existing line in
* B-tree. */
{
register Node *nodePtr;
if (linePtr->nextPtr != NULL) {
return linePtr->nextPtr;
}
/*
* This was the last line associated with the particular parent node.
* Search up the tree for the next node, then search down from that
* node to find the first line,
*/
for (nodePtr = linePtr->parentPtr; ; nodePtr = nodePtr->parentPtr) {
if (nodePtr->nextPtr != NULL) {
nodePtr = nodePtr->nextPtr;
break;
}
if (nodePtr->parentPtr == NULL) {
return (TkTextLine *) NULL;
}
}
while (nodePtr->level > 0) {
nodePtr = nodePtr->children.nodePtr;
}
return nodePtr->children.linePtr;
}
/*
*----------------------------------------------------------------------
*
* TkBTreeLineIndex --
*
* Given a pointer to a line in a B-tree, return the numerical
* index of that line.
*
* Results:
* The result is the index of linePtr within the tree, where 0
* corresponds to the first line in the tree.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
int
TkBTreeLineIndex(linePtr)
TkTextLine *linePtr; /* Pointer to existing line in
* B-tree. */
{
register TkTextLine *linePtr2;
register Node *nodePtr, *parentPtr, *nodePtr2;
int index;
/*
* First count how many lines precede this one in its level-0
* node.
*/
nodePtr = linePtr->parentPtr;
index = 0;
for (linePtr2 = nodePtr->children.linePtr; linePtr2 != linePtr;
linePtr2 = linePtr2->nextPtr) {
if (linePtr2 == NULL) {
panic("TkBTreeLineIndex couldn't find line");
}
index += 1;
}
/*
* Now work up through the levels of the tree one at a time,
* counting how many lines are in nodes preceding the current
* node.
*/
for (parentPtr = nodePtr->parentPtr ; parentPtr != NULL;
nodePtr = parentPtr, parentPtr = parentPtr->parentPtr) {
for (nodePtr2 = parentPtr->children.nodePtr; nodePtr2 != nodePtr;
nodePtr2 = nodePtr2->nextPtr) {
if (nodePtr2 == NULL) {
panic("TkBTreeLineIndex couldn't find node");
}
index += nodePtr2->numLines;
}
}
return index;
}
/*
*----------------------------------------------------------------------
*
* TkBTreeStartSearch --
*
* This procedure sets up a search for tag transitions involving
* a given tag (or all tags) in a given range of the text.
*
* Results:
* None.
*
* Side effects:
* The information at *searchPtr is set up so that subsequent calls
* to TkBTreeNextTag will return information about the locations of
* tag transitions. Note that TkBTreeNextTag must be called to get
* the first transition.
*
*----------------------------------------------------------------------
*/
void
TkBTreeStartSearch(tree, line1, ch1, line2, ch2, tagPtr, searchPtr)
TkTextBTree tree; /* Tree to search. */
int line1, ch1; /* Character position at which to * start search (tags at this position
* will be returned). */
int line2, ch2; /* Character position at which to * stop search (tags at this position
* will be returned). */
TkTextTag *tagPtr; /* Tag to search for. NULL means
* search for any tag. */
register TkTextSearch *searchPtr; /* Where to store information about
* search's progress. */
{
register TkAnnotation *annotPtr;
searchPtr->tree = tree;
if (line1 < 0) {
searchPtr->line1 = 0;
searchPtr->ch1 = 0;
} else {
searchPtr->line1 = line1;
searchPtr->ch1 = ch1;
}
searchPtr->line2 = line2;
searchPtr->ch2 = ch2;
searchPtr->tagPtr = tagPtr;
searchPtr->allTags = (tagPtr == NULL);
searchPtr->linePtr = TkBTreeFindLine(searchPtr->tree, searchPtr->line1);
if (searchPtr->linePtr == NULL) {
searchPtr->line1 = searchPtr->line2;
searchPtr->ch1 = searchPtr->ch2;
searchPtr->annotPtr = NULL;
} else {
for (annotPtr = searchPtr->linePtr->annotPtr;
(annotPtr != NULL) && (annotPtr->ch < ch1);
annotPtr = annotPtr->nextPtr) {
/* Empty loop body. */
}
searchPtr->annotPtr = annotPtr;
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeNextTag --
*
* Once a tag search has begun, successive calls to this procedure
* return successive tag toggles. Note: it is NOT SAFE to call this
* procedure if characters have been inserted into or deleted from
* the B-tree since the call to TkBTreeStartSearch.
*
* Results:
* The return value is 1 if another toggle was found that met the
* criteria specified in the call to TkBTreeStartSearch. 0 is
* returned if no more matching tag transitions were found.
*
* Side effects:
* Information in *searchPtr is modified to update the state of the
* search and indicate where the next tag toggle is located.
*
*----------------------------------------------------------------------
*/
int
TkBTreeNextTag(searchPtr)
register TkTextSearch *searchPtr; /* Information about search in
* progress; must have been set up by
* call to TkBTreeStartSearch. */
{
register TkAnnotation *annotPtr;
register Node *nodePtr;
register Summary *summaryPtr;
if (searchPtr->linePtr == NULL) {
return 0;
}
/*
* The outermost loop iterates over lines that may potentially contain
* a relevant tag transition, starting from the current line and tag.
*/
while (1) {
/*
* See if there are more tags on the current line that are relevant.
*/
for (annotPtr = searchPtr->annotPtr; annotPtr != NULL;
annotPtr = annotPtr->nextPtr) {
if ((annotPtr->type == TK_ANNOT_TOGGLE)
&& (searchPtr->allTags
|| (annotPtr->info.tagPtr == searchPtr->tagPtr))) {
if ((searchPtr->line1 == searchPtr->line2)
&& (annotPtr->ch > searchPtr->ch2)) {
goto searchOver;
}
searchPtr->tagPtr = annotPtr->info.tagPtr;
searchPtr->ch1 = annotPtr->ch;
searchPtr->annotPtr = annotPtr->nextPtr;
return 1;
}
}
/*
* See if there are more lines associated with the current parent
* node. If so, go back to the top of the loop to search the next
* one of them.
*/
if (searchPtr->line1 >= searchPtr->line2) {
goto searchOver;
}
searchPtr->line1++;
if (searchPtr->linePtr->nextPtr != NULL) {
searchPtr->linePtr = searchPtr->linePtr->nextPtr;
searchPtr->annotPtr = searchPtr->linePtr->annotPtr;
continue;
}
/*
* Search across and up through the B-tree's node hierarchy looking
* for the next node that has a relevant tag transition somewhere in
* its subtree. Be sure to update the current line number as we
* skip over large chunks of lines.
*/
nodePtr = searchPtr->linePtr->parentPtr;
while (1) {
while (nodePtr->nextPtr == NULL) {
if (nodePtr->parentPtr == NULL) {
goto searchOver;
}
nodePtr = nodePtr->parentPtr;
}
nodePtr = nodePtr->nextPtr;
for (summaryPtr = nodePtr->summaryPtr; summaryPtr != NULL;
summaryPtr = summaryPtr->nextPtr) {
if ((searchPtr->allTags) ||
(summaryPtr->tagPtr == searchPtr->tagPtr)) {
goto gotNodeWithTag;
}
}
searchPtr->line1 += nodePtr->numLines;
}
/*
* At this point we've found a subtree that has a relevant tag
* transition. Now search down (and across) through that subtree
* to find the first level-0 node that has a relevant tag transition.
*/
gotNodeWithTag:
while (nodePtr->level > 0) {
for (nodePtr = nodePtr->children.nodePtr; ;
nodePtr = nodePtr->nextPtr) {
for (summaryPtr = nodePtr->summaryPtr; summaryPtr != NULL;
summaryPtr = summaryPtr->nextPtr) {
if ((searchPtr->allTags)
|| (summaryPtr->tagPtr == searchPtr->tagPtr)) {
goto nextChild;
}
}
searchPtr->line1 += nodePtr->numLines;
if (nodePtr->nextPtr == NULL) {
panic("TkBTreeNextTag found incorrect tag summary info.");
}
}
nextChild:
continue;
}
/*
* Now we're down to a level-0 node that contains a line that contains
* a relevant tag transition. Set up line information and go back to
* the beginning of the loop to search through lines.
*/
searchPtr->linePtr = nodePtr->children.linePtr;
searchPtr->annotPtr = searchPtr->linePtr->annotPtr;
if (searchPtr->line1 > searchPtr->line2) {
goto searchOver;
}
continue;
}
searchOver:
searchPtr->line1 = searchPtr->line2;
searchPtr->ch1 = searchPtr->ch2;
searchPtr->annotPtr = NULL;
searchPtr->linePtr = NULL;
return 0;
}
/*
*----------------------------------------------------------------------
*
* TkBTreeCheck --
*
* This procedure runs a set of consistency checks over a B-tree
* and panics if any inconsistencies are found.
*
* Results:
* None.
*
* Side effects:
* If a structural defect is found, the procedure panics with an
* error message.
*
*----------------------------------------------------------------------
*/
void
TkBTreeCheck(tree)
TkTextBTree tree; /* Tree to check. */
{
BTree *treePtr = (BTree *) tree;
register Summary *summaryPtr;
/*
* Make sure that overall there is an even count of tag transitions
* for the whole text.
*/
for (summaryPtr = treePtr->rootPtr->summaryPtr; summaryPtr != NULL;
summaryPtr = summaryPtr->nextPtr) {
if (summaryPtr->toggleCount & 1) {
panic("TkBTreeCheck found odd toggle count for \"%s\" (%d)",
summaryPtr->tagPtr->name, summaryPtr->toggleCount);
}
}
/*
* Call a recursive procedure to do all of the rest of the checks.
*/
CheckNodeConsistency(treePtr->rootPtr);
}
/*
*----------------------------------------------------------------------
*
* Rebalance --
*
* This procedure is called when a node of a B-tree appears to be
* out of balance (too many children, or too few). It rebalances
* that node and all of its ancestors in the tree.
*
* Results:
* None.
*
* Side effects:
* The internal structure of treePtr may change.
*
*----------------------------------------------------------------------
*/
static void
Rebalance(treePtr, nodePtr)
BTree *treePtr; /* Tree that is being rebalanced. */
register Node *nodePtr; /* Node that may be out of balance. */
{
/*
* Loop over the entire ancestral chain of the node, working up
* through the tree one node at a time until the root node has
* been processed.
*/
for ( ; nodePtr != NULL; nodePtr = nodePtr->parentPtr) {
register Node *newPtr, *childPtr;
register TkTextLine *linePtr;
int i;
/*
* Check to see if the node has too many children. If it does,
* then split off all but the first MIN_CHILDREN into a separate
* node following the original one. Then repeat until the
* node has a decent size.
*/
if (nodePtr->numChildren > MAX_CHILDREN) {
while (1) {
/*
* If the node being split is the root node, then make a
* new root node above it first.
*/
if (nodePtr->parentPtr == NULL) {
newPtr = (Node *) ckalloc(sizeof(Node));
newPtr->parentPtr = NULL;
newPtr->nextPtr = NULL;
newPtr->summaryPtr = NULL;
newPtr->level = nodePtr->level + 1;
newPtr->children.nodePtr = nodePtr;
newPtr->numChildren = 1;
newPtr->numLines = nodePtr->numLines;
RecomputeNodeCounts(newPtr);
treePtr->rootPtr = newPtr;
}
newPtr = (Node *) ckalloc(sizeof(Node));
newPtr->parentPtr = nodePtr->parentPtr;
newPtr->nextPtr = nodePtr->nextPtr;
nodePtr->nextPtr = newPtr;
newPtr->summaryPtr = NULL;
newPtr->level = nodePtr->level;
newPtr->numChildren = nodePtr->numChildren - MIN_CHILDREN;
if (nodePtr->level == 0) {
for (i = MIN_CHILDREN-1,
linePtr = nodePtr->children.linePtr;
i > 0; i--, linePtr = linePtr->nextPtr) {
/* Empty loop body. */
}
newPtr->children.linePtr = linePtr->nextPtr;
linePtr->nextPtr = NULL;
} else {
for (i = MIN_CHILDREN-1,
childPtr = nodePtr->children.nodePtr;
i > 0; i--, childPtr = childPtr->nextPtr) {
/* Empty loop body. */
}
newPtr->children.nodePtr = childPtr->nextPtr;
childPtr->nextPtr = NULL;
}
RecomputeNodeCounts(nodePtr);
nodePtr->parentPtr->numChildren++;
nodePtr = newPtr;
if (nodePtr->numChildren <= MAX_CHILDREN) {
RecomputeNodeCounts(nodePtr);
break;
}
}
}
while (nodePtr->numChildren < MIN_CHILDREN) {
register Node *otherPtr;
Node *halfwayNodePtr = NULL; /* Initialization needed only */
TkTextLine *halfwayLinePtr = NULL; /* to prevent cc warnings. */
int totalChildren, firstChildren, i;
/*
* Too few children for this node. If this is the root,
* it's OK for it to have less than MIN_CHILDREN children
* as long as it's got at least two. If it has only one
* (and isn't at level 0), then chop the root node out of
* the tree and use its child as the new root.
*/
if (nodePtr->parentPtr == NULL) {
if ((nodePtr->numChildren == 1) && (nodePtr->level > 0)) {
treePtr->rootPtr = nodePtr->children.nodePtr;
treePtr->rootPtr->parentPtr = NULL;
DeleteSummaries(nodePtr->summaryPtr);
ckfree((char *) nodePtr);
}
return;
}
/*
* Not the root. Make sure that there are siblings to
* balance with.
*/
if (nodePtr->parentPtr->numChildren < 2) {
Rebalance(treePtr, nodePtr->parentPtr);
continue;
}
/*
* Find a sibling to borrow from, and arrange for nodePtr to
* be the earlier of the pair.
*/
if (nodePtr->nextPtr == NULL) {
for (otherPtr = nodePtr->parentPtr->children.nodePtr;
otherPtr->nextPtr != nodePtr;
otherPtr = otherPtr->nextPtr) {
/* Empty loop body. */
}
nodePtr = otherPtr;
}
otherPtr = nodePtr->nextPtr;
/*
* We're going to either merge the two siblings together
* into one node or redivide the children among them to
* balance their loads. As preparation, join their two
* child lists into a single list and remember the half-way
* point in the list.
*/
totalChildren = nodePtr->numChildren + otherPtr->numChildren;
firstChildren = totalChildren/2;
if (nodePtr->children.nodePtr == NULL) {
nodePtr->children = otherPtr->children;
otherPtr->children.nodePtr = NULL;
otherPtr->children.linePtr = NULL;
}
if (nodePtr->level == 0) {
register TkTextLine *linePtr;
for (linePtr = nodePtr->children.linePtr, i = 1;
linePtr->nextPtr != NULL;
linePtr = linePtr->nextPtr, i++) {
if (i == firstChildren) {
halfwayLinePtr = linePtr;
}
}
linePtr->nextPtr = otherPtr->children.linePtr;
while (i <= firstChildren) {
halfwayLinePtr = linePtr;
linePtr = linePtr->nextPtr;
i++;
}
} else {
register Node *childPtr;
for (childPtr = nodePtr->children.nodePtr, i = 1;
childPtr->nextPtr != NULL;
childPtr = childPtr->nextPtr, i++) {
if (i <= firstChildren) {
if (i == firstChildren) {
halfwayNodePtr = childPtr;
}
}
}
childPtr->nextPtr = otherPtr->children.nodePtr;
while (i <= firstChildren) {
halfwayNodePtr = childPtr;
childPtr = childPtr->nextPtr;
i++;
}
}
/*
* If the two siblings can simply be merged together, do it.
*/
if (totalChildren <= MAX_CHILDREN) {
RecomputeNodeCounts(nodePtr);
nodePtr->nextPtr = otherPtr->nextPtr;
nodePtr->parentPtr->numChildren--;
DeleteSummaries(otherPtr->summaryPtr);
ckfree((char *) otherPtr);
continue;
}
/*
* The siblings can't be merged, so just divide their
* children evenly between them.
*/
if (nodePtr->level == 0) {
otherPtr->children.linePtr = halfwayLinePtr->nextPtr;
halfwayLinePtr->nextPtr = NULL;
} else {
otherPtr->children.nodePtr = halfwayNodePtr->nextPtr;
halfwayNodePtr->nextPtr = NULL;
}
RecomputeNodeCounts(nodePtr);
RecomputeNodeCounts(otherPtr);
}
}
}
/*
*----------------------------------------------------------------------
*
* RecomputeNodeCounts --
*
* This procedure is called to recompute all the counts in a node
* (tags, child information, etc.) by scaning the information in
* its descendants. This procedure is called during rebalancing
* when a node's child structure has changed.
*
* Results:
* None.
*
* Side effects:
* The tag counts for nodePtr are modified to reflect its current
* child structure, as are its numChildren and numLines fields.
* Also, all of the children's parentPtr fields are made to point
* to nodePtr.
*
*----------------------------------------------------------------------
*/
static void
RecomputeNodeCounts(nodePtr)
register Node *nodePtr; /* Node whose tag summary information
* must be recomputed. */
{
register Summary *summaryPtr, *summaryPtr2;
register Node *childPtr;
register TkTextLine *linePtr;
register TkAnnotation *annotPtr;
/*
* Zero out all the existing counts for the node, but don't delete
* the existing Summary records (most of them will probably be reused).
*/
for (summaryPtr = nodePtr->summaryPtr; summaryPtr != NULL;
summaryPtr = summaryPtr->nextPtr) {
summaryPtr->toggleCount = 0;
}
nodePtr->numChildren = 0;
nodePtr->numLines = 0;
/*
* Scan through the children, adding the childrens' tag counts into
* the node's tag counts and adding new Summarys to the node if
* necessary.
*/
if (nodePtr->level == 0) {
for (linePtr = nodePtr->children.linePtr; linePtr != NULL;
linePtr = linePtr->nextPtr) {
nodePtr->numChildren++;
nodePtr->numLines++;
linePtr->parentPtr = nodePtr;
for (annotPtr = linePtr->annotPtr; annotPtr != NULL;
annotPtr = annotPtr->nextPtr) {
if (annotPtr->type != TK_ANNOT_TOGGLE) {
continue;
}
for (summaryPtr = nodePtr->summaryPtr; ;
summaryPtr = summaryPtr->nextPtr) {
if (summaryPtr == NULL) {
summaryPtr = (Summary *) ckalloc(sizeof(Summary));
summaryPtr->tagPtr = annotPtr->info.tagPtr;
summaryPtr->toggleCount = 1;
summaryPtr->nextPtr = nodePtr->summaryPtr;
nodePtr->summaryPtr = summaryPtr;
break;
}
if (summaryPtr->tagPtr == annotPtr->info.tagPtr) {
summaryPtr->toggleCount++;
break;
}
}
}
}
} else {
for (childPtr = nodePtr->children.nodePtr; childPtr != NULL;
childPtr = childPtr->nextPtr) {
nodePtr->numChildren++;
nodePtr->numLines += childPtr->numLines;
childPtr->parentPtr = nodePtr;
for (summaryPtr2 = childPtr->summaryPtr; summaryPtr2 != NULL;
summaryPtr2 = summaryPtr2->nextPtr) {
for (summaryPtr = nodePtr->summaryPtr; ;
summaryPtr = summaryPtr->nextPtr) {
if (summaryPtr == NULL) {
summaryPtr = (Summary *) ckalloc(sizeof(Summary));
summaryPtr->tagPtr = summaryPtr2->tagPtr;
summaryPtr->toggleCount = summaryPtr2->toggleCount;
summaryPtr->nextPtr = nodePtr->summaryPtr;
nodePtr->summaryPtr = summaryPtr;
break;
}
if (summaryPtr->tagPtr == summaryPtr2->tagPtr) {
summaryPtr->toggleCount += summaryPtr2->toggleCount;
break;
}
}
}
}
}
/*
* Scan through the node's tag records again and delete any Summary
* records that still have a zero count.
*/
summaryPtr2 = NULL;
for (summaryPtr = nodePtr->summaryPtr; summaryPtr != NULL; ) {
if (summaryPtr->toggleCount > 0) {
summaryPtr2 = summaryPtr;
summaryPtr = summaryPtr->nextPtr;
continue;
}
if (summaryPtr2 != NULL) {
summaryPtr2->nextPtr = summaryPtr->nextPtr;
ckfree((char *) summaryPtr);
summaryPtr = summaryPtr2->nextPtr;
} else {
nodePtr->summaryPtr = summaryPtr->nextPtr;
ckfree((char *) summaryPtr);
summaryPtr = nodePtr->summaryPtr;
}
}
}
/*
*----------------------------------------------------------------------
*
* AddToggleToLine --
*
* Insert a tag transition at a particular point in a particular
* line.
*
* Results:
* None.
*
* Side effects:
* LinePtr and all its ancestors in the B-tree stucture are modified
* to indicate the presence of a transition (either on or off) on
* tag at the given place in the given line.
*
*----------------------------------------------------------------------
*/
static void
AddToggleToLine(linePtr, index, tagPtr)
TkTextLine *linePtr; /* Line within which to add
* transition. */
int index; /* Character before which to
* add transition. */
TkTextTag *tagPtr; /* Information about tag. */
{
register TkAnnotation *annotPtr, *prevPtr;
int delta = 1;
/*
* Find the position where the toggle should be inserted into
* the array (just after prevPtr), and see if there is already
* a toggle at exactly the point where we're going to insert a
* new toggle. If so then the two toggles cancel; just delete
* the existing toggle.
*/
for (prevPtr = NULL, annotPtr = linePtr->annotPtr; annotPtr != NULL;
prevPtr = annotPtr, annotPtr = annotPtr->nextPtr) {
if (annotPtr->ch > index) {
break;
}
if ((annotPtr->type == TK_ANNOT_TOGGLE)
&& (annotPtr->ch == index)
&& (annotPtr->info.tagPtr == tagPtr)) {
if (prevPtr == NULL) {
linePtr->annotPtr = annotPtr->nextPtr;
} else {
prevPtr->nextPtr = annotPtr->nextPtr;
}
ckfree((char *) annotPtr);
delta = -1;
goto updateNodes;
}
}
/*
* Create a new toggle and insert it into the list.
*/
annotPtr = (TkAnnotation *) ckalloc(sizeof(TkAnnotation));
annotPtr->type = TK_ANNOT_TOGGLE;
annotPtr->linePtr = linePtr;
annotPtr->ch = index;
annotPtr->info.tagPtr = tagPtr;
if (prevPtr == NULL) {
annotPtr->nextPtr = linePtr->annotPtr;
linePtr->annotPtr = annotPtr;
} else {
annotPtr->nextPtr = prevPtr->nextPtr;
prevPtr->nextPtr = annotPtr;
}
/*
* Update all the nodes above this line to reflect the change in
* toggle structure.
*/
updateNodes:
ChangeNodeToggleCount(linePtr->parentPtr, tagPtr, delta);
}
/*
*----------------------------------------------------------------------
*
* ChangeNodeToggleCount --
*
* This procedure increments or decrements the toggle count for
* a particular tag in a particular node and all its ancestors.
*
* Results:
* None.
*
* Side effects:
* The toggle count for tag is adjusted up or down by "delta" in
* nodePtr.
*
*----------------------------------------------------------------------
*/
static void
ChangeNodeToggleCount(nodePtr, tagPtr, delta)
register Node *nodePtr; /* Node whose toggle count for a tag
* must be changed. */
TkTextTag *tagPtr; /* Information about tag. */
int delta; /* Amount to add to current toggle
* count for tag (may be negative). */
{
register Summary *summaryPtr, *prevPtr;
/*
* Iterate over the node and all of its ancestors.
*/
for ( ; nodePtr != NULL; nodePtr = nodePtr->parentPtr) {
/*
* See if there's already an entry for this tag for this node. If so,
* perhaps all we have to do is adjust its count.
*/
for (prevPtr = NULL, summaryPtr = nodePtr->summaryPtr;
summaryPtr != NULL;
prevPtr = summaryPtr, summaryPtr = summaryPtr->nextPtr) {
if (summaryPtr->tagPtr != tagPtr) {
continue;
}
summaryPtr->toggleCount += delta;
if (summaryPtr->toggleCount > 0) {
goto nextAncestor;
}
if (summaryPtr->toggleCount < 0) {
panic("ChangeNodeToggleCount: negative toggle count");
}
/*
* Zero count; must remove this tag from the list.
*/
if (prevPtr == NULL) {
nodePtr->summaryPtr = summaryPtr->nextPtr;
} else {
prevPtr->nextPtr = summaryPtr->nextPtr;
}
ckfree((char *) summaryPtr);
goto nextAncestor;
}
/*
* This tag isn't in the list. Add a new entry to the list.
*/
if (delta < 0) {
panic("ChangeNodeToggleCount: negative delta, no tag entry");
}
summaryPtr = (Summary *) ckalloc(sizeof(Summary));
summaryPtr->tagPtr = tagPtr;
summaryPtr->toggleCount = delta;
summaryPtr->nextPtr = nodePtr->summaryPtr;
nodePtr->summaryPtr = summaryPtr;
nextAncestor:
continue;
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeCharTagged --
*
* Determine whether a particular character has a particular tag.
*
* Results:
* The return value is 1 if the given tag is in effect at the
* character given by linePtr and ch, and 0 otherwise.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
int
TkBTreeCharTagged(linePtr, ch, tagPtr)
TkTextLine *linePtr; /* Line containing character of
* interest. */
int ch; /* Index of character in linePtr. */
TkTextTag *tagPtr; /* Tag of interest. */
{
register Node *nodePtr;
register TkTextLine *siblingLinePtr;
int toggles;
/*
* Count the number of toggles for the tag at the line level (i.e.
* in all the sibling lines that precede this one, plus in this line
* up to the character of interest.
*/
toggles = 0;
for (siblingLinePtr = linePtr->parentPtr->children.linePtr; ;
siblingLinePtr = siblingLinePtr->nextPtr) {
register TkAnnotation *annotPtr;
for (annotPtr = siblingLinePtr->annotPtr;
(annotPtr != NULL) && ((siblingLinePtr != linePtr)
|| (annotPtr->ch <= ch));
annotPtr = annotPtr->nextPtr) {
if ((annotPtr->type == TK_ANNOT_TOGGLE)
&& (annotPtr->info.tagPtr == tagPtr)) {
toggles++;
}
}
if (siblingLinePtr == linePtr) {
break;
}
}
/*
* For each node in the ancestry of this line, count the number of
* toggles of the given tag in siblings that precede that node.
*/
for (nodePtr = linePtr->parentPtr; nodePtr->parentPtr != NULL;
nodePtr = nodePtr->parentPtr) {
register Node *siblingPtr;
register Summary *summaryPtr;
for (siblingPtr = nodePtr->parentPtr->children.nodePtr;
siblingPtr != nodePtr; siblingPtr = siblingPtr->nextPtr) {
for (summaryPtr = siblingPtr->summaryPtr; summaryPtr != NULL;
summaryPtr = summaryPtr->nextPtr) {
if (summaryPtr->tagPtr == tagPtr) {
toggles += summaryPtr->toggleCount;
}
}
}
}
/*
* An odd number of toggles means that the tag is present at the
* given point.
*/
return toggles & 1;
}
/*
*----------------------------------------------------------------------
*
* TkBTreeGetTags --
*
* Return information about all of the tags that are associated
* with a particular character in a B-tree of text.
*
* Results:
* The return value is a malloc-ed array containing pointers to
* information for each of the tags that is associated with
* the character at the position given by linePtr and ch. The
* word at *numTagsPtr is filled in with the number of pointers
* in the array. It is up to the caller to free the array by
* passing it to free. If there are no tags at the given character
* then a NULL pointer is returned and *numTagsPtr will be set to 0.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
/* ARGSUSED */
TkTextTag **
TkBTreeGetTags(tree, linePtr, ch, numTagsPtr)
TkTextBTree tree; /* Tree to check. */
TkTextLine *linePtr; /* Line containing character of interest. */
int ch; /* Index within linePtr of character for
* which tag information is wanted. */
int *numTagsPtr; /* Store number of tags found at this
* location. */
{
register Node *nodePtr;
register TkTextLine *siblingLinePtr;
int src, dst;
TagInfo tagInfo;
#define NUM_TAG_INFOS 10
tagInfo.numTags = 0;
tagInfo.arraySize = NUM_TAG_INFOS;
tagInfo.tagPtrs = (TkTextTag **) ckalloc((unsigned)
NUM_TAG_INFOS*sizeof(TkTextTag *));
tagInfo.counts = (int *) ckalloc((unsigned)
NUM_TAG_INFOS*sizeof(int));
/*
* Record tag toggles at the line level (i.e. in all the sibling
* lines that precede this one, plus in this line up to the character
* of interest.
*/
for (siblingLinePtr = linePtr->parentPtr->children.linePtr; ;
siblingLinePtr = siblingLinePtr->nextPtr) {
register TkAnnotation *annotPtr;
for (annotPtr = siblingLinePtr->annotPtr;
(annotPtr != NULL) && ((siblingLinePtr != linePtr)
|| (annotPtr->ch <= ch));
annotPtr = annotPtr->nextPtr) {
if (annotPtr->type == TK_ANNOT_TOGGLE) {
IncCount(annotPtr->info.tagPtr, 1, &tagInfo);
}
}
if (siblingLinePtr == linePtr) {
break;
}
}
/*
* For each node in the ancestry of this line, record tag toggles
* for all siblings that precede that node.
*/
for (nodePtr = linePtr->parentPtr; nodePtr->parentPtr != NULL;
nodePtr = nodePtr->parentPtr) {
register Node *siblingPtr;
register Summary *summaryPtr;
for (siblingPtr = nodePtr->parentPtr->children.nodePtr;
siblingPtr != nodePtr; siblingPtr = siblingPtr->nextPtr) {
for (summaryPtr = siblingPtr->summaryPtr; summaryPtr != NULL;
summaryPtr = summaryPtr->nextPtr) {
IncCount(summaryPtr->tagPtr, summaryPtr->toggleCount, &tagInfo);
}
}
}
/*
* Go through the tag information and squash out all of the tags
* that have even toggle counts (these tags exist before the point
* of interest, but not at the desired character itself).
*/
for (src = 0, dst = 0; src < tagInfo.numTags; src++) {
if (tagInfo.counts[src] & 1) {
tagInfo.tagPtrs[dst] = tagInfo.tagPtrs[src];
dst++;
}
}
*numTagsPtr = dst;
ckfree((char *) tagInfo.counts);
if (dst == 0) {
ckfree((char *) tagInfo.tagPtrs);
return NULL;
}
return tagInfo.tagPtrs;
}
/*
*----------------------------------------------------------------------
*
* IncCount --
*
* This is a utility procedure used by TkBTreeGetTags. It
* increments the count for a particular tag, adding a new
* entry for that tag if there wasn't one previously.
*
* Results:
* None.
*
* Side effects:
* The information at *tagInfoPtr may be modified, and the arrays
* may be reallocated to make them larger.
*
*----------------------------------------------------------------------
*/
static void
IncCount(tagPtr, inc, tagInfoPtr)
TkTextTag *tagPtr; /* Handle for tag. */
int inc; /* Amount by which to increment tag count. */
TagInfo *tagInfoPtr; /* Holds cumulative information about tags;
* increment count here. */
{
register TkTextTag **tagPtrPtr;
int count;
for (tagPtrPtr = tagInfoPtr->tagPtrs, count = tagInfoPtr->numTags;
count > 0; tagPtrPtr++, count--) {
if (*tagPtrPtr == tagPtr) {
tagInfoPtr->counts[tagInfoPtr->numTags-count] += inc;
return;
}
}
/*
* There isn't currently an entry for this tag, so we have to
* make a new one. If the arrays are full, then enlarge the
* arrays first.
*/
if (tagInfoPtr->numTags == tagInfoPtr->arraySize) {
TkTextTag **newTags;
int *newCounts, newSize;
newSize = 2*tagInfoPtr->arraySize;
newTags = (TkTextTag **) ckalloc((unsigned)
(newSize*sizeof(TkTextTag *)));
memcpy((VOID *) newTags, (VOID *) tagInfoPtr->tagPtrs,
tagInfoPtr->arraySize * sizeof(TkTextTag *));
ckfree((char *) tagInfoPtr->tagPtrs);
tagInfoPtr->tagPtrs = newTags;
newCounts = (int *) ckalloc((unsigned) (newSize*sizeof(int)));
memcpy((VOID *) newCounts, (VOID *) tagInfoPtr->counts,
tagInfoPtr->arraySize * sizeof(int));
ckfree((char *) tagInfoPtr->counts);
tagInfoPtr->counts = newCounts;
tagInfoPtr->arraySize = newSize;
}
tagInfoPtr->tagPtrs[tagInfoPtr->numTags] = tagPtr;
tagInfoPtr->counts[tagInfoPtr->numTags] = inc;
tagInfoPtr->numTags++;
}
/*
*----------------------------------------------------------------------
*
* CheckNodeConsistency --
*
* This procedure is called as part of consistency checking for
* B-trees: it checks several aspects of a node and also runs
* checks recursively on the node's children.
*
* Results:
* None.
*
* Side effects:
* If anything suspicious is found in the tree structure, the
* procedure panics.
*
*----------------------------------------------------------------------
*/
static void
CheckNodeConsistency(nodePtr)
register Node *nodePtr; /* Node whose subtree should be
* checked. */
{
register Node *childNodePtr;
register Summary *summaryPtr, *summaryPtr2;
register TkAnnotation *annotPtr;
register TkTextLine *linePtr;
register char *p;
int numChildren, numLines, toggleCount, minChildren, index, numBytes;
if (nodePtr->parentPtr != NULL) {
minChildren = MIN_CHILDREN;
} else if (nodePtr->level > 0) {
minChildren = 2;
} else {
minChildren = 1;
}
if ((nodePtr->numChildren < minChildren)
|| (nodePtr->numChildren > MAX_CHILDREN)) {
panic("CheckNodeConsistency found bad child count (%d)",
nodePtr->numChildren);
}
numChildren = 0;
numLines = 0;
if (nodePtr->level == 0) {
for (linePtr = nodePtr->children.linePtr; linePtr != NULL;
linePtr = linePtr->nextPtr) {
if (linePtr->parentPtr != nodePtr) {
panic("CheckNodeConsistency found line that %s",
"didn't point to parent");
}
for (p = linePtr->bytes, numBytes = 0; *p != 0; p++, numBytes++) {
if ((*p == '\n') && (numBytes != linePtr->numBytes-1)) {
panic("CheckNodeConsistency found line with extra newline");
}
}
if (numBytes != linePtr->numBytes) {
panic("CheckNodeConsistency found line with bad numBytes");
}
if (linePtr->bytes[numBytes-1] != '\n') {
panic("CheckNodeConsistency found line with no newline");
}
index = 0;
for (annotPtr = linePtr->annotPtr; annotPtr != NULL;
annotPtr = annotPtr->nextPtr) {
if (annotPtr->ch < index) {
panic("CheckNodeConsistency found %s (%d %d)",
"out-of-order tag indices", index,
annotPtr->ch);
}
index = annotPtr->ch;
if (annotPtr->type == TK_ANNOT_TOGGLE) {
for (summaryPtr = nodePtr->summaryPtr; ;
summaryPtr = summaryPtr->nextPtr) {
if (summaryPtr == NULL) {
panic("CheckNodeConsistency found line %s",
"tag with no node tag: %s",
summaryPtr->tagPtr->name);
}
if (summaryPtr->tagPtr == annotPtr->info.tagPtr) {
break;
}
}
}
}
numChildren++;
numLines++;
}
} else {
for (childNodePtr = nodePtr->children.nodePtr; childNodePtr != NULL;
childNodePtr = childNodePtr->nextPtr) {
CheckNodeConsistency(childNodePtr);
for (summaryPtr = childNodePtr->summaryPtr; summaryPtr != NULL;
summaryPtr = summaryPtr->nextPtr) {
for (summaryPtr2 = nodePtr->summaryPtr; ;
summaryPtr2 = summaryPtr2->nextPtr) {
if (summaryPtr2 == NULL) {
panic("CheckNodeConsistency found %s (%s)",
"node tag with no parent tag",
summaryPtr->tagPtr->name);
}
if (summaryPtr->tagPtr == summaryPtr2->tagPtr) {
break;
}
}
}
numChildren++;
numLines += childNodePtr->numLines;
if (childNodePtr->parentPtr != nodePtr) {
panic("CheckNodeConsistency found node that %s",
"didn't point to parent");
}
if (childNodePtr->level != (nodePtr->level-1)) {
panic("CheckNodeConsistency found level mismatch (%d %d)",
nodePtr->level, childNodePtr->level);
}
}
}
if (numChildren != nodePtr->numChildren) {
panic("CheckNodeConsistency found mismatch in numChildren (%d %d)",
numChildren, nodePtr->numChildren);
}
if (numLines != nodePtr->numLines) {
panic("CheckNodeConsistency found mismatch in numLines (%d %d)",
numLines, nodePtr->numLines);
}
for (summaryPtr = nodePtr->summaryPtr; summaryPtr != NULL;
summaryPtr = summaryPtr->nextPtr) {
toggleCount = 0;
if (nodePtr->level == 0) {
for (linePtr = nodePtr->children.linePtr; linePtr != NULL;
linePtr = linePtr->nextPtr) {
for (annotPtr = linePtr->annotPtr; annotPtr != NULL;
annotPtr = annotPtr->nextPtr) {
if (annotPtr->info.tagPtr == summaryPtr->tagPtr) {
toggleCount++;
}
}
}
} else {
for (childNodePtr = nodePtr->children.nodePtr;
childNodePtr != NULL;
childNodePtr = childNodePtr->nextPtr) {
for (summaryPtr2 = childNodePtr->summaryPtr;
summaryPtr2 != NULL;
summaryPtr2 = summaryPtr2->nextPtr) {
if (summaryPtr2->tagPtr == summaryPtr->tagPtr) {
toggleCount += summaryPtr2->toggleCount;
}
}
}
}
if (toggleCount != summaryPtr->toggleCount) {
panic("CheckNodeConsistency found mismatch in toggleCount (%d %d)",
toggleCount, summaryPtr->toggleCount);
}
for (summaryPtr2 = summaryPtr->nextPtr; summaryPtr2 != NULL;
summaryPtr2 = summaryPtr2->nextPtr) {
if (summaryPtr2->tagPtr == summaryPtr->tagPtr) {
panic("CheckNodeConsistency found duplicated node tag: %s",
summaryPtr->tagPtr->name);
}
}
}
}
/*
*----------------------------------------------------------------------
*
* TkBTreeNumLines --
*
* This procedure returns a count of the number of lines of
* text present in a given B-tree.
*
* Results:
* The return value is a count of the number of lines in tree.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
int
TkBTreeNumLines(tree)
TkTextBTree tree; /* Information about tree. */
{
BTree *treePtr = (BTree *) tree;
return treePtr->rootPtr->numLines;
}
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