/* * tkTextDisp.c -- * * This module provides facilities to display text widgets. It is the * only place where information is kept about the screen layout of text * widgets. (Well, strictly, each TkTextLine and B-tree node caches its * last observed pixel height, but that information originates here). * * Copyright (c) 1992-1994 The Regents of the University of California. * Copyright (c) 1994-1997 Sun Microsystems, Inc. * * See the file "license.terms" for information on usage and redistribution of * this file, and for a DISCLAIMER OF ALL WARRANTIES. */ #include "tkInt.h" #include "tkText.h" #ifdef __WIN32__ #include "tkWinInt.h" #elif defined(__CYGWIN__) #include "tkUnixInt.h" #endif #ifdef MAC_OSX_TK #include "tkMacOSXInt.h" #endif /* * "Calculations of line pixel heights and the size of the vertical * scrollbar." * * Given that tag, font and elide changes can happen to large numbers of * diverse chunks in a text widget containing megabytes of text, it is not * possible to recalculate all affected height information immediately any * such change takes place and maintain a responsive user-experience. Yet, for * an accurate vertical scrollbar to be drawn, we must know the total number * of vertical pixels shown on display versus the number available to be * displayed. * * The way the text widget solves this problem is by maintaining cached line * pixel heights (in the BTree for each logical line), and having asynchronous * timer callbacks (i) to iterate through the logical lines recalculating * their heights, and (ii) to recalculate the vertical scrollbar's position * and size. * * Typically this works well but there are some situations where the overall * functional design of this file causes some problems. These problems can * only arise because the calculations used to display lines on screen are not * connected to those in the iterating-line- recalculation-process. * * The reason for this disconnect is that the display calculations operate in * display lines, and the iteration and cache operates in logical lines. * Given that the display calculations both need not contain complete logical * lines (at top or bottom of display), and that they do not actually keep * track of logical lines (for simplicity of code and historical design), this * means a line may be known and drawn with a different pixel height to that * which is cached in the BTree, and this might cause some temporary * undesirable mismatch between display and the vertical scrollbar. * * All such mismatches should be temporary, however, since the asynchronous * height calculations will always catch up eventually. * * For further details see the comments before and within the following * functions below: LayoutDLine, AsyncUpdateLineMetrics, GetYView, * GetYPixelCount, TkTextUpdateOneLine, TkTextUpdateLineMetrics. * * For details of the way in which the BTree keeps track of pixel heights, see * tkTextBTree.c. Basically the BTree maintains two pieces of information: the * logical line indices and the pixel height cache. */ /* * TK_LAYOUT_WITH_BASE_CHUNKS: * * With this macro set, collect all char chunks that have no holes * between them, that are on the same line and use the same font and font * size. Allocate the chars of all these chunks, the so-called "stretch", * in a DString in the first chunk, the so-called "base chunk". Use the * base chunk string for measuring and drawing, so that these actions are * always performed with maximum context. * * This is necessary for text rendering engines that provide ligatures * and sub-pixel layout, like ATSU on Mac. If we don't do this, the * measuring will change all the time, leading to an ugly "tremble and * shiver" effect. This is because of the continuous splitting and * re-merging of chunks that goes on in a text widget, when the cursor or * the selection move. * * Side effects: * * Memory management changes. Instead of attaching the character data to * the clientData structures of the char chunks, an additional DString is * used. The collection process will even lead to resizing this DString * for large stretches (> TCL_DSTRING_STATIC_SIZE == 200). We could * reduce the overall memory footprint by copying the result to a plain * char array after the line breaking process, but that would complicate * the code and make performance even worse speedwise. See also TODOs. * * TODOs: * * - Move the character collection process from the LayoutProc into * LayoutDLine(), so that the collection can be done before actual * layout. In this way measuring can look at the following text, too, * right from the beginning. Memory handling can also be improved with * this. Problem: We don't easily know which chunks are adjacent until * all the other chunks have calculated their width. Apparently marks * would return width==0. A separate char collection loop would have to * know these things. * * - Use a new context parameter to pass the context from LayoutDLine() to * the LayoutProc instead of using a global variable like now. Not * pressing until the previous point gets implemented. */ /* * The following structure describes how to display a range of characters. * The information is generated by scanning all of the tags associated with * the characters and combining that with default information for the overall * widget. These structures form the hash keys for dInfoPtr->styleTable. */ typedef struct StyleValues { Tk_3DBorder border; /* Used for drawing background under text. * NULL means use widget background. */ int borderWidth; /* Width of 3-D border for background. */ int relief; /* 3-D relief for background. */ Pixmap bgStipple; /* Stipple bitmap for background. None means * draw solid. */ XColor *fgColor; /* Foreground color for text. */ Tk_Font tkfont; /* Font for displaying text. */ Pixmap fgStipple; /* Stipple bitmap for text and other * foreground stuff. None means draw solid.*/ int justify; /* Justification style for text. */ int lMargin1; /* Left margin, in pixels, for first display * line of each text line. */ int lMargin2; /* Left margin, in pixels, for second and * later display lines of each text line. */ int offset; /* Offset in pixels of baseline, relative to * baseline of line. */ int overstrike; /* Non-zero means draw overstrike through * text. */ int rMargin; /* Right margin, in pixels. */ int spacing1; /* Spacing above first dline in text line. */ int spacing2; /* Spacing between lines of dline. */ int spacing3; /* Spacing below last dline in text line. */ TkTextTabArray *tabArrayPtr;/* Locations and types of tab stops (may be * NULL). */ int tabStyle; /* One of TABULAR or WORDPROCESSOR. */ int underline; /* Non-zero means draw underline underneath * text. */ int elide; /* Zero means draw text, otherwise not. */ TkWrapMode wrapMode; /* How to handle wrap-around for this tag. * One of TEXT_WRAPMODE_CHAR, * TEXT_WRAPMODE_NONE or TEXT_WRAPMODE_WORD.*/ } StyleValues; /* * The following structure extends the StyleValues structure above with * graphics contexts used to actually draw the characters. The entries in * dInfoPtr->styleTable point to structures of this type. */ typedef struct TextStyle { int refCount; /* Number of times this structure is * referenced in Chunks. */ GC bgGC; /* Graphics context for background. None means * use widget background. */ GC fgGC; /* Graphics context for foreground. */ StyleValues *sValuePtr; /* Raw information from which GCs were * derived. */ Tcl_HashEntry *hPtr; /* Pointer to entry in styleTable. Used to * delete entry. */ } TextStyle; /* * The following macro determines whether two styles have the same background * so that, for example, no beveled border should be drawn between them. */ #define SAME_BACKGROUND(s1, s2) \ (((s1)->sValuePtr->border == (s2)->sValuePtr->border) \ && ((s1)->sValuePtr->borderWidth == (s2)->sValuePtr->borderWidth) \ && ((s1)->sValuePtr->relief == (s2)->sValuePtr->relief) \ && ((s1)->sValuePtr->bgStipple == (s2)->sValuePtr->bgStipple)) /* * The following macro is used to compare two floating-point numbers to within * a certain degree of scale. Direct comparison fails on processors where the * processor and memory representations of FP numbers of a particular * precision is different (e.g. Intel) */ #define FP_EQUAL_SCALE(double1, double2, scaleFactor) \ (fabs((double1)-(double2))*((scaleFactor)+1.0) < 0.3) /* * Macro to make debugging/testing logging a little easier. */ #define LOG(toVar,what) \ Tcl_SetVar2(textPtr->interp, toVar, NULL, (what), \ TCL_GLOBAL_ONLY|TCL_APPEND_VALUE|TCL_LIST_ELEMENT) /* * The following structure describes one line of the display, which may be * either part or all of one line of the text. */ typedef struct DLine { TkTextIndex index; /* Identifies first character in text that is * displayed on this line. */ int byteCount; /* Number of bytes accounted for by this * display line, including a trailing space or * newline that isn't actually displayed. */ int logicalLinesMerged; /* Number of extra logical lines merged into * this one due to elided newlines. */ int y; /* Y-position at which line is supposed to be * drawn (topmost pixel of rectangular area * occupied by line). */ int oldY; /* Y-position at which line currently appears * on display. This is used to move lines by * scrolling rather than re-drawing. If * 'flags' have the OLD_Y_INVALID bit set, * then we will never examine this field * (which means line isn't currently visible * on display and must be redrawn). */ int height; /* Height of line, in pixels. */ int baseline; /* Offset of text baseline from y, in * pixels. */ int spaceAbove; /* How much extra space was added to the top * of the line because of spacing options. * This is included in height and baseline. */ int spaceBelow; /* How much extra space was added to the * bottom of the line because of spacing * options. This is included in height. */ int length; /* Total length of line, in pixels. */ TkTextDispChunk *chunkPtr; /* Pointer to first chunk in list of all of * those that are displayed on this line of * the screen. */ struct DLine *nextPtr; /* Next in list of all display lines for this * window. The list is sorted in order from * top to bottom. Note: the next DLine doesn't * always correspond to the next line of text: * (a) can have multiple DLines for one text * line (wrapping), (b) can have elided newlines, * and (c) can have gaps where DLine's * have been deleted because they're out of * date. */ int flags; /* Various flag bits: see below for values. */ } DLine; /* * Flag bits for DLine structures: * * HAS_3D_BORDER - Non-zero means that at least one of the chunks * in this line has a 3D border, so it * potentially interacts with 3D borders in * neighboring lines (see DisplayLineBackground). * NEW_LAYOUT - Non-zero means that the line has been * re-layed out since the last time the display * was updated. * TOP_LINE - Non-zero means that this was the top line in * in the window the last time that the window * was laid out. This is important because a line * may be displayed differently if its at the top * or bottom than if it's in the middle * (e.g. beveled edges aren't displayed for * middle lines if the adjacent line has a * similar background). * BOTTOM_LINE - Non-zero means that this was the bottom line * in the window the last time that the window * was laid out. * OLD_Y_INVALID - The value of oldY in the structure is not * valid or useful and should not be examined. * 'oldY' is only useful when the DLine is * currently displayed at a different position * and we wish to re-display it via scrolling, so * this means the DLine needs redrawing. */ #define HAS_3D_BORDER 1 #define NEW_LAYOUT 2 #define TOP_LINE 4 #define BOTTOM_LINE 8 #define OLD_Y_INVALID 16 /* * Overall display information for a text widget: */ typedef struct TextDInfo { Tcl_HashTable styleTable; /* Hash table that maps from StyleValues to * TextStyles for this widget. */ DLine *dLinePtr; /* First in list of all display lines for this * widget, in order from top to bottom. */ int topPixelOffset; /* Identifies first pixel in top display line * to display in window. */ int newTopPixelOffset; /* Desired first pixel in top display line to * display in window. */ GC copyGC; /* Graphics context for copying from off- * screen pixmaps onto screen. */ GC scrollGC; /* Graphics context for copying from one place * in the window to another (scrolling): * differs from copyGC in that we need to get * GraphicsExpose events. */ int x; /* First x-coordinate that may be used for * actually displaying line information. * Leaves space for border, etc. */ int y; /* First y-coordinate that may be used for * actually displaying line information. * Leaves space for border, etc. */ int maxX; /* First x-coordinate to right of available * space for displaying lines. */ int maxY; /* First y-coordinate below available space * for displaying lines. */ int topOfEof; /* Top-most pixel (lowest y-value) that has * been drawn in the appropriate fashion for * the portion of the window after the last * line of the text. This field is used to * figure out when to redraw part or all of * the eof field. */ /* * Information used for scrolling: */ int newXPixelOffset; /* Desired x scroll position, measured as the * number of pixels off-screen to the left for * a line with no left margin. */ int curXPixelOffset; /* Actual x scroll position, measured as the * number of pixels off-screen to the left. */ int maxLength; /* Length in pixels of longest line that's * visible in window (length may exceed window * size). If there's no wrapping, this will be * zero. */ double xScrollFirst, xScrollLast; /* Most recent values reported to horizontal * scrollbar; used to eliminate unnecessary * reports. */ double yScrollFirst, yScrollLast; /* Most recent values reported to vertical * scrollbar; used to eliminate unnecessary * reports. */ /* * The following information is used to implement scanning: */ int scanMarkXPixel; /* Pixel index of left edge of the window when * the scan started. */ int scanMarkX; /* X-position of mouse at time scan started. */ int scanTotalYScroll; /* Total scrolling (in screen pixels) that has * occurred since scanMarkY was set. */ int scanMarkY; /* Y-position of mouse at time scan started. */ /* * Miscellaneous information: */ int dLinesInvalidated; /* This value is set to 1 whenever something * happens that invalidates information in * DLine structures; if a redisplay is in * progress, it will see this and abort the * redisplay. This is needed because, for * example, an embedded window could change * its size when it is first displayed, * invalidating the DLine that is currently * being displayed. If redisplay continues, it * will use freed memory and could dump * core. */ int flags; /* Various flag values: see below for * definitions. */ /* * Information used to handle the asynchronous updating of the y-scrollbar * and the vertical height calculations: */ int lineMetricUpdateEpoch; /* Stores a number which is incremented each * time the text widget changes in a * significant way (e.g. resizing or * geometry-influencing tag changes). */ int currentMetricUpdateLine;/* Stores a counter which is used to iterate * over the logical lines contained in the * widget and update their geometry * calculations, if they are out of date. */ TkTextIndex metricIndex; /* If the current metric update line wraps * into very many display lines, then this is * used to keep track of what index we've got * to so far... */ int metricPixelHeight; /* ...and this is for the height calculation * so far...*/ int metricEpoch; /* ...and this for the epoch of the partial * calculation so it can be cancelled if * things change once more. This field will be * -1 if there is no long-line calculation in * progress, and take a non-negative value if * there is such a calculation in progress. */ int lastMetricUpdateLine; /* When the current update line reaches this * line, we are done and should stop the * asychronous callback mechanism. */ Tcl_TimerToken lineUpdateTimer; /* A token pointing to the current line metric * update callback. */ Tcl_TimerToken scrollbarTimer; /* A token pointing to the current scrollbar * update callback. */ } TextDInfo; /* * In TkTextDispChunk structures for character segments, the clientData field * points to one of the following structures: */ #if !TK_LAYOUT_WITH_BASE_CHUNKS typedef struct CharInfo { int numBytes; /* Number of bytes to display. */ char chars[4]; /* UTF characters to display. Actual size will * be numBytes, not 4. THIS MUST BE THE LAST * FIELD IN THE STRUCTURE. */ } CharInfo; #else /* TK_LAYOUT_WITH_BASE_CHUNKS */ typedef struct CharInfo { TkTextDispChunk *baseChunkPtr; int baseOffset; /* Starting offset in base chunk * baseChars. */ int numBytes; /* Number of bytes that belong to this * chunk. */ const char *chars; /* UTF characters to display. Actually points * into the baseChars of the base chunk. Only * valid after FinalizeBaseChunk(). */ } CharInfo; /* * The BaseCharInfo is a CharInfo with some additional data added. */ typedef struct BaseCharInfo { CharInfo ci; Tcl_DString baseChars; /* Actual characters for the stretch of text * represented by this base chunk. */ int width; /* Width in pixels of the whole string, if * known, else -1. Valid during * LayoutDLine(). */ } BaseCharInfo; static TkTextDispChunk *baseCharChunkPtr = NULL; #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ /* * Flag values for TextDInfo structures: * * DINFO_OUT_OF_DATE: Non-zero means that the DLine structures for * this window are partially or completely out of * date and need to be recomputed. * REDRAW_PENDING: Means that a when-idle handler has been * scheduled to update the display. * REDRAW_BORDERS: Means window border or pad area has * potentially been damaged and must be redrawn. * REPICK_NEEDED: 1 means that the widget has been modified in a * way that could change the current character (a * different character might be under the mouse * cursor now). Need to recompute the current * character before the next redisplay. */ #define DINFO_OUT_OF_DATE 1 #define REDRAW_PENDING 2 #define REDRAW_BORDERS 4 #define REPICK_NEEDED 8 /* * Action values for FreeDLines: * * DLINE_FREE: Free the lines, but no need to unlink them from the * current list of actual display lines. * DLINE_UNLINK: Free and unlink from current display. * DLINE_FREE_TEMP: Free, but don't unlink, and also don't set * 'dLinesInvalidated'. */ #define DLINE_FREE 0 #define DLINE_UNLINK 1 #define DLINE_FREE_TEMP 2 /* * The following counters keep statistics about redisplay that can be checked * to see how clever this code is at reducing redisplays. */ static int numRedisplays; /* Number of calls to DisplayText. */ static int linesRedrawn; /* Number of calls to DisplayDLine. */ static int numCopies; /* Number of calls to XCopyArea to copy part * of the screen. */ static int lineHeightsRecalculated; /* Number of line layouts purely for height * calculation purposes.*/ /* * Forward declarations for functions defined later in this file: */ static void AdjustForTab(TkText *textPtr, TkTextTabArray *tabArrayPtr, int index, TkTextDispChunk *chunkPtr); static void CharBboxProc(TkText *textPtr, TkTextDispChunk *chunkPtr, int index, int y, int lineHeight, int baseline, int *xPtr, int *yPtr, int *widthPtr, int *heightPtr); static int CharChunkMeasureChars(TkTextDispChunk *chunkPtr, const char *chars, int charsLen, int start, int end, int startX, int maxX, int flags, int *nextX); static void CharDisplayProc(TkText *textPtr, TkTextDispChunk *chunkPtr, int x, int y, int height, int baseline, Display *display, Drawable dst, int screenY); static int CharMeasureProc(TkTextDispChunk *chunkPtr, int x); static void CharUndisplayProc(TkText *textPtr, TkTextDispChunk *chunkPtr); #if TK_LAYOUT_WITH_BASE_CHUNKS static void FinalizeBaseChunk(TkTextDispChunk *additionalChunkPtr); static void FreeBaseChunk(TkTextDispChunk *baseChunkPtr); static int IsSameFGStyle(TextStyle *style1, TextStyle *style2); static void RemoveFromBaseChunk(TkTextDispChunk *chunkPtr); #endif /* * Definitions of elided procs. Compiler can't inline these since we use * pointers to these functions. ElideDisplayProc and ElideUndisplayProc are * special-cased for speed, as potentially many elided DLine chunks if large, * tag toggle-filled elided region. */ static void ElideBboxProc(TkText *textPtr, TkTextDispChunk *chunkPtr, int index, int y, int lineHeight, int baseline, int *xPtr, int *yPtr, int *widthPtr, int *heightPtr); static int ElideMeasureProc(TkTextDispChunk *chunkPtr, int x); static void DisplayDLine(TkText *textPtr, DLine *dlPtr, DLine *prevPtr, Pixmap pixmap); static void DisplayLineBackground(TkText *textPtr, DLine *dlPtr, DLine *prevPtr, Pixmap pixmap); static void DisplayText(ClientData clientData); static DLine * FindDLine(TkText *textPtr, DLine *dlPtr, CONST TkTextIndex *indexPtr); static void FreeDLines(TkText *textPtr, DLine *firstPtr, DLine *lastPtr, int action); static void FreeStyle(TkText *textPtr, TextStyle *stylePtr); static TextStyle * GetStyle(TkText *textPtr, CONST TkTextIndex *indexPtr); static void GetXView(Tcl_Interp *interp, TkText *textPtr, int report); static void GetYView(Tcl_Interp *interp, TkText *textPtr, int report); static int GetYPixelCount(TkText *textPtr, DLine *dlPtr); static DLine * LayoutDLine(TkText *textPtr, CONST TkTextIndex *indexPtr); static int MeasureChars(Tk_Font tkfont, CONST char *source, int maxBytes, int rangeStart, int rangeLength, int startX, int maxX, int flags, int *nextXPtr); static void MeasureUp(TkText *textPtr, CONST TkTextIndex *srcPtr, int distance, TkTextIndex *dstPtr, int *overlap); static int NextTabStop(Tk_Font tkfont, int x, int tabOrigin); static void UpdateDisplayInfo(TkText *textPtr); static void YScrollByLines(TkText *textPtr, int offset); static void YScrollByPixels(TkText *textPtr, int offset); static int SizeOfTab(TkText *textPtr, int tabStyle, TkTextTabArray *tabArrayPtr, int *indexPtr, int x, int maxX); static void TextChanged(TkText *textPtr, CONST TkTextIndex *index1Ptr, CONST TkTextIndex *index2Ptr); static void TextInvalidateRegion(TkText *textPtr, TkRegion region); static void TextRedrawTag(TkText *textPtr, TkTextIndex *index1Ptr, TkTextIndex *index2Ptr, TkTextTag *tagPtr, int withTag); static void TextInvalidateLineMetrics(TkText *textPtr, TkTextLine *linePtr, int lineCount, int action); static int CalculateDisplayLineHeight(TkText *textPtr, CONST TkTextIndex *indexPtr, int *byteCountPtr, int *mergedLinePtr); static void DlineIndexOfX(TkText *textPtr, DLine *dlPtr, int x, TkTextIndex *indexPtr); static int DlineXOfIndex(TkText *textPtr, DLine *dlPtr, int byteIndex); static int TextGetScrollInfoObj(Tcl_Interp *interp, TkText *textPtr, int objc, Tcl_Obj *CONST objv[], double *dblPtr, int *intPtr); static void AsyncUpdateLineMetrics(ClientData clientData); static void AsyncUpdateYScrollbar(ClientData clientData); static int IsStartOfNotMergedLine(TkText *textPtr, CONST TkTextIndex *indexPtr); /* * Result values returned by TextGetScrollInfoObj: */ #define TKTEXT_SCROLL_MOVETO 1 #define TKTEXT_SCROLL_PAGES 2 #define TKTEXT_SCROLL_UNITS 3 #define TKTEXT_SCROLL_ERROR 4 #define TKTEXT_SCROLL_PIXELS 5 /* *---------------------------------------------------------------------- * * TkTextCreateDInfo -- * * This function is called when a new text widget is created. Its job is * to set up display-related information for the widget. * * Results: * None. * * Side effects: * A TextDInfo data structure is allocated and initialized and attached * to textPtr. * *---------------------------------------------------------------------- */ void TkTextCreateDInfo( TkText *textPtr) /* Overall information for text widget. */ { register TextDInfo *dInfoPtr; XGCValues gcValues; dInfoPtr = (TextDInfo *) ckalloc(sizeof(TextDInfo)); Tcl_InitHashTable(&dInfoPtr->styleTable, sizeof(StyleValues)/sizeof(int)); dInfoPtr->dLinePtr = NULL; dInfoPtr->copyGC = None; gcValues.graphics_exposures = True; dInfoPtr->scrollGC = Tk_GetGC(textPtr->tkwin, GCGraphicsExposures, &gcValues); dInfoPtr->topOfEof = 0; dInfoPtr->newXPixelOffset = 0; dInfoPtr->curXPixelOffset = 0; dInfoPtr->maxLength = 0; dInfoPtr->xScrollFirst = -1; dInfoPtr->xScrollLast = -1; dInfoPtr->yScrollFirst = -1; dInfoPtr->yScrollLast = -1; dInfoPtr->scanMarkXPixel = 0; dInfoPtr->scanMarkX = 0; dInfoPtr->scanTotalYScroll = 0; dInfoPtr->scanMarkY = 0; dInfoPtr->dLinesInvalidated = 0; dInfoPtr->flags = DINFO_OUT_OF_DATE; dInfoPtr->topPixelOffset = 0; dInfoPtr->newTopPixelOffset = 0; dInfoPtr->currentMetricUpdateLine = -1; dInfoPtr->lastMetricUpdateLine = -1; dInfoPtr->lineMetricUpdateEpoch = 1; dInfoPtr->metricEpoch = -1; dInfoPtr->metricIndex.textPtr = NULL; dInfoPtr->metricIndex.linePtr = NULL; /* * Add a refCount for each of the idle call-backs. */ textPtr->refCount++; dInfoPtr->lineUpdateTimer = Tcl_CreateTimerHandler(0, AsyncUpdateLineMetrics, (ClientData) textPtr); textPtr->refCount++; dInfoPtr->scrollbarTimer = Tcl_CreateTimerHandler(200, AsyncUpdateYScrollbar, (ClientData) textPtr); textPtr->dInfoPtr = dInfoPtr; } /* *---------------------------------------------------------------------- * * TkTextFreeDInfo -- * * This function is called to free up all of the private display * information kept by this file for a text widget. * * Results: * None. * * Side effects: * Lots of resources get freed. * *---------------------------------------------------------------------- */ void TkTextFreeDInfo( TkText *textPtr) /* Overall information for text widget. */ { register TextDInfo *dInfoPtr = textPtr->dInfoPtr; /* * Be careful to free up styleTable *after* freeing up all the DLines, so * that the hash table is still intact to free up the style-related * information from the lines. Once the lines are all free then styleTable * will be empty. */ FreeDLines(textPtr, dInfoPtr->dLinePtr, NULL, DLINE_UNLINK); Tcl_DeleteHashTable(&dInfoPtr->styleTable); if (dInfoPtr->copyGC != None) { Tk_FreeGC(textPtr->display, dInfoPtr->copyGC); } Tk_FreeGC(textPtr->display, dInfoPtr->scrollGC); if (dInfoPtr->flags & REDRAW_PENDING) { Tcl_CancelIdleCall(DisplayText, (ClientData) textPtr); } if (dInfoPtr->lineUpdateTimer != NULL) { Tcl_DeleteTimerHandler(dInfoPtr->lineUpdateTimer); textPtr->refCount--; dInfoPtr->lineUpdateTimer = NULL; } if (dInfoPtr->scrollbarTimer != NULL) { Tcl_DeleteTimerHandler(dInfoPtr->scrollbarTimer); textPtr->refCount--; dInfoPtr->scrollbarTimer = NULL; } ckfree((char *) dInfoPtr); } /* *---------------------------------------------------------------------- * * GetStyle -- * * This function creates all the information needed to display text at a * particular location. * * Results: * The return value is a pointer to a TextStyle structure that * corresponds to *sValuePtr. * * Side effects: * A new entry may be created in the style table for the widget. * *---------------------------------------------------------------------- */ static TextStyle * GetStyle( TkText *textPtr, /* Overall information about text widget. */ CONST TkTextIndex *indexPtr)/* The character in the text for which display * information is wanted. */ { TkTextTag **tagPtrs; register TkTextTag *tagPtr; StyleValues styleValues; TextStyle *stylePtr; Tcl_HashEntry *hPtr; int numTags, isNew, i; XGCValues gcValues; unsigned long mask; /* * The variables below keep track of the highest-priority specification * that has occurred for each of the various fields of the StyleValues. */ int borderPrio, borderWidthPrio, reliefPrio, bgStipplePrio; int fgPrio, fontPrio, fgStipplePrio; int underlinePrio, elidePrio, justifyPrio, offsetPrio; int lMargin1Prio, lMargin2Prio, rMarginPrio; int spacing1Prio, spacing2Prio, spacing3Prio; int overstrikePrio, tabPrio, tabStylePrio, wrapPrio; /* * Find out what tags are present for the character, then compute a * StyleValues structure corresponding to those tags (scan through all of * the tags, saving information for the highest-priority tag). */ tagPtrs = TkBTreeGetTags(indexPtr, textPtr, &numTags); borderPrio = borderWidthPrio = reliefPrio = bgStipplePrio = -1; fgPrio = fontPrio = fgStipplePrio = -1; underlinePrio = elidePrio = justifyPrio = offsetPrio = -1; lMargin1Prio = lMargin2Prio = rMarginPrio = -1; spacing1Prio = spacing2Prio = spacing3Prio = -1; overstrikePrio = tabPrio = tabStylePrio = wrapPrio = -1; memset(&styleValues, 0, sizeof(StyleValues)); styleValues.relief = TK_RELIEF_FLAT; styleValues.fgColor = textPtr->fgColor; styleValues.tkfont = textPtr->tkfont; styleValues.justify = TK_JUSTIFY_LEFT; styleValues.spacing1 = textPtr->spacing1; styleValues.spacing2 = textPtr->spacing2; styleValues.spacing3 = textPtr->spacing3; styleValues.tabArrayPtr = textPtr->tabArrayPtr; styleValues.tabStyle = textPtr->tabStyle; styleValues.wrapMode = textPtr->wrapMode; styleValues.elide = 0; for (i = 0 ; i < numTags; i++) { Tk_3DBorder border; tagPtr = tagPtrs[i]; border = tagPtr->border; /* * If this is the selection tag, and inactiveSelBorder is NULL (the * default on Windows), then we need to skip it if we don't have the * focus. */ if ((tagPtr == textPtr->selTagPtr) && !(textPtr->flags & GOT_FOCUS)) { if (textPtr->inactiveSelBorder == NULL #ifdef MAC_OSX_TK /* Don't show inactive selection in disabled widgets. */ || textPtr->state == TK_TEXT_STATE_DISABLED #endif ) { continue; } border = textPtr->inactiveSelBorder; } if ((border != NULL) && (tagPtr->priority > borderPrio)) { styleValues.border = border; borderPrio = tagPtr->priority; } if ((tagPtr->borderWidthPtr != NULL) && (Tcl_GetString(tagPtr->borderWidthPtr)[0] != '\0') && (tagPtr->priority > borderWidthPrio)) { styleValues.borderWidth = tagPtr->borderWidth; borderWidthPrio = tagPtr->priority; } if ((tagPtr->reliefString != NULL) && (tagPtr->priority > reliefPrio)) { if (styleValues.border == NULL) { styleValues.border = textPtr->border; } styleValues.relief = tagPtr->relief; reliefPrio = tagPtr->priority; } if ((tagPtr->bgStipple != None) && (tagPtr->priority > bgStipplePrio)) { styleValues.bgStipple = tagPtr->bgStipple; bgStipplePrio = tagPtr->priority; } if ((tagPtr->fgColor != None) && (tagPtr->priority > fgPrio)) { styleValues.fgColor = tagPtr->fgColor; fgPrio = tagPtr->priority; } if ((tagPtr->tkfont != None) && (tagPtr->priority > fontPrio)) { styleValues.tkfont = tagPtr->tkfont; fontPrio = tagPtr->priority; } if ((tagPtr->fgStipple != None) && (tagPtr->priority > fgStipplePrio)) { styleValues.fgStipple = tagPtr->fgStipple; fgStipplePrio = tagPtr->priority; } if ((tagPtr->justifyString != NULL) && (tagPtr->priority > justifyPrio)) { styleValues.justify = tagPtr->justify; justifyPrio = tagPtr->priority; } if ((tagPtr->lMargin1String != NULL) && (tagPtr->priority > lMargin1Prio)) { styleValues.lMargin1 = tagPtr->lMargin1; lMargin1Prio = tagPtr->priority; } if ((tagPtr->lMargin2String != NULL) && (tagPtr->priority > lMargin2Prio)) { styleValues.lMargin2 = tagPtr->lMargin2; lMargin2Prio = tagPtr->priority; } if ((tagPtr->offsetString != NULL) && (tagPtr->priority > offsetPrio)) { styleValues.offset = tagPtr->offset; offsetPrio = tagPtr->priority; } if ((tagPtr->overstrikeString != NULL) && (tagPtr->priority > overstrikePrio)) { styleValues.overstrike = tagPtr->overstrike; overstrikePrio = tagPtr->priority; } if ((tagPtr->rMarginString != NULL) && (tagPtr->priority > rMarginPrio)) { styleValues.rMargin = tagPtr->rMargin; rMarginPrio = tagPtr->priority; } if ((tagPtr->spacing1String != NULL) && (tagPtr->priority > spacing1Prio)) { styleValues.spacing1 = tagPtr->spacing1; spacing1Prio = tagPtr->priority; } if ((tagPtr->spacing2String != NULL) && (tagPtr->priority > spacing2Prio)) { styleValues.spacing2 = tagPtr->spacing2; spacing2Prio = tagPtr->priority; } if ((tagPtr->spacing3String != NULL) && (tagPtr->priority > spacing3Prio)) { styleValues.spacing3 = tagPtr->spacing3; spacing3Prio = tagPtr->priority; } if ((tagPtr->tabStringPtr != NULL) && (tagPtr->priority > tabPrio)) { styleValues.tabArrayPtr = tagPtr->tabArrayPtr; tabPrio = tagPtr->priority; } if ((tagPtr->tabStyle != TK_TEXT_TABSTYLE_NONE) && (tagPtr->priority > tabStylePrio)) { styleValues.tabStyle = tagPtr->tabStyle; tabStylePrio = tagPtr->priority; } if ((tagPtr->underlineString != NULL) && (tagPtr->priority > underlinePrio)) { styleValues.underline = tagPtr->underline; underlinePrio = tagPtr->priority; } if ((tagPtr->elideString != NULL) && (tagPtr->priority > elidePrio)) { styleValues.elide = tagPtr->elide; elidePrio = tagPtr->priority; } if ((tagPtr->wrapMode != TEXT_WRAPMODE_NULL) && (tagPtr->priority > wrapPrio)) { styleValues.wrapMode = tagPtr->wrapMode; wrapPrio = tagPtr->priority; } } if (tagPtrs != NULL) { ckfree((char *) tagPtrs); } /* * Use an existing style if there's one around that matches. */ hPtr = Tcl_CreateHashEntry(&textPtr->dInfoPtr->styleTable, (char *) &styleValues, &isNew); if (!isNew) { stylePtr = (TextStyle *) Tcl_GetHashValue(hPtr); stylePtr->refCount++; return stylePtr; } /* * No existing style matched. Make a new one. */ stylePtr = (TextStyle *) ckalloc(sizeof(TextStyle)); stylePtr->refCount = 1; if (styleValues.border != NULL) { gcValues.foreground = Tk_3DBorderColor(styleValues.border)->pixel; mask = GCForeground; if (styleValues.bgStipple != None) { gcValues.stipple = styleValues.bgStipple; gcValues.fill_style = FillStippled; mask |= GCStipple|GCFillStyle; } stylePtr->bgGC = Tk_GetGC(textPtr->tkwin, mask, &gcValues); } else { stylePtr->bgGC = None; } mask = GCFont; gcValues.font = Tk_FontId(styleValues.tkfont); mask |= GCForeground; gcValues.foreground = styleValues.fgColor->pixel; if (styleValues.fgStipple != None) { gcValues.stipple = styleValues.fgStipple; gcValues.fill_style = FillStippled; mask |= GCStipple|GCFillStyle; } stylePtr->fgGC = Tk_GetGC(textPtr->tkwin, mask, &gcValues); stylePtr->sValuePtr = (StyleValues *) Tcl_GetHashKey(&textPtr->dInfoPtr->styleTable, hPtr); stylePtr->hPtr = hPtr; Tcl_SetHashValue(hPtr, stylePtr); return stylePtr; } /* *---------------------------------------------------------------------- * * FreeStyle -- * * This function is called when a TextStyle structure is no longer * needed. It decrements the reference count and frees up the space for * the style structure if the reference count is 0. * * Results: * None. * * Side effects: * The storage and other resources associated with the style are freed up * if no-one's still using it. * *---------------------------------------------------------------------- */ static void FreeStyle( TkText *textPtr, /* Information about overall widget. */ register TextStyle *stylePtr) /* Information about style to free. */ { stylePtr->refCount--; if (stylePtr->refCount == 0) { if (stylePtr->bgGC != None) { Tk_FreeGC(textPtr->display, stylePtr->bgGC); } if (stylePtr->fgGC != None) { Tk_FreeGC(textPtr->display, stylePtr->fgGC); } Tcl_DeleteHashEntry(stylePtr->hPtr); ckfree((char *) stylePtr); } } /* *---------------------------------------------------------------------- * * LayoutDLine -- * * This function generates a single DLine structure for a display line * whose leftmost character is given by indexPtr. * * Results: * The return value is a pointer to a DLine structure describing the * display line. All fields are filled in and correct except for y and * nextPtr. * * Side effects: * Storage is allocated for the new DLine. * * See the comments in 'GetYView' for some thoughts on what the side- * effects of this call (or its callers) should be; the synchronisation * of TkTextLine->pixelHeight with the sum of the results of this * function operating on all display lines within each logical line. * Ideally the code should be refactored to ensure the cached pixel * height is never behind what is known when this function is called * elsewhere. * * Unfortunately, this function is currently called from many different * places, not just to layout a display line for actual display, but also * simply to calculate some metric or other of one or more display lines * (typically the height). It would be a good idea to do some profiling * of typical text widget usage and the way in which this is called and * see if some optimization could or should be done. * *---------------------------------------------------------------------- */ static DLine * LayoutDLine( TkText *textPtr, /* Overall information about text widget. */ CONST TkTextIndex *indexPtr)/* Beginning of display line. May not * necessarily point to a character * segment. */ { register DLine *dlPtr; /* New display line. */ TkTextSegment *segPtr; /* Current segment in text. */ TkTextDispChunk *lastChunkPtr; /* Last chunk allocated so far for line. */ TkTextDispChunk *chunkPtr; /* Current chunk. */ TkTextIndex curIndex; TkTextDispChunk *breakChunkPtr; /* Chunk containing best word break point, if * any. */ TkTextIndex breakIndex; /* Index of first character in * breakChunkPtr. */ int breakByteOffset; /* Byte offset of character within * breakChunkPtr just to right of best break * point. */ int noCharsYet; /* Non-zero means that no characters have been * placed on the line yet. */ int paragraphStart; /* Non-zero means that we are on the first * line of a paragraph (used to choose between * lmargin1, lmargin2). */ int justify; /* How to justify line: taken from style for * the first character in line. */ int jIndent; /* Additional indentation (beyond margins) due * to justification. */ int rMargin; /* Right margin width for line. */ TkWrapMode wrapMode; /* Wrap mode to use for this line. */ int x = 0, maxX = 0; /* Initializations needed only to stop * compiler warnings. */ int wholeLine; /* Non-zero means this display line runs to * the end of the text line. */ int tabIndex; /* Index of the current tab stop. */ int gotTab; /* Non-zero means the current chunk contains a * tab. */ TkTextDispChunk *tabChunkPtr; /* Pointer to the chunk containing the * previous tab stop. */ int maxBytes; /* Maximum number of bytes to include in this * chunk. */ TkTextTabArray *tabArrayPtr;/* Tab stops for line; taken from style for * the first character on line. */ int tabStyle; /* One of TABULAR or WORDPROCESSOR. */ int tabSize; /* Number of pixels consumed by current tab * stop. */ TkTextDispChunk *lastCharChunkPtr; /* Pointer to last chunk in display lines with * numBytes > 0. Used to drop 0-sized chunks * from the end of the line. */ int byteOffset, ascent, descent, code, elide, elidesize; StyleValues *sValuePtr; TkTextElideInfo info; /* Keep track of elide state. */ /* * Create and initialize a new DLine structure. */ dlPtr = (DLine *) ckalloc(sizeof(DLine)); dlPtr->index = *indexPtr; dlPtr->byteCount = 0; dlPtr->y = 0; dlPtr->oldY = 0; /* Only set to avoid compiler warnings. */ dlPtr->height = 0; dlPtr->baseline = 0; dlPtr->chunkPtr = NULL; dlPtr->nextPtr = NULL; dlPtr->flags = NEW_LAYOUT | OLD_Y_INVALID; dlPtr->logicalLinesMerged = 0; /* * This is not necessarily totally correct, where we have merged logical * lines. Fixing this would require a quite significant overhaul, though, * so currently we make do with this. */ paragraphStart = (indexPtr->byteIndex == 0); /* * Special case entirely elide line as there may be 1000s or more. */ elide = TkTextIsElided(textPtr, indexPtr, &info); if (elide && indexPtr->byteIndex == 0) { maxBytes = 0; for (segPtr = info.segPtr; segPtr != NULL; segPtr = segPtr->nextPtr) { if (segPtr->size > 0) { if (elide == 0) { /* * We toggled a tag and the elide state changed to * visible, and we have something of non-zero size. * Therefore we must bail out. */ break; } maxBytes += segPtr->size; /* * Reset tag elide priority, since we're on a new character. */ } else if ((segPtr->typePtr == &tkTextToggleOffType) || (segPtr->typePtr == &tkTextToggleOnType)) { TkTextTag *tagPtr = segPtr->body.toggle.tagPtr; /* * The elide state only changes if this tag is either the * current highest priority tag (and is therefore being * toggled off), or it's a new tag with higher priority. */ if (tagPtr->elideString != NULL) { info.tagCnts[tagPtr->priority]++; if (info.tagCnts[tagPtr->priority] & 1) { info.tagPtrs[tagPtr->priority] = tagPtr; } if (tagPtr->priority >= info.elidePriority) { if (segPtr->typePtr == &tkTextToggleOffType) { /* * If it is being toggled off, and it has an elide * string, it must actually be the current highest * priority tag, so this check is redundant: */ if (tagPtr->priority != info.elidePriority) { Tcl_Panic("Bad tag priority being toggled off"); } /* * Find previous elide tag, if any (if not then * elide will be zero, of course). */ elide = 0; while (--info.elidePriority > 0) { if (info.tagCnts[info.elidePriority] & 1) { elide = info.tagPtrs[info.elidePriority] ->elide; break; } } } else { elide = tagPtr->elide; info.elidePriority = tagPtr->priority; } } } } } if (elide) { dlPtr->byteCount = maxBytes; dlPtr->spaceAbove = dlPtr->spaceBelow = dlPtr->length = 0; if (dlPtr->index.byteIndex == 0) { /* * Elided state goes from beginning to end of an entire * logical line. This means we can update the line's pixel * height, and bring its pixel calculation up to date. */ TkBTreeLinePixelEpoch(textPtr, dlPtr->index.linePtr) = textPtr->dInfoPtr->lineMetricUpdateEpoch; if (TkBTreeLinePixelCount(textPtr,dlPtr->index.linePtr) != 0) { TkBTreeAdjustPixelHeight(textPtr, dlPtr->index.linePtr, 0, 0); } } TkTextFreeElideInfo(&info); return dlPtr; } } TkTextFreeElideInfo(&info); /* * Each iteration of the loop below creates one TkTextDispChunk for the * new display line. The line will always have at least one chunk (for the * newline character at the end, if there's nothing else available). */ curIndex = *indexPtr; lastChunkPtr = NULL; chunkPtr = NULL; noCharsYet = 1; elide = 0; breakChunkPtr = NULL; breakByteOffset = 0; justify = TK_JUSTIFY_LEFT; tabIndex = -1; tabChunkPtr = NULL; tabArrayPtr = NULL; tabStyle = TK_TEXT_TABSTYLE_TABULAR; rMargin = 0; wrapMode = TEXT_WRAPMODE_CHAR; tabSize = 0; lastCharChunkPtr = NULL; /* * Find the first segment to consider for the line. Can't call * TkTextIndexToSeg for this because it won't return a segment with zero * size (such as the insertion cursor's mark). */ connectNextLogicalLine: byteOffset = curIndex.byteIndex; segPtr = curIndex.linePtr->segPtr; while ((byteOffset > 0) && (byteOffset >= segPtr->size)) { byteOffset -= segPtr->size; segPtr = segPtr->nextPtr; if (segPtr == NULL) { /* * Two logical lines merged into one display line through eliding * of a newline. */ TkTextLine *linePtr = TkBTreeNextLine(NULL, curIndex.linePtr); if (linePtr != NULL) { dlPtr->logicalLinesMerged++; curIndex.byteIndex = 0; curIndex.linePtr = linePtr; segPtr = curIndex.linePtr->segPtr; } else { break; } } } while (segPtr != NULL) { /* * Every logical line still gets at least one chunk due to * expectations in the rest of the code, but we are able to skip * elided portions of the line quickly. * * If current chunk is elided and last chunk was too, coalese. * * This also means that each logical line which is entirely elided * still gets laid out into a DLine, but with zero height. This isn't * particularly a problem, but it does seem somewhat unnecessary. We * may wish to redesign the code to remove these zero height DLines in * the future. */ if (elide && (lastChunkPtr != NULL) && (lastChunkPtr->displayProc == NULL /*ElideDisplayProc*/)) { elidesize = segPtr->size - byteOffset; if (elidesize > 0) { curIndex.byteIndex += elidesize; lastChunkPtr->numBytes += elidesize; breakByteOffset = lastChunkPtr->breakIndex = lastChunkPtr->numBytes; /* * If have we have a tag toggle, there is a chance that * invisibility state changed, so bail out. */ } else if ((segPtr->typePtr == &tkTextToggleOffType) || (segPtr->typePtr == &tkTextToggleOnType)) { if (segPtr->body.toggle.tagPtr->elideString != NULL) { elide = (segPtr->typePtr == &tkTextToggleOffType) ^ segPtr->body.toggle.tagPtr->elide; } } byteOffset = 0; segPtr = segPtr->nextPtr; if (segPtr == NULL) { /* * Two logical lines merged into one display line through * eliding of a newline. */ TkTextLine *linePtr = TkBTreeNextLine(NULL, curIndex.linePtr); if (linePtr != NULL) { dlPtr->logicalLinesMerged++; curIndex.byteIndex = 0; curIndex.linePtr = linePtr; goto connectNextLogicalLine; } } /* * Code no longer needed, now that we allow logical lines to merge * into a single display line. * if (segPtr == NULL && chunkPtr != NULL) { ckfree((char *) chunkPtr); chunkPtr = NULL; } */ continue; } if (segPtr->typePtr->layoutProc == NULL) { segPtr = segPtr->nextPtr; byteOffset = 0; continue; } if (chunkPtr == NULL) { chunkPtr = (TkTextDispChunk *) ckalloc(sizeof(TkTextDispChunk)); chunkPtr->nextPtr = NULL; chunkPtr->clientData = NULL; } chunkPtr->stylePtr = GetStyle(textPtr, &curIndex); elide = chunkPtr->stylePtr->sValuePtr->elide; /* * Save style information such as justification and indentation, up * until the first character is encountered, then retain that * information for the rest of the line. */ if (!elide && noCharsYet) { tabArrayPtr = chunkPtr->stylePtr->sValuePtr->tabArrayPtr; tabStyle = chunkPtr->stylePtr->sValuePtr->tabStyle; justify = chunkPtr->stylePtr->sValuePtr->justify; rMargin = chunkPtr->stylePtr->sValuePtr->rMargin; wrapMode = chunkPtr->stylePtr->sValuePtr->wrapMode; /* * See above - this test may not be entirely correct where we have * partially elided lines (and therefore merged logical lines). * In such a case a byteIndex of zero doesn't necessarily mean the * beginning of a logical line. */ if (paragraphStart) { /* * Beginning of logical line. */ x = chunkPtr->stylePtr->sValuePtr->lMargin1; } else { /* * Beginning of display line. */ x = chunkPtr->stylePtr->sValuePtr->lMargin2; } if (wrapMode == TEXT_WRAPMODE_NONE) { maxX = -1; } else { maxX = textPtr->dInfoPtr->maxX - textPtr->dInfoPtr->x - rMargin; if (maxX < x) { maxX = x; } } } gotTab = 0; maxBytes = segPtr->size - byteOffset; if (segPtr->typePtr == &tkTextCharType) { /* * See if there is a tab in the current chunk; if so, only layout * characters up to (and including) the tab. */ if (!elide && justify == TK_JUSTIFY_LEFT) { char *p; for (p = segPtr->body.chars + byteOffset; *p != 0; p++) { if (*p == '\t') { maxBytes = (p + 1 - segPtr->body.chars) - byteOffset; gotTab = 1; break; } } } #if TK_LAYOUT_WITH_BASE_CHUNKS if (baseCharChunkPtr != NULL) { int expectedX = ((BaseCharInfo *) baseCharChunkPtr->clientData)->width + baseCharChunkPtr->x; if ((expectedX != x) || !IsSameFGStyle( baseCharChunkPtr->stylePtr, chunkPtr->stylePtr)) { FinalizeBaseChunk(NULL); } } #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ } chunkPtr->x = x; if (elide /*&& maxBytes*/) { /* * Don't free style here, as other code expects to be able to do * that. */ /* breakByteOffset =*/ chunkPtr->breakIndex = chunkPtr->numBytes = maxBytes; chunkPtr->width = 0; chunkPtr->minAscent = chunkPtr->minDescent = chunkPtr->minHeight = 0; /* * Would just like to point to canonical empty chunk. */ chunkPtr->displayProc = NULL; chunkPtr->undisplayProc = NULL; chunkPtr->measureProc = ElideMeasureProc; chunkPtr->bboxProc = ElideBboxProc; code = 1; } else { code = (*segPtr->typePtr->layoutProc)(textPtr, &curIndex, segPtr, byteOffset, maxX-tabSize, maxBytes, noCharsYet, wrapMode, chunkPtr); } if (code <= 0) { FreeStyle(textPtr, chunkPtr->stylePtr); if (code < 0) { /* * This segment doesn't wish to display itself (e.g. most * marks). */ segPtr = segPtr->nextPtr; byteOffset = 0; continue; } /* * No characters from this segment fit in the window: this means * we're at the end of the display line. */ if (chunkPtr != NULL) { ckfree((char *) chunkPtr); } break; } /* * We currently say we have some characters (and therefore something * from which to examine tag values for the first character of the * line) even if those characters are actually elided. This behaviour * is not well documented, and it might be more consistent to * completely ignore such elided characters and their tags. To do so * change this to: * * if (!elide && chunkPtr->numBytes > 0). */ if (!elide && chunkPtr->numBytes > 0) { noCharsYet = 0; lastCharChunkPtr = chunkPtr; } if (lastChunkPtr == NULL) { dlPtr->chunkPtr = chunkPtr; } else { lastChunkPtr->nextPtr = chunkPtr; } lastChunkPtr = chunkPtr; x += chunkPtr->width; if (chunkPtr->breakIndex > 0) { breakByteOffset = chunkPtr->breakIndex; breakIndex = curIndex; breakChunkPtr = chunkPtr; } if (chunkPtr->numBytes != maxBytes) { break; } /* * If we're at a new tab, adjust the layout for all the chunks * pertaining to the previous tab. Also adjust the amount of space * left in the line to account for space that will be eaten up by the * tab. */ if (gotTab) { if (tabIndex >= 0) { AdjustForTab(textPtr, tabArrayPtr, tabIndex, tabChunkPtr); x = chunkPtr->x + chunkPtr->width; } tabChunkPtr = chunkPtr; tabSize = SizeOfTab(textPtr, tabStyle, tabArrayPtr, &tabIndex, x, maxX); if ((maxX >= 0) && (tabSize >= maxX - x)) { break; } } curIndex.byteIndex += chunkPtr->numBytes; byteOffset += chunkPtr->numBytes; if (byteOffset >= segPtr->size) { byteOffset = 0; segPtr = segPtr->nextPtr; if (elide && segPtr == NULL) { /* * An elided section started on this line, and carries on * until the newline. Hence the newline is actually elided, * and we want to merge the display of the next logical line * with this one. */ TkTextLine *linePtr = TkBTreeNextLine(NULL, curIndex.linePtr); if (linePtr != NULL) { dlPtr->logicalLinesMerged++; curIndex.byteIndex = 0; curIndex.linePtr = linePtr; chunkPtr = NULL; goto connectNextLogicalLine; } } } chunkPtr = NULL; } #if TK_LAYOUT_WITH_BASE_CHUNKS FinalizeBaseChunk(NULL); #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ if (noCharsYet) { dlPtr->spaceAbove = 0; dlPtr->spaceBelow = 0; dlPtr->length = 0; /* * We used to Tcl_Panic here, saying that LayoutDLine couldn't place * any characters on a line, but I believe a more appropriate response * is to return a DLine with zero height. With elided lines, tag * transitions and asynchronous line height calculations, it is hard * to avoid this situation ever arising with the current code design. */ return dlPtr; } wholeLine = (segPtr == NULL); /* * We're at the end of the display line. Throw away everything after the * most recent word break, if there is one; this may potentially require * the last chunk to be layed out again. */ if (breakChunkPtr == NULL) { /* * This code makes sure that we don't accidentally display chunks with * no characters at the end of the line (such as the insertion * cursor). These chunks belong on the next line. So, throw away * everything after the last chunk that has characters in it. */ breakChunkPtr = lastCharChunkPtr; breakByteOffset = breakChunkPtr->numBytes; } if ((breakChunkPtr != NULL) && ((lastChunkPtr != breakChunkPtr) || (breakByteOffset != lastChunkPtr->numBytes))) { while (1) { chunkPtr = breakChunkPtr->nextPtr; if (chunkPtr == NULL) { break; } FreeStyle(textPtr, chunkPtr->stylePtr); breakChunkPtr->nextPtr = chunkPtr->nextPtr; if (chunkPtr->undisplayProc != NULL) { (*chunkPtr->undisplayProc)(textPtr, chunkPtr); } ckfree((char *) chunkPtr); } if (breakByteOffset != breakChunkPtr->numBytes) { if (breakChunkPtr->undisplayProc != NULL) { (*breakChunkPtr->undisplayProc)(textPtr, breakChunkPtr); } segPtr = TkTextIndexToSeg(&breakIndex, &byteOffset); (*segPtr->typePtr->layoutProc)(textPtr, &breakIndex, segPtr, byteOffset, maxX, breakByteOffset, 0, wrapMode, breakChunkPtr); #if TK_LAYOUT_WITH_BASE_CHUNKS FinalizeBaseChunk(NULL); #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ } lastChunkPtr = breakChunkPtr; wholeLine = 0; } /* * Make tab adjustments for the last tab stop, if there is one. */ if ((tabIndex >= 0) && (tabChunkPtr != NULL)) { AdjustForTab(textPtr, tabArrayPtr, tabIndex, tabChunkPtr); } /* * Make one more pass over the line to recompute various things like its * height, length, and total number of bytes. Also modify the x-locations * of chunks to reflect justification. If we're not wrapping, I'm not sure * what is the best way to handle left and center justification: should * the total length, for purposes of justification, be (a) the window * width, (b) the length of the longest line in the window, or (c) the * length of the longest line in the text? (c) isn't available, (b) seems * weird, since it can change with vertical scrolling, so (a) is what is * implemented below. */ if (wrapMode == TEXT_WRAPMODE_NONE) { maxX = textPtr->dInfoPtr->maxX - textPtr->dInfoPtr->x - rMargin; } dlPtr->length = lastChunkPtr->x + lastChunkPtr->width; if (justify == TK_JUSTIFY_LEFT) { jIndent = 0; } else if (justify == TK_JUSTIFY_RIGHT) { jIndent = maxX - dlPtr->length; } else { jIndent = (maxX - dlPtr->length)/2; } ascent = descent = 0; for (chunkPtr = dlPtr->chunkPtr; chunkPtr != NULL; chunkPtr = chunkPtr->nextPtr) { chunkPtr->x += jIndent; dlPtr->byteCount += chunkPtr->numBytes; if (chunkPtr->minAscent > ascent) { ascent = chunkPtr->minAscent; } if (chunkPtr->minDescent > descent) { descent = chunkPtr->minDescent; } if (chunkPtr->minHeight > dlPtr->height) { dlPtr->height = chunkPtr->minHeight; } sValuePtr = chunkPtr->stylePtr->sValuePtr; if ((sValuePtr->borderWidth > 0) && (sValuePtr->relief != TK_RELIEF_FLAT)) { dlPtr->flags |= HAS_3D_BORDER; } } if (dlPtr->height < (ascent + descent)) { dlPtr->height = ascent + descent; dlPtr->baseline = ascent; } else { dlPtr->baseline = ascent + (dlPtr->height - ascent - descent)/2; } sValuePtr = dlPtr->chunkPtr->stylePtr->sValuePtr; if (dlPtr->index.byteIndex == 0) { dlPtr->spaceAbove = sValuePtr->spacing1; } else { dlPtr->spaceAbove = sValuePtr->spacing2 - sValuePtr->spacing2/2; } if (wholeLine) { dlPtr->spaceBelow = sValuePtr->spacing3; } else { dlPtr->spaceBelow = sValuePtr->spacing2/2; } dlPtr->height += dlPtr->spaceAbove + dlPtr->spaceBelow; dlPtr->baseline += dlPtr->spaceAbove; /* * Recompute line length: may have changed because of justification. */ dlPtr->length = lastChunkPtr->x + lastChunkPtr->width; return dlPtr; } /* *---------------------------------------------------------------------- * * UpdateDisplayInfo -- * * This function is invoked to recompute some or all of the DLine * structures for a text widget. At the time it is called the DLine * structures still left in the widget are guaranteed to be correct * except that (a) the y-coordinates aren't necessarily correct, (b) * there may be missing structures (the DLine structures get removed as * soon as they are potentially out-of-date), and (c) DLine structures * that don't start at the beginning of a line may be incorrect if * previous information in the same line changed size in a way that moved * a line boundary (DLines for any info that changed will have been * deleted, but not DLines for unchanged info in the same text line). * * Results: * None. * * Side effects: * Upon return, the DLine information for textPtr correctly reflects the * positions where characters will be displayed. However, this function * doesn't actually bring the display up-to-date. * *---------------------------------------------------------------------- */ static void UpdateDisplayInfo( TkText *textPtr) /* Text widget to update. */ { register TextDInfo *dInfoPtr = textPtr->dInfoPtr; register DLine *dlPtr, *prevPtr; TkTextIndex index; TkTextLine *lastLinePtr; int y, maxY, xPixelOffset, maxOffset, lineHeight; if (!(dInfoPtr->flags & DINFO_OUT_OF_DATE)) { return; } dInfoPtr->flags &= ~DINFO_OUT_OF_DATE; /* * Delete any DLines that are now above the top of the window. */ index = textPtr->topIndex; dlPtr = FindDLine(textPtr, dInfoPtr->dLinePtr, &index); if ((dlPtr != NULL) && (dlPtr != dInfoPtr->dLinePtr)) { FreeDLines(textPtr, dInfoPtr->dLinePtr, dlPtr, DLINE_UNLINK); } if (index.byteIndex == 0) { lineHeight = 0; } else { lineHeight = -1; } /* * Scan through the contents of the window from top to bottom, recomputing * information for lines that are missing. */ lastLinePtr = TkBTreeFindLine(textPtr->sharedTextPtr->tree, textPtr, TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr)); dlPtr = dInfoPtr->dLinePtr; prevPtr = NULL; y = dInfoPtr->y - dInfoPtr->newTopPixelOffset; maxY = dInfoPtr->maxY; while (1) { register DLine *newPtr; if (index.linePtr == lastLinePtr) { break; } /* * There are three possibilities right now: * (a) the next DLine (dlPtr) corresponds exactly to the next * information we want to display: just use it as-is. * (b) the next DLine corresponds to a different line, or to a segment * that will be coming later in the same line: leave this DLine * alone in the hopes that we'll be able to use it later, then * create a new DLine in front of it. * (c) the next DLine corresponds to a segment in the line we want, * but it's a segment that has already been processed or will * never be processed. Delete the DLine and try again. * * One other twist on all this. It's possible for 3D borders to * interact between lines (see DisplayLineBackground) so if a line is * relayed out and has styles with 3D borders, its neighbors have to * be redrawn if they have 3D borders too, since the interactions * could have changed (the neighbors don't have to be relayed out, * just redrawn). */ if ((dlPtr == NULL) || (dlPtr->index.linePtr != index.linePtr)) { /* * Case (b) -- must make new DLine. */ makeNewDLine: if (tkTextDebug) { char string[TK_POS_CHARS]; /* * Debugging is enabled, so keep a log of all the lines that * were re-layed out. The test suite uses this information. */ TkTextPrintIndex(textPtr, &index, string); LOG("tk_textRelayout", string); } newPtr = LayoutDLine(textPtr, &index); if (prevPtr == NULL) { dInfoPtr->dLinePtr = newPtr; } else { prevPtr->nextPtr = newPtr; if (prevPtr->flags & HAS_3D_BORDER) { prevPtr->flags |= OLD_Y_INVALID; } } newPtr->nextPtr = dlPtr; dlPtr = newPtr; } else { /* * DlPtr refers to the line we want. Next check the index within * the line. */ if (index.byteIndex == dlPtr->index.byteIndex) { /* * Case (a) - can use existing display line as-is. */ if ((dlPtr->flags & HAS_3D_BORDER) && (prevPtr != NULL) && (prevPtr->flags & (NEW_LAYOUT))) { dlPtr->flags |= OLD_Y_INVALID; } goto lineOK; } if (index.byteIndex < dlPtr->index.byteIndex) { goto makeNewDLine; } /* * Case (c) - dlPtr is useless. Discard it and start again with * the next display line. */ newPtr = dlPtr->nextPtr; FreeDLines(textPtr, dlPtr, newPtr, DLINE_FREE); dlPtr = newPtr; if (prevPtr != NULL) { prevPtr->nextPtr = newPtr; } else { dInfoPtr->dLinePtr = newPtr; } continue; } /* * Advance to the start of the next line. */ lineOK: dlPtr->y = y; y += dlPtr->height; if (lineHeight != -1) { lineHeight += dlPtr->height; } TkTextIndexForwBytes(textPtr, &index, dlPtr->byteCount, &index); prevPtr = dlPtr; dlPtr = dlPtr->nextPtr; /* * If we switched text lines, delete any DLines left for the old text * line. */ if (index.linePtr != prevPtr->index.linePtr) { register DLine *nextPtr; nextPtr = dlPtr; while ((nextPtr != NULL) && (nextPtr->index.linePtr == prevPtr->index.linePtr)) { nextPtr = nextPtr->nextPtr; } if (nextPtr != dlPtr) { FreeDLines(textPtr, dlPtr, nextPtr, DLINE_FREE); prevPtr->nextPtr = nextPtr; dlPtr = nextPtr; } if ((lineHeight != -1) && (TkBTreeLinePixelCount(textPtr, prevPtr->index.linePtr) != lineHeight)) { /* * The logical line height we just calculated is actually * different to the currently cached height of the text line. * That is fine (the text line heights are only calculated * asynchronously), but we must update the cached height so * that any counts made with DLine pointers are the same as * counts made through the BTree. This helps to ensure that * the scrollbar size corresponds accurately to that displayed * contents, even as the window is re-sized. */ TkBTreeAdjustPixelHeight(textPtr, prevPtr->index.linePtr, lineHeight, 0); /* * I believe we can be 100% sure that we started at the * beginning of the logical line, so we can also adjust the * 'pixelCalculationEpoch' to mark it as being up to date. * There is a slight concern that we might not have got this * right for the first line in the re-display. */ TkBTreeLinePixelEpoch(textPtr, prevPtr->index.linePtr) = dInfoPtr->lineMetricUpdateEpoch; } lineHeight = 0; } /* * It's important to have the following check here rather than in the * while statement for the loop, so that there's always at least one * DLine generated, regardless of how small the window is. This keeps * a lot of other code from breaking. */ if (y >= maxY) { break; } } /* * Delete any DLine structures that don't fit on the screen. */ FreeDLines(textPtr, dlPtr, NULL, DLINE_UNLINK); /* * If there is extra space at the bottom of the window (because we've hit * the end of the text), then bring in more lines at the top of the * window, if there are any, to fill in the view. * * Since the top line may only be partially visible, we try first to * simply show more pixels from that line (newTopPixelOffset). If that * isn't enough, we have to layout more lines. */ if (y < maxY) { /* * This counts how many vertical pixels we have left to fill by * pulling in more display pixels either from the first currently * displayed, or the lines above it. */ int spaceLeft = maxY - y; if (spaceLeft <= dInfoPtr->newTopPixelOffset) { /* * We can fill up all the needed space just by showing more of the * current top line. */ dInfoPtr->newTopPixelOffset -= spaceLeft; y += spaceLeft; spaceLeft = 0; } else { int lineNum, bytesToCount; DLine *lowestPtr; /* * Add in all of the current top line, which won't be enough to * bring y up to maxY (if it was we would be in the 'if' block * above). */ y += dInfoPtr->newTopPixelOffset; dInfoPtr->newTopPixelOffset = 0; /* * Layout an entire text line (potentially > 1 display line), then * link in as many display lines as fit without moving the bottom * line out of the window. Repeat this until all the extra space * has been used up or we've reached the beginning of the text. */ spaceLeft = maxY - y; if (dInfoPtr->dLinePtr == NULL) { /* * No lines have been laid out. This must be an empty peer * widget. */ lineNum = TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr) - 1; bytesToCount = INT_MAX; } else { lineNum = TkBTreeLinesTo(textPtr, dInfoPtr->dLinePtr->index.linePtr); bytesToCount = dInfoPtr->dLinePtr->index.byteIndex; if (bytesToCount == 0) { bytesToCount = INT_MAX; lineNum--; } } for ( ; (lineNum >= 0) && (spaceLeft > 0); lineNum--) { int pixelHeight = 0; index.linePtr = TkBTreeFindLine(textPtr->sharedTextPtr->tree, textPtr, lineNum); index.byteIndex = 0; lowestPtr = NULL; do { dlPtr = LayoutDLine(textPtr, &index); pixelHeight += dlPtr->height; dlPtr->nextPtr = lowestPtr; lowestPtr = dlPtr; if (dlPtr->length == 0 && dlPtr->height == 0) { bytesToCount--; break; } /* elide */ TkTextIndexForwBytes(textPtr, &index, dlPtr->byteCount, &index); bytesToCount -= dlPtr->byteCount; } while ((bytesToCount > 0) && (index.linePtr == lowestPtr->index.linePtr)); /* * We may not have examined the entire line (depending on the * value of 'bytesToCount', so we only want to set this if it * is genuinely bigger). */ if (pixelHeight > TkBTreeLinePixelCount(textPtr, lowestPtr->index.linePtr)) { TkBTreeAdjustPixelHeight(textPtr, lowestPtr->index.linePtr, pixelHeight, 0); if (index.linePtr != lowestPtr->index.linePtr) { /* * We examined the entire line, so can update the * epoch. */ TkBTreeLinePixelEpoch(textPtr, lowestPtr->index.linePtr) = dInfoPtr->lineMetricUpdateEpoch; } } /* * Scan through the display lines from the bottom one up to * the top one. */ while (lowestPtr != NULL) { dlPtr = lowestPtr; spaceLeft -= dlPtr->height; lowestPtr = dlPtr->nextPtr; dlPtr->nextPtr = dInfoPtr->dLinePtr; dInfoPtr->dLinePtr = dlPtr; if (tkTextDebug) { char string[TK_POS_CHARS]; TkTextPrintIndex(textPtr, &dlPtr->index, string); LOG("tk_textRelayout", string); } if (spaceLeft <= 0) { break; } } FreeDLines(textPtr, lowestPtr, NULL, DLINE_FREE); bytesToCount = INT_MAX; } /* * We've either filled in the space we wanted to or we've run out * of display lines at the top of the text. Note that we already * set dInfoPtr->newTopPixelOffset to zero above. */ if (spaceLeft < 0) { /* * We've laid out a few too many vertical pixels at or above * the first line. Therefore we only want to show part of the * first displayed line, so that the last displayed line just * fits in the window. */ dInfoPtr->newTopPixelOffset = -spaceLeft; if (dInfoPtr->newTopPixelOffset>=dInfoPtr->dLinePtr->height) { /* * Somehow the entire first line we laid out is shorter * than the new offset. This should not occur and would * indicate a bad problem in the logic above. */ Tcl_Panic("Error in pixel height consistency while filling in spacesLeft"); } } } /* * Now we're all done except that the y-coordinates in all the DLines * are wrong and the top index for the text is wrong. Update them. */ if (dInfoPtr->dLinePtr != NULL) { textPtr->topIndex = dInfoPtr->dLinePtr->index; y = dInfoPtr->y - dInfoPtr->newTopPixelOffset; for (dlPtr = dInfoPtr->dLinePtr; dlPtr != NULL; dlPtr = dlPtr->nextPtr) { if (y > dInfoPtr->maxY) { Tcl_Panic("Added too many new lines in UpdateDisplayInfo"); } dlPtr->y = y; y += dlPtr->height; } } } /* * If the old top or bottom line has scrolled elsewhere on the screen, we * may not be able to re-use its old contents by copying bits (e.g., a * beveled edge that was drawn when it was at the top or bottom won't be * drawn when the line is in the middle and its neighbor has a matching * background). Similarly, if the new top or bottom line came from * somewhere else on the screen, we may not be able to copy the old bits. */ dlPtr = dInfoPtr->dLinePtr; if (dlPtr != NULL) { if ((dlPtr->flags & HAS_3D_BORDER) && !(dlPtr->flags & TOP_LINE)) { dlPtr->flags |= OLD_Y_INVALID; } while (1) { if ((dlPtr->flags & TOP_LINE) && (dlPtr != dInfoPtr->dLinePtr) && (dlPtr->flags & HAS_3D_BORDER)) { dlPtr->flags |= OLD_Y_INVALID; } /* * If the old top-line was not completely showing (i.e. the * pixelOffset is non-zero) and is no longer the top-line, then we * must re-draw it. */ if ((dlPtr->flags & TOP_LINE) && dInfoPtr->topPixelOffset!=0 && dlPtr!=dInfoPtr->dLinePtr) { dlPtr->flags |= OLD_Y_INVALID; } if ((dlPtr->flags & BOTTOM_LINE) && (dlPtr->nextPtr != NULL) && (dlPtr->flags & HAS_3D_BORDER)) { dlPtr->flags |= OLD_Y_INVALID; } if (dlPtr->nextPtr == NULL) { if ((dlPtr->flags & HAS_3D_BORDER) && !(dlPtr->flags & BOTTOM_LINE)) { dlPtr->flags |= OLD_Y_INVALID; } dlPtr->flags &= ~TOP_LINE; dlPtr->flags |= BOTTOM_LINE; break; } dlPtr->flags &= ~(TOP_LINE|BOTTOM_LINE); dlPtr = dlPtr->nextPtr; } dInfoPtr->dLinePtr->flags |= TOP_LINE; dInfoPtr->topPixelOffset = dInfoPtr->newTopPixelOffset; } /* * Arrange for scrollbars to be updated. */ textPtr->flags |= UPDATE_SCROLLBARS; /* * Deal with horizontal scrolling: * 1. If there's empty space to the right of the longest line, shift the * screen to the right to fill in the empty space. * 2. If the desired horizontal scroll position has changed, force a full * redisplay of all the lines in the widget. * 3. If the wrap mode isn't "none" then re-scroll to the base position. */ dInfoPtr->maxLength = 0; for (dlPtr = dInfoPtr->dLinePtr; dlPtr != NULL; dlPtr = dlPtr->nextPtr) { if (dlPtr->length > dInfoPtr->maxLength) { dInfoPtr->maxLength = dlPtr->length; } } maxOffset = dInfoPtr->maxLength - (dInfoPtr->maxX - dInfoPtr->x); xPixelOffset = dInfoPtr->newXPixelOffset; if (xPixelOffset > maxOffset) { xPixelOffset = maxOffset; } if (xPixelOffset < 0) { xPixelOffset = 0; } /* * Here's a problem: see the tests textDisp-29.2.1-4 * * If the widget is being created, but has not yet been configured it will * have a maxY of 1 above, and we we won't have examined all the lines * (just the first line, in fact), and so maxOffset will not be a true * reflection of the widget's lines. Therefore we must not overwrite the * original newXPixelOffset in this case. */ if (!(((Tk_FakeWin *) (textPtr->tkwin))->flags & TK_NEED_CONFIG_NOTIFY)) { dInfoPtr->newXPixelOffset = xPixelOffset; } if (xPixelOffset != dInfoPtr->curXPixelOffset) { dInfoPtr->curXPixelOffset = xPixelOffset; for (dlPtr = dInfoPtr->dLinePtr; dlPtr != NULL; dlPtr = dlPtr->nextPtr) { dlPtr->flags |= OLD_Y_INVALID; } } } /* *---------------------------------------------------------------------- * * FreeDLines -- * * This function is called to free up all of the resources associated * with one or more DLine structures. * * Results: * None. * * Side effects: * Memory gets freed and various other resources are released. * *---------------------------------------------------------------------- */ static void FreeDLines( TkText *textPtr, /* Information about overall text widget. */ register DLine *firstPtr, /* Pointer to first DLine to free up. */ DLine *lastPtr, /* Pointer to DLine just after last one to * free (NULL means everything starting with * firstPtr). */ int action) /* DLINE_UNLINK means DLines are currently * linked into the list rooted at * textPtr->dInfoPtr->dLinePtr and they have * to be unlinked. DLINE_FREE means just free * without unlinking. DLINE_FREE_TEMP means * the DLine given is just a temporary one and * we shouldn't invalidate anything for the * overall widget. */ { register TkTextDispChunk *chunkPtr, *nextChunkPtr; register DLine *nextDLinePtr; if (action == DLINE_FREE_TEMP) { lineHeightsRecalculated++; if (tkTextDebug) { char string[TK_POS_CHARS]; /* * Debugging is enabled, so keep a log of all the lines whose * height was recalculated. The test suite uses this information. */ TkTextPrintIndex(textPtr, &firstPtr->index, string); LOG("tk_textHeightCalc", string); } } else if (action == DLINE_UNLINK) { if (textPtr->dInfoPtr->dLinePtr == firstPtr) { textPtr->dInfoPtr->dLinePtr = lastPtr; } else { register DLine *prevPtr; for (prevPtr = textPtr->dInfoPtr->dLinePtr; prevPtr->nextPtr != firstPtr; prevPtr = prevPtr->nextPtr) { /* Empty loop body. */ } prevPtr->nextPtr = lastPtr; } } while (firstPtr != lastPtr) { nextDLinePtr = firstPtr->nextPtr; for (chunkPtr = firstPtr->chunkPtr; chunkPtr != NULL; chunkPtr = nextChunkPtr) { if (chunkPtr->undisplayProc != NULL) { (*chunkPtr->undisplayProc)(textPtr, chunkPtr); } FreeStyle(textPtr, chunkPtr->stylePtr); nextChunkPtr = chunkPtr->nextPtr; ckfree((char *) chunkPtr); } ckfree((char *) firstPtr); firstPtr = nextDLinePtr; } if (action != DLINE_FREE_TEMP) { textPtr->dInfoPtr->dLinesInvalidated = 1; } } /* *---------------------------------------------------------------------- * * DisplayDLine -- * * This function is invoked to draw a single line on the screen. * * Results: * None. * * Side effects: * The line given by dlPtr is drawn at its correct position in textPtr's * window. Note that this is one *display* line, not one *text* line. * *---------------------------------------------------------------------- */ static void DisplayDLine( TkText *textPtr, /* Text widget in which to draw line. */ register DLine *dlPtr, /* Information about line to draw. */ DLine *prevPtr, /* Line just before one to draw, or NULL if * dlPtr is the top line. */ Pixmap pixmap) /* Pixmap to use for double-buffering. Caller * must make sure it's large enough to hold * line. */ { register TkTextDispChunk *chunkPtr; TextDInfo *dInfoPtr = textPtr->dInfoPtr; Display *display; int height, y_off; #ifndef TK_NO_DOUBLE_BUFFERING const int y = 0; #else const int y = dlPtr->y; #endif /* TK_NO_DOUBLE_BUFFERING */ if (dlPtr->chunkPtr == NULL) return; display = Tk_Display(textPtr->tkwin); height = dlPtr->height; if ((height + dlPtr->y) > dInfoPtr->maxY) { height = dInfoPtr->maxY - dlPtr->y; } if (dlPtr->y < dInfoPtr->y) { y_off = dInfoPtr->y - dlPtr->y; height -= y_off; } else { y_off = 0; } #ifdef TK_NO_DOUBLE_BUFFERING TkpClipDrawableToRect(display, pixmap, dInfoPtr->x, y + y_off, dInfoPtr->maxX - dInfoPtr->x, height); #endif /* TK_NO_DOUBLE_BUFFERING */ /* * First, clear the area of the line to the background color for the text * widget. */ Tk_Fill3DRectangle(textPtr->tkwin, pixmap, textPtr->border, 0, y, Tk_Width(textPtr->tkwin), dlPtr->height, 0, TK_RELIEF_FLAT); /* * Next, draw background information for the whole line. */ DisplayLineBackground(textPtr, dlPtr, prevPtr, pixmap); /* * Make another pass through all of the chunks to redraw the insertion * cursor, if it is visible on this line. Must do it here rather than in * the foreground pass below because otherwise a wide insertion cursor * will obscure the character to its left. */ if (textPtr->state == TK_TEXT_STATE_NORMAL) { for (chunkPtr = dlPtr->chunkPtr; (chunkPtr != NULL); chunkPtr = chunkPtr->nextPtr) { if (chunkPtr->displayProc == TkTextInsertDisplayProc) { int x = chunkPtr->x + dInfoPtr->x - dInfoPtr->curXPixelOffset; (*chunkPtr->displayProc)(textPtr, chunkPtr, x, y + dlPtr->spaceAbove, dlPtr->height - dlPtr->spaceAbove - dlPtr->spaceBelow, dlPtr->baseline - dlPtr->spaceAbove, display, pixmap, dlPtr->y + dlPtr->spaceAbove); } } } /* * Make yet another pass through all of the chunks to redraw all of * foreground information. Note: we have to call the displayProc even for * chunks that are off-screen. This is needed, for example, so that * embedded windows can be unmapped in this case. */ for (chunkPtr = dlPtr->chunkPtr; (chunkPtr != NULL); chunkPtr = chunkPtr->nextPtr) { if (chunkPtr->displayProc == TkTextInsertDisplayProc) { /* * Already displayed the insertion cursor above. Don't do it again * here. */ continue; } /* * Don't call if elide. This tax OK since not very many visible DLines * in an area, but potentially many elide ones. */ if (chunkPtr->displayProc != NULL) { int x = chunkPtr->x + dInfoPtr->x - dInfoPtr->curXPixelOffset; if ((x + chunkPtr->width <= 0) || (x >= dInfoPtr->maxX)) { /* * Note: we have to call the displayProc even for chunks that * are off-screen. This is needed, for example, so that * embedded windows can be unmapped in this case. Display the * chunk at a coordinate that can be clearly identified by the * displayProc as being off-screen to the left (the * displayProc may not be able to tell if something is off to * the right). */ x = -chunkPtr->width; } (*chunkPtr->displayProc)(textPtr, chunkPtr, x, y + dlPtr->spaceAbove, dlPtr->height - dlPtr->spaceAbove - dlPtr->spaceBelow, dlPtr->baseline - dlPtr->spaceAbove, display, pixmap, dlPtr->y + dlPtr->spaceAbove); } if (dInfoPtr->dLinesInvalidated) { return; } } #ifndef TK_NO_DOUBLE_BUFFERING /* * Copy the pixmap onto the screen. If this is the first or last line on * the screen then copy a piece of the line, so that it doesn't overflow * into the border area. Another special trick: copy the padding area to * the left of the line; this is because the insertion cursor sometimes * overflows onto that area and we want to get as much of the cursor as * possible. */ XCopyArea(display, pixmap, Tk_WindowId(textPtr->tkwin), dInfoPtr->copyGC, dInfoPtr->x, y + y_off, (unsigned) (dInfoPtr->maxX - dInfoPtr->x), (unsigned) height, dInfoPtr->x, dlPtr->y + y_off); #else TkpClipDrawableToRect(display, pixmap, 0, 0, -1, -1); #endif /* TK_NO_DOUBLE_BUFFERING */ linesRedrawn++; } /* *-------------------------------------------------------------- * * DisplayLineBackground -- * * This function is called to fill in the background for a display line. * It draws 3D borders cleverly so that adjacent chunks with the same * style (whether on the same line or different lines) have a single 3D * border around the whole region. * * Results: * There is no return value. Pixmap is filled in with background * information for dlPtr. * * Side effects: * None. * *-------------------------------------------------------------- */ static void DisplayLineBackground( TkText *textPtr, /* Text widget containing line. */ register DLine *dlPtr, /* Information about line to draw. */ DLine *prevPtr, /* Line just above dlPtr, or NULL if dlPtr is * the top-most line in the window. */ Pixmap pixmap) /* Pixmap to use for double-buffering. Caller * must make sure it's large enough to hold * line. Caller must also have filled it with * the background color for the widget. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; TkTextDispChunk *chunkPtr; /* Pointer to chunk in the current line. */ TkTextDispChunk *chunkPtr2; /* Pointer to chunk in the line above or below * the current one. NULL if we're to the left * of or to the right of the chunks in the * line. */ TkTextDispChunk *nextPtr2; /* Next chunk after chunkPtr2 (it's not the * same as chunkPtr2->nextPtr in the case * where chunkPtr2 is NULL because the line is * indented). */ int leftX; /* The left edge of the region we're currently * working on. */ int leftXIn; /* 1 means beveled edge at leftX slopes right * as it goes down, 0 means it slopes left as * it goes down. */ int rightX; /* Right edge of chunkPtr. */ int rightX2; /* Right edge of chunkPtr2. */ int matchLeft; /* Does the style of this line match that of * its neighbor just to the left of the * current x coordinate? */ int matchRight; /* Does line's style match its neighbor just * to the right of the current x-coord? */ int minX, maxX, xOffset; StyleValues *sValuePtr; Display *display; #ifndef TK_NO_DOUBLE_BUFFERING const int y = 0; #else const int y = dlPtr->y; #endif /* TK_NO_DOUBLE_BUFFERING */ /* * Pass 1: scan through dlPtr from left to right. For each range of chunks * with the same style, draw the main background for the style plus the * vertical parts of the 3D borders (the left and right edges). */ display = Tk_Display(textPtr->tkwin); minX = dInfoPtr->curXPixelOffset; xOffset = dInfoPtr->x - minX; maxX = minX + dInfoPtr->maxX - dInfoPtr->x; chunkPtr = dlPtr->chunkPtr; /* * Note A: in the following statement, and a few others later in this file * marked with "See Note A above", the right side of the assignment was * replaced with 0 on 6/18/97. This has the effect of highlighting the * empty space to the left of a line whenever the leftmost character of * the line is highlighted. This way, multi-line highlights always line up * along their left edges. However, this may look funny in the case where * a single word is highlighted. To undo the change, replace "leftX = 0" * with "leftX = chunkPtr->x" and "rightX2 = 0" with "rightX2 = * nextPtr2->x" here and at all the marked points below. This restores the * old behavior where empty space to the left of a line is not * highlighted, leaving a ragged left edge for multi-line highlights. */ leftX = 0; for (; leftX < maxX; chunkPtr = chunkPtr->nextPtr) { if ((chunkPtr->nextPtr != NULL) && SAME_BACKGROUND(chunkPtr->nextPtr->stylePtr, chunkPtr->stylePtr)) { continue; } sValuePtr = chunkPtr->stylePtr->sValuePtr; rightX = chunkPtr->x + chunkPtr->width; if ((chunkPtr->nextPtr == NULL) && (rightX < maxX)) { rightX = maxX; } if (chunkPtr->stylePtr->bgGC != None) { /* * Not visible - bail out now. */ if (rightX + xOffset <= 0) { leftX = rightX; continue; } /* * Trim the start position for drawing to be no further away than * -borderWidth. The reason is that on many X servers drawing from * -32768 (or less) to +something simply does not display * correctly. [Patch #541999] */ if ((leftX + xOffset) < -(sValuePtr->borderWidth)) { leftX = -sValuePtr->borderWidth - xOffset; } if ((rightX - leftX) > 32767) { rightX = leftX + 32767; } XFillRectangle(display, pixmap, chunkPtr->stylePtr->bgGC, leftX + xOffset, y, (unsigned int) (rightX - leftX), (unsigned int) dlPtr->height); if (sValuePtr->relief != TK_RELIEF_FLAT) { Tk_3DVerticalBevel(textPtr->tkwin, pixmap, sValuePtr->border, leftX + xOffset, y, sValuePtr->borderWidth, dlPtr->height, 1, sValuePtr->relief); Tk_3DVerticalBevel(textPtr->tkwin, pixmap, sValuePtr->border, rightX - sValuePtr->borderWidth + xOffset, y, sValuePtr->borderWidth, dlPtr->height, 0, sValuePtr->relief); } } leftX = rightX; } /* * Pass 2: draw the horizontal bevels along the top of the line. To do * this, scan through dlPtr from left to right while simultaneously * scanning through the line just above dlPtr. ChunkPtr2 and nextPtr2 * refer to two adjacent chunks in the line above. */ chunkPtr = dlPtr->chunkPtr; leftX = 0; /* See Note A above. */ leftXIn = 1; rightX = chunkPtr->x + chunkPtr->width; if ((chunkPtr->nextPtr == NULL) && (rightX < maxX)) { rightX = maxX; } chunkPtr2 = NULL; if (prevPtr != NULL && prevPtr->chunkPtr != NULL) { /* * Find the chunk in the previous line that covers leftX. */ nextPtr2 = prevPtr->chunkPtr; rightX2 = 0; /* See Note A above. */ while (rightX2 <= leftX) { chunkPtr2 = nextPtr2; if (chunkPtr2 == NULL) { break; } nextPtr2 = chunkPtr2->nextPtr; rightX2 = chunkPtr2->x + chunkPtr2->width; if (nextPtr2 == NULL) { rightX2 = INT_MAX; } } } else { nextPtr2 = NULL; rightX2 = INT_MAX; } while (leftX < maxX) { matchLeft = (chunkPtr2 != NULL) && SAME_BACKGROUND(chunkPtr2->stylePtr, chunkPtr->stylePtr); sValuePtr = chunkPtr->stylePtr->sValuePtr; if (rightX <= rightX2) { /* * The chunk in our line is about to end. If its style changes * then draw the bevel for the current style. */ if ((chunkPtr->nextPtr == NULL) || !SAME_BACKGROUND(chunkPtr->stylePtr, chunkPtr->nextPtr->stylePtr)) { if (!matchLeft && (sValuePtr->relief != TK_RELIEF_FLAT)) { Tk_3DHorizontalBevel(textPtr->tkwin, pixmap, sValuePtr->border, leftX + xOffset, y, rightX - leftX, sValuePtr->borderWidth, leftXIn, 1, 1, sValuePtr->relief); } leftX = rightX; leftXIn = 1; /* * If the chunk in the line above is also ending at the same * point then advance to the next chunk in that line. */ if ((rightX == rightX2) && (chunkPtr2 != NULL)) { goto nextChunk2; } } chunkPtr = chunkPtr->nextPtr; if (chunkPtr == NULL) { break; } rightX = chunkPtr->x + chunkPtr->width; if ((chunkPtr->nextPtr == NULL) && (rightX < maxX)) { rightX = maxX; } continue; } /* * The chunk in the line above is ending at an x-position where there * is no change in the style of the current line. If the style above * matches the current line on one side of the change but not on the * other, we have to draw an L-shaped piece of bevel. */ matchRight = (nextPtr2 != NULL) && SAME_BACKGROUND(nextPtr2->stylePtr, chunkPtr->stylePtr); if (matchLeft && !matchRight) { if (sValuePtr->relief != TK_RELIEF_FLAT) { Tk_3DVerticalBevel(textPtr->tkwin, pixmap, sValuePtr->border, rightX2 - sValuePtr->borderWidth + xOffset, y, sValuePtr->borderWidth, sValuePtr->borderWidth, 0, sValuePtr->relief); } leftX = rightX2 - sValuePtr->borderWidth; leftXIn = 0; } else if (!matchLeft && matchRight && (sValuePtr->relief != TK_RELIEF_FLAT)) { Tk_3DVerticalBevel(textPtr->tkwin, pixmap, sValuePtr->border, rightX2 + xOffset, y, sValuePtr->borderWidth, sValuePtr->borderWidth, 1, sValuePtr->relief); Tk_3DHorizontalBevel(textPtr->tkwin, pixmap, sValuePtr->border, leftX + xOffset, y, rightX2 + sValuePtr->borderWidth - leftX, sValuePtr->borderWidth, leftXIn, 0, 1, sValuePtr->relief); } nextChunk2: chunkPtr2 = nextPtr2; if (chunkPtr2 == NULL) { rightX2 = INT_MAX; } else { nextPtr2 = chunkPtr2->nextPtr; rightX2 = chunkPtr2->x + chunkPtr2->width; if (nextPtr2 == NULL) { rightX2 = INT_MAX; } } } /* * Pass 3: draw the horizontal bevels along the bottom of the line. This * uses the same approach as pass 2. */ chunkPtr = dlPtr->chunkPtr; leftX = 0; /* See Note A above. */ leftXIn = 0; rightX = chunkPtr->x + chunkPtr->width; if ((chunkPtr->nextPtr == NULL) && (rightX < maxX)) { rightX = maxX; } chunkPtr2 = NULL; if (dlPtr->nextPtr != NULL && dlPtr->nextPtr->chunkPtr != NULL) { /* * Find the chunk in the previous line that covers leftX. */ nextPtr2 = dlPtr->nextPtr->chunkPtr; rightX2 = 0; /* See Note A above. */ while (rightX2 <= leftX) { chunkPtr2 = nextPtr2; if (chunkPtr2 == NULL) { break; } nextPtr2 = chunkPtr2->nextPtr; rightX2 = chunkPtr2->x + chunkPtr2->width; if (nextPtr2 == NULL) { rightX2 = INT_MAX; } } } else { nextPtr2 = NULL; rightX2 = INT_MAX; } while (leftX < maxX) { matchLeft = (chunkPtr2 != NULL) && SAME_BACKGROUND(chunkPtr2->stylePtr, chunkPtr->stylePtr); sValuePtr = chunkPtr->stylePtr->sValuePtr; if (rightX <= rightX2) { if ((chunkPtr->nextPtr == NULL) || !SAME_BACKGROUND(chunkPtr->stylePtr, chunkPtr->nextPtr->stylePtr)) { if (!matchLeft && (sValuePtr->relief != TK_RELIEF_FLAT)) { Tk_3DHorizontalBevel(textPtr->tkwin, pixmap, sValuePtr->border, leftX + xOffset, y + dlPtr->height - sValuePtr->borderWidth, rightX - leftX, sValuePtr->borderWidth, leftXIn, 0, 0, sValuePtr->relief); } leftX = rightX; leftXIn = 0; if ((rightX == rightX2) && (chunkPtr2 != NULL)) { goto nextChunk2b; } } chunkPtr = chunkPtr->nextPtr; if (chunkPtr == NULL) { break; } rightX = chunkPtr->x + chunkPtr->width; if ((chunkPtr->nextPtr == NULL) && (rightX < maxX)) { rightX = maxX; } continue; } matchRight = (nextPtr2 != NULL) && SAME_BACKGROUND(nextPtr2->stylePtr, chunkPtr->stylePtr); if (matchLeft && !matchRight) { if (sValuePtr->relief != TK_RELIEF_FLAT) { Tk_3DVerticalBevel(textPtr->tkwin, pixmap, sValuePtr->border, rightX2 - sValuePtr->borderWidth + xOffset, y + dlPtr->height - sValuePtr->borderWidth, sValuePtr->borderWidth, sValuePtr->borderWidth, 0, sValuePtr->relief); } leftX = rightX2 - sValuePtr->borderWidth; leftXIn = 1; } else if (!matchLeft && matchRight && (sValuePtr->relief != TK_RELIEF_FLAT)) { Tk_3DVerticalBevel(textPtr->tkwin, pixmap, sValuePtr->border, rightX2 + xOffset, y + dlPtr->height - sValuePtr->borderWidth, sValuePtr->borderWidth, sValuePtr->borderWidth, 1, sValuePtr->relief); Tk_3DHorizontalBevel(textPtr->tkwin, pixmap, sValuePtr->border, leftX + xOffset, y + dlPtr->height - sValuePtr->borderWidth, rightX2 + sValuePtr->borderWidth - leftX, sValuePtr->borderWidth, leftXIn, 1, 0, sValuePtr->relief); } nextChunk2b: chunkPtr2 = nextPtr2; if (chunkPtr2 == NULL) { rightX2 = INT_MAX; } else { nextPtr2 = chunkPtr2->nextPtr; rightX2 = chunkPtr2->x + chunkPtr2->width; if (nextPtr2 == NULL) { rightX2 = INT_MAX; } } } } /* *---------------------------------------------------------------------- * * AsyncUpdateLineMetrics -- * * This function is invoked as a background handler to update the pixel- * height calculations of individual lines in an asychronous manner. * * Currently a timer-handler is used for this purpose, which continuously * reschedules itself. It may well be better to use some other approach * (e.g., a background thread). We can't use an idle-callback because of * a known bug in Tcl/Tk in which idle callbacks are not allowed to * re-schedule themselves. This just causes an effective infinite loop. * * Results: * None. * * Side effects: * Line heights may be recalculated. * *---------------------------------------------------------------------- */ static void AsyncUpdateLineMetrics( ClientData clientData) /* Information about widget. */ { register TkText *textPtr = (TkText *) clientData; TextDInfo *dInfoPtr = textPtr->dInfoPtr; int lineNum; dInfoPtr->lineUpdateTimer = NULL; if ((textPtr->tkwin == NULL) || (textPtr->flags & DESTROYED)) { /* * The widget has been deleted. Don't do anything. */ if (--textPtr->refCount == 0) { ckfree((char *) textPtr); } return; } if (dInfoPtr->flags & REDRAW_PENDING) { dInfoPtr->lineUpdateTimer = Tcl_CreateTimerHandler(1, AsyncUpdateLineMetrics, clientData); return; } lineNum = dInfoPtr->currentMetricUpdateLine; if (dInfoPtr->lastMetricUpdateLine == -1) { dInfoPtr->lastMetricUpdateLine = TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr); } /* * Update the lines in blocks of about 24 recalculations, or 250+ lines * examined, so we pass in 256 for 'doThisMuch'. */ lineNum = TkTextUpdateLineMetrics(textPtr, lineNum, dInfoPtr->lastMetricUpdateLine, 256); if (tkTextDebug) { char buffer[2 * TCL_INTEGER_SPACE + 1]; sprintf(buffer, "%d %d", lineNum, dInfoPtr->lastMetricUpdateLine); LOG("tk_textInvalidateLine", buffer); } /* * If we're not in the middle of a long-line calculation (metricEpoch==-1) * and we've reached the last line, then we're done. */ if (dInfoPtr->metricEpoch == -1 && lineNum == dInfoPtr->lastMetricUpdateLine) { /* * We have looped over all lines, so we're done. We must release our * refCount on the widget (the timer token was already set to NULL * above). */ textPtr->refCount--; if (textPtr->refCount == 0) { ckfree((char *) textPtr); } return; } dInfoPtr->currentMetricUpdateLine = lineNum; /* * Re-arm the timer. We already have a refCount on the text widget so no * need to adjust that. */ dInfoPtr->lineUpdateTimer = Tcl_CreateTimerHandler(1, AsyncUpdateLineMetrics, (ClientData) textPtr); } /* *---------------------------------------------------------------------- * * TkTextUpdateLineMetrics -- * * This function updates the pixel height calculations of a range of * lines in the widget. The range is from lineNum to endLine, but, if * doThisMuch is positive, then the function may return earlier, once a * certain number of lines has been examined. The line counts are from 0. * * If doThisMuch is -1, then all lines in the range will be updated. This * will potentially take quite some time for a large text widget. * * Note: with bad input for lineNum and endLine, this function can loop * indefinitely. * * Results: * The index of the last line examined (or -1 if we are about to wrap * around from end to beginning of the widget, and the next line will be * the first line). * * Side effects: * Line heights may be recalculated. * *---------------------------------------------------------------------- */ int TkTextUpdateLineMetrics( TkText *textPtr, /* Information about widget. */ int lineNum, /* Start at this line. */ int endLine, /* Go no further than this line. */ int doThisMuch) /* How many lines to check, or how many 10s of * lines to recalculate. If '-1' then do * everything in the range (which may take a * while). */ { TkTextLine *linePtr = NULL; int count = 0; int totalLines = TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr); if (totalLines == 0) { /* * Empty peer widget. */ return endLine; } while (1) { /* * Get a suitable line. */ if (lineNum == -1 && linePtr == NULL) { lineNum = 0; linePtr = TkBTreeFindLine(textPtr->sharedTextPtr->tree, textPtr, lineNum); } else { if (lineNum == -1 || linePtr == NULL) { if (lineNum == -1) { lineNum = 0; } linePtr = TkBTreeFindLine(textPtr->sharedTextPtr->tree, textPtr, lineNum); } else { lineNum++; linePtr = TkBTreeNextLine(textPtr, linePtr); } /* * If we're in the middle of a partial-line height calculation, * then we can't be done. */ if (textPtr->dInfoPtr->metricEpoch == -1 && lineNum == endLine) { /* * We have looped over all lines, so we're done. */ break; } } if (lineNum < totalLines) { if (tkTextDebug) { char buffer[4 * TCL_INTEGER_SPACE + 3]; sprintf(buffer, "%d %d %d %d", lineNum, endLine, totalLines, count); LOG("tk_textInvalidateLine", buffer); } /* * Now update the line's metrics if necessary. */ if (TkBTreeLinePixelEpoch(textPtr, linePtr) != textPtr->dInfoPtr->lineMetricUpdateEpoch) { if (doThisMuch == -1) { count += 8 * TkTextUpdateOneLine(textPtr, linePtr, 0, NULL, 0); } else { TkTextIndex index; TkTextIndex *indexPtr; int pixelHeight; /* * If the metric epoch is the same as the widget's epoch, * then we know that indexPtrs are still valid, and if the * cached metricIndex (if any) is for the same line as we * wish to examine, then we are looking at a long line * wrapped many times, which we will examine in pieces. */ if (textPtr->dInfoPtr->metricEpoch == textPtr->sharedTextPtr->stateEpoch && textPtr->dInfoPtr->metricIndex.linePtr==linePtr) { indexPtr = &textPtr->dInfoPtr->metricIndex; pixelHeight = textPtr->dInfoPtr->metricPixelHeight; } else { /* * We must reset the partial line height calculation * data here, so we don't use it when it is out of * date. */ textPtr->dInfoPtr->metricEpoch = -1; index.tree = textPtr->sharedTextPtr->tree; index.linePtr = linePtr; index.byteIndex = 0; index.textPtr = NULL; indexPtr = &index; pixelHeight = 0; } /* * Update the line and update the counter, counting 8 for * each display line we actually re-layout. */ count += 8 * TkTextUpdateOneLine(textPtr, linePtr, pixelHeight, indexPtr, 1); if (indexPtr->linePtr == linePtr) { /* * We didn't complete the logical line, because it * produced very many display lines - it must be a * long line wrapped many times. So we must cache as * far as we got for next time around. */ if (pixelHeight == 0) { /* * These have already been stored, unless we just * started the new line. */ textPtr->dInfoPtr->metricIndex = index; textPtr->dInfoPtr->metricEpoch = textPtr->sharedTextPtr->stateEpoch; } textPtr->dInfoPtr->metricPixelHeight = TkBTreeLinePixelCount(textPtr, linePtr); break; } else { /* * We're done with this long line. */ textPtr->dInfoPtr->metricEpoch = -1; } } } else { /* * This line is already up to date. That means there's nothing * to do here. */ } } else { /* * We must never recalculate the height of the last artificial * line. It must stay at zero, and if we recalculate it, it will * change. */ if (endLine >= totalLines) { lineNum = endLine; break; } /* * Set things up for the next loop through. */ lineNum = -1; } count++; if (doThisMuch != -1 && count >= doThisMuch) { break; } } if (doThisMuch == -1) { /* * If we were requested to provide a full update, then also update the * scrollbar. */ GetYView(textPtr->interp, textPtr, 1); } return lineNum; } /* *---------------------------------------------------------------------- * * TkTextInvalidateLineMetrics, TextInvalidateLineMetrics -- * * Mark a number of text lines as having invalid line metric * calculations. Never call this with linePtr as the last (artificial) * line in the text. Depending on 'action' which indicates whether the * given lines are simply invalid or have been inserted or deleted, the * pre-existing asynchronous line update range may need to be adjusted. * * If linePtr is NULL then 'lineCount' and 'action' are ignored and all * lines are invalidated. * * Results: * None. * * Side effects: * May schedule an asychronous callback. * *---------------------------------------------------------------------- */ void TkTextInvalidateLineMetrics( TkSharedText *sharedTextPtr,/* Shared widget section for all peers, or * NULL. */ TkText *textPtr, /* Widget record for text widget. */ TkTextLine *linePtr, /* Invalidation starts from this line. */ int lineCount, /* And includes this many following lines. */ int action) /* Indicates what type of invalidation * occurred (insert, delete, or simple). */ { if (sharedTextPtr == NULL) { TextInvalidateLineMetrics(textPtr, linePtr, lineCount, action); } else { textPtr = sharedTextPtr->peers; while (textPtr != NULL) { TextInvalidateLineMetrics(textPtr, linePtr, lineCount, action); textPtr = textPtr->next; } } } static void TextInvalidateLineMetrics( TkText *textPtr, /* Widget record for text widget. */ TkTextLine *linePtr, /* Invalidation starts from this line. */ int lineCount, /* And includes this many following lines. */ int action) /* Indicates what type of invalidation * occurred (insert, delete, or simple). */ { int fromLine; TextDInfo *dInfoPtr = textPtr->dInfoPtr; if (linePtr != NULL) { int counter = lineCount; fromLine = TkBTreeLinesTo(textPtr, linePtr); /* * Invalidate the height calculations of each line in the given range. */ TkBTreeLinePixelEpoch(textPtr, linePtr) = 0; while (counter > 0 && linePtr != NULL) { linePtr = TkBTreeNextLine(textPtr, linePtr); if (linePtr != NULL) { TkBTreeLinePixelEpoch(textPtr, linePtr) = 0; } counter--; } /* * Now schedule an examination of each line in the union of the old * and new update ranges, including the (possibly empty) range in * between. If that between range is not-empty, then we are examining * more lines than is strictly necessary (but the examination of the * extra lines should be quick, since their pixelCalculationEpoch will * be up to date). However, to keep track of that would require more * complex record-keeping than what we have. */ if (dInfoPtr->lineUpdateTimer == NULL) { dInfoPtr->currentMetricUpdateLine = fromLine; if (action == TK_TEXT_INVALIDATE_DELETE) { lineCount = 0; } dInfoPtr->lastMetricUpdateLine = fromLine + lineCount + 1; } else { int toLine = fromLine + lineCount + 1; if (action == TK_TEXT_INVALIDATE_DELETE) { if (toLine <= dInfoPtr->currentMetricUpdateLine) { dInfoPtr->currentMetricUpdateLine = fromLine; if (dInfoPtr->lastMetricUpdateLine != -1) { dInfoPtr->lastMetricUpdateLine -= lineCount; } } else if (fromLine <= dInfoPtr->currentMetricUpdateLine) { dInfoPtr->currentMetricUpdateLine = fromLine; if (toLine <= dInfoPtr->lastMetricUpdateLine) { dInfoPtr->lastMetricUpdateLine -= lineCount; } } else { if (dInfoPtr->lastMetricUpdateLine != -1) { dInfoPtr->lastMetricUpdateLine = toLine; } } } else if (action == TK_TEXT_INVALIDATE_INSERT) { if (toLine <= dInfoPtr->currentMetricUpdateLine) { dInfoPtr->currentMetricUpdateLine = fromLine; if (dInfoPtr->lastMetricUpdateLine != -1) { dInfoPtr->lastMetricUpdateLine += lineCount; } } else if (fromLine <= dInfoPtr->currentMetricUpdateLine) { dInfoPtr->currentMetricUpdateLine = fromLine; if (toLine <= dInfoPtr->lastMetricUpdateLine) { dInfoPtr->lastMetricUpdateLine += lineCount; } if (toLine > dInfoPtr->lastMetricUpdateLine) { dInfoPtr->lastMetricUpdateLine = toLine; } } else { if (dInfoPtr->lastMetricUpdateLine != -1) { dInfoPtr->lastMetricUpdateLine = toLine; } } } else { if (fromLine < dInfoPtr->currentMetricUpdateLine) { dInfoPtr->currentMetricUpdateLine = fromLine; } if (dInfoPtr->lastMetricUpdateLine != -1 && toLine > dInfoPtr->lastMetricUpdateLine) { dInfoPtr->lastMetricUpdateLine = toLine; } } } } else { /* * This invalidates the height of all lines in the widget. */ if ((++dInfoPtr->lineMetricUpdateEpoch) == 0) { dInfoPtr->lineMetricUpdateEpoch++; } /* * This has the effect of forcing an entire new loop of update checks * on all lines in the widget. */ if (dInfoPtr->lineUpdateTimer == NULL) { dInfoPtr->currentMetricUpdateLine = -1; } dInfoPtr->lastMetricUpdateLine = dInfoPtr->currentMetricUpdateLine; } /* * Now re-set the current update calculations. */ if (dInfoPtr->lineUpdateTimer == NULL) { textPtr->refCount++; dInfoPtr->lineUpdateTimer = Tcl_CreateTimerHandler(1, AsyncUpdateLineMetrics, (ClientData) textPtr); } } /* *---------------------------------------------------------------------- * * TkTextFindDisplayLineEnd -- * * This function is invoked to find the index of the beginning or end of * the particular display line on which the given index sits, whether * that line is displayed or not. * * If 'end' is zero, we look for the start, and if 'end' is one we look * for the end. * * If the beginning of the current display line is elided, and we are * looking for the start of the line, then the returned index will be the * first elided index on the display line. * * Similarly if the end of the current display line is elided and we are * looking for the end, then the returned index will be the last elided * index on the display line. * * Results: * Modifies indexPtr to point to the given end. * * If xOffset is non-NULL, it is set to the x-pixel offset of the given * original index within the given display line. * * Side effects: * The combination of 'LayoutDLine' and 'FreeDLines' seems like a rather * time-consuming way of gathering the information we need, so this would * be a good place to look to speed up the calculations. In particular * these calls will map and unmap embedded windows respectively, which I * would hope isn't exactly necessary! * *---------------------------------------------------------------------- */ void TkTextFindDisplayLineEnd( TkText *textPtr, /* Widget record for text widget. */ TkTextIndex *indexPtr, /* Index we will adjust to the display line * start or end. */ int end, /* 0 = start, 1 = end. */ int *xOffset) /* NULL, or used to store the x-pixel offset * of the original index within its display * line. */ { if (!end && IsStartOfNotMergedLine(textPtr, indexPtr)) { /* * Nothing to do. */ if (xOffset != NULL) { *xOffset = 0; } return; } else { TkTextIndex index = *indexPtr; index.byteIndex = 0; index.textPtr = NULL; while (1) { TkTextIndex endOfLastLine; if (TkTextIndexBackBytes(textPtr, &index, 1, &endOfLastLine)) { /* * Reached beginning of text. */ break; } if (!TkTextIsElided(textPtr, &endOfLastLine, NULL)) { /* * The eol is not elided, so 'index' points to the start of a * display line (as well as logical line). */ break; } /* * indexPtr's logical line is actually merged with the previous * logical line whose eol is elided. Continue searching back to * get a real line start. */ index = endOfLastLine; index.byteIndex = 0; } while (1) { DLine *dlPtr; int byteCount; TkTextIndex nextLineStart; dlPtr = LayoutDLine(textPtr, &index); byteCount = dlPtr->byteCount; TkTextIndexForwBytes(textPtr, &index, byteCount, &nextLineStart); /* * 'byteCount' goes up to the beginning of the next display line, * so equality here says we need one more line. We try to perform * a quick comparison which is valid for the case where the * logical line is the same, but otherwise fall back on a full * TkTextIndexCmp. */ if (((index.linePtr == indexPtr->linePtr) && (index.byteIndex + byteCount > indexPtr->byteIndex)) || (dlPtr->logicalLinesMerged > 0 && TkTextIndexCmp(&nextLineStart, indexPtr) > 0)) { /* * It's on this display line. */ if (xOffset != NULL) { /* * This call takes a byte index relative to the start of * the current _display_ line, not logical line. We are * about to overwrite indexPtr->byteIndex, so we must do * this now. */ *xOffset = DlineXOfIndex(textPtr, dlPtr, TkTextIndexCountBytes(textPtr, &dlPtr->index, indexPtr)); } if (end) { /* * The index we want is one less than the number of bytes * in the display line. */ TkTextIndexBackBytes(textPtr, &nextLineStart, 1, indexPtr); } else { *indexPtr = index; } FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE_TEMP); return; } FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE_TEMP); index = nextLineStart; } } } /* *---------------------------------------------------------------------- * * CalculateDisplayLineHeight -- * * This function is invoked to recalculate the height of the particular * display line which starts with the given index, whether that line is * displayed or not. * * This function does not, in itself, update any cached information about * line heights. That should be done, where necessary, by its callers. * * The behaviour of this function is _undefined_ if indexPtr is not * currently at the beginning of a display line. * * Results: * The number of vertical pixels used by the display line. * * If 'byteCountPtr' is non-NULL, then returns in that pointer the number * of byte indices on the given display line (which can be used to update * indexPtr in a loop). * * If 'mergedLinePtr' is non-NULL, then returns in that pointer the * number of extra logical lines merged into the given display line. * * Side effects: * The combination of 'LayoutDLine' and 'FreeDLines' seems like a rather * time-consuming way of gathering the information we need, so this would * be a good place to look to speed up the calculations. In particular * these calls will map and unmap embedded windows respectively, which I * would hope isn't exactly necessary! * *---------------------------------------------------------------------- */ static int CalculateDisplayLineHeight( TkText *textPtr, /* Widget record for text widget. */ CONST TkTextIndex *indexPtr,/* The index at the beginning of the display * line of interest. */ int *byteCountPtr, /* NULL or used to return the number of byte * indices on the given display line. */ int *mergedLinePtr) /* NULL or used to return if the given display * line merges with a following logical line * (because the eol is elided). */ { DLine *dlPtr; int pixelHeight; if (tkTextDebug) { int oldtkTextDebug = tkTextDebug; /* * Check that the indexPtr we are given really is at the start of a * display line. The gymnastics with tkTextDebug is to prevent * failure of a test suite test, that checks that lines are rendered * exactly once. TkTextFindDisplayLineEnd is used here for checking * indexPtr but it calls LayoutDLine/FreeDLine which makes the * counting wrong. The debug mode shall therefore be switched off * when calling TkTextFindDisplayLineEnd. */ TkTextIndex indexPtr2 = *indexPtr; tkTextDebug = 0; TkTextFindDisplayLineEnd(textPtr, &indexPtr2, 0, NULL); tkTextDebug = oldtkTextDebug; if (TkTextIndexCmp(&indexPtr2,indexPtr) != 0) { Tcl_Panic("CalculateDisplayLineHeight called with bad indexPtr"); } } /* * Special case for artificial last line. May be better to move this * inside LayoutDLine. */ if (indexPtr->byteIndex == 0 && TkBTreeNextLine(textPtr, indexPtr->linePtr) == NULL) { if (byteCountPtr != NULL) { *byteCountPtr = 0; } if (mergedLinePtr != NULL) { *mergedLinePtr = 0; } return 0; } /* * Layout, find the information we need and then free the display-line we * laid-out. We must use 'FreeDLines' because it will actually call the * relevant code to unmap any embedded windows which were mapped in the * LayoutDLine call! */ dlPtr = LayoutDLine(textPtr, indexPtr); pixelHeight = dlPtr->height; if (byteCountPtr != NULL) { *byteCountPtr = dlPtr->byteCount; } if (mergedLinePtr != NULL) { *mergedLinePtr = dlPtr->logicalLinesMerged; } FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE_TEMP); return pixelHeight; } /* *---------------------------------------------------------------------- * * TkTextIndexYPixels -- * * This function is invoked to calculate the number of vertical pixels * between the first index of the text widget and the given index. The * range from first logical line to given logical line is determined * using the cached values, and the range inside the given logical line * is calculated on the fly. * * Results: * The pixel distance between first pixel in the widget and the * top of the index's current display line (could be zero). * * Side effects: * Just those of 'CalculateDisplayLineHeight'. * *---------------------------------------------------------------------- */ int TkTextIndexYPixels( TkText *textPtr, /* Widget record for text widget. */ CONST TkTextIndex *indexPtr)/* The index of which we want the pixel * distance from top of logical line to top of * index. */ { int pixelHeight; TkTextIndex index; int alreadyStartOfLine = 1; /* * Find the index denoting the closest position being at the same time * the start of a logical line above indexPtr and the start of a display * line. */ index = *indexPtr; while (1) { TkTextFindDisplayLineEnd(textPtr, &index, 0, NULL); if (index.byteIndex == 0) { break; } TkTextIndexBackBytes(textPtr, &index, 1, &index); alreadyStartOfLine = 0; } pixelHeight = TkBTreePixelsTo(textPtr, index.linePtr); /* * Shortcut to avoid layout of a superfluous display line. We know there * is nothing more to add up to the height if the index we were given was * already on the first display line of a logical line. */ if (alreadyStartOfLine) { return pixelHeight; } /* * Iterate through display lines, starting at the logical line belonging * to index, adding up the pixel height of each such display line as we * go along, until we go past 'indexPtr'. */ while (1) { int bytes, height, compare; /* * Currently this call doesn't have many side-effects. However, if in * the future we change the code so there are side-effects (such as * adjusting linePtr->pixelHeight), then the code might not quite work * as intended, specifically the 'linePtr->pixelHeight == pixelHeight' * test below this while loop. */ height = CalculateDisplayLineHeight(textPtr, &index, &bytes, NULL); TkTextIndexForwBytes(textPtr, &index, bytes, &index); compare = TkTextIndexCmp(&index,indexPtr); if (compare > 0) { return pixelHeight; } if (height > 0) { pixelHeight += height; } if (compare == 0) { return pixelHeight; } } } /* *---------------------------------------------------------------------- * * TkTextUpdateOneLine -- * * This function is invoked to recalculate the height of a particular * logical line, whether that line is displayed or not. * * It must NEVER be called for the artificial last TkTextLine which is * used internally for administrative purposes only. That line must * retain its initial height of 0 otherwise the pixel height calculation * maintained by the B-tree will be wrong. * * Results: * The number of display lines in the logical line. This could be zero if * the line is totally elided. * * Side effects: * Line heights may be recalculated, and a timer to update the scrollbar * may be installed. Also see the called function * CalculateDisplayLineHeight for its side effects. * *---------------------------------------------------------------------- */ int TkTextUpdateOneLine( TkText *textPtr, /* Widget record for text widget. */ TkTextLine *linePtr, /* The line of which to calculate the * height. */ int pixelHeight, /* If indexPtr is non-NULL, then this is the * number of pixels in the logical line * linePtr, up to the index which has been * given. */ TkTextIndex *indexPtr, /* Either NULL or an index at the start of a * display line belonging to linePtr, at which * we wish to start (e.g. up to which we have * already calculated). On return this will be * set to the first index on the next line. */ int partialCalc) /* Set to 1 if we are allowed to do partial * height calculations of long-lines. In this * case we'll only return what we know so * far. */ { TkTextIndex index; int displayLines; int mergedLines; if (indexPtr == NULL) { index.tree = textPtr->sharedTextPtr->tree; index.linePtr = linePtr; index.byteIndex = 0; index.textPtr = NULL; indexPtr = &index; pixelHeight = 0; } /* * CalculateDisplayLineHeight _must_ be called (below) with an index at * the beginning of a display line. Force this to happen. This is needed * when TkTextUpdateOneLine is called with a line that is merged with its * previous line: the number of merged logical lines in a display line is * calculated correctly only when CalculateDisplayLineHeight receives * an index at the beginning of a display line. In turn this causes the * merged lines to receive their correct zero pixel height in * TkBTreeAdjustPixelHeight. */ TkTextFindDisplayLineEnd(textPtr, indexPtr, 0, NULL); linePtr = indexPtr->linePtr; /* * Iterate through all display-lines corresponding to the single logical * line 'linePtr' (and lines merged into this line due to eol elision), * adding up the pixel height of each such display line as we go along. * The final total is, therefore, the total height of all display lines * made up by the logical line 'linePtr' and subsequent logical lines * merged into this line. */ displayLines = 0; mergedLines = 0; while (1) { int bytes, height, logicalLines; /* * Currently this call doesn't have many side-effects. However, if in * the future we change the code so there are side-effects (such as * adjusting linePtr->pixelHeight), then the code might not quite work * as intended, specifically the 'linePtr->pixelHeight == pixelHeight' * test below this while loop. */ height = CalculateDisplayLineHeight(textPtr, indexPtr, &bytes, &logicalLines); if (height > 0) { pixelHeight += height; displayLines++; } mergedLines += logicalLines; if (TkTextIndexForwBytes(textPtr, indexPtr, bytes, indexPtr)) { break; } if (mergedLines == 0) { if (indexPtr->linePtr != linePtr) { /* * If we reached the end of the logical line, then either way * we don't have a partial calculation. */ partialCalc = 0; break; } } else { if (IsStartOfNotMergedLine(textPtr, indexPtr)) { /* * We've ended a logical line. */ partialCalc = 0; break; } /* * We must still be on the same wrapped line, on a new logical * line merged with the logical line 'linePtr'. */ } if (partialCalc && displayLines > 50 && mergedLines == 0) { /* * Only calculate 50 display lines at a time, to avoid huge * delays. In any case it is very rare that a single line wraps 50 * times! * * If we have any merged lines, we must complete the full logical * line layout here and now, because the partial-calculation code * isn't designed to handle merged logical lines. Hence the * 'mergedLines == 0' check. */ break; } } if (!partialCalc) { int changed = 0; /* * Cancel any partial line height calculation state. */ textPtr->dInfoPtr->metricEpoch = -1; /* * Mark the logical line as being up to date (caution: it isn't yet up * to date, that will happen in TkBTreeAdjustPixelHeight just below). */ TkBTreeLinePixelEpoch(textPtr, linePtr) = textPtr->dInfoPtr->lineMetricUpdateEpoch; if (TkBTreeLinePixelCount(textPtr, linePtr) != pixelHeight) { changed = 1; } if (mergedLines > 0) { int i = mergedLines; TkTextLine *mergedLinePtr; /* * Loop over all merged logical lines, marking them up to date * (again, the pixel count setting will actually happen in * TkBTreeAdjustPixelHeight). */ mergedLinePtr = linePtr; while (i-- > 0) { mergedLinePtr = TkBTreeNextLine(textPtr, mergedLinePtr); TkBTreeLinePixelEpoch(textPtr, mergedLinePtr) = textPtr->dInfoPtr->lineMetricUpdateEpoch; if (TkBTreeLinePixelCount(textPtr, mergedLinePtr) != 0) { changed = 1; } } } if (!changed) { /* * If there's nothing to change, then we can already return. */ return displayLines; } } /* * We set the line's height, but the return value is now the height of the * entire widget, which may be used just below for reporting/debugging * purposes. */ pixelHeight = TkBTreeAdjustPixelHeight(textPtr, linePtr, pixelHeight, mergedLines); if (tkTextDebug) { char buffer[2 * TCL_INTEGER_SPACE + 1]; if (TkBTreeNextLine(textPtr, linePtr) == NULL) { Tcl_Panic("Mustn't ever update line height of last artificial line"); } sprintf(buffer, "%d %d", TkBTreeLinesTo(textPtr,linePtr), pixelHeight); LOG("tk_textNumPixels", buffer); } if (textPtr->dInfoPtr->scrollbarTimer == NULL) { textPtr->refCount++; textPtr->dInfoPtr->scrollbarTimer = Tcl_CreateTimerHandler(200, AsyncUpdateYScrollbar, (ClientData) textPtr); } return displayLines; } /* *---------------------------------------------------------------------- * * DisplayText -- * * This function is invoked as a when-idle handler to update the display. * It only redisplays the parts of the text widget that are out of date. * * Results: * None. * * Side effects: * Information is redrawn on the screen. * *---------------------------------------------------------------------- */ #ifdef MAC_OSX_TK static void RedisplayText( ClientData clientData ) { register TkText *textPtr = (TkText *) clientData; TextDInfo *dInfoPtr = textPtr->dInfoPtr; TkRegion damageRegion; XRectangle rectangle; if (dInfoPtr == NULL) { return; } damageRegion = TkCreateRegion(); rectangle.x = 0; rectangle.y = 0; rectangle.width = dInfoPtr->maxX; rectangle.height = dInfoPtr->maxY; TkUnionRectWithRegion(&rectangle, damageRegion, damageRegion); TextInvalidateRegion(textPtr, damageRegion); DisplayText(clientData); } #endif static void DisplayText( ClientData clientData) /* Information about widget. */ { register TkText *textPtr = (TkText *) clientData; TextDInfo *dInfoPtr = textPtr->dInfoPtr; register DLine *dlPtr; DLine *prevPtr; Pixmap pixmap; int maxHeight, borders; int bottomY = 0; /* Initialization needed only to stop compiler * warnings. */ Tcl_Interp *interp; #ifdef MAC_OSX_TK Tcl_TimerToken macRefreshTimer = NULL; #endif if ((textPtr->tkwin == NULL) || (textPtr->flags & DESTROYED)) { /* * The widget has been deleted. Don't do anything. */ return; } interp = textPtr->interp; Tcl_Preserve((ClientData) interp); if (tkTextDebug) { Tcl_SetVar2(interp, "tk_textRelayout", NULL, "", TCL_GLOBAL_ONLY); } if ((textPtr->tkwin == NULL) || (textPtr->flags & DESTROYED)) { /* * The widget has been deleted. Don't do anything. */ goto end; } if (!Tk_IsMapped(textPtr->tkwin) || (dInfoPtr->maxX <= dInfoPtr->x) || (dInfoPtr->maxY <= dInfoPtr->y)) { UpdateDisplayInfo(textPtr); dInfoPtr->flags &= ~REDRAW_PENDING; goto doScrollbars; } numRedisplays++; if (tkTextDebug) { Tcl_SetVar2(interp, "tk_textRedraw", NULL, "", TCL_GLOBAL_ONLY); } if ((textPtr->tkwin == NULL) || (textPtr->flags & DESTROYED)) { /* * The widget has been deleted. Don't do anything. */ goto end; } /* * Choose a new current item if that is needed (this could cause event * handlers to be invoked, hence the preserve/release calls and the loop, * since the handlers could conceivably necessitate yet another current * item calculation). The tkwin check is because the whole window could go * away in the Tcl_Release call. */ while (dInfoPtr->flags & REPICK_NEEDED) { textPtr->refCount++; dInfoPtr->flags &= ~REPICK_NEEDED; TkTextPickCurrent(textPtr, &textPtr->pickEvent); if (--textPtr->refCount == 0) { ckfree((char *) textPtr); goto end; } if ((textPtr->tkwin == NULL) || (textPtr->flags & DESTROYED)) { goto end; } } /* * First recompute what's supposed to be displayed. */ UpdateDisplayInfo(textPtr); dInfoPtr->dLinesInvalidated = 0; /* * See if it's possible to bring some parts of the screen up-to-date by * scrolling (copying from other parts of the screen). We have to be * particularly careful with the top and bottom lines of the display, * since these may only be partially visible and therefore not helpful for * some scrolling purposes. */ for (dlPtr = dInfoPtr->dLinePtr; dlPtr != NULL; dlPtr = dlPtr->nextPtr) { register DLine *dlPtr2; int offset, height, y, oldY; TkRegion damageRgn; /* * These tests are, in order: * * 1. If the line is already marked as invalid * 2. If the line hasn't moved * 3. If the line overlaps the bottom of the window and we are * scrolling up. * 4. If the line overlaps the top of the window and we are scrolling * down. * * If any of these tests are true, then we can't scroll this line's * part of the display. * * Note that even if tests 3 or 4 aren't true, we may be able to * scroll the line, but we still need to be sure to call embedded * window display procs on top and bottom lines if they have any * portion non-visible (see below). */ if ((dlPtr->flags & OLD_Y_INVALID) || (dlPtr->y == dlPtr->oldY) || (((dlPtr->oldY + dlPtr->height) > dInfoPtr->maxY) && (dlPtr->y < dlPtr->oldY)) || ((dlPtr->oldY < dInfoPtr->y) && (dlPtr->y > dlPtr->oldY))) { continue; } /* * This line is already drawn somewhere in the window so it only needs * to be copied to its new location. See if there's a group of lines * that can all be copied together. */ offset = dlPtr->y - dlPtr->oldY; height = dlPtr->height; y = dlPtr->y; for (dlPtr2 = dlPtr->nextPtr; dlPtr2 != NULL; dlPtr2 = dlPtr2->nextPtr) { if ((dlPtr2->flags & OLD_Y_INVALID) || ((dlPtr2->oldY + offset) != dlPtr2->y) || ((dlPtr2->oldY + dlPtr2->height) > dInfoPtr->maxY)) { break; } height += dlPtr2->height; } /* * Reduce the height of the area being copied if necessary to avoid * overwriting the border area. */ if ((y + height) > dInfoPtr->maxY) { height = dInfoPtr->maxY -y; } oldY = dlPtr->oldY; if (y < dInfoPtr->y) { /* * Adjust if the area being copied is going to overwrite the top * border of the window (so the top line is only half onscreen). */ int y_off = dInfoPtr->y - dlPtr->y; height -= y_off; oldY += y_off; y = dInfoPtr->y; } /* * Update the lines we are going to scroll to show that they have been * copied. */ while (1) { /* * The DLine already has OLD_Y_INVALID cleared. */ dlPtr->oldY = dlPtr->y; if (dlPtr->nextPtr == dlPtr2) { break; } dlPtr = dlPtr->nextPtr; } /* * Scan through the lines following the copied ones to see if we are * going to overwrite them with the copy operation. If so, mark them * for redisplay. */ for ( ; dlPtr2 != NULL; dlPtr2 = dlPtr2->nextPtr) { if ((!(dlPtr2->flags & OLD_Y_INVALID)) && ((dlPtr2->oldY + dlPtr2->height) > y) && (dlPtr2->oldY < (y + height))) { dlPtr2->flags |= OLD_Y_INVALID; } } /* * Now scroll the lines. This may generate damage which we handle by * calling TextInvalidateRegion to mark the display blocks as stale. */ damageRgn = TkCreateRegion(); if (TkScrollWindow(textPtr->tkwin, dInfoPtr->scrollGC, dInfoPtr->x, oldY, dInfoPtr->maxX-dInfoPtr->x, height, 0, y-oldY, damageRgn)) { TextInvalidateRegion(textPtr, damageRgn); #ifdef MAC_OSX_TK /* * On OS X large scrolls sometimes leave garbage on the screen. * This attempts to clean it up by redisplaying the Text window * after 200 milliseconds. */ if ( abs(y-oldY) > 14 ) { Tcl_DeleteTimerHandler(macRefreshTimer); macRefreshTimer = Tcl_CreateTimerHandler(200, RedisplayText, clientData); } #endif } numCopies++; TkDestroyRegion(damageRgn); } /* * Clear the REDRAW_PENDING flag here. This is actually pretty tricky. We * want to wait until *after* doing the scrolling, since that could * generate more areas to redraw and don't want to reschedule a redisplay * for them. On the other hand, we can't wait until after all the * redisplaying, because the act of redisplaying could actually generate * more redisplays (e.g. in the case of a nested window with event * bindings triggered by redisplay). */ dInfoPtr->flags &= ~REDRAW_PENDING; /* * Redraw the borders if that's needed. */ if (dInfoPtr->flags & REDRAW_BORDERS) { if (tkTextDebug) { LOG("tk_textRedraw", "borders"); } if (textPtr->tkwin == NULL) { /* * The widget has been deleted. Don't do anything. */ goto end; } Tk_Draw3DRectangle(textPtr->tkwin, Tk_WindowId(textPtr->tkwin), textPtr->border, textPtr->highlightWidth, textPtr->highlightWidth, Tk_Width(textPtr->tkwin) - 2*textPtr->highlightWidth, Tk_Height(textPtr->tkwin) - 2*textPtr->highlightWidth, textPtr->borderWidth, textPtr->relief); if (textPtr->highlightWidth != 0) { GC fgGC, bgGC; bgGC = Tk_GCForColor(textPtr->highlightBgColorPtr, Tk_WindowId(textPtr->tkwin)); if (textPtr->flags & GOT_FOCUS) { fgGC = Tk_GCForColor(textPtr->highlightColorPtr, Tk_WindowId(textPtr->tkwin)); TkpDrawHighlightBorder(textPtr->tkwin, fgGC, bgGC, textPtr->highlightWidth, Tk_WindowId(textPtr->tkwin)); } else { TkpDrawHighlightBorder(textPtr->tkwin, bgGC, bgGC, textPtr->highlightWidth, Tk_WindowId(textPtr->tkwin)); } } borders = textPtr->borderWidth + textPtr->highlightWidth; if (textPtr->padY > 0) { Tk_Fill3DRectangle(textPtr->tkwin, Tk_WindowId(textPtr->tkwin), textPtr->border, borders, borders, Tk_Width(textPtr->tkwin) - 2*borders, textPtr->padY, 0, TK_RELIEF_FLAT); Tk_Fill3DRectangle(textPtr->tkwin, Tk_WindowId(textPtr->tkwin), textPtr->border, borders, Tk_Height(textPtr->tkwin) - borders - textPtr->padY, Tk_Width(textPtr->tkwin) - 2*borders, textPtr->padY, 0, TK_RELIEF_FLAT); } if (textPtr->padX > 0) { Tk_Fill3DRectangle(textPtr->tkwin, Tk_WindowId(textPtr->tkwin), textPtr->border, borders, borders + textPtr->padY, textPtr->padX, Tk_Height(textPtr->tkwin) - 2*borders -2*textPtr->padY, 0, TK_RELIEF_FLAT); Tk_Fill3DRectangle(textPtr->tkwin, Tk_WindowId(textPtr->tkwin), textPtr->border, Tk_Width(textPtr->tkwin) - borders - textPtr->padX, borders + textPtr->padY, textPtr->padX, Tk_Height(textPtr->tkwin) - 2*borders -2*textPtr->padY, 0, TK_RELIEF_FLAT); } dInfoPtr->flags &= ~REDRAW_BORDERS; } /* * Now we have to redraw the lines that couldn't be updated by scrolling. * First, compute the height of the largest line and allocate an off- * screen pixmap to use for double-buffered displays. */ maxHeight = -1; for (dlPtr = dInfoPtr->dLinePtr; dlPtr != NULL; dlPtr = dlPtr->nextPtr) { if ((dlPtr->height > maxHeight) && ((dlPtr->flags&OLD_Y_INVALID) || (dlPtr->oldY != dlPtr->y))) { maxHeight = dlPtr->height; } bottomY = dlPtr->y + dlPtr->height; } /* * There used to be a line here which restricted 'maxHeight' to be no * larger than 'dInfoPtr->maxY', but this is incorrect for the case where * individual lines may be taller than the widget _and_ we have smooth * scrolling. What we can do is restrict maxHeight to be no larger than * 'dInfoPtr->maxY + dInfoPtr->topPixelOffset'. */ if (maxHeight > (dInfoPtr->maxY + dInfoPtr->topPixelOffset)) { maxHeight = (dInfoPtr->maxY + dInfoPtr->topPixelOffset); } if (maxHeight > 0) { #ifndef TK_NO_DOUBLE_BUFFERING pixmap = Tk_GetPixmap(Tk_Display(textPtr->tkwin), Tk_WindowId(textPtr->tkwin), Tk_Width(textPtr->tkwin), maxHeight, Tk_Depth(textPtr->tkwin)); #else pixmap = Tk_WindowId(textPtr->tkwin); #endif /* TK_NO_DOUBLE_BUFFERING */ for (prevPtr = NULL, dlPtr = textPtr->dInfoPtr->dLinePtr; (dlPtr != NULL) && (dlPtr->y < dInfoPtr->maxY); prevPtr = dlPtr, dlPtr = dlPtr->nextPtr) { if (dlPtr->chunkPtr == NULL) { continue; } if ((dlPtr->flags & OLD_Y_INVALID) || dlPtr->oldY != dlPtr->y) { if (tkTextDebug) { char string[TK_POS_CHARS]; TkTextPrintIndex(textPtr, &dlPtr->index, string); LOG("tk_textRedraw", string); } DisplayDLine(textPtr, dlPtr, prevPtr, pixmap); if (dInfoPtr->dLinesInvalidated) { #ifndef TK_NO_DOUBLE_BUFFERING Tk_FreePixmap(Tk_Display(textPtr->tkwin), pixmap); #endif /* TK_NO_DOUBLE_BUFFERING */ return; } dlPtr->oldY = dlPtr->y; dlPtr->flags &= ~(NEW_LAYOUT | OLD_Y_INVALID); } else if (dlPtr->chunkPtr != NULL && ((dlPtr->y < 0) || (dlPtr->y + dlPtr->height > dInfoPtr->maxY))) { register TkTextDispChunk *chunkPtr; /* * It's the first or last DLine which are also overlapping the * top or bottom of the window, but we decided above it wasn't * necessary to display them (we were able to update them by * scrolling). This is fine, except that if the lines contain * any embedded windows, we must still call the display proc * on them because they might need to be unmapped or they * might need to be moved to reflect their new position. * Otherwise, everything else moves, but the embedded window * doesn't! * * So, we loop through all the chunks, calling the display * proc of embedded windows only. */ for (chunkPtr = dlPtr->chunkPtr; (chunkPtr != NULL); chunkPtr = chunkPtr->nextPtr) { int x; if (chunkPtr->displayProc != TkTextEmbWinDisplayProc) { continue; } x = chunkPtr->x + dInfoPtr->x - dInfoPtr->curXPixelOffset; if ((x + chunkPtr->width <= 0) || (x >= dInfoPtr->maxX)) { /* * Note: we have to call the displayProc even for * chunks that are off-screen. This is needed, for * example, so that embedded windows can be unmapped * in this case. Display the chunk at a coordinate * that can be clearly identified by the displayProc * as being off-screen to the left (the displayProc * may not be able to tell if something is off to the * right). */ x = -chunkPtr->width; } TkTextEmbWinDisplayProc(textPtr, chunkPtr, x, dlPtr->spaceAbove, dlPtr->height-dlPtr->spaceAbove-dlPtr->spaceBelow, dlPtr->baseline - dlPtr->spaceAbove, NULL, (Drawable) None, dlPtr->y + dlPtr->spaceAbove); } } } #ifndef TK_NO_DOUBLE_BUFFERING Tk_FreePixmap(Tk_Display(textPtr->tkwin), pixmap); #endif /* TK_NO_DOUBLE_BUFFERING */ } /* * See if we need to refresh the part of the window below the last line of * text (if there is any such area). Refresh the padding area on the left * too, since the insertion cursor might have been displayed there * previously). */ if (dInfoPtr->topOfEof > dInfoPtr->maxY) { dInfoPtr->topOfEof = dInfoPtr->maxY; } if (bottomY < dInfoPtr->topOfEof) { if (tkTextDebug) { LOG("tk_textRedraw", "eof"); } if ((textPtr->tkwin == NULL) || (textPtr->flags & DESTROYED)) { /* * The widget has been deleted. Don't do anything. */ goto end; } Tk_Fill3DRectangle(textPtr->tkwin, Tk_WindowId(textPtr->tkwin), textPtr->border, dInfoPtr->x - textPtr->padX, bottomY, dInfoPtr->maxX - (dInfoPtr->x - textPtr->padX), dInfoPtr->topOfEof-bottomY, 0, TK_RELIEF_FLAT); } dInfoPtr->topOfEof = bottomY; /* * Update the vertical scrollbar, if there is one. Note: it's important to * clear REDRAW_PENDING here, just in case the scroll function does * something that requires redisplay. */ doScrollbars: if (textPtr->flags & UPDATE_SCROLLBARS) { textPtr->flags &= ~UPDATE_SCROLLBARS; if (textPtr->yScrollCmd != NULL) { GetYView(textPtr->interp, textPtr, 1); } if ((textPtr->tkwin == NULL) || (textPtr->flags & DESTROYED)) { /* * The widget has been deleted. Don't do anything. */ goto end; } /* * Update the horizontal scrollbar, if any. */ if (textPtr->xScrollCmd != NULL) { GetXView(textPtr->interp, textPtr, 1); } } end: Tcl_Release((ClientData) interp); } /* *---------------------------------------------------------------------- * * TkTextEventuallyRepick -- * * This function is invoked whenever something happens that could change * the current character or the tags associated with it. * * Results: * None. * * Side effects: * A repick is scheduled as an idle handler. * *---------------------------------------------------------------------- */ void TkTextEventuallyRepick( TkText *textPtr) /* Widget record for text widget. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; dInfoPtr->flags |= REPICK_NEEDED; if (!(dInfoPtr->flags & REDRAW_PENDING)) { dInfoPtr->flags |= REDRAW_PENDING; Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } } /* *---------------------------------------------------------------------- * * TkTextRedrawRegion -- * * This function is invoked to schedule a redisplay for a given region of * a text widget. The redisplay itself may not occur immediately: it's * scheduled as a when-idle handler. * * Results: * None. * * Side effects: * Information will eventually be redrawn on the screen. * *---------------------------------------------------------------------- */ void TkTextRedrawRegion( TkText *textPtr, /* Widget record for text widget. */ int x, int y, /* Coordinates of upper-left corner of area to * be redrawn, in pixels relative to textPtr's * window. */ int width, int height) /* Width and height of area to be redrawn. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; TkRegion damageRgn = TkCreateRegion(); XRectangle rect; rect.x = x; rect.y = y; rect.width = width; rect.height = height; TkUnionRectWithRegion(&rect, damageRgn, damageRgn); TextInvalidateRegion(textPtr, damageRgn); if (!(dInfoPtr->flags & REDRAW_PENDING)) { dInfoPtr->flags |= REDRAW_PENDING; Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } TkDestroyRegion(damageRgn); } /* *---------------------------------------------------------------------- * * TextInvalidateRegion -- * * Mark a region of text as invalid. * * Results: * None. * * Side effects: * Updates the display information for the text widget. * *---------------------------------------------------------------------- */ static void TextInvalidateRegion( TkText *textPtr, /* Widget record for text widget. */ TkRegion region) /* Region of area to redraw. */ { register DLine *dlPtr; TextDInfo *dInfoPtr = textPtr->dInfoPtr; int maxY, inset; XRectangle rect; /* * Find all lines that overlap the given region and mark them for * redisplay. */ TkClipBox(region, &rect); maxY = rect.y + rect.height; for (dlPtr = dInfoPtr->dLinePtr; dlPtr != NULL; dlPtr = dlPtr->nextPtr) { if ((!(dlPtr->flags & OLD_Y_INVALID)) && (TkRectInRegion(region, rect.x, dlPtr->y, rect.width, (unsigned int) dlPtr->height) != RectangleOut)) { dlPtr->flags |= OLD_Y_INVALID; } } if (dInfoPtr->topOfEof < maxY) { dInfoPtr->topOfEof = maxY; } /* * Schedule the redisplay operation if there isn't one already scheduled. */ inset = textPtr->borderWidth + textPtr->highlightWidth; if ((rect.x < (inset + textPtr->padX)) || (rect.y < (inset + textPtr->padY)) || ((int) (rect.x + rect.width) > (Tk_Width(textPtr->tkwin) - inset - textPtr->padX)) || (maxY > (Tk_Height(textPtr->tkwin) - inset - textPtr->padY))) { dInfoPtr->flags |= REDRAW_BORDERS; } } /* *---------------------------------------------------------------------- * * TkTextChanged, TextChanged -- * * This function is invoked when info in a text widget is about to be * modified in a way that changes how it is displayed (e.g. characters * were inserted or deleted, or tag information was changed). This * function must be called *before* a change is made, so that indexes in * the display information are still valid. * * Note: if the range of indices may change geometry as well as simply * requiring redisplay, then the caller should also call * TkTextInvalidateLineMetrics. * * Results: * None. * * Side effects: * The range of character between index1Ptr (inclusive) and index2Ptr * (exclusive) will be redisplayed at some point in the future (the * actual redisplay is scheduled as a when-idle handler). * *---------------------------------------------------------------------- */ void TkTextChanged( TkSharedText *sharedTextPtr,/* Shared widget section, or NULL. */ TkText *textPtr, /* Widget record for text widget, or NULL. */ CONST TkTextIndex*index1Ptr,/* Index of first character to redisplay. */ CONST TkTextIndex*index2Ptr)/* Index of character just after last one to * redisplay. */ { if (sharedTextPtr == NULL) { TextChanged(textPtr, index1Ptr, index2Ptr); } else { textPtr = sharedTextPtr->peers; while (textPtr != NULL) { TextChanged(textPtr, index1Ptr, index2Ptr); textPtr = textPtr->next; } } } static void TextChanged( TkText *textPtr, /* Widget record for text widget, or NULL. */ CONST TkTextIndex*index1Ptr,/* Index of first character to redisplay. */ CONST TkTextIndex*index2Ptr)/* Index of character just after last one to * redisplay. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; DLine *firstPtr, *lastPtr; TkTextIndex rounded; TkTextLine *linePtr; int notBegin; /* * Schedule both a redisplay and a recomputation of display information. * It's done here rather than the end of the function for two reasons: * * 1. If there are no display lines to update we'll want to return * immediately, well before the end of the function. * 2. It's important to arrange for the redisplay BEFORE calling * FreeDLines. The reason for this is subtle and has to do with * embedded windows. The chunk delete function for an embedded window * will schedule an idle handler to unmap the window. However, we want * the idle handler for redisplay to be called first, so that it can * put the embedded window back on the screen again (if appropriate). * This will prevent the window from ever being unmapped, and thereby * avoid flashing. */ if (!(dInfoPtr->flags & REDRAW_PENDING)) { Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } dInfoPtr->flags |= REDRAW_PENDING|DINFO_OUT_OF_DATE|REPICK_NEEDED; /* * Find the DLines corresponding to index1Ptr and index2Ptr. There is one * tricky thing here, which is that we have to relayout in units of whole * text lines: This is necessary because the indices stored in the display * lines will no longer be valid. It's also needed because any edit could * change the way lines wrap. * To relayout in units of whole text (logical) lines, round index1Ptr * back to the beginning of its text line (or, if this line start is * elided, to the beginning of the text line that starts the display line * it is included in), and include all the display lines after index2Ptr, * up to the end of its text line (or, if this line end is elided, up to * the end of the first non elided text line after this line end). */ rounded = *index1Ptr; rounded.byteIndex = 0; notBegin = 0; while (!IsStartOfNotMergedLine(textPtr, &rounded) && notBegin) { notBegin = !TkTextIndexBackBytes(textPtr, &rounded, 1, &rounded); rounded.byteIndex = 0; } /* * 'rounded' now points to the start of a display line as well as the * real (non elided) start of a logical line, and this index is the * closest before index1Ptr. */ firstPtr = FindDLine(textPtr, dInfoPtr->dLinePtr, &rounded); if (firstPtr == NULL) { /* * index1Ptr pertains to no display line, i.e this index is after * the last display line. Since index2Ptr is after index1Ptr, there * is no display line to free/redisplay and we can return early. */ return; } rounded = *index2Ptr; linePtr = index2Ptr->linePtr; do { linePtr = TkBTreeNextLine(textPtr, linePtr); if (linePtr == NULL) { break; } rounded.linePtr = linePtr; rounded.byteIndex = 0; } while (!IsStartOfNotMergedLine(textPtr, &rounded)); if (linePtr == NULL) { lastPtr = NULL; } else { /* * 'rounded' now points to the start of a display line as well as the * start of a logical line not merged with its previous line, and * this index is the closest after index2Ptr. */ lastPtr = FindDLine(textPtr, dInfoPtr->dLinePtr, &rounded); /* * At least one display line is supposed to change. This makes the * redisplay OK in case the display line we expect to get here was * unlinked by a previous call to TkTextChanged and the text widget * did not update before reaching this point. This happens for * instance when moving the cursor up one line. * Note that lastPtr != NULL here, otherwise we would have returned * earlier when we tested for firstPtr being NULL. */ if (lastPtr == firstPtr) { lastPtr = lastPtr->nextPtr; } } /* * Delete all the DLines from firstPtr up to but not including lastPtr. */ FreeDLines(textPtr, firstPtr, lastPtr, DLINE_UNLINK); } /* *---------------------------------------------------------------------- * * TkTextRedrawTag, TextRedrawTag -- * * This function is invoked to request a redraw of all characters in a * given range that have a particular tag on or off. It's called, for * example, when tag options change. * * Results: * None. * * Side effects: * Information on the screen may be redrawn, and the layout of the screen * may change. * *---------------------------------------------------------------------- */ void TkTextRedrawTag( TkSharedText *sharedTextPtr,/* Shared widget section, or NULL. */ TkText *textPtr, /* Widget record for text widget. */ TkTextIndex *index1Ptr, /* First character in range to consider for * redisplay. NULL means start at beginning of * text. */ TkTextIndex *index2Ptr, /* Character just after last one to consider * for redisplay. NULL means process all the * characters in the text. */ TkTextTag *tagPtr, /* Information about tag. */ int withTag) /* 1 means redraw characters that have the * tag, 0 means redraw those without. */ { if (sharedTextPtr == NULL) { TextRedrawTag(textPtr, index1Ptr, index2Ptr, tagPtr, withTag); } else { textPtr = sharedTextPtr->peers; while (textPtr != NULL) { TextRedrawTag(textPtr, index1Ptr, index2Ptr, tagPtr, withTag); textPtr = textPtr->next; } } } static void TextRedrawTag( TkText *textPtr, /* Widget record for text widget. */ TkTextIndex *index1Ptr, /* First character in range to consider for * redisplay. NULL means start at beginning of * text. */ TkTextIndex *index2Ptr, /* Character just after last one to consider * for redisplay. NULL means process all the * characters in the text. */ TkTextTag *tagPtr, /* Information about tag. */ int withTag) /* 1 means redraw characters that have the * tag, 0 means redraw those without. */ { register DLine *dlPtr; DLine *endPtr; int tagOn; TkTextSearch search; TextDInfo *dInfoPtr = textPtr->dInfoPtr; TkTextIndex *curIndexPtr; TkTextIndex endOfText, *endIndexPtr; /* * Invalidate the pixel calculation of all lines in the given range. This * may be a bit over-aggressive, so we could consider more subtle * techniques here in the future. In particular, when we create a tag for * the first time with '.t tag configure foo -font "Arial 20"', say, even * though that obviously can't apply to anything at all (the tag didn't * exist a moment ago), we invalidate every single line in the widget. */ if (tagPtr->affectsDisplayGeometry) { TkTextLine *startLine, *endLine; int lineCount; if (index2Ptr == NULL) { endLine = NULL; lineCount = TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr); } else { endLine = index2Ptr->linePtr; lineCount = TkBTreeLinesTo(textPtr, endLine); } if (index1Ptr == NULL) { startLine = NULL; } else { startLine = index1Ptr->linePtr; lineCount -= TkBTreeLinesTo(textPtr, startLine); } TkTextInvalidateLineMetrics(NULL, textPtr, startLine, lineCount, TK_TEXT_INVALIDATE_ONLY); } /* * Round up the starting position if it's before the first line visible on * the screen (we only care about what's on the screen). */ dlPtr = dInfoPtr->dLinePtr; if (dlPtr == NULL) { return; } if ((index1Ptr == NULL) || (TkTextIndexCmp(&dlPtr->index, index1Ptr)>0)) { index1Ptr = &dlPtr->index; } /* * Set the stopping position if it wasn't specified. */ if (index2Ptr == NULL) { int lastLine = TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr); index2Ptr = TkTextMakeByteIndex(textPtr->sharedTextPtr->tree, textPtr, lastLine, 0, &endOfText); } /* * Initialize a search through all transitions on the tag, starting with * the first transition where the tag's current state is different from * what it will eventually be. */ TkBTreeStartSearch(index1Ptr, index2Ptr, tagPtr, &search); /* * Make our own curIndex because at this point search.curIndex may not * equal index1Ptr->curIndex in the case the first tag toggle comes after * index1Ptr (See the use of FindTagStart in TkBTreeStartSearch). */ curIndexPtr = index1Ptr; tagOn = TkBTreeCharTagged(index1Ptr, tagPtr); if (tagOn != withTag) { if (!TkBTreeNextTag(&search)) { return; } curIndexPtr = &search.curIndex; } /* * Schedule a redisplay and layout recalculation if they aren't already * pending. This has to be done before calling FreeDLines, for the reason * given in TkTextChanged. */ if (!(dInfoPtr->flags & REDRAW_PENDING)) { Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } dInfoPtr->flags |= REDRAW_PENDING|DINFO_OUT_OF_DATE|REPICK_NEEDED; /* * Each loop through the loop below is for one range of characters where * the tag's current state is different than its eventual state. At the * top of the loop, search contains information about the first character * in the range. */ while (1) { /* * Find the first DLine structure in the range. Note: if the desired * character isn't the first in its text line, then look for the * character just before it instead. This is needed to handle the case * where the first character of a wrapped display line just got * smaller, so that it now fits on the line before: need to relayout * the line containing the previous character. */ if (IsStartOfNotMergedLine(textPtr, curIndexPtr)) { dlPtr = FindDLine(textPtr, dlPtr, curIndexPtr); } else { TkTextIndex tmp = *curIndexPtr; TkTextIndexBackBytes(textPtr, &tmp, 1, &tmp); dlPtr = FindDLine(textPtr, dlPtr, &tmp); } if (dlPtr == NULL) { break; } /* * Find the first DLine structure that's past the end of the range. */ if (!TkBTreeNextTag(&search)) { endIndexPtr = index2Ptr; } else { curIndexPtr = &search.curIndex; endIndexPtr = curIndexPtr; } endPtr = FindDLine(textPtr, dlPtr, endIndexPtr); if ((endPtr != NULL) && (TkTextIndexCmp(&endPtr->index,endIndexPtr) < 0)) { endPtr = endPtr->nextPtr; } /* * Delete all of the display lines in the range, so that they'll be * re-layed out and redrawn. */ FreeDLines(textPtr, dlPtr, endPtr, DLINE_UNLINK); dlPtr = endPtr; /* * Find the first text line in the next range. */ if (!TkBTreeNextTag(&search)) { break; } } } /* *---------------------------------------------------------------------- * * TkTextRelayoutWindow -- * * This function is called when something has happened that invalidates * the whole layout of characters on the screen, such as a change in a * configuration option for the overall text widget or a change in the * window size. It causes all display information to be recomputed and * the window to be redrawn. * * Results: * None. * * Side effects: * All the display information will be recomputed for the window and the * window will be redrawn. * *---------------------------------------------------------------------- */ void TkTextRelayoutWindow( TkText *textPtr, /* Widget record for text widget. */ int mask) /* OR'd collection of bits showing what has * changed. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; GC newGC; XGCValues gcValues; /* * Schedule the window redisplay. See TkTextChanged for the reason why * this has to be done before any calls to FreeDLines. */ if (!(dInfoPtr->flags & REDRAW_PENDING)) { Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } dInfoPtr->flags |= REDRAW_PENDING|REDRAW_BORDERS|DINFO_OUT_OF_DATE |REPICK_NEEDED; /* * (Re-)create the graphics context for drawing the traversal highlight. */ gcValues.graphics_exposures = False; newGC = Tk_GetGC(textPtr->tkwin, GCGraphicsExposures, &gcValues); if (dInfoPtr->copyGC != None) { Tk_FreeGC(textPtr->display, dInfoPtr->copyGC); } dInfoPtr->copyGC = newGC; /* * Throw away all the current layout information. */ FreeDLines(textPtr, dInfoPtr->dLinePtr, NULL, DLINE_UNLINK); dInfoPtr->dLinePtr = NULL; /* * Recompute some overall things for the layout. Even if the window gets * very small, pretend that there's at least one pixel of drawing space in * it. */ if (textPtr->highlightWidth < 0) { textPtr->highlightWidth = 0; } dInfoPtr->x = textPtr->highlightWidth + textPtr->borderWidth + textPtr->padX; dInfoPtr->y = textPtr->highlightWidth + textPtr->borderWidth + textPtr->padY; dInfoPtr->maxX = Tk_Width(textPtr->tkwin) - textPtr->highlightWidth - textPtr->borderWidth - textPtr->padX; if (dInfoPtr->maxX <= dInfoPtr->x) { dInfoPtr->maxX = dInfoPtr->x + 1; } /* * This is the only place where dInfoPtr->maxY is set. */ dInfoPtr->maxY = Tk_Height(textPtr->tkwin) - textPtr->highlightWidth - textPtr->borderWidth - textPtr->padY; if (dInfoPtr->maxY <= dInfoPtr->y) { dInfoPtr->maxY = dInfoPtr->y + 1; } dInfoPtr->topOfEof = dInfoPtr->maxY; /* * If the upper-left character isn't the first in a line, recompute it. * This is necessary because a change in the window's size or options * could change the way lines wrap. */ if (!IsStartOfNotMergedLine(textPtr, &textPtr->topIndex)) { TkTextFindDisplayLineEnd(textPtr, &textPtr->topIndex, 0, NULL); } /* * Invalidate cached scrollbar positions, so that scrollbars sliders will * be udpated. */ dInfoPtr->xScrollFirst = dInfoPtr->xScrollLast = -1; dInfoPtr->yScrollFirst = dInfoPtr->yScrollLast = -1; if (mask & TK_TEXT_LINE_GEOMETRY) { /* * Set up line metric recalculation. * * Avoid the special zero value, since that is used to mark individual * lines as being out of date. */ if ((++dInfoPtr->lineMetricUpdateEpoch) == 0) { dInfoPtr->lineMetricUpdateEpoch++; } dInfoPtr->currentMetricUpdateLine = -1; /* * Also cancel any partial line-height calculations (for long-wrapped * lines) in progress. */ dInfoPtr->metricEpoch = -1; if (dInfoPtr->lineUpdateTimer == NULL) { textPtr->refCount++; dInfoPtr->lineUpdateTimer = Tcl_CreateTimerHandler(1, AsyncUpdateLineMetrics, (ClientData) textPtr); } } } /* *---------------------------------------------------------------------- * * TkTextSetYView -- * * This function is called to specify what lines are to be displayed in a * text widget. * * Results: * None. * * Side effects: * The display will (eventually) be updated so that the position given by * "indexPtr" is visible on the screen at the position determined by * "pickPlace". * *---------------------------------------------------------------------- */ void TkTextSetYView( TkText *textPtr, /* Widget record for text widget. */ TkTextIndex *indexPtr, /* Position that is to appear somewhere in the * view. */ int pickPlace) /* 0 means the given index must appear exactly * at the top of the screen. TK_TEXT_PICKPLACE * (-1) means we get to pick where it appears: * minimize screen motion or else display line * at center of screen. TK_TEXT_NOPIXELADJUST * (-2) indicates to make the given index the * top line, but if it is already the top * line, don't nudge it up or down by a few * pixels just to make sure it is entirely * displayed. Positive numbers indicate the * number of pixels of the index's line which * are to be off the top of the screen. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; register DLine *dlPtr; int bottomY, close, lineIndex; TkTextIndex tmpIndex, rounded; int lineHeight; /* * If the specified position is the extra line at the end of the text, * round it back to the last real line. */ lineIndex = TkBTreeLinesTo(textPtr, indexPtr->linePtr); if (lineIndex == TkBTreeNumLines(indexPtr->tree, textPtr)) { TkTextIndexBackChars(textPtr, indexPtr, 1, &rounded, COUNT_INDICES); indexPtr = &rounded; } if (pickPlace == TK_TEXT_NOPIXELADJUST) { if (textPtr->topIndex.linePtr == indexPtr->linePtr && textPtr->topIndex.byteIndex == indexPtr->byteIndex) { pickPlace = dInfoPtr->topPixelOffset; } else { pickPlace = 0; } } if (pickPlace != TK_TEXT_PICKPLACE) { /* * The specified position must go at the top of the screen. Just leave * all the DLine's alone: we may be able to reuse some of the * information that's currently on the screen without redisplaying it * all. */ textPtr->topIndex = *indexPtr; if (!IsStartOfNotMergedLine(textPtr, indexPtr)) { TkTextFindDisplayLineEnd(textPtr, &textPtr->topIndex, 0, NULL); } dInfoPtr->newTopPixelOffset = pickPlace; goto scheduleUpdate; } /* * We have to pick where to display the index. First, bring the display * information up to date and see if the index will be completely visible * in the current screen configuration. If so then there's nothing to do. */ if (dInfoPtr->flags & DINFO_OUT_OF_DATE) { UpdateDisplayInfo(textPtr); } dlPtr = FindDLine(textPtr, dInfoPtr->dLinePtr, indexPtr); if (dlPtr != NULL) { if ((dlPtr->y + dlPtr->height) > dInfoPtr->maxY) { /* * Part of the line hangs off the bottom of the screen; pretend * the whole line is off-screen. */ dlPtr = NULL; } else { if (TkTextIndexCmp(&dlPtr->index, indexPtr) <= 0) { if (dInfoPtr->dLinePtr == dlPtr && dInfoPtr->topPixelOffset != 0) { /* * It is on the top line, but that line is hanging off the top * of the screen. Change the top overlap to zero and update. */ dInfoPtr->newTopPixelOffset = 0; goto scheduleUpdate; } return; } } } /* * The desired line isn't already on-screen. Figure out what it means to * be "close" to the top or bottom of the screen. Close means within 1/3 * of the screen height or within three lines, whichever is greater. * * If the line is not close, place it in the center of the window. */ tmpIndex = *indexPtr; TkTextFindDisplayLineEnd(textPtr, &tmpIndex, 0, NULL); lineHeight = CalculateDisplayLineHeight(textPtr, &tmpIndex, NULL, NULL); /* * It would be better if 'bottomY' were calculated using the actual height * of the given line, not 'textPtr->charHeight'. */ bottomY = (dInfoPtr->y + dInfoPtr->maxY + lineHeight)/2; close = (dInfoPtr->maxY - dInfoPtr->y)/3; if (close < 3*textPtr->charHeight) { close = 3*textPtr->charHeight; } if (dlPtr != NULL) { int overlap; /* * The desired line is above the top of screen. If it is "close" to * the top of the window then make it the top line on the screen. * MeasureUp counts from the bottom of the given index upwards, so we * add an extra half line to be sure we count far enough. */ MeasureUp(textPtr, &textPtr->topIndex, close + textPtr->charHeight/2, &tmpIndex, &overlap); if (TkTextIndexCmp(&tmpIndex, indexPtr) <= 0) { textPtr->topIndex = *indexPtr; TkTextFindDisplayLineEnd(textPtr, &textPtr->topIndex, 0, NULL); dInfoPtr->newTopPixelOffset = 0; goto scheduleUpdate; } } else { int overlap; /* * The desired line is below the bottom of the screen. If it is * "close" to the bottom of the screen then position it at the bottom * of the screen. */ MeasureUp(textPtr, indexPtr, close + lineHeight - textPtr->charHeight/2, &tmpIndex, &overlap); if (FindDLine(textPtr, dInfoPtr->dLinePtr, &tmpIndex) != NULL) { bottomY = dInfoPtr->maxY - dInfoPtr->y; } } /* * Our job now is to arrange the display so that indexPtr appears as low * on the screen as possible but with its bottom no lower than bottomY. * BottomY is the bottom of the window if the desired line is just below * the current screen, otherwise it is a half-line lower than the center * of the window. */ MeasureUp(textPtr, indexPtr, bottomY, &textPtr->topIndex, &dInfoPtr->newTopPixelOffset); scheduleUpdate: if (!(dInfoPtr->flags & REDRAW_PENDING)) { Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } dInfoPtr->flags |= REDRAW_PENDING|DINFO_OUT_OF_DATE|REPICK_NEEDED; } /* *-------------------------------------------------------------- * * TkTextMeasureDown -- * * Given one index, find the index of the first character on the highest * display line that would be displayed no more than "distance" pixels * below the top of the given index. * * Results: * The srcPtr is manipulated in place to reflect the new position. We * return the number of pixels by which 'distance' overlaps the srcPtr. * * Side effects: * None. * *-------------------------------------------------------------- */ int TkTextMeasureDown( TkText *textPtr, /* Text widget in which to measure. */ TkTextIndex *srcPtr, /* Index of character from which to start * measuring. */ int distance) /* Vertical distance in pixels measured from * the top pixel in srcPtr's logical line. */ { TkTextLine *lastLinePtr; DLine *dlPtr; TkTextIndex loop; lastLinePtr = TkBTreeFindLine(textPtr->sharedTextPtr->tree, textPtr, TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr)); do { dlPtr = LayoutDLine(textPtr, srcPtr); dlPtr->nextPtr = NULL; if (distance < dlPtr->height) { FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE_TEMP); break; } distance -= dlPtr->height; TkTextIndexForwBytes(textPtr, srcPtr, dlPtr->byteCount, &loop); FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE_TEMP); if (loop.linePtr == lastLinePtr) { break; } *srcPtr = loop; } while (distance > 0); return distance; } /* *-------------------------------------------------------------- * * MeasureUp -- * * Given one index, find the index of the first character on the highest * display line that would be displayed no more than "distance" pixels * above the given index. * * If this function is called with distance=0, it simply finds the first * index on the same display line as srcPtr. However, there is a another * function TkTextFindDisplayLineEnd designed just for that task which is * probably better to use. * * Results: * *dstPtr is filled in with the index of the first character on a * display line. The display line is found by measuring up "distance" * pixels above the pixel just below an imaginary display line that * contains srcPtr. If the display line that covers this coordinate * actually extends above the coordinate, then return any excess pixels * in *overlap, if that is non-NULL. * * Side effects: * None. * *-------------------------------------------------------------- */ static void MeasureUp( TkText *textPtr, /* Text widget in which to measure. */ CONST TkTextIndex *srcPtr, /* Index of character from which to start * measuring. */ int distance, /* Vertical distance in pixels measured from * the pixel just below the lowest one in * srcPtr's line. */ TkTextIndex *dstPtr, /* Index to fill in with result. */ int *overlap) /* Used to store how much of the final index * returned was not covered by 'distance'. */ { int lineNum; /* Number of current line. */ int bytesToCount; /* Maximum number of bytes to measure in * current line. */ TkTextIndex index; DLine *dlPtr, *lowestPtr; bytesToCount = srcPtr->byteIndex + 1; index.tree = srcPtr->tree; for (lineNum = TkBTreeLinesTo(textPtr, srcPtr->linePtr); lineNum >= 0; lineNum--) { /* * Layout an entire text line (potentially > 1 display line). * * For the first line, which contains srcPtr, only layout the part up * through srcPtr (bytesToCount is non-infinite to accomplish this). * Make a list of all the display lines in backwards order (the lowest * DLine on the screen is first in the list). */ index.linePtr = TkBTreeFindLine(srcPtr->tree, textPtr, lineNum); index.byteIndex = 0; TkTextFindDisplayLineEnd(textPtr, &index, 0, NULL); lineNum = TkBTreeLinesTo(textPtr, index.linePtr); lowestPtr = NULL; do { dlPtr = LayoutDLine(textPtr, &index); dlPtr->nextPtr = lowestPtr; lowestPtr = dlPtr; TkTextIndexForwBytes(textPtr, &index, dlPtr->byteCount, &index); bytesToCount -= dlPtr->byteCount; } while (bytesToCount>0 && index.linePtr==dlPtr->index.linePtr); /* * Scan through the display lines to see if we've covered enough * vertical distance. If so, save the starting index for the line at * the desired location. If distance was zero to start with then we * simply get the first index on the same display line as the original * index. */ for (dlPtr = lowestPtr; dlPtr != NULL; dlPtr = dlPtr->nextPtr) { distance -= dlPtr->height; if (distance <= 0) { *dstPtr = dlPtr->index; /* * dstPtr is the start of a display line that is or is not * the start of a logical line. If it is the start of a * logical line, we must check whether this line is merged * with the previous logical line, and if so we must adjust * dstPtr to the start of the display line since a display * line start needs to be returned. */ if (!IsStartOfNotMergedLine(textPtr, dstPtr)) { TkTextFindDisplayLineEnd(textPtr, dstPtr, 0, NULL); } if (overlap != NULL) { *overlap = -distance; } break; } } /* * Discard the display lines, then either return or prepare for the * next display line to lay out. */ FreeDLines(textPtr, lowestPtr, NULL, DLINE_FREE); if (distance <= 0) { return; } bytesToCount = INT_MAX; /* Consider all chars. in next line. */ } /* * Ran off the beginning of the text. Return the first character in the * text. */ TkTextMakeByteIndex(textPtr->sharedTextPtr->tree, textPtr, 0, 0, dstPtr); if (overlap != NULL) { *overlap = 0; } } /* *-------------------------------------------------------------- * * TkTextSeeCmd -- * * This function is invoked to process the "see" option for the widget * command for text widgets. See the user documentation for details on * what it does. * * Results: * A standard Tcl result. * * Side effects: * See the user documentation. * *-------------------------------------------------------------- */ int TkTextSeeCmd( TkText *textPtr, /* Information about text widget. */ Tcl_Interp *interp, /* Current interpreter. */ int objc, /* Number of arguments. */ Tcl_Obj *CONST objv[]) /* Argument objects. Someone else has already * parsed this command enough to know that * objv[1] is "see". */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; TkTextIndex index; int x, y, width, height, lineWidth, byteCount, oneThird, delta; DLine *dlPtr; TkTextDispChunk *chunkPtr; if (objc != 3) { Tcl_WrongNumArgs(interp, 2, objv, "index"); return TCL_ERROR; } if (TkTextGetObjIndex(interp, textPtr, objv[2], &index) != TCL_OK) { return TCL_ERROR; } /* * If the specified position is the extra line at the end of the text, * round it back to the last real line. */ if (TkBTreeLinesTo(textPtr, index.linePtr) == TkBTreeNumLines(index.tree, textPtr)) { TkTextIndexBackChars(textPtr, &index, 1, &index, COUNT_INDICES); } /* * First get the desired position into the vertical range of the window. */ TkTextSetYView(textPtr, &index, TK_TEXT_PICKPLACE); /* * Now make sure that the character is in view horizontally. */ if (dInfoPtr->flags & DINFO_OUT_OF_DATE) { UpdateDisplayInfo(textPtr); } lineWidth = dInfoPtr->maxX - dInfoPtr->x; if (dInfoPtr->maxLength < lineWidth) { return TCL_OK; } /* * Find the display line containing the desired index. dlPtr may be NULL * if the widget is not mapped. [Bug #641778] */ dlPtr = FindDLine(textPtr, dInfoPtr->dLinePtr, &index); if (dlPtr == NULL) { return TCL_OK; } /* * Find the chunk within the display line that contains the desired * index. The chunks making the display line are skipped up to but not * including the one crossing index. Skipping is done based on a * byteCount offset possibly spanning several logical lines in case * they are elided. */ byteCount = TkTextIndexCountBytes(textPtr, &dlPtr->index, &index); for (chunkPtr = dlPtr->chunkPtr; chunkPtr != NULL ; chunkPtr = chunkPtr->nextPtr) { if (byteCount < chunkPtr->numBytes) { break; } byteCount -= chunkPtr->numBytes; } /* * Call a chunk-specific function to find the horizontal range of the * character within the chunk. chunkPtr is NULL if trying to see in elided * region. */ if (chunkPtr != NULL) { (*chunkPtr->bboxProc)(textPtr, chunkPtr, byteCount, dlPtr->y + dlPtr->spaceAbove, dlPtr->height - dlPtr->spaceAbove - dlPtr->spaceBelow, dlPtr->baseline - dlPtr->spaceAbove, &x, &y, &width, &height); delta = x - dInfoPtr->curXPixelOffset; oneThird = lineWidth/3; if (delta < 0) { if (delta < -oneThird) { dInfoPtr->newXPixelOffset = (x - lineWidth/2); } else { dInfoPtr->newXPixelOffset -= ((-delta) ); } } else { delta -= (lineWidth - width); if (delta > 0) { if (delta > oneThird) { dInfoPtr->newXPixelOffset = (x - lineWidth/2); } else { dInfoPtr->newXPixelOffset += (delta ); } } else { return TCL_OK; } } } dInfoPtr->flags |= DINFO_OUT_OF_DATE; if (!(dInfoPtr->flags & REDRAW_PENDING)) { dInfoPtr->flags |= REDRAW_PENDING; Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } return TCL_OK; } /* *-------------------------------------------------------------- * * TkTextXviewCmd -- * * This function is invoked to process the "xview" option for the widget * command for text widgets. See the user documentation for details on * what it does. * * Results: * A standard Tcl result. * * Side effects: * See the user documentation. * *-------------------------------------------------------------- */ int TkTextXviewCmd( TkText *textPtr, /* Information about text widget. */ Tcl_Interp *interp, /* Current interpreter. */ int objc, /* Number of arguments. */ Tcl_Obj *CONST objv[]) /* Argument objects. Someone else has already * parsed this command enough to know that * objv[1] is "xview". */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; int type, count; double fraction; if (dInfoPtr->flags & DINFO_OUT_OF_DATE) { UpdateDisplayInfo(textPtr); } if (objc == 2) { GetXView(interp, textPtr, 0); return TCL_OK; } type = TextGetScrollInfoObj(interp, textPtr, objc, objv, &fraction, &count); switch (type) { case TKTEXT_SCROLL_ERROR: return TCL_ERROR; case TKTEXT_SCROLL_MOVETO: if (fraction > 1.0) { fraction = 1.0; } if (fraction < 0) { fraction = 0; } dInfoPtr->newXPixelOffset = (int) (fraction * dInfoPtr->maxLength + 0.5); break; case TKTEXT_SCROLL_PAGES: { int pixelsPerPage; pixelsPerPage = (dInfoPtr->maxX-dInfoPtr->x) - 2*textPtr->charWidth; if (pixelsPerPage < 1) { pixelsPerPage = 1; } dInfoPtr->newXPixelOffset += pixelsPerPage * count; break; } case TKTEXT_SCROLL_UNITS: dInfoPtr->newXPixelOffset += count * textPtr->charWidth; break; case TKTEXT_SCROLL_PIXELS: dInfoPtr->newXPixelOffset += count; break; } dInfoPtr->flags |= DINFO_OUT_OF_DATE; if (!(dInfoPtr->flags & REDRAW_PENDING)) { dInfoPtr->flags |= REDRAW_PENDING; Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } return TCL_OK; } /* *---------------------------------------------------------------------- * * YScrollByPixels -- * * This function is called to scroll a text widget up or down by a given * number of pixels. * * Results: * None. * * Side effects: * The view in textPtr's window changes to reflect the value of "offset". * *---------------------------------------------------------------------- */ static void YScrollByPixels( TkText *textPtr, /* Widget to scroll. */ int offset) /* Amount by which to scroll, in pixels. * Positive means that information later in * text becomes visible, negative means that * information earlier in the text becomes * visible. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; if (offset < 0) { /* * Now we want to measure up this number of pixels from the top of the * screen. But the top line may not be totally visible. Note that * 'count' is negative here. */ offset -= CalculateDisplayLineHeight(textPtr, &textPtr->topIndex, NULL, NULL) - dInfoPtr->topPixelOffset; MeasureUp(textPtr, &textPtr->topIndex, -offset, &textPtr->topIndex, &dInfoPtr->newTopPixelOffset); } else if (offset > 0) { DLine *dlPtr; TkTextLine *lastLinePtr; TkTextIndex newIdx; /* * Scrolling down by pixels. Layout lines starting at the top index * and count through the desired vertical distance. */ lastLinePtr = TkBTreeFindLine(textPtr->sharedTextPtr->tree, textPtr, TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr)); offset += dInfoPtr->topPixelOffset; dInfoPtr->newTopPixelOffset = 0; while (offset > 0) { dlPtr = LayoutDLine(textPtr, &textPtr->topIndex); dlPtr->nextPtr = NULL; TkTextIndexForwBytes(textPtr, &textPtr->topIndex, dlPtr->byteCount, &newIdx); if (offset <= dlPtr->height) { /* * Adjust the top overlap accordingly. */ dInfoPtr->newTopPixelOffset = offset; } offset -= dlPtr->height; FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE_TEMP); if (newIdx.linePtr == lastLinePtr || offset <= 0) { break; } textPtr->topIndex = newIdx; } } else { /* * offset = 0, so no scrolling required. */ return; } if (!(dInfoPtr->flags & REDRAW_PENDING)) { Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } dInfoPtr->flags |= REDRAW_PENDING|DINFO_OUT_OF_DATE|REPICK_NEEDED; } /* *---------------------------------------------------------------------- * * YScrollByLines -- * * This function is called to scroll a text widget up or down by a given * number of lines. * * Results: * None. * * Side effects: * The view in textPtr's window changes to reflect the value of "offset". * *---------------------------------------------------------------------- */ static void YScrollByLines( TkText *textPtr, /* Widget to scroll. */ int offset) /* Amount by which to scroll, in display * lines. Positive means that information * later in text becomes visible, negative * means that information earlier in the text * becomes visible. */ { int i, bytesToCount, lineNum; TkTextIndex newIdx, index; TkTextLine *lastLinePtr; TextDInfo *dInfoPtr = textPtr->dInfoPtr; DLine *dlPtr, *lowestPtr; if (offset < 0) { /* * Must scroll up (to show earlier information in the text). The code * below is similar to that in MeasureUp, except that it counts lines * instead of pixels. */ bytesToCount = textPtr->topIndex.byteIndex + 1; index.tree = textPtr->sharedTextPtr->tree; offset--; /* Skip line containing topIndex. */ for (lineNum = TkBTreeLinesTo(textPtr, textPtr->topIndex.linePtr); lineNum >= 0; lineNum--) { index.linePtr = TkBTreeFindLine(textPtr->sharedTextPtr->tree, textPtr, lineNum); index.byteIndex = 0; lowestPtr = NULL; do { dlPtr = LayoutDLine(textPtr, &index); dlPtr->nextPtr = lowestPtr; lowestPtr = dlPtr; TkTextIndexForwBytes(textPtr, &index, dlPtr->byteCount,&index); bytesToCount -= dlPtr->byteCount; } while ((bytesToCount > 0) && (index.linePtr == dlPtr->index.linePtr)); for (dlPtr = lowestPtr; dlPtr != NULL; dlPtr = dlPtr->nextPtr) { offset++; if (offset == 0) { textPtr->topIndex = dlPtr->index; /* * topIndex is the start of a logical line. However, if * the eol of the previous logical line is elided, then * topIndex may be elsewhere than the first character of * a display line, which is unwanted. Adjust to the start * of the display line, if needed. * topIndex is the start of a display line that is or is * not the start of a logical line. If it is the start of * a logical line, we must check whether this line is * merged with the previous logical line, and if so we * must adjust topIndex to the start of the display line. */ if (!IsStartOfNotMergedLine(textPtr, &textPtr->topIndex)) { TkTextFindDisplayLineEnd(textPtr, &textPtr->topIndex, 0, NULL); } break; } } /* * Discard the display lines, then either return or prepare for * the next display line to lay out. */ FreeDLines(textPtr, lowestPtr, NULL, DLINE_FREE); if (offset >= 0) { goto scheduleUpdate; } bytesToCount = INT_MAX; } /* * Ran off the beginning of the text. Return the first character in * the text, and make sure we haven't left anything overlapping the * top window border. */ TkTextMakeByteIndex(textPtr->sharedTextPtr->tree, textPtr, 0, 0, &textPtr->topIndex); dInfoPtr->newTopPixelOffset = 0; } else { /* * Scrolling down, to show later information in the text. Just count * lines from the current top of the window. */ lastLinePtr = TkBTreeFindLine(textPtr->sharedTextPtr->tree, textPtr, TkBTreeNumLines(textPtr->sharedTextPtr->tree, textPtr)); for (i = 0; i < offset; i++) { dlPtr = LayoutDLine(textPtr, &textPtr->topIndex); if (dlPtr->length == 0 && dlPtr->height == 0) { offset++; } dlPtr->nextPtr = NULL; TkTextIndexForwBytes(textPtr, &textPtr->topIndex, dlPtr->byteCount, &newIdx); FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE); if (newIdx.linePtr == lastLinePtr) { break; } textPtr->topIndex = newIdx; } } scheduleUpdate: if (!(dInfoPtr->flags & REDRAW_PENDING)) { Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } dInfoPtr->flags |= REDRAW_PENDING|DINFO_OUT_OF_DATE|REPICK_NEEDED; } /* *-------------------------------------------------------------- * * TkTextYviewCmd -- * * This function is invoked to process the "yview" option for the widget * command for text widgets. See the user documentation for details on * what it does. * * Results: * A standard Tcl result. * * Side effects: * See the user documentation. * *-------------------------------------------------------------- */ int TkTextYviewCmd( TkText *textPtr, /* Information about text widget. */ Tcl_Interp *interp, /* Current interpreter. */ int objc, /* Number of arguments. */ Tcl_Obj *CONST objv[]) /* Argument objects. Someone else has already * parsed this command enough to know that * objv[1] is "yview". */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; int pickPlace, type; int pixels, count; int switchLength; double fraction; TkTextIndex index; if (dInfoPtr->flags & DINFO_OUT_OF_DATE) { UpdateDisplayInfo(textPtr); } if (objc == 2) { GetYView(interp, textPtr, 0); return TCL_OK; } /* * Next, handle the old syntax: "pathName yview ?-pickplace? where" */ pickPlace = 0; if (Tcl_GetString(objv[2])[0] == '-') { register CONST char *switchStr = Tcl_GetStringFromObj(objv[2], &switchLength); if ((switchLength >= 2) && (strncmp(switchStr, "-pickplace", (unsigned) switchLength) == 0)) { pickPlace = 1; if (objc != 4) { Tcl_WrongNumArgs(interp, 3, objv, "lineNum|index"); return TCL_ERROR; } } } if ((objc == 3) || pickPlace) { int lineNum; if (Tcl_GetIntFromObj(interp, objv[2+pickPlace], &lineNum) == TCL_OK) { TkTextMakeByteIndex(textPtr->sharedTextPtr->tree, textPtr, lineNum, 0, &index); TkTextSetYView(textPtr, &index, 0); return TCL_OK; } /* * The argument must be a regular text index. */ Tcl_ResetResult(interp); if (TkTextGetObjIndex(interp, textPtr, objv[2+pickPlace], &index) != TCL_OK) { return TCL_ERROR; } TkTextSetYView(textPtr, &index, (pickPlace ? TK_TEXT_PICKPLACE : 0)); return TCL_OK; } /* * New syntax: dispatch based on objv[2]. */ type = TextGetScrollInfoObj(interp, textPtr, objc,objv, &fraction, &count); switch (type) { case TKTEXT_SCROLL_ERROR: return TCL_ERROR; case TKTEXT_SCROLL_MOVETO: { int numPixels = TkBTreeNumPixels(textPtr->sharedTextPtr->tree, textPtr); int topMostPixel; if (numPixels == 0) { /* * If the window is totally empty no scrolling is needed, and the * TkTextMakePixelIndex call below will fail. */ break; } if (fraction > 1.0) { fraction = 1.0; } if (fraction < 0) { fraction = 0; } /* * Calculate the pixel count for the new topmost pixel in the topmost * line of the window. Note that the interpretation of 'fraction' is * that it counts from 0 (top pixel in buffer) to 1.0 (one pixel past * the last pixel in buffer). */ topMostPixel = (int) (0.5 + fraction * numPixels); if (topMostPixel >= numPixels) { topMostPixel = numPixels -1; } /* * This function returns the number of pixels by which the given line * should overlap the top of the visible screen. * * This is then used to provide smooth scrolling. */ pixels = TkTextMakePixelIndex(textPtr, topMostPixel, &index); TkTextSetYView(textPtr, &index, pixels); break; } case TKTEXT_SCROLL_PAGES: { /* * Scroll up or down by screenfuls. Actually, use the window height * minus two lines, so that there's some overlap between adjacent * pages. */ int height = dInfoPtr->maxY - dInfoPtr->y; if (textPtr->charHeight * 4 >= height) { /* * A single line is more than a quarter of the display. We choose * to scroll by 3/4 of the height instead. */ pixels = 3*height/4; if (pixels < textPtr->charHeight) { /* * But, if 3/4 of the height is actually less than a single * typical character height, then scroll by the minimum of the * linespace or the total height. */ if (textPtr->charHeight < height) { pixels = textPtr->charHeight; } else { pixels = height; } } pixels *= count; } else { pixels = (height - 2*textPtr->charHeight)*count; } YScrollByPixels(textPtr, pixels); break; } case TKTEXT_SCROLL_PIXELS: YScrollByPixels(textPtr, count); break; case TKTEXT_SCROLL_UNITS: YScrollByLines(textPtr, count); break; } return TCL_OK; } /* *-------------------------------------------------------------- * * TkTextScanCmd -- * * This function is invoked to process the "scan" option for the widget * command for text widgets. See the user documentation for details on * what it does. * * Results: * A standard Tcl result. * * Side effects: * See the user documentation. * *-------------------------------------------------------------- */ int TkTextScanCmd( register TkText *textPtr, /* Information about text widget. */ Tcl_Interp *interp, /* Current interpreter. */ int objc, /* Number of arguments. */ Tcl_Obj *CONST objv[]) /* Argument objects. Someone else has already * parsed this command enough to know that * objv[1] is "scan". */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; TkTextIndex index; int c, x, y, totalScroll, gain=10; size_t length; if ((objc != 5) && (objc != 6)) { Tcl_WrongNumArgs(interp, 2, objv, "mark x y"); Tcl_AppendResult(interp, " or \"", Tcl_GetString(objv[0]), " scan dragto x y ?gain?\"", NULL); /* * Ought to be: * Tcl_WrongNumArgs(interp, 2, objc, "dragto x y ?gain?"); */ return TCL_ERROR; } if (Tcl_GetIntFromObj(interp, objv[3], &x) != TCL_OK) { return TCL_ERROR; } if (Tcl_GetIntFromObj(interp, objv[4], &y) != TCL_OK) { return TCL_ERROR; } if ((objc == 6) && (Tcl_GetIntFromObj(interp, objv[5], &gain) != TCL_OK)) { return TCL_ERROR; } c = Tcl_GetString(objv[2])[0]; length = strlen(Tcl_GetString(objv[2])); if (c=='d' && strncmp(Tcl_GetString(objv[2]), "dragto", length)==0) { int newX, maxX; /* * Amplify the difference between the current position and the mark * position to compute how much the view should shift, then update the * mark position to correspond to the new view. If we run off the edge * of the text, reset the mark point so that the current position * continues to correspond to the edge of the window. This means that * the picture will start dragging as soon as the mouse reverses * direction (without this reset, might have to slide mouse a long * ways back before the picture starts moving again). */ newX = dInfoPtr->scanMarkXPixel + gain*(dInfoPtr->scanMarkX - x); maxX = 1 + dInfoPtr->maxLength - (dInfoPtr->maxX - dInfoPtr->x); if (newX < 0) { newX = 0; dInfoPtr->scanMarkXPixel = 0; dInfoPtr->scanMarkX = x; } else if (newX > maxX) { newX = maxX; dInfoPtr->scanMarkXPixel = maxX; dInfoPtr->scanMarkX = x; } dInfoPtr->newXPixelOffset = newX; totalScroll = gain*(dInfoPtr->scanMarkY - y); if (totalScroll != dInfoPtr->scanTotalYScroll) { index = textPtr->topIndex; YScrollByPixels(textPtr, totalScroll-dInfoPtr->scanTotalYScroll); dInfoPtr->scanTotalYScroll = totalScroll; if ((index.linePtr == textPtr->topIndex.linePtr) && (index.byteIndex == textPtr->topIndex.byteIndex)) { dInfoPtr->scanTotalYScroll = 0; dInfoPtr->scanMarkY = y; } } dInfoPtr->flags |= DINFO_OUT_OF_DATE; if (!(dInfoPtr->flags & REDRAW_PENDING)) { dInfoPtr->flags |= REDRAW_PENDING; Tcl_DoWhenIdle(DisplayText, (ClientData) textPtr); } } else if (c=='m' && strncmp(Tcl_GetString(objv[2]), "mark", length)==0) { dInfoPtr->scanMarkXPixel = dInfoPtr->newXPixelOffset; dInfoPtr->scanMarkX = x; dInfoPtr->scanTotalYScroll = 0; dInfoPtr->scanMarkY = y; } else { Tcl_AppendResult(interp, "bad scan option \"", Tcl_GetString(objv[2]), "\": must be mark or dragto", NULL); return TCL_ERROR; } return TCL_OK; } /* *---------------------------------------------------------------------- * * GetXView -- * * This function computes the fractions that indicate what's visible in a * text window and, optionally, evaluates a Tcl script to report them to * the text's associated scrollbar. * * Results: * If report is zero, then the interp's result is filled in with two real * numbers separated by a space, giving the position of the left and * right edges of the window as fractions from 0 to 1, where 0 means the * left edge of the text and 1 means the right edge. If report is * non-zero, then the interp's result isn't modified directly, but * instead a script is evaluated in interp to report the new horizontal * scroll position to the scrollbar (if the scroll position hasn't * changed then no script is invoked). * * Side effects: * None. * *---------------------------------------------------------------------- */ static void GetXView( Tcl_Interp *interp, /* If "report" is FALSE, string describing * visible range gets stored in the interp's * result. */ TkText *textPtr, /* Information about text widget. */ int report) /* Non-zero means report info to scrollbar if * it has changed. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; double first, last; int code; Tcl_Obj *listObj; if (dInfoPtr->maxLength > 0) { first = ((double) dInfoPtr->curXPixelOffset) / dInfoPtr->maxLength; last = ((double) (dInfoPtr->curXPixelOffset + dInfoPtr->maxX - dInfoPtr->x))/dInfoPtr->maxLength; if (last > 1.0) { last = 1.0; } } else { first = 0; last = 1.0; } if (!report) { listObj = Tcl_NewListObj(0, NULL); Tcl_ListObjAppendElement(interp, listObj, Tcl_NewDoubleObj(first)); Tcl_ListObjAppendElement(interp, listObj, Tcl_NewDoubleObj(last)); Tcl_SetObjResult(interp, listObj); return; } if (FP_EQUAL_SCALE(first, dInfoPtr->xScrollFirst, dInfoPtr->maxLength) && FP_EQUAL_SCALE(last, dInfoPtr->xScrollLast, dInfoPtr->maxLength)) { return; } dInfoPtr->xScrollFirst = first; dInfoPtr->xScrollLast = last; if (textPtr->xScrollCmd != NULL) { char buf1[TCL_DOUBLE_SPACE+1]; char buf2[TCL_DOUBLE_SPACE+1]; buf1[0] = ' '; buf2[0] = ' '; Tcl_PrintDouble(NULL, first, buf1+1); Tcl_PrintDouble(NULL, last, buf2+1); code = Tcl_VarEval(interp, textPtr->xScrollCmd, buf1, buf2, NULL); if (code != TCL_OK) { Tcl_AddErrorInfo(interp, "\n (horizontal scrolling command executed by text)"); Tcl_BackgroundError(interp); } } } /* *---------------------------------------------------------------------- * * GetYPixelCount -- * * How many pixels are there between the absolute top of the widget and * the top of the given DLine. * * While this function will work for any valid DLine, it is only ever * called when dlPtr is the first display line in the widget (by * 'GetYView'). This means that usually this function is a very quick * calculation, since it can use the pre-calculated linked-list of DLines * for height information. * * The only situation where this breaks down is if dlPtr's logical line * wraps enough times to fill the text widget's current view - in this * case we won't have enough dlPtrs in the linked list to be able to * subtract off what we want. * * Results: * The number of pixels. * * This value has a valid range between '0' (the very top of the widget) * and the number of pixels in the total widget minus the pixel-height of * the last line. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int GetYPixelCount( TkText *textPtr, /* Information about text widget. */ DLine *dlPtr) /* Information about the layout of a given * index. */ { TkTextLine *linePtr = dlPtr->index.linePtr; int count; /* * Get the pixel count to the top of dlPtr's logical line. The rest of the * function is then concerned with updating 'count' for any difference * between the top of the logical line and the display line. */ count = TkBTreePixelsTo(textPtr, linePtr); /* * For the common case where this dlPtr is also the start of the logical * line, we can return right away. */ if (IsStartOfNotMergedLine(textPtr, &dlPtr->index)) { return count; } /* * Add on the logical line's height to reach one pixel beyond the bottom * of the logical line. And then subtract off the heights of all the * display lines from dlPtr to the end of its logical line. * * A different approach would be to lay things out from the start of the * logical line until we reach dlPtr, but since none of those are * pre-calculated, it'll usually take a lot longer. (But there are cases * where it would be more efficient: say if we're on the second of 1000 * wrapped lines all from a single logical line - but that sort of * optimization is left for the future). */ count += TkBTreeLinePixelCount(textPtr, linePtr); do { count -= dlPtr->height; if (dlPtr->nextPtr == NULL) { /* * We've run out of pre-calculated display lines, so we have to * lay them out ourselves until the end of the logical line. Here * is where we could be clever and ask: what's faster, to layout * all lines from here to line-end, or all lines from the original * dlPtr to the line-start? We just assume the former. */ TkTextIndex index; int notFirst = 0; while (1) { TkTextIndexForwBytes(textPtr, &dlPtr->index, dlPtr->byteCount, &index); if (notFirst) { FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE_TEMP); } if (index.linePtr != linePtr) { break; } dlPtr = LayoutDLine(textPtr, &index); if (tkTextDebug) { char string[TK_POS_CHARS]; /* * Debugging is enabled, so keep a log of all the lines * whose height was recalculated. The test suite uses this * information. */ TkTextPrintIndex(textPtr, &index, string); LOG("tk_textHeightCalc", string); } count -= dlPtr->height; notFirst = 1; } break; } else { dlPtr = dlPtr->nextPtr; } } while (dlPtr->index.linePtr == linePtr); return count; } /* *---------------------------------------------------------------------- * * GetYView -- * * This function computes the fractions that indicate what's visible in a * text window and, optionally, evaluates a Tcl script to report them to * the text's associated scrollbar. * * Results: * If report is zero, then the interp's result is filled in with two real * numbers separated by a space, giving the position of the top and * bottom of the window as fractions from 0 to 1, where 0 means the * beginning of the text and 1 means the end. If report is non-zero, then * the interp's result isn't modified directly, but a script is evaluated * in interp to report the new scroll position to the scrollbar (if the * scroll position hasn't changed then no script is invoked). * * Side effects: * None. * *---------------------------------------------------------------------- */ static void GetYView( Tcl_Interp *interp, /* If "report" is FALSE, string describing * visible range gets stored in the interp's * result. */ TkText *textPtr, /* Information about text widget. */ int report) /* Non-zero means report info to scrollbar if * it has changed. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; double first, last; DLine *dlPtr; int totalPixels, code, count; Tcl_Obj *listObj; dlPtr = dInfoPtr->dLinePtr; if (dlPtr == NULL) { return; } totalPixels = TkBTreeNumPixels(textPtr->sharedTextPtr->tree, textPtr); if (totalPixels == 0) { first = 0.0; last = 1.0; } else { /* * Get the pixel count for the first visible pixel of the first * visible line. If the first visible line is only partially visible, * then we use 'topPixelOffset' to get the difference. */ count = GetYPixelCount(textPtr, dlPtr); first = (count + dInfoPtr->topPixelOffset) / (double) totalPixels; /* * Add on the total number of visible pixels to get the count to one * pixel _past_ the last visible pixel. This is how the 'yview' * command is documented, and also explains why we are dividing by * 'totalPixels' and not 'totalPixels-1'. */ while (1) { int extra; count += dlPtr->height; extra = dlPtr->y + dlPtr->height - dInfoPtr->maxY; if (extra > 0) { /* * This much of the last line is not visible, so don't count * these pixels. Since we've reached the bottom of the window, * we break out of the loop. */ count -= extra; break; } if (dlPtr->nextPtr == NULL) { break; } dlPtr = dlPtr->nextPtr; } if (count > totalPixels) { /* * It can be possible, if we do not update each line's pixelHeight * cache when we lay out individual DLines that the count * generated here is more up-to-date than that maintained by the * BTree. In such a case, the best we can do here is to fix up * 'count' and continue, which might result in small, temporary * perturbations to the size of the scrollbar. This is basically * harmless, but in a perfect world we would not have this * problem. * * For debugging purposes, if anyone wishes to improve the text * widget further, the following 'panic' can be activated. In * principle it should be possible to ensure the BTree is always * at least as up to date as the display, so in the future we * might be able to leave the 'panic' in permanently when we * believe we have resolved the cache synchronisation issue. * * However, to achieve that goal would, I think, require a fairly * substantial refactorisation of the code in this file so that * there is much more obvious and explicit coordination between * calls to LayoutDLine and updating of each TkTextLine's * pixelHeight. The complicated bit is that LayoutDLine deals with * individual display lines, but pixelHeight is for a logical * line. */ #if 0 Tcl_Panic("Counted more pixels (%d) than expected (%d) total " "pixels in text widget scroll bar calculation.", count, totalPixels); #endif count = totalPixels; } last = ((double) count)/((double)totalPixels); } if (!report) { listObj = Tcl_NewListObj(0,NULL); Tcl_ListObjAppendElement(interp, listObj, Tcl_NewDoubleObj(first)); Tcl_ListObjAppendElement(interp, listObj, Tcl_NewDoubleObj(last)); Tcl_SetObjResult(interp, listObj); return; } if (FP_EQUAL_SCALE(first, dInfoPtr->yScrollFirst, totalPixels) && FP_EQUAL_SCALE(last, dInfoPtr->yScrollLast, totalPixels)) { return; } dInfoPtr->yScrollFirst = first; dInfoPtr->yScrollLast = last; if (textPtr->yScrollCmd != NULL) { char buf1[TCL_DOUBLE_SPACE+1]; char buf2[TCL_DOUBLE_SPACE+1]; buf1[0] = ' '; buf2[0] = ' '; Tcl_PrintDouble(NULL, first, buf1+1); Tcl_PrintDouble(NULL, last, buf2+1); code = Tcl_VarEval(interp, textPtr->yScrollCmd, buf1, buf2, NULL); if (code != TCL_OK) { Tcl_AddErrorInfo(interp, "\n (vertical scrolling command executed by text)"); Tcl_BackgroundError(interp); } } } /* *---------------------------------------------------------------------- * * AsyncUpdateYScrollbar -- * * This function is called to update the vertical scrollbar asychronously * as the pixel height calculations progress for lines in the widget. * * Results: * None. * * Side effects: * See 'GetYView'. In particular the scrollbar position and size may be * changed. * *---------------------------------------------------------------------- */ static void AsyncUpdateYScrollbar( ClientData clientData) /* Information about widget. */ { register TkText *textPtr = (TkText *) clientData; textPtr->dInfoPtr->scrollbarTimer = NULL; if (!(textPtr->flags & DESTROYED)) { GetYView(textPtr->interp, textPtr, 1); } if (--textPtr->refCount == 0) { ckfree((char *) textPtr); } } /* *---------------------------------------------------------------------- * * FindDLine -- * * This function is called to find the DLine corresponding to a given * text index. * * Results: * The return value is a pointer to the first DLine found in the list * headed by dlPtr that displays information at or after the specified * position. If there is no such line in the list then NULL is returned. * * Side effects: * None. * *---------------------------------------------------------------------- */ static DLine * FindDLine( TkText *textPtr, /* Widget record for text widget. */ register DLine *dlPtr, /* Pointer to first in list of DLines to * search. */ CONST TkTextIndex *indexPtr)/* Index of desired character. */ { DLine *dlPtrPrev; if (dlPtr == NULL) { return NULL; } if (TkBTreeLinesTo(NULL, indexPtr->linePtr) < TkBTreeLinesTo(NULL, dlPtr->index.linePtr)) { /* * The first display line is already past the desired line. */ return dlPtr; } /* * The display line containing the desired index is such that the index * of the first character of this display line is at or before the * desired index, and the index of the first character of the next * display line is after the desired index. */ while (TkTextIndexCmp(&dlPtr->index,indexPtr) < 0) { dlPtrPrev = dlPtr; dlPtr = dlPtr->nextPtr; if (dlPtr == NULL) { TkTextIndex indexPtr2; /* * We're past the last display line, either because the desired * index lies past the visible text, or because the desired index * is on the last display line showing the last logical line. */ indexPtr2 = dlPtrPrev->index; TkTextIndexForwBytes(textPtr, &indexPtr2, dlPtrPrev->byteCount, &indexPtr2); if (TkTextIndexCmp(&indexPtr2,indexPtr) > 0) { dlPtr = dlPtrPrev; break; } else { return NULL; } } if (TkTextIndexCmp(&dlPtr->index,indexPtr) > 0) { dlPtr = dlPtrPrev; break; } } return dlPtr; } /* *---------------------------------------------------------------------- * * IsStartOfNotMergedLine -- * * This function checks whether the given index is the start of a * logical line that is not merged with the previous logical line * (due to elision of the eol of the previous line). * * Results: * Returns whether the given index denotes the first index of a * logical line not merged with its previous line. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int IsStartOfNotMergedLine( TkText *textPtr, /* Widget record for text widget. */ CONST TkTextIndex *indexPtr) /* Index to check. */ { TkTextIndex indexPtr2; if (indexPtr->byteIndex != 0) { /* * Not the start of a logical line. */ return 0; } if (TkTextIndexBackBytes(textPtr, indexPtr, 1, &indexPtr2)) { /* * indexPtr is the first index of the text widget. */ return 1; } if (!TkTextIsElided(textPtr, &indexPtr2, NULL)) { /* * The eol of the line just before indexPtr is elided. */ return 1; } return 0; } /* *---------------------------------------------------------------------- * * TkTextPixelIndex -- * * Given an (x,y) coordinate on the screen, find the location of the * character closest to that location. * * Results: * The index at *indexPtr is modified to refer to the character on the * display that is closest to (x,y). * * Side effects: * None. * *---------------------------------------------------------------------- */ void TkTextPixelIndex( TkText *textPtr, /* Widget record for text widget. */ int x, int y, /* Pixel coordinates of point in widget's * window. */ TkTextIndex *indexPtr, /* This index gets filled in with the index of * the character nearest to (x,y). */ int *nearest) /* If non-NULL then gets set to 0 if (x,y) is * actually over the returned index, and 1 if * it is just nearby (e.g. if x,y is on the * border of the widget). */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; register DLine *dlPtr, *validDlPtr; int nearby = 0; /* * Make sure that all of the layout information about what's displayed * where on the screen is up-to-date. */ if (dInfoPtr->flags & DINFO_OUT_OF_DATE) { UpdateDisplayInfo(textPtr); } /* * If the coordinates are above the top of the window, then adjust them to * refer to the upper-right corner of the window. If they're off to one * side or the other, then adjust to the closest side. */ if (y < dInfoPtr->y) { y = dInfoPtr->y; x = dInfoPtr->x; nearby = 1; } if (x >= dInfoPtr->maxX) { x = dInfoPtr->maxX - 1; nearby = 1; } if (x < dInfoPtr->x) { x = dInfoPtr->x; nearby = 1; } /* * Find the display line containing the desired y-coordinate. */ if (dInfoPtr->dLinePtr == NULL) { if (nearest != NULL) { *nearest = 1; } *indexPtr = textPtr->topIndex; return; } else { for (dlPtr = validDlPtr = dInfoPtr->dLinePtr; y >= (dlPtr->y + dlPtr->height); dlPtr = dlPtr->nextPtr) { if (dlPtr->chunkPtr != NULL) { validDlPtr = dlPtr; } if (dlPtr->nextPtr == NULL) { /* * Y-coordinate is off the bottom of the displayed text. Use * the last character on the last line. */ x = dInfoPtr->maxX - 1; nearby = 1; break; } } if (dlPtr->chunkPtr == NULL) dlPtr = validDlPtr; } if (nearest != NULL) { *nearest = nearby; } DlineIndexOfX(textPtr, dlPtr, x, indexPtr); } /* *---------------------------------------------------------------------- * * DlineIndexOfX -- * * Given an x coordinate in a display line, find the index of the * character closest to that location. * * This is effectively the opposite of DlineXOfIndex. * * Results: * The index at *indexPtr is modified to refer to the character on the * display line that is closest to x. * * Side effects: * None. * *---------------------------------------------------------------------- */ static void DlineIndexOfX( TkText *textPtr, /* Widget record for text widget. */ DLine *dlPtr, /* Display information for this display * line. */ int x, /* Pixel x coordinate of point in widget's * window. */ TkTextIndex *indexPtr) /* This index gets filled in with the index of * the character nearest to x. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; register TkTextDispChunk *chunkPtr; /* * Scan through the line's chunks to find the one that contains the * desired x-coordinate. Before doing this, translate the x-coordinate * from the coordinate system of the window to the coordinate system of * the line (to take account of x-scrolling). */ *indexPtr = dlPtr->index; x = x - dInfoPtr->x + dInfoPtr->curXPixelOffset; chunkPtr = dlPtr->chunkPtr; if (chunkPtr == NULL || x == 0) { /* * This may occur if everything is elided, or if we're simply already * at the beginning of the line. */ return; } while (x >= (chunkPtr->x + chunkPtr->width)) { /* * Note that this forward then backward movement of the index can be * problematic at the end of the buffer (we can't move forward, and * then when we move backward, we do, leading to the wrong position). * Hence when x == 0 we take special action above. */ if (TkTextIndexForwBytes(NULL,indexPtr,chunkPtr->numBytes,indexPtr)) { /* * We've reached the end of the text. */ TkTextIndexBackChars(NULL, indexPtr, 1, indexPtr, COUNT_INDICES); return; } if (chunkPtr->nextPtr == NULL) { /* * We've reached the end of the display line. */ TkTextIndexBackChars(NULL, indexPtr, 1, indexPtr, COUNT_INDICES); return; } chunkPtr = chunkPtr->nextPtr; } /* * If the chunk has more than one byte in it, ask it which character is at * the desired location. In this case we can manipulate * 'indexPtr->byteIndex' directly, because we know we're staying inside a * single logical line. */ if (chunkPtr->numBytes > 1) { indexPtr->byteIndex += (*chunkPtr->measureProc)(chunkPtr, x); } } /* *---------------------------------------------------------------------- * * TkTextIndexOfX -- * * Given a logical x coordinate (i.e. distance in pixels from the * beginning of the display line, not taking into account any information * about the window, scrolling etc.) on the display line starting with * the given index, adjust that index to refer to the object under the x * coordinate. * * Results: * None. * * Side effects: * None. * *---------------------------------------------------------------------- */ void TkTextIndexOfX( TkText *textPtr, /* Widget record for text widget. */ int x, /* The x coordinate for which we want the * index. */ TkTextIndex *indexPtr) /* Index of display line start, which will be * adjusted to the index under the given x * coordinate. */ { DLine *dlPtr = LayoutDLine(textPtr, indexPtr); DlineIndexOfX(textPtr, dlPtr, x + textPtr->dInfoPtr->x - textPtr->dInfoPtr->curXPixelOffset, indexPtr); FreeDLines(textPtr, dlPtr, NULL, DLINE_FREE_TEMP); } /* *---------------------------------------------------------------------- * * DlineXOfIndex -- * * Given a relative byte index on a given display line (i.e. the number * of byte indices from the beginning of the given display line), find * the x coordinate of that index within the abstract display line, * without adjusting for the x-scroll state of the line. * * This is effectively the opposite of DlineIndexOfX. * * NB. The 'byteIndex' is relative to the display line, NOT the logical * line. * * Results: * The x coordinate. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int DlineXOfIndex( TkText *textPtr, /* Widget record for text widget. */ DLine *dlPtr, /* Display information for this display * line. */ int byteIndex) /* The byte index for which we want the * coordinate. */ { register TkTextDispChunk *chunkPtr = dlPtr->chunkPtr; int x; if (byteIndex == 0 || chunkPtr == NULL) { return 0; } /* * Scan through the line's chunks to find the one that contains the * desired byte index. */ chunkPtr = dlPtr->chunkPtr; while (byteIndex > 0) { if (byteIndex < chunkPtr->numBytes) { int y, width, height; (*chunkPtr->bboxProc)(textPtr, chunkPtr, byteIndex, dlPtr->y + dlPtr->spaceAbove, dlPtr->height - dlPtr->spaceAbove - dlPtr->spaceBelow, dlPtr->baseline - dlPtr->spaceAbove, &x, &y, &width, &height); break; } else { byteIndex -= chunkPtr->numBytes; } if (chunkPtr->nextPtr == NULL || byteIndex == 0) { x = chunkPtr->x + chunkPtr->width; break; } chunkPtr = chunkPtr->nextPtr; } return x; } /* *---------------------------------------------------------------------- * * TkTextIndexBbox -- * * Given an index, find the bounding box of the screen area occupied by * the entity (character, window, image) at that index. * * Results: * Zero is returned if the index is on the screen. -1 means the index is * not on the screen. If the return value is 0, then the bounding box of * the part of the index that's visible on the screen is returned to * *xPtr, *yPtr, *widthPtr, and *heightPtr. * * Side effects: * None. * *---------------------------------------------------------------------- */ int TkTextIndexBbox( TkText *textPtr, /* Widget record for text widget. */ CONST TkTextIndex *indexPtr,/* Index whose bounding box is desired. */ int *xPtr, int *yPtr, /* Filled with index's upper-left * coordinate. */ int *widthPtr, int *heightPtr, /* Filled in with index's dimensions. */ int *charWidthPtr) /* If the 'index' is at the end of a display * line and therefore takes up a very large * width, this is used to return the smaller * width actually desired by the index. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; DLine *dlPtr; register TkTextDispChunk *chunkPtr; int byteCount; /* * Make sure that all of the screen layout information is up to date. */ if (dInfoPtr->flags & DINFO_OUT_OF_DATE) { UpdateDisplayInfo(textPtr); } /* * Find the display line containing the desired index. */ dlPtr = FindDLine(textPtr, dInfoPtr->dLinePtr, indexPtr); /* * Two cases shall be trapped here because the logic later really * needs dlPtr to be the display line containing indexPtr: * 1. if no display line contains the desired index (NULL dlPtr) * 2. if indexPtr is before the first display line, in which case * dlPtr currently points to the first display line */ if ((dlPtr == NULL) || (TkTextIndexCmp(&dlPtr->index, indexPtr) > 0)) { return -1; } /* * Find the chunk within the display line that contains the desired * index. The chunks making the display line are skipped up to but not * including the one crossing indexPtr. Skipping is done based on * a byteCount offset possibly spanning several logical lines in case * they are elided. */ byteCount = TkTextIndexCountBytes(textPtr, &dlPtr->index, indexPtr); for (chunkPtr = dlPtr->chunkPtr; ; chunkPtr = chunkPtr->nextPtr) { if (chunkPtr == NULL) { return -1; } if (byteCount < chunkPtr->numBytes) { break; } byteCount -= chunkPtr->numBytes; } /* * Call a chunk-specific function to find the horizontal range of the * character within the chunk, then fill in the vertical range. The * x-coordinate returned by bboxProc is a coordinate within a line, not a * coordinate on the screen. Translate it to reflect horizontal scrolling. */ (*chunkPtr->bboxProc)(textPtr, chunkPtr, byteCount, dlPtr->y + dlPtr->spaceAbove, dlPtr->height - dlPtr->spaceAbove - dlPtr->spaceBelow, dlPtr->baseline - dlPtr->spaceAbove, xPtr, yPtr, widthPtr, heightPtr); *xPtr = *xPtr + dInfoPtr->x - dInfoPtr->curXPixelOffset; if ((byteCount == chunkPtr->numBytes-1) && (chunkPtr->nextPtr == NULL)) { /* * Last character in display line. Give it all the space up to the * line. */ if (charWidthPtr != NULL) { *charWidthPtr = dInfoPtr->maxX - *xPtr; if (*charWidthPtr > textPtr->charWidth) { *charWidthPtr = textPtr->charWidth; } } if (*xPtr > dInfoPtr->maxX) { *xPtr = dInfoPtr->maxX; } *widthPtr = dInfoPtr->maxX - *xPtr; } else { if (charWidthPtr != NULL) { *charWidthPtr = *widthPtr; } } if (*widthPtr == 0) { /* * With zero width (e.g. elided text) we just need to make sure it is * onscreen, where the '=' case here is ok. */ if (*xPtr < dInfoPtr->x) { return -1; } } else { if ((*xPtr + *widthPtr) <= dInfoPtr->x) { return -1; } } if ((*xPtr + *widthPtr) > dInfoPtr->maxX) { *widthPtr = dInfoPtr->maxX - *xPtr; if (*widthPtr <= 0) { return -1; } } if ((*yPtr + *heightPtr) > dInfoPtr->maxY) { *heightPtr = dInfoPtr->maxY - *yPtr; if (*heightPtr <= 0) { return -1; } } return 0; } /* *---------------------------------------------------------------------- * * TkTextDLineInfo -- * * Given an index, return information about the display line containing * that character. * * Results: * Zero is returned if the character is on the screen. -1 means the * character isn't on the screen. If the return value is 0, then * information is returned in the variables pointed to by xPtr, yPtr, * widthPtr, heightPtr, and basePtr. * * Side effects: * None. * *---------------------------------------------------------------------- */ int TkTextDLineInfo( TkText *textPtr, /* Widget record for text widget. */ CONST TkTextIndex *indexPtr,/* Index of character whose bounding box is * desired. */ int *xPtr, int *yPtr, /* Filled with line's upper-left * coordinate. */ int *widthPtr, int *heightPtr, /* Filled in with line's dimensions. */ int *basePtr) /* Filled in with the baseline position, * measured as an offset down from *yPtr. */ { TextDInfo *dInfoPtr = textPtr->dInfoPtr; DLine *dlPtr; int dlx; /* * Make sure that all of the screen layout information is up to date. */ if (dInfoPtr->flags & DINFO_OUT_OF_DATE) { UpdateDisplayInfo(textPtr); } /* * Find the display line containing the desired index. */ dlPtr = FindDLine(textPtr, dInfoPtr->dLinePtr, indexPtr); /* * Two cases shall be trapped here because the logic later really * needs dlPtr to be the display line containing indexPtr: * 1. if no display line contains the desired index (NULL dlPtr) * 2. if indexPtr is before the first display line, in which case * dlPtr currently points to the first display line */ if ((dlPtr == NULL) || (TkTextIndexCmp(&dlPtr->index, indexPtr) > 0)) { return -1; } dlx = (dlPtr->chunkPtr != NULL? dlPtr->chunkPtr->x: 0); *xPtr = dInfoPtr->x - dInfoPtr->curXPixelOffset + dlx; *widthPtr = dlPtr->length - dlx; *yPtr = dlPtr->y; if ((dlPtr->y + dlPtr->height) > dInfoPtr->maxY) { *heightPtr = dInfoPtr->maxY - dlPtr->y; } else { *heightPtr = dlPtr->height; } *basePtr = dlPtr->baseline; return 0; } /* * Get bounding-box information about an elided chunk. */ static void ElideBboxProc( TkText *textPtr, TkTextDispChunk *chunkPtr, /* Chunk containing desired char. */ int index, /* Index of desired character within the * chunk. */ int y, /* Topmost pixel in area allocated for this * line. */ int lineHeight, /* Height of line, in pixels. */ int baseline, /* Location of line's baseline, in pixels * measured down from y. */ int *xPtr, int *yPtr, /* Gets filled in with coords of character's * upper-left pixel. X-coord is in same * coordinate system as chunkPtr->x. */ int *widthPtr, /* Gets filled in with width of character, in * pixels. */ int *heightPtr) /* Gets filled in with height of character, in * pixels. */ { *xPtr = chunkPtr->x; *yPtr = y; *widthPtr = *heightPtr = 0; } /* * Measure an elided chunk. */ static int ElideMeasureProc( TkTextDispChunk *chunkPtr, /* Chunk containing desired coord. */ int x) /* X-coordinate, in same coordinate system as * chunkPtr->x. */ { return 0 /*chunkPtr->numBytes - 1*/; } /* *-------------------------------------------------------------- * * TkTextCharLayoutProc -- * * This function is the "layoutProc" for character segments. * * Results: * If there is something to display for the chunk then a non-zero value * is returned and the fields of chunkPtr will be filled in (see the * declaration of TkTextDispChunk in tkText.h for details). If zero is * returned it means that no characters from this chunk fit in the * window. If -1 is returned it means that this segment just doesn't need * to be displayed (never happens for text). * * Side effects: * Memory is allocated to hold additional information about the chunk. * *-------------------------------------------------------------- */ int TkTextCharLayoutProc( TkText *textPtr, /* Text widget being layed out. */ TkTextIndex *indexPtr, /* Index of first character to lay out * (corresponds to segPtr and offset). */ TkTextSegment *segPtr, /* Segment being layed out. */ int byteOffset, /* Byte offset within segment of first * character to consider. */ int maxX, /* Chunk must not occupy pixels at this * position or higher. */ int maxBytes, /* Chunk must not include more than this many * characters. */ int noCharsYet, /* Non-zero means no characters have been * assigned to this display line yet. */ TkWrapMode wrapMode, /* How to handle line wrapping: * TEXT_WRAPMODE_CHAR, TEXT_WRAPMODE_NONE, or * TEXT_WRAPMODE_WORD. */ register TkTextDispChunk *chunkPtr) /* Structure to fill in with information about * this chunk. The x field has already been * set by the caller. */ { Tk_Font tkfont; int nextX, bytesThatFit, count; CharInfo *ciPtr; char *p; TkTextSegment *nextPtr; Tk_FontMetrics fm; #if TK_LAYOUT_WITH_BASE_CHUNKS const char *line; int lineOffset; BaseCharInfo *bciPtr; Tcl_DString *baseString; #endif /* * Figure out how many characters will fit in the space we've got. Include * the next character, even though it won't fit completely, if any of the * following is true: * (a) the chunk contains no characters and the display line contains no * characters yet (i.e. the line isn't wide enough to hold even a * single character). * (b) at least one pixel of the character is visible, we have not * already exceeded the character limit, and the next character is a * white space character. */ p = segPtr->body.chars + byteOffset; tkfont = chunkPtr->stylePtr->sValuePtr->tkfont; #if TK_LAYOUT_WITH_BASE_CHUNKS if (baseCharChunkPtr == NULL) { baseCharChunkPtr = chunkPtr; bciPtr = (BaseCharInfo *) ckalloc(sizeof(BaseCharInfo)); baseString = &bciPtr->baseChars; Tcl_DStringInit(baseString); bciPtr->width = 0; ciPtr = &bciPtr->ci; } else { bciPtr = (BaseCharInfo *) baseCharChunkPtr->clientData; ciPtr = (CharInfo *) ckalloc(sizeof(CharInfo)); baseString = &bciPtr->baseChars; } lineOffset = Tcl_DStringLength(baseString); line = Tcl_DStringAppend(baseString,p,maxBytes); chunkPtr->clientData = (ClientData) ciPtr; ciPtr->baseChunkPtr = baseCharChunkPtr; ciPtr->baseOffset = lineOffset; ciPtr->chars = NULL; ciPtr->numBytes = 0; bytesThatFit = CharChunkMeasureChars(chunkPtr, line, lineOffset + maxBytes, lineOffset, -1, chunkPtr->x, maxX, TK_ISOLATE_END, &nextX); #else /* !TK_LAYOUT_WITH_BASE_CHUNKS */ bytesThatFit = CharChunkMeasureChars(chunkPtr, p, maxBytes, 0, -1, chunkPtr->x, maxX, TK_ISOLATE_END, &nextX); #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ if (bytesThatFit < maxBytes) { if ((bytesThatFit == 0) && noCharsYet) { Tcl_UniChar ch; int chLen = Tcl_UtfToUniChar(p, &ch); #if TK_LAYOUT_WITH_BASE_CHUNKS bytesThatFit = CharChunkMeasureChars(chunkPtr, line, lineOffset+chLen, lineOffset, -1, chunkPtr->x, -1, 0, &nextX); #else /* !TK_LAYOUT_WITH_BASE_CHUNKS */ bytesThatFit = CharChunkMeasureChars(chunkPtr, p, chLen, 0, -1, chunkPtr->x, -1, 0, &nextX); #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ } if ((nextX < maxX) && ((p[bytesThatFit] == ' ') || (p[bytesThatFit] == '\t'))) { /* * Space characters are funny, in that they are considered to fit * if there is at least one pixel of space left on the line. Just * give the space character whatever space is left. */ nextX = maxX; bytesThatFit++; } if (p[bytesThatFit] == '\n') { /* * A newline character takes up no space, so if the previous * character fits then so does the newline. */ bytesThatFit++; } if (bytesThatFit == 0) { #if TK_LAYOUT_WITH_BASE_CHUNKS chunkPtr->clientData = NULL; if (chunkPtr == baseCharChunkPtr) { baseCharChunkPtr = NULL; Tcl_DStringFree(baseString); } else { Tcl_DStringSetLength(baseString,lineOffset); } ckfree((char *) ciPtr); #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ return 0; } } Tk_GetFontMetrics(tkfont, &fm); /* * Fill in the chunk structure and allocate and initialize a CharInfo * structure. If the last character is a newline then don't bother to * display it. */ chunkPtr->displayProc = CharDisplayProc; chunkPtr->undisplayProc = CharUndisplayProc; chunkPtr->measureProc = CharMeasureProc; chunkPtr->bboxProc = CharBboxProc; chunkPtr->numBytes = bytesThatFit; chunkPtr->minAscent = fm.ascent + chunkPtr->stylePtr->sValuePtr->offset; chunkPtr->minDescent = fm.descent - chunkPtr->stylePtr->sValuePtr->offset; chunkPtr->minHeight = 0; chunkPtr->width = nextX - chunkPtr->x; chunkPtr->breakIndex = -1; #if !TK_LAYOUT_WITH_BASE_CHUNKS ciPtr = (CharInfo *) ckalloc((unsigned) bytesThatFit + Tk_Offset(CharInfo, chars) + 1); chunkPtr->clientData = (ClientData) ciPtr; memcpy(ciPtr->chars, p, (unsigned) bytesThatFit); #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ ciPtr->numBytes = bytesThatFit; if (p[bytesThatFit - 1] == '\n') { ciPtr->numBytes--; } #if TK_LAYOUT_WITH_BASE_CHUNKS /* * Final update for the current base chunk data. */ Tcl_DStringSetLength(baseString,lineOffset+ciPtr->numBytes); bciPtr->width = nextX - baseCharChunkPtr->x; /* * Finalize the base chunk if this chunk ends in a tab, which definitly * breaks the context and needs to be handled on a higher level. */ if (ciPtr->numBytes > 0 && p[ciPtr->numBytes - 1] == '\t') { FinalizeBaseChunk(chunkPtr); } #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ /* * Compute a break location. If we're in word wrap mode, a break can occur * after any space character, or at the end of the chunk if the next * segment (ignoring those with zero size) is not a character segment. */ if (wrapMode != TEXT_WRAPMODE_WORD) { chunkPtr->breakIndex = chunkPtr->numBytes; } else { for (count = bytesThatFit, p += bytesThatFit - 1; count > 0; count--, p--) { if (UCHAR(*p) < 0x80 && isspace(UCHAR(*p))) { chunkPtr->breakIndex = count; break; } } if ((bytesThatFit + byteOffset) == segPtr->size) { for (nextPtr = segPtr->nextPtr; nextPtr != NULL; nextPtr = nextPtr->nextPtr) { if (nextPtr->size != 0) { if (nextPtr->typePtr != &tkTextCharType) { chunkPtr->breakIndex = chunkPtr->numBytes; } break; } } } } return 1; } /* *--------------------------------------------------------------------------- * * CharChunkMeasureChars -- * * Determine the number of characters from a char chunk that will fit in * the given horizontal span. * * This is the same as MeasureChars (which see), but in the context of a * char chunk, i.e. on a higher level of abstraction. Use this function * whereever possible instead of plain MeasureChars, so that the right * context is used automatically. * * Results: * The return value is the number of bytes from the range of start to end * in source that fit in the span given by startX and maxX. *nextXPtr is * filled in with the x-coordinate at which the first character that * didn't fit would be drawn, if it were to be drawn. * * Side effects: * None. *-------------------------------------------------------------- */ static int CharChunkMeasureChars( TkTextDispChunk *chunkPtr, /* Chunk from which to measure. */ const char *chars, /* Chars to use, instead of the chunk's own. * Used by the layoutproc during chunk setup. * All other callers use NULL. Not * NUL-terminated. */ int charsLen, /* Length of the "chars" parameter. */ int start, int end, /* The range of chars to measure inside the * chunk (or inside the additional chars). */ int startX, /* Starting x coordinate where the measured * span will begin. */ int maxX, /* Maximum pixel width of the span. May be -1 * for unlimited. */ int flags, /* Flags to pass to MeasureChars. */ int *nextXPtr) /* The function puts the newly calculated * right border x-position of the span * here. */ { Tk_Font tkfont = chunkPtr->stylePtr->sValuePtr->tkfont; CharInfo *ciPtr = (CharInfo *) chunkPtr->clientData; #if !TK_LAYOUT_WITH_BASE_CHUNKS if (chars == NULL) { chars = ciPtr->chars; charsLen = ciPtr->numBytes; } if (end == -1) { end = charsLen; } return MeasureChars(tkfont, chars, charsLen, start, end-start, startX, maxX, flags, nextXPtr); #else { int xDisplacement; int fit, bstart = start, bend = end; if (chars == NULL) { Tcl_DString *baseChars = &((BaseCharInfo *) ciPtr->baseChunkPtr->clientData)->baseChars; chars = Tcl_DStringValue(baseChars); charsLen = Tcl_DStringLength(baseChars); bstart += ciPtr->baseOffset; if (bend == -1) { bend = ciPtr->baseOffset + ciPtr->numBytes; } else { bend += ciPtr->baseOffset; } } else if (bend == -1) { bend = charsLen; } if (bstart == ciPtr->baseOffset) { xDisplacement = startX - chunkPtr->x; } else { int widthUntilStart = 0; MeasureChars(tkfont, chars, charsLen, 0, bstart, 0, -1, 0, &widthUntilStart); xDisplacement = startX - widthUntilStart - chunkPtr->x; } fit = MeasureChars(tkfont, chars, charsLen, 0, bend, ciPtr->baseChunkPtr->x + xDisplacement, maxX, flags, nextXPtr); if (fit < bstart) { return 0; } else { return fit - bstart; } } #endif } /* *-------------------------------------------------------------- * * CharDisplayProc -- * * This function is called to display a character chunk on the screen or * in an off-screen pixmap. * * Results: * None. * * Side effects: * Graphics are drawn. * *-------------------------------------------------------------- */ static void CharDisplayProc( TkText *textPtr, TkTextDispChunk *chunkPtr, /* Chunk that is to be drawn. */ int x, /* X-position in dst at which to draw this * chunk (may differ from the x-position in * the chunk because of scrolling). */ int y, /* Y-position at which to draw this chunk in * dst. */ int height, /* Total height of line. */ int baseline, /* Offset of baseline from y. */ Display *display, /* Display to use for drawing. */ Drawable dst, /* Pixmap or window in which to draw chunk. */ int screenY) /* Y-coordinate in text window that * corresponds to y. */ { CharInfo *ciPtr = (CharInfo *) chunkPtr->clientData; const char *string; TextStyle *stylePtr; StyleValues *sValuePtr; int numBytes, offsetBytes, offsetX; #if TK_DRAW_IN_CONTEXT BaseCharInfo *bciPtr; #endif /* TK_DRAW_IN_CONTEXT */ if ((x + chunkPtr->width) <= 0) { /* * The chunk is off-screen. */ return; } #if TK_DRAW_IN_CONTEXT bciPtr = (BaseCharInfo *) ciPtr->baseChunkPtr->clientData; numBytes = Tcl_DStringLength(&bciPtr->baseChars); string = Tcl_DStringValue(&bciPtr->baseChars); #elif TK_LAYOUT_WITH_BASE_CHUNKS if (ciPtr->baseChunkPtr != chunkPtr) { /* * Without context drawing only base chunks display their foreground. */ return; } numBytes = Tcl_DStringLength(&((BaseCharInfo *) ciPtr)->baseChars); string = ciPtr->chars; #else /* !TK_LAYOUT_WITH_BASE_CHUNKS */ numBytes = ciPtr->numBytes; string = ciPtr->chars; #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ stylePtr = chunkPtr->stylePtr; sValuePtr = stylePtr->sValuePtr; /* * If the text sticks out way to the left of the window, skip over the * characters that aren't in the visible part of the window. This is * essential if x is very negative (such as less than 32K); otherwise * overflow problems will occur in servers that use 16-bit arithmetic, * like X. */ offsetX = x; offsetBytes = 0; if (x < 0) { offsetBytes = CharChunkMeasureChars(chunkPtr, NULL, 0, 0, -1, x, 0, 0, &offsetX); } /* * Draw the text, underline, and overstrike for this chunk. */ if (!sValuePtr->elide && (numBytes > offsetBytes) && (stylePtr->fgGC != None)) { #if TK_DRAW_IN_CONTEXT int start = ciPtr->baseOffset + offsetBytes; int len = ciPtr->numBytes - offsetBytes; int xDisplacement = x - chunkPtr->x; if ((len > 0) && (string[start + len - 1] == '\t')) { len--; } if (len <= 0) { return; } TkpDrawCharsInContext(display, dst, stylePtr->fgGC, sValuePtr->tkfont, string, numBytes, start, len, ciPtr->baseChunkPtr->x + xDisplacement, y + baseline - sValuePtr->offset); if (sValuePtr->underline) { TkUnderlineCharsInContext(display, dst, stylePtr->fgGC, sValuePtr->tkfont, string, numBytes, ciPtr->baseChunkPtr->x + xDisplacement, y + baseline - sValuePtr->offset, start, start+len); } if (sValuePtr->overstrike) { Tk_FontMetrics fm; Tk_GetFontMetrics(sValuePtr->tkfont, &fm); TkUnderlineCharsInContext(display, dst, stylePtr->fgGC, sValuePtr->tkfont, string, numBytes, ciPtr->baseChunkPtr->x + xDisplacement, y + baseline - sValuePtr->offset - fm.descent - (fm.ascent * 3) / 10, start, start+len); } #else /* !TK_DRAW_IN_CONTEXT */ string += offsetBytes; numBytes -= offsetBytes; if ((numBytes > 0) && (string[numBytes - 1] == '\t')) { numBytes--; } Tk_DrawChars(display, dst, stylePtr->fgGC, sValuePtr->tkfont, string, numBytes, offsetX, y + baseline - sValuePtr->offset); if (sValuePtr->underline) { Tk_UnderlineChars(display, dst, stylePtr->fgGC, sValuePtr->tkfont, string, offsetX, y + baseline - sValuePtr->offset, 0, numBytes); } if (sValuePtr->overstrike) { Tk_FontMetrics fm; Tk_GetFontMetrics(sValuePtr->tkfont, &fm); Tk_UnderlineChars(display, dst, stylePtr->fgGC, sValuePtr->tkfont, string, offsetX, y + baseline - sValuePtr->offset - fm.descent - (fm.ascent * 3) / 10, 0, numBytes); } #endif /* TK_DRAW_IN_CONTEXT */ } } /* *-------------------------------------------------------------- * * CharUndisplayProc -- * * This function is called when a character chunk is no longer going to * be displayed. It frees up resources that were allocated to display the * chunk. * * Results: * None. * * Side effects: * Memory and other resources get freed. * *-------------------------------------------------------------- */ static void CharUndisplayProc( TkText *textPtr, /* Overall information about text widget. */ TkTextDispChunk *chunkPtr) /* Chunk that is about to be freed. */ { CharInfo *ciPtr = (CharInfo *) chunkPtr->clientData; if (ciPtr) { #if TK_LAYOUT_WITH_BASE_CHUNKS if (chunkPtr == ciPtr->baseChunkPtr) { /* * Basechunks are undisplayed first, when DLines are freed or * partially freed, so this makes sure we don't access their data * any more. */ FreeBaseChunk(chunkPtr); } else if (ciPtr->baseChunkPtr != NULL) { /* * When other char chunks are undisplayed, drop their characters * from the base chunk. This usually happens, when they are last * in a line and need to be re-layed out. */ RemoveFromBaseChunk(chunkPtr); } ciPtr->baseChunkPtr = NULL; ciPtr->chars = NULL; ciPtr->numBytes = 0; #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ ckfree((char *) ciPtr); chunkPtr->clientData = NULL; } } /* *-------------------------------------------------------------- * * CharMeasureProc -- * * This function is called to determine which character in a character * chunk lies over a given x-coordinate. * * Results: * The return value is the index *within the chunk* of the character that * covers the position given by "x". * * Side effects: * None. * *-------------------------------------------------------------- */ static int CharMeasureProc( TkTextDispChunk *chunkPtr, /* Chunk containing desired coord. */ int x) /* X-coordinate, in same coordinate system as * chunkPtr->x. */ { int endX; return CharChunkMeasureChars(chunkPtr, NULL, 0, 0, chunkPtr->numBytes-1, chunkPtr->x, x, 0, &endX); /* CHAR OFFSET */ } /* *-------------------------------------------------------------- * * CharBboxProc -- * * This function is called to compute the bounding box of the area * occupied by a single character. * * Results: * There is no return value. *xPtr and *yPtr are filled in with the * coordinates of the upper left corner of the character, and *widthPtr * and *heightPtr are filled in with the dimensions of the character in * pixels. Note: not all of the returned bbox is necessarily visible on * the screen (the rightmost part might be off-screen to the right, and * the bottommost part might be off-screen to the bottom). * * Side effects: * None. * *-------------------------------------------------------------- */ static void CharBboxProc( TkText *textPtr, TkTextDispChunk *chunkPtr, /* Chunk containing desired char. */ int byteIndex, /* Byte offset of desired character within the * chunk. */ int y, /* Topmost pixel in area allocated for this * line. */ int lineHeight, /* Height of line, in pixels. */ int baseline, /* Location of line's baseline, in pixels * measured down from y. */ int *xPtr, int *yPtr, /* Gets filled in with coords of character's * upper-left pixel. X-coord is in same * coordinate system as chunkPtr->x. */ int *widthPtr, /* Gets filled in with width of character, in * pixels. */ int *heightPtr) /* Gets filled in with height of character, in * pixels. */ { CharInfo *ciPtr = (CharInfo *) chunkPtr->clientData; int maxX; maxX = chunkPtr->width + chunkPtr->x; CharChunkMeasureChars(chunkPtr, NULL, 0, 0, byteIndex, chunkPtr->x, -1, 0, xPtr); if (byteIndex == ciPtr->numBytes) { /* * This situation only happens if the last character in a line is a * space character, in which case it absorbs all of the extra space in * the line (see TkTextCharLayoutProc). */ *widthPtr = maxX - *xPtr; } else if ((ciPtr->chars[byteIndex] == '\t') && (byteIndex == ciPtr->numBytes - 1)) { /* * The desired character is a tab character that terminates a chunk; * give it all the space left in the chunk. */ *widthPtr = maxX - *xPtr; } else { CharChunkMeasureChars(chunkPtr, NULL, 0, byteIndex, byteIndex+1, *xPtr, -1, 0, widthPtr); if (*widthPtr > maxX) { *widthPtr = maxX - *xPtr; } else { *widthPtr -= *xPtr; } } *yPtr = y + baseline - chunkPtr->minAscent; *heightPtr = chunkPtr->minAscent + chunkPtr->minDescent; } /* *---------------------------------------------------------------------- * * AdjustForTab -- * * This function is called to move a series of chunks right in order to * align them with a tab stop. * * Results: * None. * * Side effects: * The width of chunkPtr gets adjusted so that it absorbs the extra space * due to the tab. The x locations in all the chunks after chunkPtr are * adjusted rightward to align with the tab stop given by tabArrayPtr and * index. * *---------------------------------------------------------------------- */ static void AdjustForTab( TkText *textPtr, /* Information about the text widget as a * whole. */ TkTextTabArray *tabArrayPtr,/* Information about the tab stops that apply * to this line. May be NULL to indicate * default tabbing (every 8 chars). */ int index, /* Index of current tab stop. */ TkTextDispChunk *chunkPtr) /* Chunk whose last character is the tab; the * following chunks contain information to be * shifted right. */ { int x, desired, delta, width, decimal, i, gotDigit; TkTextDispChunk *chunkPtr2, *decimalChunkPtr; CharInfo *ciPtr; int tabX, spaceWidth; const char *p; TkTextTabAlign alignment; if (chunkPtr->nextPtr == NULL) { /* * Nothing after the actual tab; just return. */ return; } x = chunkPtr->nextPtr->x; /* * If no tab information has been given, assuming tab stops are at 8 * average-sized characters. Still ensure we respect the tabular versus * wordprocessor tab style. */ if ((tabArrayPtr == NULL) || (tabArrayPtr->numTabs == 0)) { /* * No tab information has been given, so use the default * interpretation of tabs. */ if (textPtr->tabStyle == TK_TEXT_TABSTYLE_TABULAR) { int tabWidth = Tk_TextWidth(textPtr->tkfont, "0", 1) * 8; if (tabWidth == 0) { tabWidth = 1; } desired = tabWidth * (index + 1); } else { desired = NextTabStop(textPtr->tkfont, x, 0); } goto update; } if (index < tabArrayPtr->numTabs) { alignment = tabArrayPtr->tabs[index].alignment; tabX = tabArrayPtr->tabs[index].location; } else { /* * Ran out of tab stops; compute a tab position by extrapolating from * the last two tab positions. */ tabX = (int) (tabArrayPtr->lastTab + (index + 1 - tabArrayPtr->numTabs)*tabArrayPtr->tabIncrement + 0.5); alignment = tabArrayPtr->tabs[tabArrayPtr->numTabs-1].alignment; } if (alignment == LEFT) { desired = tabX; goto update; } if ((alignment == CENTER) || (alignment == RIGHT)) { /* * Compute the width of all the information in the tab group, then use * it to pick a desired location. */ width = 0; for (chunkPtr2 = chunkPtr->nextPtr; chunkPtr2 != NULL; chunkPtr2 = chunkPtr2->nextPtr) { width += chunkPtr2->width; } if (alignment == CENTER) { desired = tabX - width/2; } else { desired = tabX - width; } goto update; } /* * Must be numeric alignment. Search through the text to be tabbed, * looking for the last , or . before the first character that isn't a * number, comma, period, or sign. */ decimalChunkPtr = NULL; decimal = gotDigit = 0; for (chunkPtr2 = chunkPtr->nextPtr; chunkPtr2 != NULL; chunkPtr2 = chunkPtr2->nextPtr) { if (chunkPtr2->displayProc != CharDisplayProc) { continue; } ciPtr = (CharInfo *) chunkPtr2->clientData; for (p = ciPtr->chars, i = 0; i < ciPtr->numBytes; p++, i++) { if (isdigit(UCHAR(*p))) { gotDigit = 1; } else if ((*p == '.') || (*p == ',')) { decimal = p-ciPtr->chars; decimalChunkPtr = chunkPtr2; } else if (gotDigit) { if (decimalChunkPtr == NULL) { decimal = p-ciPtr->chars; decimalChunkPtr = chunkPtr2; } goto endOfNumber; } } } endOfNumber: if (decimalChunkPtr != NULL) { int curX; ciPtr = (CharInfo *) decimalChunkPtr->clientData; CharChunkMeasureChars(decimalChunkPtr, NULL, 0, 0, decimal, decimalChunkPtr->x, -1, 0, &curX); desired = tabX - (curX - x); goto update; } else { /* * There wasn't a decimal point. Right justify the text. */ width = 0; for (chunkPtr2 = chunkPtr->nextPtr; chunkPtr2 != NULL; chunkPtr2 = chunkPtr2->nextPtr) { width += chunkPtr2->width; } desired = tabX - width; } /* * Shift all of the chunks to the right so that the left edge is at the * desired location, then expand the chunk containing the tab. Be sure * that the tab occupies at least the width of a space character. */ update: delta = desired - x; MeasureChars(textPtr->tkfont, " ", 1, 0, 1, 0, -1, 0, &spaceWidth); if (delta < spaceWidth) { delta = spaceWidth; } for (chunkPtr2 = chunkPtr->nextPtr; chunkPtr2 != NULL; chunkPtr2 = chunkPtr2->nextPtr) { chunkPtr2->x += delta; } chunkPtr->width += delta; } /* *---------------------------------------------------------------------- * * SizeOfTab -- * * This returns an estimate of the amount of white space that will be * consumed by a tab. * * Results: * The return value is the minimum number of pixels that will be occupied * by the next tab of tabArrayPtr, assuming that the current position on * the line is x and the end of the line is maxX. The 'next tab' is * determined by a combination of the current position (x) which it must * be equal to or beyond, and the tab count in indexPtr. * * For numeric tabs, this is a conservative estimate. The return value is * always >= 0. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int SizeOfTab( TkText *textPtr, /* Information about the text widget as a * whole. */ int tabStyle, /* One of TK_TEXT_TABSTYLE_TABULAR * or TK_TEXT_TABSTYLE_WORDPROCESSOR. */ TkTextTabArray *tabArrayPtr,/* Information about the tab stops that apply * to this line. NULL means use default * tabbing (every 8 chars.) */ int *indexPtr, /* Contains index of previous tab stop, will * be updated to reflect the number of stops * used. */ int x, /* Current x-location in line. */ int maxX) /* X-location of pixel just past the right * edge of the line. */ { int tabX, result, index, spaceWidth, tabWidth; TkTextTabAlign alignment; index = *indexPtr; if ((tabArrayPtr == NULL) || (tabArrayPtr->numTabs == 0)) { /* * We're using a default tab spacing of 8 characters. */ tabWidth = Tk_TextWidth(textPtr->tkfont, "0", 1) * 8; if (tabWidth == 0) { tabWidth = 1; } } else { tabWidth = 0; /* Avoid compiler error. */ } do { /* * We were given the count before this tab, so increment it first. */ index++; if ((tabArrayPtr == NULL) || (tabArrayPtr->numTabs == 0)) { /* * We're using a default tab spacing calculated above. */ tabX = tabWidth * (index + 1); alignment = LEFT; } else if (index < tabArrayPtr->numTabs) { tabX = tabArrayPtr->tabs[index].location; alignment = tabArrayPtr->tabs[index].alignment; } else { /* * Ran out of tab stops; compute a tab position by extrapolating. */ tabX = (int) (tabArrayPtr->lastTab + (index + 1 - tabArrayPtr->numTabs) * tabArrayPtr->tabIncrement + 0.5); alignment = tabArrayPtr->tabs[tabArrayPtr->numTabs-1].alignment; } /* * If this tab stop is before the current x position, then we have two * cases: * * With 'wordprocessor' style tabs, we must obviously continue until * we reach the text tab stop. * * With 'tabular' style tabs, we always use the index'th tab stop. */ } while (tabX <= x && (tabStyle == TK_TEXT_TABSTYLE_WORDPROCESSOR)); /* * Inform our caller of how many tab stops we've used up. */ *indexPtr = index; if (alignment == CENTER) { /* * Be very careful in the arithmetic below, because maxX may be the * largest positive number: watch out for integer overflow. */ if ((maxX-tabX) < (tabX - x)) { result = (maxX - x) - 2*(maxX - tabX); } else { result = 0; } goto done; } if (alignment == RIGHT) { result = 0; goto done; } /* * Note: this treats NUMERIC alignment the same as LEFT alignment, which * is somewhat conservative. However, it's pretty tricky at this point to * figure out exactly where the damn decimal point will be. */ if (tabX > x) { result = tabX - x; } else { result = 0; } done: MeasureChars(textPtr->tkfont, " ", 1, 0, 1, 0, -1, 0, &spaceWidth); if (result < spaceWidth) { result = spaceWidth; } return result; } /* *--------------------------------------------------------------------------- * * NextTabStop -- * * Given the current position, determine where the next default tab stop * would be located. This function is called when the current chunk in * the text has no tabs defined and so the default tab spacing for the * font should be used, provided we are using wordprocessor style tabs. * * Results: * The location in pixels of the next tab stop. * * Side effects: * None. * *--------------------------------------------------------------------------- */ static int NextTabStop( Tk_Font tkfont, /* Font in which chunk that contains tab stop * will be drawn. */ int x, /* X-position in pixels where last character * was drawn. The next tab stop occurs * somewhere after this location. */ int tabOrigin) /* The origin for tab stops. May be non-zero * if text has been scrolled. */ { int tabWidth, rem; tabWidth = Tk_TextWidth(tkfont, "0", 1) * 8; if (tabWidth == 0) { tabWidth = 1; } x += tabWidth; rem = (x - tabOrigin) % tabWidth; if (rem < 0) { rem += tabWidth; } x -= rem; return x; } /* *--------------------------------------------------------------------------- * * MeasureChars -- * * Determine the number of characters from the string that will fit in * the given horizontal span. The measurement is done under the * assumption that Tk_DrawChars will be used to actually display the * characters. * * If tabs are encountered in the string, they will be ignored (they * should only occur as last character of the string anyway). * * If a newline is encountered in the string, the line will be broken at * that point. * * Results: * The return value is the number of bytes from the range of start to end * in source that fit in the span given by startX and maxX. *nextXPtr is * filled in with the x-coordinate at which the first character that * didn't fit would be drawn, if it were to be drawn. * * Side effects: * None. * *-------------------------------------------------------------- */ static int MeasureChars( Tk_Font tkfont, /* Font in which to draw characters. */ CONST char *source, /* Characters to be displayed. Need not be * NULL-terminated. */ int maxBytes, /* Maximum # of bytes to consider from * source. */ int rangeStart, int rangeLength, /* Range of bytes to consider in source.*/ int startX, /* X-position at which first character will be * drawn. */ int maxX, /* Don't consider any character that would * cross this x-position. */ int flags, /* Flags to pass to Tk_MeasureChars. */ int *nextXPtr) /* Return x-position of terminating character * here. */ { int curX, width, ch; CONST char *special, *end, *start; ch = 0; /* lint. */ curX = startX; start = source + rangeStart; end = start + rangeLength; special = start; while (start < end) { if (start >= special) { /* * Find the next special character in the string. */ for (special = start; special < end; special++) { ch = *special; if ((ch == '\t') || (ch == '\n')) { break; } } } /* * Special points at the next special character (or the end of the * string). Process characters between start and special. */ if ((maxX >= 0) && (curX >= maxX)) { break; } #if TK_DRAW_IN_CONTEXT start += TkpMeasureCharsInContext(tkfont, source, maxBytes, start - source, special - start, maxX >= 0 ? maxX - curX : -1, flags, &width); #else (void) maxBytes; start += Tk_MeasureChars(tkfont, start, special - start, maxX >= 0 ? maxX - curX : -1, flags, &width); #endif /* TK_DRAW_IN_CONTEXT */ curX += width; if (start < special) { /* * No more chars fit in line. */ break; } if (special < end) { if (ch == '\t') { start++; } else { break; } } } *nextXPtr = curX; return start - (source+rangeStart); } /* *---------------------------------------------------------------------- * * TextGetScrollInfoObj -- * * This function is invoked to parse "xview" and "yview" scrolling * commands for text widgets using the new scrolling command syntax * ("moveto" or "scroll" options). It extends the public * Tk_GetScrollInfoObj function with the addition of "pixels" as a valid * unit alongside "pages" and "units". It is a shame the core API isn't * more flexible in this regard. * * Results: * The return value is either TKTEXT_SCROLL_MOVETO, TKTEXT_SCROLL_PAGES, * TKTEXT_SCROLL_UNITS, TKTEXT_SCROLL_PIXELS or TKTEXT_SCROLL_ERROR. This * indicates whether the command was successfully parsed and what form * the command took. If TKTEXT_SCROLL_MOVETO, *dblPtr is filled in with * the desired position; if TKTEXT_SCROLL_PAGES, TKTEXT_SCROLL_PIXELS or * TKTEXT_SCROLL_UNITS, *intPtr is filled in with the number of * pages/pixels/lines to move (may be negative); if TKTEXT_SCROLL_ERROR, * the interp's result contains an error message. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int TextGetScrollInfoObj( Tcl_Interp *interp, /* Used for error reporting. */ TkText *textPtr, /* Information about the text widget. */ int objc, /* # arguments for command. */ Tcl_Obj *CONST objv[], /* Arguments for command. */ double *dblPtr, /* Filled in with argument "moveto" option, if * any. */ int *intPtr) /* Filled in with number of pages or lines or * pixels to scroll, if any. */ { static CONST char *subcommands[] = { "moveto", "scroll", NULL }; enum viewSubcmds { VIEW_MOVETO, VIEW_SCROLL }; static CONST char *units[] = { "units", "pages", "pixels", NULL }; enum viewUnits { VIEW_SCROLL_UNITS, VIEW_SCROLL_PAGES, VIEW_SCROLL_PIXELS }; int index; if (Tcl_GetIndexFromObj(interp, objv[2], subcommands, "option", 0, &index) != TCL_OK) { return TKTEXT_SCROLL_ERROR; } switch ((enum viewSubcmds) index) { case VIEW_MOVETO: if (objc != 4) { Tcl_WrongNumArgs(interp, 3, objv, "fraction"); return TKTEXT_SCROLL_ERROR; } if (Tcl_GetDoubleFromObj(interp, objv[3], dblPtr) != TCL_OK) { return TKTEXT_SCROLL_ERROR; } return TKTEXT_SCROLL_MOVETO; case VIEW_SCROLL: if (objc != 5) { Tcl_WrongNumArgs(interp, 3, objv, "number units|pages|pixels"); return TKTEXT_SCROLL_ERROR; } if (Tcl_GetIndexFromObj(interp, objv[4], units, "argument", 0, &index) != TCL_OK) { return TKTEXT_SCROLL_ERROR; } switch ((enum viewUnits) index) { case VIEW_SCROLL_PAGES: if (Tcl_GetIntFromObj(interp, objv[3], intPtr) != TCL_OK) { return TKTEXT_SCROLL_ERROR; } return TKTEXT_SCROLL_PAGES; case VIEW_SCROLL_PIXELS: if (Tk_GetPixelsFromObj(interp, textPtr->tkwin, objv[3], intPtr) != TCL_OK) { return TKTEXT_SCROLL_ERROR; } return TKTEXT_SCROLL_PIXELS; case VIEW_SCROLL_UNITS: if (Tcl_GetIntFromObj(interp, objv[3], intPtr) != TCL_OK) { return TKTEXT_SCROLL_ERROR; } return TKTEXT_SCROLL_UNITS; } } Tcl_Panic("unexpected switch fallthrough"); return TKTEXT_SCROLL_ERROR; } #if TK_LAYOUT_WITH_BASE_CHUNKS /* *---------------------------------------------------------------------- * * FinalizeBaseChunk -- * * This procedure makes sure that all the chunks of the stretch are * up-to-date. It is invoked when the LayoutProc has been called for all * chunks and the base chunk is stable. * * Results: * None. * * Side effects: * The CharInfo.chars of all dependent chunks point into * BaseCharInfo.baseChars for easy access (and compatibility). * *---------------------------------------------------------------------- */ static void FinalizeBaseChunk( TkTextDispChunk *addChunkPtr) /* An additional chunk to add to the stretch, * even though it may not be in the linked * list yet. Used by the LayoutProc, otherwise * NULL. */ { const char *baseChars; TkTextDispChunk *chunkPtr; CharInfo *ciPtr; #if TK_DRAW_IN_CONTEXT int widthAdjust = 0; int newwidth; #endif /* TK_DRAW_IN_CONTEXT */ if (baseCharChunkPtr == NULL) { return; } baseChars = Tcl_DStringValue( &((BaseCharInfo *) baseCharChunkPtr->clientData)->baseChars); for (chunkPtr = baseCharChunkPtr; chunkPtr != NULL; chunkPtr = chunkPtr->nextPtr) { #if TK_DRAW_IN_CONTEXT chunkPtr->x += widthAdjust; #endif /* TK_DRAW_IN_CONTEXT */ if (chunkPtr->displayProc != CharDisplayProc) { continue; } ciPtr = (CharInfo *)chunkPtr->clientData; if (ciPtr->baseChunkPtr != baseCharChunkPtr) { break; } ciPtr->chars = baseChars + ciPtr->baseOffset; #if TK_DRAW_IN_CONTEXT newwidth = 0; CharChunkMeasureChars(chunkPtr, NULL, 0, 0, -1, 0, -1, 0, &newwidth); if (newwidth != chunkPtr->width) { widthAdjust += newwidth - chunkPtr->width; chunkPtr->width = newwidth; } #endif /* TK_DRAW_IN_CONTEXT */ } if (addChunkPtr != NULL) { ciPtr = (CharInfo *)addChunkPtr->clientData; ciPtr->chars = baseChars + ciPtr->baseOffset; #if TK_DRAW_IN_CONTEXT addChunkPtr->x += widthAdjust; CharChunkMeasureChars(addChunkPtr, NULL, 0, 0, -1, 0, -1, 0, &addChunkPtr->width); #endif /* TK_DRAW_IN_CONTEXT */ } baseCharChunkPtr = NULL; } /* *---------------------------------------------------------------------- * * FreeBaseChunk -- * * This procedure makes sure that all the chunks of the stretch are * disconnected from the base chunk and the base chunk specific data is * freed. It is invoked from the UndisplayProc. The procedure doesn't * ckfree the base chunk clientData itself, that's up to the main * UndisplayProc. * * Results: * None. * * Side effects: * The CharInfo.chars of all dependent chunks are set to NULL. Memory * that belongs specifically to the base chunk is freed. * *---------------------------------------------------------------------- */ static void FreeBaseChunk( TkTextDispChunk *baseChunkPtr) /* The base chunk of the stretch and head of * the linked list. */ { TkTextDispChunk *chunkPtr; CharInfo *ciPtr; if (baseCharChunkPtr == baseChunkPtr) { baseCharChunkPtr = NULL; } for (chunkPtr=baseChunkPtr; chunkPtr!=NULL; chunkPtr=chunkPtr->nextPtr) { if (chunkPtr->undisplayProc != CharUndisplayProc) { continue; } ciPtr = (CharInfo *) chunkPtr->clientData; if (ciPtr->baseChunkPtr != baseChunkPtr) { break; } ciPtr->baseChunkPtr = NULL; ciPtr->chars = NULL; } Tcl_DStringFree(&((BaseCharInfo *) baseChunkPtr->clientData)->baseChars); } /* *---------------------------------------------------------------------- * * IsSameFGStyle -- * * Compare the foreground attributes of two styles. Specifically must * consider: foreground color, font, font style and font decorations, * elide, "offset" and foreground stipple. Do *not* consider: background * color, border, relief or background stipple. * * If we use TkpDrawCharsInContext(), we also don't need to check * foreground color, font decorations, elide, offset and foreground * stipple, so all that is left is font (including font size and font * style) and "offset". * * Results: * 1 if the two styles match, 0 otherwise. * * Side effects: * None. * *---------------------------------------------------------------------- */ static int IsSameFGStyle( TextStyle *style1, TextStyle *style2) { StyleValues *sv1; StyleValues *sv2; if (style1 == style2) { return 1; } #if !TK_DRAW_IN_CONTEXT if ( #ifdef MAC_OSX_TK !TkMacOSXCompareColors(style1->fgGC->foreground, style2->fgGC->foreground) #else style1->fgGC->foreground != style2->fgGC->foreground #endif ) { return 0; } #endif /* !TK_DRAW_IN_CONTEXT */ sv1 = style1->sValuePtr; sv2 = style2->sValuePtr; #if TK_DRAW_IN_CONTEXT return sv1->tkfont == sv2->tkfont && sv1->offset == sv2->offset; #else return sv1->tkfont == sv2->tkfont && sv1->underline == sv2->underline && sv1->overstrike == sv2->overstrike && sv1->elide == sv2->elide && sv1->offset == sv2->offset && sv1->fgStipple == sv1->fgStipple; #endif /* TK_DRAW_IN_CONTEXT */ } /* *---------------------------------------------------------------------- * * RemoveFromBaseChunk -- * * This procedure removes a chunk from the stretch as a result of * UndisplayProc. The chunk in question should be the last in a stretch. * This happens during re-layouting of the break position. * * Results: * None. * * Side effects: * The characters that belong to this chunk are removed from the base * chunk. It is assumed that LayoutProc and FinalizeBaseChunk are called * next to repair any damage that this causes to the integrity of the * stretch and the other chunks. For that reason the base chunk is also * put into baseCharChunkPtr automatically, so that LayoutProc can resume * correctly. * *---------------------------------------------------------------------- */ static void RemoveFromBaseChunk( TkTextDispChunk *chunkPtr) /* The chunk to remove from the end of the * stretch. */ { CharInfo *ciPtr; BaseCharInfo *bciPtr; if (chunkPtr->displayProc != CharDisplayProc) { #ifdef DEBUG_LAYOUT_WITH_BASE_CHUNKS fprintf(stderr,"RemoveFromBaseChunk called with wrong chunk type\n"); #endif return; } /* * Reinstitute this base chunk for re-layout. */ ciPtr = (CharInfo *) chunkPtr->clientData; baseCharChunkPtr = ciPtr->baseChunkPtr; /* * Remove the chunk data from the base chunk data. */ bciPtr = (BaseCharInfo *) baseCharChunkPtr->clientData; if ((ciPtr->baseOffset + ciPtr->numBytes) != Tcl_DStringLength(&bciPtr->baseChars)) { #ifdef DEBUG_LAYOUT_WITH_BASE_CHUNKS fprintf(stderr,"RemoveFromBaseChunk called with wrong chunk " "(not last)\n"); #endif } Tcl_DStringSetLength(&bciPtr->baseChars, ciPtr->baseOffset); /* * Invalidate the stored pixel width of the base chunk. */ bciPtr->width = -1; } #endif /* TK_LAYOUT_WITH_BASE_CHUNKS */ /* * Local Variables: * mode: c * c-basic-offset: 4 * fill-column: 78 * End: */