/* * tkCanvUtil.c -- * * This file contains a collection of utility functions used by the * implementations of various canvas item types. * * Copyright (c) 1994 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 "tkCanvas.h" /* * Structures defined only in this file. */ typedef struct SmoothAssocData { struct SmoothAssocData *nextPtr; /* Pointer to next SmoothAssocData. */ Tk_SmoothMethod smooth; /* Name and functions associated with this * option. */ } SmoothAssocData; const Tk_SmoothMethod tkBezierSmoothMethod = { "true", TkMakeBezierCurve, (void (*) (Tcl_Interp *interp, Tk_Canvas canvas, double *coordPtr, int numPoints, int numSteps))(void *)TkMakeBezierPostscript, }; static const Tk_SmoothMethod tkRawSmoothMethod = { "raw", TkMakeRawCurve, (void (*) (Tcl_Interp *interp, Tk_Canvas canvas, double *coordPtr, int numPoints, int numSteps))(void *)TkMakeRawCurvePostscript, }; /* * Function forward-declarations. */ static void SmoothMethodCleanupProc(ClientData clientData, Tcl_Interp *interp); static SmoothAssocData *InitSmoothMethods(Tcl_Interp *interp); static int DashConvert(char *l, const char *p, int n, double width); static void TranslateAndAppendCoords(TkCanvas *canvPtr, double x, double y, XPoint *outArr, int numOut); static inline Tcl_Obj * GetPostscriptBuffer(Tcl_Interp *interp); #define ABS(a) ((a>=0)?(a):(-(a))) static inline Tcl_Obj * GetPostscriptBuffer( Tcl_Interp *interp) { Tcl_Obj *psObj = Tcl_GetObjResult(interp); if (Tcl_IsShared(psObj)) { psObj = Tcl_DuplicateObj(psObj); Tcl_SetObjResult(interp, psObj); } return psObj; } /* *---------------------------------------------------------------------- * * Tk_CanvasTkwin -- * * Given a token for a canvas, this function returns the widget that * represents the canvas. * * Results: * The return value is a handle for the widget. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tk_Window Tk_CanvasTkwin( Tk_Canvas canvas) /* Token for the canvas. */ { return Canvas(canvas)->tkwin; } /* *---------------------------------------------------------------------- * * Tk_CanvasDrawableCoords -- * * Given an (x,y) coordinate pair within a canvas, this function * returns the corresponding coordinates at which the point should * be drawn in the drawable used for display. * * Results: * There is no return value. The values at *drawableXPtr and * *drawableYPtr are filled in with the coordinates at which x and y * should be drawn. These coordinates are clipped to fit within a * "short", since this is what X uses in most cases for drawing. * * Side effects: * None. * *---------------------------------------------------------------------- */ void Tk_CanvasDrawableCoords( Tk_Canvas canvas, /* Token for the canvas. */ double x, /* Coordinates in canvas space. */ double y, short *drawableXPtr, /* Screen coordinates are stored here. */ short *drawableYPtr) { double tmp; tmp = x - Canvas(canvas)->drawableXOrigin; if (tmp > 0) { tmp += 0.5; } else { tmp -= 0.5; } if (tmp > 32767) { *drawableXPtr = 32767; } else if (tmp < -32768) { *drawableXPtr = -32768; } else { *drawableXPtr = (short) tmp; } tmp = y - Canvas(canvas)->drawableYOrigin; if (tmp > 0) { tmp += 0.5; } else { tmp -= 0.5; } if (tmp > 32767) { *drawableYPtr = 32767; } else if (tmp < -32768) { *drawableYPtr = -32768; } else { *drawableYPtr = (short) tmp; } } /* *---------------------------------------------------------------------- * * Tk_CanvasWindowCoords -- * * Given an (x,y) coordinate pair within a canvas, this function returns * the corresponding coordinates in the canvas's window. * * Results: * There is no return value. The values at *screenXPtr and *screenYPtr * are filled in with the coordinates at which (x,y) appears in the * canvas's window. These coordinates are clipped to fit within a * "short", since this is what X uses in most cases for drawing. * * Side effects: * None. * *---------------------------------------------------------------------- */ void Tk_CanvasWindowCoords( Tk_Canvas canvas, /* Token for the canvas. */ double x, /* Coordinates in canvas space. */ double y, short *screenXPtr, /* Screen coordinates are stored here. */ short *screenYPtr) { double tmp; tmp = x - Canvas(canvas)->xOrigin; if (tmp > 0) { tmp += 0.5; } else { tmp -= 0.5; } if (tmp > 32767) { *screenXPtr = 32767; } else if (tmp < -32768) { *screenXPtr = -32768; } else { *screenXPtr = (short) tmp; } tmp = y - Canvas(canvas)->yOrigin; if (tmp > 0) { tmp += 0.5; } else { tmp -= 0.5; } if (tmp > 32767) { *screenYPtr = 32767; } else if (tmp < -32768) { *screenYPtr = -32768; } else { *screenYPtr = (short) tmp; } } /* *-------------------------------------------------------------- * * Tk_CanvasGetCoord -- * * Given a string, returns a floating-point canvas coordinate * corresponding to that string. * * Results: * The return value is a standard Tcl return result. If TCL_OK is * returned, then everything went well and the canvas coordinate is * stored at *doublePtr; otherwise TCL_ERROR is returned and an error * message is left in the interp's result. * * Side effects: * None. * *-------------------------------------------------------------- */ int Tk_CanvasGetCoord( Tcl_Interp *interp, /* Interpreter for error reporting. */ Tk_Canvas canvas, /* Canvas to which coordinate applies. */ const char *string, /* Describes coordinate (any screen coordinate * form may be used here). */ double *doublePtr) /* Place to store converted coordinate. */ { if (Tk_GetScreenMM(Canvas(canvas)->interp, Canvas(canvas)->tkwin, string, doublePtr) != TCL_OK) { return TCL_ERROR; } *doublePtr *= Canvas(canvas)->pixelsPerMM; return TCL_OK; } /* *-------------------------------------------------------------- * * Tk_CanvasGetCoordFromObj -- * * Given a string, returns a floating-point canvas coordinate * corresponding to that string. * * Results: * The return value is a standard Tcl return result. If TCL_OK is * returned, then everything went well and the canvas coordinate is * stored at *doublePtr; otherwise TCL_ERROR is returned and an error * message is left in interp->result. * * Side effects: * None. * *-------------------------------------------------------------- */ int Tk_CanvasGetCoordFromObj( Tcl_Interp *interp, /* Interpreter for error reporting. */ Tk_Canvas canvas, /* Canvas to which coordinate applies. */ Tcl_Obj *obj, /* Describes coordinate (any screen coordinate * form may be used here). */ double *doublePtr) /* Place to store converted coordinate. */ { return Tk_GetDoublePixelsFromObj(Canvas(canvas)->interp, Canvas(canvas)->tkwin, obj, doublePtr); } /* *---------------------------------------------------------------------- * * Tk_CanvasSetStippleOrigin -- * * This function sets the stipple origin in a graphics context so that * stipples drawn with the GC will line up with other stipples previously * drawn in the canvas. * * Results: * None. * * Side effects: * The graphics context is modified. * *---------------------------------------------------------------------- */ void Tk_CanvasSetStippleOrigin( Tk_Canvas canvas, /* Token for a canvas. */ GC gc) /* Graphics context that is about to be used * to draw a stippled pattern as part of * redisplaying the canvas. */ { XSetTSOrigin(Canvas(canvas)->display, gc, -Canvas(canvas)->drawableXOrigin, -Canvas(canvas)->drawableYOrigin); } /* *---------------------------------------------------------------------- * * Tk_CanvasSetOffset-- * * This function sets the stipple offset in a graphics context so that * stipples drawn with the GC will line up with other stipples with the * same offset. * * Results: * None. * * Side effects: * The graphics context is modified. * *---------------------------------------------------------------------- */ void Tk_CanvasSetOffset( Tk_Canvas canvas, /* Token for a canvas. */ GC gc, /* Graphics context that is about to be used * to draw a stippled pattern as part of * redisplaying the canvas. */ Tk_TSOffset *offset) /* Offset (may be NULL pointer)*/ { register TkCanvas *canvasPtr = Canvas(canvas); int flags = 0; int x = - canvasPtr->drawableXOrigin; int y = - canvasPtr->drawableYOrigin; if (offset != NULL) { flags = offset->flags; x += offset->xoffset; y += offset->yoffset; } if ((flags & TK_OFFSET_RELATIVE) && !(flags & TK_OFFSET_INDEX)) { Tk_SetTSOrigin(canvasPtr->tkwin, gc, x - canvasPtr->xOrigin, y - canvasPtr->yOrigin); } else { XSetTSOrigin(canvasPtr->display, gc, x, y); } } /* *---------------------------------------------------------------------- * * Tk_CanvasGetTextInfo -- * * This function returns a pointer to a structure containing information * about the selection and insertion cursor for a canvas widget. Items * such as text items save the pointer and use it to share access to the * information with the generic canvas code. * * Results: * The return value is a pointer to the structure holding text * information for the canvas. Most of the fields should not be modified * outside the generic canvas code; see the user documentation for * details. * * Side effects: * None. * *---------------------------------------------------------------------- */ Tk_CanvasTextInfo * Tk_CanvasGetTextInfo( Tk_Canvas canvas) /* Token for the canvas widget. */ { return &Canvas(canvas)->textInfo; } /* *-------------------------------------------------------------- * * Tk_CanvasTagsParseProc -- * * This function is invoked during option processing to handle "-tags" * options for canvas items. * * Results: * A standard Tcl return value. * * Side effects: * The tags for a given item get replaced by those indicated in the value * argument. * *-------------------------------------------------------------- */ int Tk_CanvasTagsParseProc( ClientData clientData, /* Not used.*/ Tcl_Interp *interp, /* Used for reporting errors. */ Tk_Window tkwin, /* Window containing canvas widget. */ const char *value, /* Value of option (list of tag names). */ char *widgRec, /* Pointer to record for item. */ int offset) /* Offset into item (ignored). */ { register Tk_Item *itemPtr = (Tk_Item *) widgRec; int argc, i; const char **argv; Tk_Uid *newPtr; /* * Break the value up into the individual tag names. */ if (Tcl_SplitList(interp, value, &argc, &argv) != TCL_OK) { return TCL_ERROR; } /* * Make sure that there's enough space in the item to hold the tag names. */ if (itemPtr->tagSpace < argc) { newPtr = ckalloc(argc * sizeof(Tk_Uid)); for (i = itemPtr->numTags-1; i >= 0; i--) { newPtr[i] = itemPtr->tagPtr[i]; } if (itemPtr->tagPtr != itemPtr->staticTagSpace) { ckfree(itemPtr->tagPtr); } itemPtr->tagPtr = newPtr; itemPtr->tagSpace = argc; } itemPtr->numTags = argc; for (i = 0; i < argc; i++) { itemPtr->tagPtr[i] = Tk_GetUid(argv[i]); } ckfree(argv); return TCL_OK; } /* *-------------------------------------------------------------- * * Tk_CanvasTagsPrintProc -- * * This function is invoked by the Tk configuration code to produce a * printable string for the "-tags" configuration option for canvas * items. * * Results: * The return value is a string describing all the tags for the item * referred to by "widgRec". In addition, *freeProcPtr is filled in with * the address of a function to call to free the result string when it's * no longer needed (or NULL to indicate that the string doesn't need to * be freed). * * Side effects: * None. * *-------------------------------------------------------------- */ const char * Tk_CanvasTagsPrintProc( ClientData clientData, /* Ignored. */ Tk_Window tkwin, /* Window containing canvas widget. */ char *widgRec, /* Pointer to record for item. */ int offset, /* Ignored. */ Tcl_FreeProc **freeProcPtr) /* Pointer to variable to fill in with * information about how to reclaim storage * for return string. */ { register Tk_Item *itemPtr = (Tk_Item *) widgRec; if (itemPtr->numTags == 0) { *freeProcPtr = NULL; return ""; } if (itemPtr->numTags == 1) { *freeProcPtr = NULL; return (const char *) itemPtr->tagPtr[0]; } *freeProcPtr = TCL_DYNAMIC; return Tcl_Merge(itemPtr->numTags, (const char **) itemPtr->tagPtr); } /* *-------------------------------------------------------------- * * TkCanvasDashParseProc -- * * This function is invoked during option processing to handle "-dash", * "-activedash" and "-disableddash" options for canvas objects. * * Results: * A standard Tcl return value. * * Side effects: * The dash list for a given canvas object gets replaced by those * indicated in the value argument. * *-------------------------------------------------------------- */ int TkCanvasDashParseProc( ClientData clientData, /* Not used.*/ Tcl_Interp *interp, /* Used for reporting errors. */ Tk_Window tkwin, /* Window containing canvas widget. */ const char *value, /* Value of option. */ char *widgRec, /* Pointer to record for item. */ int offset) /* Offset into item. */ { return Tk_GetDash(interp, value, (Tk_Dash *) (widgRec+offset)); } /* *-------------------------------------------------------------- * * TkCanvasDashPrintProc -- * * This function is invoked by the Tk configuration code to produce a * printable string for the "-dash", "-activedash" and "-disableddash" * configuration options for canvas items. * * Results: * The return value is a string describing all the dash list for the item * referred to by "widgRec"and "offset". In addition, *freeProcPtr is * filled in with the address of a function to call to free the result * string when it's no longer needed (or NULL to indicate that the string * doesn't need to be freed). * * Side effects: * None. * *-------------------------------------------------------------- */ const char * TkCanvasDashPrintProc( ClientData clientData, /* Ignored. */ Tk_Window tkwin, /* Window containing canvas widget. */ char *widgRec, /* Pointer to record for item. */ int offset, /* Offset in record for item. */ Tcl_FreeProc **freeProcPtr) /* Pointer to variable to fill in with * information about how to reclaim storage * for return string. */ { Tk_Dash *dash = (Tk_Dash *) (widgRec+offset); char *buffer, *p; int i = dash->number; if (i < 0) { i = -i; *freeProcPtr = TCL_DYNAMIC; buffer = ckalloc(i + 1); p = (i > (int)sizeof(char *)) ? dash->pattern.pt : dash->pattern.array; memcpy(buffer, p, (unsigned int) i); buffer[i] = 0; return buffer; } else if (!i) { *freeProcPtr = NULL; return ""; } buffer = ckalloc(4 * i); *freeProcPtr = TCL_DYNAMIC; p = (i > (int)sizeof(char *)) ? dash->pattern.pt : dash->pattern.array; sprintf(buffer, "%d", *p++ & 0xff); while (--i) { sprintf(buffer+strlen(buffer), " %d", *p++ & 0xff); } return buffer; } /* *-------------------------------------------------------------- * * InitSmoothMethods -- * * This function is invoked to set up the initial state of the list of * "-smooth" methods. It should only be called when the list installed * in the interpreter is NULL. * * Results: * Pointer to the start of the list of default smooth methods. * * Side effects: * A linked list of smooth methods is created and attached to the * interpreter's association key "smoothMethod" * *-------------------------------------------------------------- */ static SmoothAssocData * InitSmoothMethods( Tcl_Interp *interp) { SmoothAssocData *methods, *ptr; methods = ckalloc(sizeof(SmoothAssocData)); methods->smooth.name = tkRawSmoothMethod.name; methods->smooth.coordProc = tkRawSmoothMethod.coordProc; methods->smooth.postscriptProc = tkRawSmoothMethod.postscriptProc; ptr = methods->nextPtr = ckalloc(sizeof(SmoothAssocData)); ptr->smooth.name = tkBezierSmoothMethod.name; ptr->smooth.coordProc = tkBezierSmoothMethod.coordProc; ptr->smooth.postscriptProc = tkBezierSmoothMethod.postscriptProc; ptr->nextPtr = NULL; Tcl_SetAssocData(interp, "smoothMethod", SmoothMethodCleanupProc,methods); return methods; } /* *-------------------------------------------------------------- * * Tk_CreateSmoothMethod -- * * This function is invoked to add additional values for the "-smooth" * option to the list. * * Results: * A standard Tcl return value. * * Side effects: * In the future "-smooth " will be accepted as smooth method for * the line and polygon. * *-------------------------------------------------------------- */ void Tk_CreateSmoothMethod( Tcl_Interp *interp, const Tk_SmoothMethod *smooth) { SmoothAssocData *methods, *typePtr2, *prevPtr, *ptr; methods = Tcl_GetAssocData(interp, "smoothMethod", NULL); /* * Initialize if we were not previously initialized. */ if (methods == NULL) { methods = InitSmoothMethods(interp); } /* * If there's already a smooth method with the given name, remove it. */ for (typePtr2 = methods, prevPtr = NULL; typePtr2 != NULL; prevPtr = typePtr2, typePtr2 = typePtr2->nextPtr) { if (!strcmp(typePtr2->smooth.name, smooth->name)) { if (prevPtr == NULL) { methods = typePtr2->nextPtr; } else { prevPtr->nextPtr = typePtr2->nextPtr; } ckfree(typePtr2); break; } } ptr = ckalloc(sizeof(SmoothAssocData)); ptr->smooth.name = smooth->name; ptr->smooth.coordProc = smooth->coordProc; ptr->smooth.postscriptProc = smooth->postscriptProc; ptr->nextPtr = methods; Tcl_SetAssocData(interp, "smoothMethod", SmoothMethodCleanupProc, ptr); } /* *---------------------------------------------------------------------- * * SmoothMethodCleanupProc -- * * This function is invoked whenever an interpreter is deleted to * cleanup the smooth methods. * * Results: * None. * * Side effects: * Smooth methods are removed. * *---------------------------------------------------------------------- */ static void SmoothMethodCleanupProc( ClientData clientData, /* Points to "smoothMethod" AssocData for the * interpreter. */ Tcl_Interp *interp) /* Interpreter that is being deleted. */ { SmoothAssocData *ptr, *methods = clientData; while (methods != NULL) { ptr = methods; methods = methods->nextPtr; ckfree(ptr); } } /* *-------------------------------------------------------------- * * TkSmoothParseProc -- * * This function is invoked during option processing to handle the * "-smooth" option. * * Results: * A standard Tcl return value. * * Side effects: * The smooth option for a given item gets replaced by the value * indicated in the value argument. * *-------------------------------------------------------------- */ int TkSmoothParseProc( ClientData clientData, /* Ignored. */ Tcl_Interp *interp, /* Used for reporting errors. */ Tk_Window tkwin, /* Window containing canvas widget. */ const char *value, /* Value of option. */ char *widgRec, /* Pointer to record for item. */ int offset) /* Offset into item. */ { register const Tk_SmoothMethod **smoothPtr = (const Tk_SmoothMethod **) (widgRec + offset); const Tk_SmoothMethod *smooth = NULL; int b; size_t length; SmoothAssocData *methods; if (value == NULL || *value == 0) { *smoothPtr = NULL; return TCL_OK; } length = strlen(value); methods = Tcl_GetAssocData(interp, "smoothMethod", NULL); /* * Not initialized yet; fix that now. */ if (methods == NULL) { methods = InitSmoothMethods(interp); } /* * Backward compatability hack. */ if (strncmp(value, "bezier", length) == 0) { smooth = &tkBezierSmoothMethod; } /* * Search the list of installed smooth methods. */ while (methods != NULL) { if (strncmp(value, methods->smooth.name, length) == 0) { if (smooth != NULL) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "ambiguous smooth method \"%s\"", value)); Tcl_SetErrorCode(interp, "TK", "LOOKUP", "SMOOTH", value, NULL); return TCL_ERROR; } smooth = &methods->smooth; } methods = methods->nextPtr; } if (smooth) { *smoothPtr = smooth; return TCL_OK; } /* * Did not find it. Try parsing as a boolean instead. */ if (Tcl_GetBoolean(interp, (char *) value, &b) != TCL_OK) { return TCL_ERROR; } *smoothPtr = b ? &tkBezierSmoothMethod : NULL; return TCL_OK; } /* *-------------------------------------------------------------- * * TkSmoothPrintProc -- * * This function is invoked by the Tk configuration code to produce a * printable string for the "-smooth" configuration option. * * Results: * The return value is a string describing the smooth option for the item * referred to by "widgRec". In addition, *freeProcPtr is filled in with * the address of a function to call to free the result string when it's * no longer needed (or NULL to indicate that the string doesn't need to * be freed). * * Side effects: * None. * *-------------------------------------------------------------- */ const char * TkSmoothPrintProc( ClientData clientData, /* Ignored. */ Tk_Window tkwin, /* Window containing canvas widget. */ char *widgRec, /* Pointer to record for item. */ int offset, /* Offset into item. */ Tcl_FreeProc **freeProcPtr) /* Pointer to variable to fill in with * information about how to reclaim storage * for return string. */ { register const Tk_SmoothMethod *smoothPtr = * (Tk_SmoothMethod **) (widgRec + offset); return smoothPtr ? smoothPtr->name : "0"; } /* *-------------------------------------------------------------- * * Tk_GetDash * * This function is used to parse a string, assuming it is dash * information. * * Results: * The return value is a standard Tcl result: TCL_OK means that the dash * information was parsed ok, and TCL_ERROR means it couldn't be parsed. * * Side effects: * Dash information in the dash structure is updated. * *-------------------------------------------------------------- */ int Tk_GetDash( Tcl_Interp *interp, /* Used for error reporting. */ const char *value, /* Textual specification of dash list. */ Tk_Dash *dash) /* Pointer to record in which to store dash * information. */ { int argc, i; const char **largv, **argv = NULL; char *pt; if ((value == NULL) || (*value == '\0')) { dash->number = 0; return TCL_OK; } /* * switch is usually compiled more efficiently than a chain of conditions. */ switch (*value) { case '.': case ',': case '-': case '_': i = DashConvert(NULL, value, -1, 0.0); if (i <= 0) { goto badDashList; } i = strlen(value); if (i > (int) sizeof(char *)) { dash->pattern.pt = pt = ckalloc(strlen(value)); } else { pt = dash->pattern.array; } memcpy(pt, value, (unsigned) i); dash->number = -i; return TCL_OK; } if (Tcl_SplitList(interp, (char *) value, &argc, &argv) != TCL_OK) { Tcl_ResetResult(interp); goto badDashList; } if ((unsigned) ABS(dash->number) > sizeof(char *)) { ckfree(dash->pattern.pt); } if (argc > (int) sizeof(char *)) { dash->pattern.pt = pt = ckalloc(argc); } else { pt = dash->pattern.array; } dash->number = argc; largv = argv; while (argc > 0) { if (Tcl_GetInt(interp, *largv, &i) != TCL_OK || i < 1 || i>255) { Tcl_SetObjResult(interp, Tcl_ObjPrintf( "expected integer in the range 1..255 but got \"%s\"", *largv)); Tcl_SetErrorCode(interp, "TK", "VALUE", "DASH", NULL); goto syntaxError; } *pt++ = i; argc--; largv++; } if (argv != NULL) { ckfree(argv); } return TCL_OK; /* * Something went wrong. Generate error message, clean up and return. */ badDashList: Tcl_SetObjResult(interp, Tcl_ObjPrintf( "bad dash list \"%s\": must be a list of integers or a format like \"-..\"", value)); Tcl_SetErrorCode(interp, "TK", "VALUE", "DASH", NULL); syntaxError: if (argv != NULL) { ckfree(argv); } if ((unsigned) ABS(dash->number) > sizeof(char *)) { ckfree(dash->pattern.pt); } dash->number = 0; return TCL_ERROR; } /* *-------------------------------------------------------------- * * Tk_CreateOutline * * This function initializes the Tk_Outline structure with default * values. * * Results: * None * * Side effects: * None * *-------------------------------------------------------------- */ void Tk_CreateOutline( Tk_Outline *outline) /* Outline structure to be filled in. */ { outline->gc = NULL; outline->width = 1.0; outline->activeWidth = 0.0; outline->disabledWidth = 0.0; outline->offset = 0; outline->dash.number = 0; outline->activeDash.number = 0; outline->disabledDash.number = 0; outline->tsoffset.flags = 0; outline->tsoffset.xoffset = 0; outline->tsoffset.yoffset = 0; outline->color = NULL; outline->activeColor = NULL; outline->disabledColor = NULL; outline->stipple = None; outline->activeStipple = None; outline->disabledStipple = None; } /* *-------------------------------------------------------------- * * Tk_DeleteOutline * * This function frees all memory that might be allocated and referenced * in the Tk_Outline structure. * * Results: * None * * Side effects: * None * *-------------------------------------------------------------- */ void Tk_DeleteOutline( Display *display, /* Display containing window. */ Tk_Outline *outline) { if (outline->gc != NULL) { Tk_FreeGC(display, outline->gc); } if ((unsigned) ABS(outline->dash.number) > sizeof(char *)) { ckfree(outline->dash.pattern.pt); } if ((unsigned) ABS(outline->activeDash.number) > sizeof(char *)) { ckfree(outline->activeDash.pattern.pt); } if ((unsigned) ABS(outline->disabledDash.number) > sizeof(char *)) { ckfree(outline->disabledDash.pattern.pt); } if (outline->color != NULL) { Tk_FreeColor(outline->color); } if (outline->activeColor != NULL) { Tk_FreeColor(outline->activeColor); } if (outline->disabledColor != NULL) { Tk_FreeColor(outline->disabledColor); } if (outline->stipple != None) { Tk_FreeBitmap(display, outline->stipple); } if (outline->activeStipple != None) { Tk_FreeBitmap(display, outline->activeStipple); } if (outline->disabledStipple != None) { Tk_FreeBitmap(display, outline->disabledStipple); } } /* *-------------------------------------------------------------- * * Tk_ConfigOutlineGC * * This function should be called in the canvas object during the * configure command. The graphics context description in gcValues is * updated according to the information in the dash structure, as far as * possible. * * Results: * The return-value is a mask, indicating which elements of gcValues have * been updated. 0 means there is no outline. * * Side effects: * GC information in gcValues is updated. * *-------------------------------------------------------------- */ int Tk_ConfigOutlineGC( XGCValues *gcValues, Tk_Canvas canvas, Tk_Item *item, Tk_Outline *outline) { int mask = 0; double width; Tk_Dash *dash; XColor *color; Pixmap stipple; Tk_State state = item->state; if (outline->width < 0.0) { outline->width = 0.0; } if (outline->activeWidth < 0.0) { outline->activeWidth = 0.0; } if (outline->disabledWidth < 0) { outline->disabledWidth = 0.0; } if (state==TK_STATE_HIDDEN) { return 0; } width = outline->width; if (width < 1.0) { width = 1.0; } dash = &(outline->dash); color = outline->color; stipple = outline->stipple; if (state == TK_STATE_NULL) { state = Canvas(canvas)->canvas_state; } if (Canvas(canvas)->currentItemPtr == item) { if (outline->activeWidth>width) { width = outline->activeWidth; } if (outline->activeDash.number != 0) { dash = &(outline->activeDash); } if (outline->activeColor!=NULL) { color = outline->activeColor; } if (outline->activeStipple!=None) { stipple = outline->activeStipple; } } else if (state == TK_STATE_DISABLED) { if (outline->disabledWidth>0) { width = outline->disabledWidth; } if (outline->disabledDash.number != 0) { dash = &(outline->disabledDash); } if (outline->disabledColor!=NULL) { color = outline->disabledColor; } if (outline->disabledStipple!=None) { stipple = outline->disabledStipple; } } if (color==NULL) { return 0; } gcValues->line_width = (int) (width + 0.5); if (color != NULL) { gcValues->foreground = color->pixel; mask = GCForeground|GCLineWidth; if (stipple != None) { gcValues->stipple = stipple; gcValues->fill_style = FillStippled; mask |= GCStipple|GCFillStyle; } } if (mask && (dash->number != 0)) { gcValues->line_style = LineOnOffDash; gcValues->dash_offset = outline->offset; if ((unsigned int)ABS(dash->number) > sizeof(char *)) { gcValues->dashes = dash->pattern.pt[0]; } else if (dash->number != 0) { gcValues->dashes = dash->pattern.array[0]; } else { gcValues->dashes = (char) (4 * width + 0.5); } mask |= GCLineStyle|GCDashList|GCDashOffset; } return mask; } /* *-------------------------------------------------------------- * * Tk_ChangeOutlineGC * * Updates the GC to represent the full information of the dash * structure. Partly this is already done in Tk_ConfigOutlineGC(). This * function should be called just before drawing the dashed item. * * Results: * 1 if there is a stipple pattern, and 0 otherwise. * * Side effects: * GC is updated. * *-------------------------------------------------------------- */ int Tk_ChangeOutlineGC( Tk_Canvas canvas, Tk_Item *item, Tk_Outline *outline) { const char *p; double width; Tk_Dash *dash; XColor *color; Pixmap stipple; Tk_State state = item->state; width = outline->width; if (width < 1.0) { width = 1.0; } dash = &(outline->dash); color = outline->color; stipple = outline->stipple; if (state == TK_STATE_NULL) { state = Canvas(canvas)->canvas_state; } if (Canvas(canvas)->currentItemPtr == item) { if (outline->activeWidth > width) { width = outline->activeWidth; } if (outline->activeDash.number != 0) { dash = &(outline->activeDash); } if (outline->activeColor != NULL) { color = outline->activeColor; } if (outline->activeStipple != None) { stipple = outline->activeStipple; } } else if (state == TK_STATE_DISABLED) { if (outline->disabledWidth > width) { width = outline->disabledWidth; } if (outline->disabledDash.number != 0) { dash = &(outline->disabledDash); } if (outline->disabledColor != NULL) { color = outline->disabledColor; } if (outline->disabledStipple != None) { stipple = outline->disabledStipple; } } if (color==NULL) { return 0; } if ((dash->number<-1) || ((dash->number == -1) && (dash->pattern.array[0] != ','))) { char *q; int i = -dash->number; p = (i > (int)sizeof(char *)) ? dash->pattern.pt : dash->pattern.array; q = ckalloc(2 * i); i = DashConvert(q, p, i, width); XSetDashes(Canvas(canvas)->display, outline->gc, outline->offset, q,i); ckfree(q); } else if (dash->number>2 || (dash->number==2 && (dash->pattern.array[0]!=dash->pattern.array[1]))) { p = (dash->number > (int) sizeof(char *)) ? dash->pattern.pt : dash->pattern.array; XSetDashes(Canvas(canvas)->display, outline->gc, outline->offset, p, dash->number); } if (stipple!=None) { int w = 0; int h = 0; Tk_TSOffset *tsoffset = &outline->tsoffset; int flags = tsoffset->flags; if (!(flags & TK_OFFSET_INDEX) && (flags & (TK_OFFSET_CENTER|TK_OFFSET_MIDDLE))) { Tk_SizeOfBitmap(Canvas(canvas)->display, stipple, &w, &h); if (flags & TK_OFFSET_CENTER) { w /= 2; } else { w = 0; } if (flags & TK_OFFSET_MIDDLE) { h /= 2; } else { h = 0; } } tsoffset->xoffset -= w; tsoffset->yoffset -= h; Tk_CanvasSetOffset(canvas, outline->gc, tsoffset); tsoffset->xoffset += w; tsoffset->yoffset += h; return 1; } return 0; } /* *-------------------------------------------------------------- * * Tk_ResetOutlineGC * * Restores the GC to the situation before Tk_ChangeOutlineGC() was * called. This function should be called just after the dashed item is * drawn, because the GC is supposed to be read-only. * * Results: * 1 if there is a stipple pattern, and 0 otherwise. * * Side effects: * GC is updated. * *-------------------------------------------------------------- */ int Tk_ResetOutlineGC( Tk_Canvas canvas, Tk_Item *item, Tk_Outline *outline) { char dashList; double width; Tk_Dash *dash; XColor *color; Pixmap stipple; Tk_State state = item->state; width = outline->width; if (width < 1.0) { width = 1.0; } dash = &(outline->dash); color = outline->color; stipple = outline->stipple; if (state == TK_STATE_NULL) { state = Canvas(canvas)->canvas_state; } if (Canvas(canvas)->currentItemPtr == item) { if (outline->activeWidth>width) { width = outline->activeWidth; } if (outline->activeDash.number != 0) { dash = &(outline->activeDash); } if (outline->activeColor!=NULL) { color = outline->activeColor; } if (outline->activeStipple!=None) { stipple = outline->activeStipple; } } else if (state == TK_STATE_DISABLED) { if (outline->disabledWidth>width) { width = outline->disabledWidth; } if (outline->disabledDash.number != 0) { dash = &(outline->disabledDash); } if (outline->disabledColor!=NULL) { color = outline->disabledColor; } if (outline->disabledStipple!=None) { stipple = outline->disabledStipple; } } if (color==NULL) { return 0; } if ((dash->number > 2) || (dash->number < -1) || (dash->number==2 && (dash->pattern.array[0] != dash->pattern.array[1])) || ((dash->number == -1) && (dash->pattern.array[0] != ','))) { if ((unsigned int)ABS(dash->number) > sizeof(char *)) { dashList = dash->pattern.pt[0]; } else if (dash->number != 0) { dashList = dash->pattern.array[0]; } else { dashList = (char) (4 * width + 0.5); } XSetDashes(Canvas(canvas)->display, outline->gc, outline->offset, &dashList , 1); } if (stipple != None) { XSetTSOrigin(Canvas(canvas)->display, outline->gc, 0, 0); return 1; } return 0; } /* *-------------------------------------------------------------- * * Tk_CanvasPsOutline * * Creates the postscript command for the correct Outline-information * (width, dash, color and stipple). * * Results: * TCL_OK if succeeded, otherwise TCL_ERROR. * * Side effects: * canvas->interp->result contains the postscript string, or an error * message if the result was TCL_ERROR. * *-------------------------------------------------------------- */ int Tk_CanvasPsOutline( Tk_Canvas canvas, Tk_Item *item, Tk_Outline *outline) { char pattern[11]; int i; char *ptr, *lptr = pattern; Tcl_Interp *interp = Canvas(canvas)->interp; double width = outline->width; Tk_Dash *dash = &outline->dash; XColor *color = outline->color; Pixmap stipple = outline->stipple; Tk_State state = item->state; Tcl_Obj *psObj = GetPostscriptBuffer(interp); if (state == TK_STATE_NULL) { state = Canvas(canvas)->canvas_state; } if (Canvas(canvas)->currentItemPtr == item) { if (outline->activeWidth > width) { width = outline->activeWidth; } if (outline->activeDash.number > 0) { dash = &outline->activeDash; } if (outline->activeColor != NULL) { color = outline->activeColor; } if (outline->activeStipple != None) { stipple = outline->activeStipple; } } else if (state == TK_STATE_DISABLED) { if (outline->disabledWidth > 0) { width = outline->disabledWidth; } if (outline->disabledDash.number > 0) { dash = &outline->disabledDash; } if (outline->disabledColor != NULL) { color = outline->disabledColor; } if (outline->disabledStipple != None) { stipple = outline->disabledStipple; } } Tcl_AppendPrintfToObj(psObj, "%.15g setlinewidth\n", width); ptr = ((unsigned) ABS(dash->number) > sizeof(char *)) ? dash->pattern.pt : dash->pattern.array; Tcl_AppendToObj(psObj, "[", -1); if (dash->number > 0) { Tcl_Obj *converted; char *p = ptr; converted = Tcl_ObjPrintf("%d", *p++ & 0xff); for (i = dash->number-1 ; i>0 ; i--) { Tcl_AppendPrintfToObj(converted, " %d", *p++ & 0xff); } Tcl_AppendObjToObj(psObj, converted); if (dash->number & 1) { Tcl_AppendToObj(psObj, " ", -1); Tcl_AppendObjToObj(psObj, converted); } Tcl_DecrRefCount(converted); Tcl_AppendPrintfToObj(psObj, "] %d setdash\n", outline->offset); } else if (dash->number < 0) { if (dash->number < -5) { lptr = ckalloc(1 - 2*dash->number); } i = DashConvert(lptr, ptr, -dash->number, width); if (i > 0) { char *p = lptr; Tcl_AppendPrintfToObj(psObj, "%d", *p++ & 0xff); for (; --i>0 ;) { Tcl_AppendPrintfToObj(psObj, " %d", *p++ & 0xff); } Tcl_AppendPrintfToObj(psObj, "] %d setdash\n", outline->offset); } else { Tcl_AppendToObj(psObj, "] 0 setdash\n", -1); } if (lptr != pattern) { ckfree(lptr); } } else { Tcl_AppendToObj(psObj, "] 0 setdash\n", -1); } if (Tk_CanvasPsColor(interp, canvas, color) != TCL_OK) { return TCL_ERROR; } /* * Note that psObj might hold an invalid reference now. */ if (stipple != None) { Tcl_AppendToObj(GetPostscriptBuffer(interp), "StrokeClip ", -1); if (Tk_CanvasPsStipple(interp, canvas, stipple) != TCL_OK) { return TCL_ERROR; } } else { Tcl_AppendToObj(GetPostscriptBuffer(interp), "stroke\n", -1); } return TCL_OK; } /* *-------------------------------------------------------------- * * DashConvert * * Converts a character-like dash-list (e.g. "-..") into an X11-style. l * must point to a string that holds room to at least 2*n characters. If * l == NULL, this function can be used for syntax checking only. * * Results: * The length of the resulting X11 compatible dash-list. -1 if failed. * * Side effects: * None * *-------------------------------------------------------------- */ static int DashConvert( char *l, /* Must be at least 2*n chars long, or NULL to * indicate "just check syntax". */ const char *p, /* String to parse. */ int n, /* Length of string to parse, or -1 to * indicate that strlen() should be used. */ double width) /* Width of line. */ { int result = 0; int size, intWidth; if (n < 0) { n = strlen(p); } intWidth = (int) (width + 0.5); if (intWidth < 1) { intWidth = 1; } while (n-- && *p) { switch (*p++) { case ' ': if (result) { if (l) { l[-1] += intWidth + 1; } continue; } return 0; case '_': size = 8; break; case '-': size = 6; break; case ',': size = 4; break; case '.': size = 2; break; default: return -1; } if (l) { *l++ = size * intWidth; *l++ = 4 * intWidth; } result += 2; } return result; } /* *---------------------------------------------------------------------- * * TranslateAndAppendCoords -- * * This is a helper routine for TkCanvTranslatePath() below. * * Given an (x,y) coordinate pair within a canvas, this function computes * the corresponding coordinates at which the point should be drawn in * the drawable used for display. Those coordinates are then written into * outArr[numOut*2] and outArr[numOut*2+1]. * * Results: * There is no return value. * * Side effects: * None. * *---------------------------------------------------------------------- */ static void TranslateAndAppendCoords( TkCanvas *canvPtr, /* The canvas. */ double x, /* Coordinates in canvas space. */ double y, XPoint *outArr, /* Write results into this array */ int numOut) /* Num of prior entries in outArr[] */ { double tmp; tmp = x - canvPtr->drawableXOrigin; if (tmp > 0) { tmp += 0.5; } else { tmp -= 0.5; } outArr[numOut].x = (short) tmp; tmp = y - canvPtr->drawableYOrigin; if (tmp > 0) { tmp += 0.5; } else { tmp -= 0.5; } outArr[numOut].y = (short) tmp; } /* *-------------------------------------------------------------- * * TkCanvTranslatePath * * Translate a line or polygon path so that all vertices are within a * rectangle that is 1000 pixels larger than the total size of the canvas * window. This will prevent pixel coordinates from overflowing the * 16-bit integer size limitation imposed by most windowing systems. * * coordPtr must point to an array of doubles, two doubles per vertex. * There are a total of numVertex vertices, or 2*numVertex entries in * coordPtr. The result vertices written into outArr have their * coordinate origin shifted to canvPtr->drawableXOrigin by * canvPtr->drawableYOrigin. There might be as many as 3 times more * output vertices than there are input vertices. The calling function * should allocate space accordingly. * * This routine limits the width and height of a canvas window to 31767 * pixels. At the highest resolution display devices available today (210 * ppi in Jan 2003) that's a window that is over 13 feet wide and tall. * Should be enough for the near future. * * Results: * Clipped and translated path vertices are written into outArr[]. There * might be as many as twice the vertices in outArr[] as there are in * coordPtr[]. The return value is the number of vertices actually * written into outArr[]. * * Side effects: * None * *-------------------------------------------------------------- */ int TkCanvTranslatePath( TkCanvas *canvPtr, /* The canvas */ int numVertex, /* Number of vertices specified by * coordArr[] */ double *coordArr, /* X and Y coordinates for each vertex */ int closedPath, /* True if this is a closed polygon */ XPoint *outArr) /* Write results here, if not NULL */ { int numOutput = 0; /* Number of output coordinates */ double lft, rgh; /* Left and right sides of the bounding box */ double top, btm; /* Top and bottom sizes of the bounding box */ double *tempArr; /* Temporary storage used by the clipper */ double *a, *b, *t; /* Pointers to parts of the temporary * storage */ int i, j; /* Loop counters */ double limit[4]; /* Boundries at which clipping occurs */ double staticSpace[480]; /* Temp space from the stack */ /* * Constrain all vertices of the path to be within a box that is no larger * than 32000 pixels wide or height. The top-left corner of this clipping * box is 1000 pixels above and to the left of the top left corner of the * window on which the canvas is displayed. * * This means that a canvas will not display properly on a canvas window * that is larger than 31000 pixels wide or high. That is not a problem * today, but might someday become a factor for ultra-high resolutions * displays. * * The X11 protocol allows us (in theory) to expand the size of the * clipping box to 32767 pixels. But we have found experimentally that * XFree86 sometimes fails to draw lines correctly if they are longer than * about 32500 pixels. So we have left a little margin in the size to mask * that bug. */ lft = canvPtr->xOrigin - 1000.0; top = canvPtr->yOrigin - 1000.0; rgh = lft + 32000.0; btm = top + 32000.0; /* * Try the common case first - no clipping. Loop over the input * coordinates and translate them into appropriate output coordinates. * But if a vertex outside of the bounding box is seen, break out of the * loop. * * Most of the time, no clipping is needed, so this one loop is sufficient * to do the translation. */ for (i=0; irgh || ybtm) { break; } TranslateAndAppendCoords(canvPtr, x, y, outArr, numOutput++); } if (i == numVertex){ assert(numOutput == numVertex); return numOutput; } /* * If we reach this point, it means that some clipping is required. Begin * by allocating some working storage - at least 6 times as much space as * coordArr[] requires. Divide this space into two separate arrays a[] and * b[]. Initialize a[] to be equal to coordArr[]. */ if (numVertex*12 <= (int) (sizeof(staticSpace) / sizeof(double))) { tempArr = staticSpace; } else { tempArr = ckalloc(numVertex * 12 * sizeof(double)); } for (i=0; i= xClip) { /* * The current vertex is to the right of xClip. */ if (inside) { /* * If the current vertex is to the right of xClip but the * previous vertex was left of xClip, then draw a line * segment from the previous vertex to until it intersects * the vertical at xClip. */ double x0, y0, yN; assert(i > 0); x0 = a[i*2 - 2]; y0 = a[i*2 - 1]; yN = y0 + (y - y0)*(xClip-x0)/(x-x0); b[numOutput*2] = -yN; b[numOutput*2 + 1] = xClip; numOutput++; assert(numOutput <= numVertex*3); priorY = yN; inside = 0; } else if (i == 0) { /* * If the first vertex is to the right of xClip, add a * vertex that is the projection of the first vertex onto * the vertical xClip line. */ b[0] = -y; b[1] = xClip; numOutput = 1; priorY = y; } } else { /* * The current vertex is to the left of xClip */ if (!inside) { /* * If the current vertex is on the left of xClip and one * or more prior vertices where to the right, then we have * to draw a line segment along xClip that extends from * the spot where we first crossed from left to right to * the spot where we cross back from right to left. */ double x0, y0, yN; assert(i > 0); x0 = a[i*2 - 2]; y0 = a[i*2 - 1]; yN = y0 + (y - y0)*(xClip-x0)/(x-x0); if (yN != priorY) { b[numOutput*2] = -yN; b[numOutput*2 + 1] = xClip; numOutput++; assert(numOutput <= numVertex*3); } inside = 1; } b[numOutput*2] = -y; b[numOutput*2 + 1] = x; numOutput++; assert(numOutput <= numVertex*3); } } /* * Interchange a[] and b[] in preparation for the next pass. */ t = a; a = b; b = t; numVertex = numOutput; } /* * All clipping is now finished. Convert the coordinates from doubles into * XPoints and translate the origin for the drawable. */ for (i=0; i