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cpython-source-deps/generic/tkGrid.c
Cheryl Sabella 8e57feeeb9 Import Tk 8.6.8
2018-02-22 14:31:15 -05:00

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/*
* tkGrid.c --
*
* Grid based geometry manager.
*
* Copyright (c) 1996-1997 by 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"
/*
* Convenience Macros
*/
#ifdef MAX
# undef MAX
#endif
#define MAX(x,y) ((x) > (y) ? (x) : (y))
#define COLUMN (1) /* Working on column offsets. */
#define ROW (2) /* Working on row offsets. */
#define CHECK_ONLY (1) /* Check max slot constraint. */
#define CHECK_SPACE (2) /* Alloc more space, don't change max. */
/*
* Pre-allocate enough row and column slots for "typical" sized tables this
* value should be chosen so by the time the extra malloc's are required, the
* layout calculations overwehlm them. [A "slot" contains information for
* either a row or column, depending upon the context.]
*/
#define TYPICAL_SIZE 25 /* (Arbitrary guess) */
#define PREALLOC 10 /* Extra slots to allocate. */
/*
* Pre-allocate room for uniform groups during layout.
*/
#define UNIFORM_PREALLOC 10
/*
* Data structures are allocated dynamically to support arbitrary sized
* tables. However, the space is proportional to the highest numbered slot
* with some non-default property. This limit is used to head off mistakes and
* denial of service attacks by limiting the amount of storage required.
*/
#define MAX_ELEMENT 10000
/*
* Special characters to support relative layouts.
*/
#define REL_SKIP 'x' /* Skip this column. */
#define REL_HORIZ '-' /* Extend previous widget horizontally. */
#define REL_VERT '^' /* Extend widget from row above. */
/*
* Default value for 'grid anchor'.
*/
#define GRID_DEFAULT_ANCHOR TK_ANCHOR_NW
/*
* Structure to hold information for grid masters. A slot is either a row or
* column.
*/
typedef struct SlotInfo {
int minSize; /* The minimum size of this slot (in pixels).
* It is set via the rowconfigure or
* columnconfigure commands. */
int weight; /* The resize weight of this slot. (0) means
* this slot doesn't resize. Extra space in
* the layout is given distributed among slots
* inproportion to their weights. */
int pad; /* Extra padding, in pixels, required for this
* slot. This amount is "added" to the largest
* slave in the slot. */
Tk_Uid uniform; /* Value of -uniform option. It is used to
* group slots that should have the same
* size. */
int offset; /* This is a cached value used for
* introspection. It is the pixel offset of
* the right or bottom edge of this slot from
* the beginning of the layout. */
int temp; /* This is a temporary value used for
* calculating adjusted weights when shrinking
* the layout below its nominal size. */
} SlotInfo;
/*
* Structure to hold information during layout calculations. There is one of
* these for each slot, an array for each of the rows or columns.
*/
typedef struct GridLayout {
struct Gridder *binNextPtr; /* The next slave window in this bin. Each bin
* contains a list of all slaves whose spans
* are >1 and whose right edges fall in this
* slot. */
int minSize; /* Minimum size needed for this slot, in
* pixels. This is the space required to hold
* any slaves contained entirely in this slot,
* adjusted for any slot constrants, such as
* size or padding. */
int pad; /* Padding needed for this slot */
int weight; /* Slot weight, controls resizing. */
Tk_Uid uniform; /* Value of -uniform option. It is used to
* group slots that should have the same
* size. */
int minOffset; /* The minimum offset, in pixels, from the
* beginning of the layout to the bottom/right
* edge of the slot calculated from top/left
* to bottom/right. */
int maxOffset; /* The maximum offset, in pixels, from the
* beginning of the layout to the bottom/right
* edge of the slot calculated from
* bottom/right to top/left. */
} GridLayout;
/*
* Keep one of these for each geometry master.
*/
typedef struct {
SlotInfo *columnPtr; /* Pointer to array of column constraints. */
SlotInfo *rowPtr; /* Pointer to array of row constraints. */
int columnEnd; /* The last column occupied by any slave. */
int columnMax; /* The number of columns with constraints. */
int columnSpace; /* The number of slots currently allocated for
* column constraints. */
int rowEnd; /* The last row occupied by any slave. */
int rowMax; /* The number of rows with constraints. */
int rowSpace; /* The number of slots currently allocated for
* row constraints. */
int startX; /* Pixel offset of this layout within its
* master. */
int startY; /* Pixel offset of this layout within its
* master. */
Tk_Anchor anchor; /* Value of anchor option: specifies where a
* grid without weight should be placed. */
} GridMaster;
/*
* For each window that the grid cares about (either because the window is
* managed by the grid or because the window has slaves that are managed by
* the grid), there is a structure of the following type:
*/
typedef struct Gridder {
Tk_Window tkwin; /* Tk token for window. NULL means that the
* window has been deleted, but the gridder
* hasn't had a chance to clean up yet because
* the structure is still in use. */
struct Gridder *masterPtr; /* Master window within which this window is
* managed (NULL means this window isn't
* managed by the gridder). */
struct Gridder *nextPtr; /* Next window managed within same master.
* List order doesn't matter. */
struct Gridder *slavePtr; /* First in list of slaves managed inside this
* window (NULL means no grid slaves). */
GridMaster *masterDataPtr; /* Additional data for geometry master. */
Tcl_Obj *in; /* Store master name when removed. */
int column, row; /* Location in the grid (starting from
* zero). */
int numCols, numRows; /* Number of columns or rows this slave spans.
* Should be at least 1. */
int padX, padY; /* Total additional pixels to leave around the
* window. Some is of this space is on each
* side. This is space *outside* the window:
* we'll allocate extra space in frame but
* won't enlarge window). */
int padLeft, padTop; /* The part of padX or padY to use on the left
* or top of the widget, respectively. By
* default, this is half of padX or padY. */
int iPadX, iPadY; /* Total extra pixels to allocate inside the
* window (half this amount will appear on
* each side). */
int sticky; /* which sides of its cavity this window
* sticks to. See below for definitions */
int doubleBw; /* Twice the window's last known border width.
* If this changes, the window must be
* re-arranged within its master. */
int *abortPtr; /* If non-NULL, it means that there is a
* nested call to ArrangeGrid already working
* on this window. *abortPtr may be set to 1
* to abort that nested call. This happens,
* for example, if tkwin or any of its slaves
* is deleted. */
int flags; /* Miscellaneous flags; see below for
* definitions. */
/*
* These fields are used temporarily for layout calculations only.
*/
struct Gridder *binNextPtr; /* Link to next span>1 slave in this bin. */
int size; /* Nominal size (width or height) in pixels of
* the slave. This includes the padding. */
} Gridder;
/*
* Flag values for "sticky"ness. The 16 combinations subsume the packer's
* notion of anchor and fill.
*
* STICK_NORTH This window sticks to the top of its cavity.
* STICK_EAST This window sticks to the right edge of its
* cavity.
* STICK_SOUTH This window sticks to the bottom of its cavity.
* STICK_WEST This window sticks to the left edge of its
* cavity.
*/
#define STICK_NORTH 1
#define STICK_EAST 2
#define STICK_SOUTH 4
#define STICK_WEST 8
/*
* Structure to gather information about uniform groups during layout.
*/
typedef struct UniformGroup {
Tk_Uid group;
int minSize;
} UniformGroup;
/*
* Flag values for Grid structures:
*
* REQUESTED_RELAYOUT 1 means a Tcl_DoWhenIdle request has already
* been made to re-arrange all the slaves of this
* window.
* DONT_PROPAGATE 1 means don't set this window's requested
* size. 0 means if this window is a master then
* Tk will set its requested size to fit the
* needs of its slaves.
* ALLOCED_MASTER 1 means that Grid has allocated itself as
* geometry master for this window.
*/
#define REQUESTED_RELAYOUT 1
#define DONT_PROPAGATE 2
#define ALLOCED_MASTER 4
/*
* Prototypes for procedures used only in this file:
*/
static void AdjustForSticky(Gridder *slavePtr, int *xPtr,
int *yPtr, int *widthPtr, int *heightPtr);
static int AdjustOffsets(int width, int elements,
SlotInfo *slotPtr);
static void ArrangeGrid(ClientData clientData);
static int CheckSlotData(Gridder *masterPtr, int slot,
int slotType, int checkOnly);
static int ConfigureSlaves(Tcl_Interp *interp, Tk_Window tkwin,
int objc, Tcl_Obj *const objv[]);
static void DestroyGrid(void *memPtr);
static Gridder * GetGrid(Tk_Window tkwin);
static int GridAnchorCommand(Tk_Window tkwin, Tcl_Interp *interp,
int objc, Tcl_Obj *const objv[]);
static int GridBboxCommand(Tk_Window tkwin, Tcl_Interp *interp,
int objc, Tcl_Obj *const objv[]);
static int GridForgetRemoveCommand(Tk_Window tkwin,
Tcl_Interp *interp, int objc,
Tcl_Obj *const objv[]);
static int GridInfoCommand(Tk_Window tkwin, Tcl_Interp *interp,
int objc, Tcl_Obj *const objv[]);
static int GridLocationCommand(Tk_Window tkwin,
Tcl_Interp *interp, int objc,
Tcl_Obj *const objv[]);
static int GridPropagateCommand(Tk_Window tkwin,
Tcl_Interp *interp, int objc,
Tcl_Obj *const objv[]);
static int GridRowColumnConfigureCommand(Tk_Window tkwin,
Tcl_Interp *interp, int objc,
Tcl_Obj *const objv[]);
static int GridSizeCommand(Tk_Window tkwin, Tcl_Interp *interp,
int objc, Tcl_Obj *const objv[]);
static int GridSlavesCommand(Tk_Window tkwin, Tcl_Interp *interp,
int objc, Tcl_Obj *const objv[]);
static void GridStructureProc(ClientData clientData,
XEvent *eventPtr);
static void GridLostSlaveProc(ClientData clientData,
Tk_Window tkwin);
static void GridReqProc(ClientData clientData, Tk_Window tkwin);
static void InitMasterData(Gridder *masterPtr);
static Tcl_Obj * NewPairObj(int, int);
static Tcl_Obj * NewQuadObj(int, int, int, int);
static int ResolveConstraints(Gridder *gridPtr, int rowOrColumn,
int maxOffset);
static void SetGridSize(Gridder *gridPtr);
static int SetSlaveColumn(Tcl_Interp *interp, Gridder *slavePtr,
int column, int numCols);
static int SetSlaveRow(Tcl_Interp *interp, Gridder *slavePtr,
int row, int numRows);
static Tcl_Obj * StickyToObj(int flags);
static int StringToSticky(const char *string);
static void Unlink(Gridder *gridPtr);
static const Tk_GeomMgr gridMgrType = {
"grid", /* name */
GridReqProc, /* requestProc */
GridLostSlaveProc, /* lostSlaveProc */
};
/*
*----------------------------------------------------------------------
*
* Tk_GridCmd --
*
* This procedure is invoked to process the "grid" Tcl command. See the
* user documentation for details on what it does.
*
* Results:
* A standard Tcl result.
*
* Side effects:
* See the user documentation.
*
*----------------------------------------------------------------------
*/
int
Tk_GridObjCmd(
ClientData clientData, /* Main window associated with interpreter. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window tkwin = clientData;
static const char *const optionStrings[] = {
"anchor", "bbox", "columnconfigure", "configure",
"forget", "info", "location", "propagate", "remove",
"rowconfigure", "size", "slaves", NULL
};
enum options {
GRID_ANCHOR, GRID_BBOX, GRID_COLUMNCONFIGURE, GRID_CONFIGURE,
GRID_FORGET, GRID_INFO, GRID_LOCATION, GRID_PROPAGATE, GRID_REMOVE,
GRID_ROWCONFIGURE, GRID_SIZE, GRID_SLAVES
};
int index;
if (objc >= 2) {
const char *argv1 = Tcl_GetString(objv[1]);
if ((argv1[0] == '.') || (argv1[0] == REL_SKIP) ||
(argv1[0] == REL_VERT)) {
return ConfigureSlaves(interp, tkwin, objc-1, objv+1);
}
}
if (objc < 3) {
Tcl_WrongNumArgs(interp, 1, objv, "option arg ?arg ...?");
return TCL_ERROR;
}
if (Tcl_GetIndexFromObjStruct(interp, objv[1], optionStrings,
sizeof(char *), "option", 0, &index) != TCL_OK) {
return TCL_ERROR;
}
switch ((enum options) index) {
case GRID_ANCHOR:
return GridAnchorCommand(tkwin, interp, objc, objv);
case GRID_BBOX:
return GridBboxCommand(tkwin, interp, objc, objv);
case GRID_CONFIGURE:
return ConfigureSlaves(interp, tkwin, objc-2, objv+2);
case GRID_FORGET:
case GRID_REMOVE:
return GridForgetRemoveCommand(tkwin, interp, objc, objv);
case GRID_INFO:
return GridInfoCommand(tkwin, interp, objc, objv);
case GRID_LOCATION:
return GridLocationCommand(tkwin, interp, objc, objv);
case GRID_PROPAGATE:
return GridPropagateCommand(tkwin, interp, objc, objv);
case GRID_SIZE:
return GridSizeCommand(tkwin, interp, objc, objv);
case GRID_SLAVES:
return GridSlavesCommand(tkwin, interp, objc, objv);
/*
* Sample argument combinations:
* grid columnconfigure <master> <index> -option
* grid columnconfigure <master> <index> -option value -option value
* grid rowconfigure <master> <index>
* grid rowconfigure <master> <index> -option
* grid rowconfigure <master> <index> -option value -option value.
*/
case GRID_COLUMNCONFIGURE:
case GRID_ROWCONFIGURE:
return GridRowColumnConfigureCommand(tkwin, interp, objc, objv);
}
/* This should not happen */
Tcl_SetObjResult(interp, Tcl_NewStringObj("internal error in grid", -1));
Tcl_SetErrorCode(interp, "TK", "API_ABUSE", NULL);
return TCL_ERROR;
}
/*
*----------------------------------------------------------------------
*
* GridAnchorCommand --
*
* Implementation of the [grid anchor] subcommand. See the user
* documentation for details on what it does.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* May recompute grid geometry.
*
*----------------------------------------------------------------------
*/
static int
GridAnchorCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window master;
Gridder *masterPtr;
GridMaster *gridPtr;
Tk_Anchor old;
if (objc > 4) {
Tcl_WrongNumArgs(interp, 2, objv, "window ?anchor?");
return TCL_ERROR;
}
if (TkGetWindowFromObj(interp, tkwin, objv[2], &master) != TCL_OK) {
return TCL_ERROR;
}
masterPtr = GetGrid(master);
if (objc == 3) {
gridPtr = masterPtr->masterDataPtr;
Tcl_SetObjResult(interp, Tcl_NewStringObj(
Tk_NameOfAnchor(gridPtr?gridPtr->anchor:GRID_DEFAULT_ANCHOR),
-1));
return TCL_OK;
}
InitMasterData(masterPtr);
gridPtr = masterPtr->masterDataPtr;
old = gridPtr->anchor;
if (Tk_GetAnchorFromObj(interp, objv[3], &gridPtr->anchor) != TCL_OK) {
return TCL_ERROR;
}
/*
* Only request a relayout if the anchor changes.
*/
if (old != gridPtr->anchor) {
if (masterPtr->abortPtr != NULL) {
*masterPtr->abortPtr = 1;
}
if (!(masterPtr->flags & REQUESTED_RELAYOUT)) {
masterPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, masterPtr);
}
}
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* GridBboxCommand --
*
* Implementation of the [grid bbox] subcommand.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* Places bounding box information in the interp's result field.
*
*----------------------------------------------------------------------
*/
static int
GridBboxCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window master;
Gridder *masterPtr; /* master grid record */
GridMaster *gridPtr; /* pointer to grid data */
int row, column; /* origin for bounding box */
int row2, column2; /* end of bounding box */
int endX, endY; /* last column/row in the layout */
int x=0, y=0; /* starting pixels for this bounding box */
int width, height; /* size of the bounding box */
if (objc!=3 && objc != 5 && objc != 7) {
Tcl_WrongNumArgs(interp, 2, objv, "master ?column row ?column row??");
return TCL_ERROR;
}
if (TkGetWindowFromObj(interp, tkwin, objv[2], &master) != TCL_OK) {
return TCL_ERROR;
}
masterPtr = GetGrid(master);
if (objc >= 5) {
if (Tcl_GetIntFromObj(interp, objv[3], &column) != TCL_OK) {
return TCL_ERROR;
}
if (Tcl_GetIntFromObj(interp, objv[4], &row) != TCL_OK) {
return TCL_ERROR;
}
column2 = column;
row2 = row;
}
if (objc == 7) {
if (Tcl_GetIntFromObj(interp, objv[5], &column2) != TCL_OK) {
return TCL_ERROR;
}
if (Tcl_GetIntFromObj(interp, objv[6], &row2) != TCL_OK) {
return TCL_ERROR;
}
}
gridPtr = masterPtr->masterDataPtr;
if (gridPtr == NULL) {
Tcl_SetObjResult(interp, NewQuadObj(0, 0, 0, 0));
return TCL_OK;
}
SetGridSize(masterPtr);
endX = MAX(gridPtr->columnEnd, gridPtr->columnMax);
endY = MAX(gridPtr->rowEnd, gridPtr->rowMax);
if ((endX == 0) || (endY == 0)) {
Tcl_SetObjResult(interp, NewQuadObj(0, 0, 0, 0));
return TCL_OK;
}
if (objc == 3) {
row = 0;
column = 0;
row2 = endY;
column2 = endX;
}
if (column > column2) {
int temp = column;
column = column2;
column2 = temp;
}
if (row > row2) {
int temp = row;
row = row2;
row2 = temp;
}
if (column > 0 && column < endX) {
x = gridPtr->columnPtr[column-1].offset;
} else if (column > 0) {
x = gridPtr->columnPtr[endX-1].offset;
}
if (row > 0 && row < endY) {
y = gridPtr->rowPtr[row-1].offset;
} else if (row > 0) {
y = gridPtr->rowPtr[endY-1].offset;
}
if (column2 < 0) {
width = 0;
} else if (column2 >= endX) {
width = gridPtr->columnPtr[endX-1].offset - x;
} else {
width = gridPtr->columnPtr[column2].offset - x;
}
if (row2 < 0) {
height = 0;
} else if (row2 >= endY) {
height = gridPtr->rowPtr[endY-1].offset - y;
} else {
height = gridPtr->rowPtr[row2].offset - y;
}
Tcl_SetObjResult(interp, NewQuadObj(
x + gridPtr->startX, y + gridPtr->startY, width, height));
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* GridForgetRemoveCommand --
*
* Implementation of the [grid forget]/[grid remove] subcommands. See the
* user documentation for details on what these do.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* Removes a window from a grid layout.
*
*----------------------------------------------------------------------
*/
static int
GridForgetRemoveCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window slave;
Gridder *slavePtr;
int i;
const char *string = Tcl_GetString(objv[1]);
char c = string[0];
for (i = 2; i < objc; i++) {
if (TkGetWindowFromObj(interp, tkwin, objv[i], &slave) != TCL_OK) {
return TCL_ERROR;
}
slavePtr = GetGrid(slave);
if (slavePtr->masterPtr != NULL) {
/*
* For "forget", reset all the settings to their defaults
*/
if (c == 'f') {
slavePtr->column = -1;
slavePtr->row = -1;
slavePtr->numCols = 1;
slavePtr->numRows = 1;
slavePtr->padX = 0;
slavePtr->padY = 0;
slavePtr->padLeft = 0;
slavePtr->padTop = 0;
slavePtr->iPadX = 0;
slavePtr->iPadY = 0;
if (slavePtr->in != NULL) {
Tcl_DecrRefCount(slavePtr->in);
slavePtr->in = NULL;
}
slavePtr->doubleBw = 2*Tk_Changes(tkwin)->border_width;
if (slavePtr->flags & REQUESTED_RELAYOUT) {
Tcl_CancelIdleCall(ArrangeGrid, slavePtr);
}
slavePtr->flags = 0;
slavePtr->sticky = 0;
} else {
/*
* When removing, store name of master to be able to
* restore it later, even if the master is recreated.
*/
if (slavePtr->in != NULL) {
Tcl_DecrRefCount(slavePtr->in);
slavePtr->in = NULL;
}
if (slavePtr->masterPtr != NULL) {
slavePtr->in = Tcl_NewStringObj(
Tk_PathName(slavePtr->masterPtr->tkwin), -1);
Tcl_IncrRefCount(slavePtr->in);
}
}
Tk_ManageGeometry(slave, NULL, NULL);
if (slavePtr->masterPtr->tkwin != Tk_Parent(slavePtr->tkwin)) {
Tk_UnmaintainGeometry(slavePtr->tkwin,
slavePtr->masterPtr->tkwin);
}
Unlink(slavePtr);
Tk_UnmapWindow(slavePtr->tkwin);
}
}
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* GridInfoCommand --
*
* Implementation of the [grid info] subcommand. See the user
* documentation for details on what it does.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* Puts gridding information in the interpreter's result.
*
*----------------------------------------------------------------------
*/
static int
GridInfoCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
register Gridder *slavePtr;
Tk_Window slave;
Tcl_Obj *infoObj;
if (objc != 3) {
Tcl_WrongNumArgs(interp, 2, objv, "window");
return TCL_ERROR;
}
if (TkGetWindowFromObj(interp, tkwin, objv[2], &slave) != TCL_OK) {
return TCL_ERROR;
}
slavePtr = GetGrid(slave);
if (slavePtr->masterPtr == NULL) {
Tcl_ResetResult(interp);
return TCL_OK;
}
infoObj = Tcl_NewObj();
Tcl_DictObjPut(NULL, infoObj, Tcl_NewStringObj("-in", -1),
TkNewWindowObj(slavePtr->masterPtr->tkwin));
Tcl_DictObjPut(NULL, infoObj, Tcl_NewStringObj("-column", -1),
Tcl_NewIntObj(slavePtr->column));
Tcl_DictObjPut(NULL, infoObj, Tcl_NewStringObj("-row", -1),
Tcl_NewIntObj(slavePtr->row));
Tcl_DictObjPut(NULL, infoObj, Tcl_NewStringObj("-columnspan", -1),
Tcl_NewIntObj(slavePtr->numCols));
Tcl_DictObjPut(NULL, infoObj, Tcl_NewStringObj("-rowspan", -1),
Tcl_NewIntObj(slavePtr->numRows));
TkAppendPadAmount(infoObj, "-ipadx", slavePtr->iPadX/2, slavePtr->iPadX);
TkAppendPadAmount(infoObj, "-ipady", slavePtr->iPadY/2, slavePtr->iPadY);
TkAppendPadAmount(infoObj, "-padx", slavePtr->padLeft, slavePtr->padX);
TkAppendPadAmount(infoObj, "-pady", slavePtr->padTop, slavePtr->padY);
Tcl_DictObjPut(NULL, infoObj, Tcl_NewStringObj("-sticky", -1),
StickyToObj(slavePtr->sticky));
Tcl_SetObjResult(interp, infoObj);
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* GridLocationCommand --
*
* Implementation of the [grid location] subcommand. See the user
* documentation for details on what it does.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* Puts location information in the interpreter's result field.
*
*----------------------------------------------------------------------
*/
static int
GridLocationCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window master;
Gridder *masterPtr; /* Master grid record. */
GridMaster *gridPtr; /* Pointer to grid data. */
register SlotInfo *slotPtr;
int x, y; /* Offset in pixels, from edge of master. */
int i, j; /* Corresponding column and row indeces. */
int endX, endY; /* End of grid. */
if (objc != 5) {
Tcl_WrongNumArgs(interp, 2, objv, "master x y");
return TCL_ERROR;
}
if (TkGetWindowFromObj(interp, tkwin, objv[2], &master) != TCL_OK) {
return TCL_ERROR;
}
if (Tk_GetPixelsFromObj(interp, master, objv[3], &x) != TCL_OK) {
return TCL_ERROR;
}
if (Tk_GetPixelsFromObj(interp, master, objv[4], &y) != TCL_OK) {
return TCL_ERROR;
}
masterPtr = GetGrid(master);
if (masterPtr->masterDataPtr == NULL) {
Tcl_SetObjResult(interp, NewPairObj(-1, -1));
return TCL_OK;
}
gridPtr = masterPtr->masterDataPtr;
/*
* Update any pending requests. This is not always the steady state value,
* as more configure events could be in the pipeline, but its as close as
* its easy to get.
*/
while (masterPtr->flags & REQUESTED_RELAYOUT) {
Tcl_CancelIdleCall(ArrangeGrid, masterPtr);
ArrangeGrid(masterPtr);
}
SetGridSize(masterPtr);
endX = MAX(gridPtr->columnEnd, gridPtr->columnMax);
endY = MAX(gridPtr->rowEnd, gridPtr->rowMax);
slotPtr = masterPtr->masterDataPtr->columnPtr;
if (x < masterPtr->masterDataPtr->startX) {
i = -1;
} else {
x -= masterPtr->masterDataPtr->startX;
for (i = 0; slotPtr[i].offset < x && i < endX; i++) {
/* null body */
}
}
slotPtr = masterPtr->masterDataPtr->rowPtr;
if (y < masterPtr->masterDataPtr->startY) {
j = -1;
} else {
y -= masterPtr->masterDataPtr->startY;
for (j = 0; slotPtr[j].offset < y && j < endY; j++) {
/* null body */
}
}
Tcl_SetObjResult(interp, NewPairObj(i, j));
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* GridPropagateCommand --
*
* Implementation of the [grid propagate] subcommand. See the user
* documentation for details on what it does.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* May alter geometry propagation for a widget.
*
*----------------------------------------------------------------------
*/
static int
GridPropagateCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window master;
Gridder *masterPtr;
int propagate, old;
if (objc > 4) {
Tcl_WrongNumArgs(interp, 2, objv, "window ?boolean?");
return TCL_ERROR;
}
if (TkGetWindowFromObj(interp, tkwin, objv[2], &master) != TCL_OK) {
return TCL_ERROR;
}
masterPtr = GetGrid(master);
if (objc == 3) {
Tcl_SetObjResult(interp,
Tcl_NewBooleanObj(!(masterPtr->flags & DONT_PROPAGATE)));
return TCL_OK;
}
if (Tcl_GetBooleanFromObj(interp, objv[3], &propagate) != TCL_OK) {
return TCL_ERROR;
}
/*
* Only request a relayout if the propagation bit changes.
*/
old = !(masterPtr->flags & DONT_PROPAGATE);
if (propagate != old) {
if (propagate) {
/*
* If we have slaves, we need to register as geometry master.
*/
if (masterPtr->slavePtr != NULL) {
if (TkSetGeometryMaster(interp, master, "grid") != TCL_OK) {
return TCL_ERROR;
}
masterPtr->flags |= ALLOCED_MASTER;
}
masterPtr->flags &= ~DONT_PROPAGATE;
} else {
if (masterPtr->flags & ALLOCED_MASTER) {
TkFreeGeometryMaster(master, "grid");
masterPtr->flags &= ~ALLOCED_MASTER;
}
masterPtr->flags |= DONT_PROPAGATE;
}
/*
* Re-arrange the master to allow new geometry information to
* propagate upwards to the master's master.
*/
if (masterPtr->abortPtr != NULL) {
*masterPtr->abortPtr = 1;
}
if (!(masterPtr->flags & REQUESTED_RELAYOUT)) {
masterPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, masterPtr);
}
}
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* GridRowColumnConfigureCommand --
*
* Implementation of the [grid rowconfigure] and [grid columnconfigure]
* subcommands. See the user documentation for details on what these do.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* Depends on arguments; see user documentation.
*
*----------------------------------------------------------------------
*/
static int
GridRowColumnConfigureCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window master, slave;
Gridder *masterPtr, *slavePtr;
SlotInfo *slotPtr = NULL;
int slot; /* the column or row number */
int slotType; /* COLUMN or ROW */
int size; /* the configuration value */
int lObjc; /* Number of items in index list */
Tcl_Obj **lObjv; /* array of indices */
int ok; /* temporary TCL result code */
int i, j, first, last;
const char *string;
static const char *const optionStrings[] = {
"-minsize", "-pad", "-uniform", "-weight", NULL
};
enum options {
ROWCOL_MINSIZE, ROWCOL_PAD, ROWCOL_UNIFORM, ROWCOL_WEIGHT
};
int index;
Tcl_Obj *listCopy;
if (((objc % 2 != 0) && (objc > 6)) || (objc < 4)) {
Tcl_WrongNumArgs(interp, 2, objv, "master index ?-option value ...?");
return TCL_ERROR;
}
if (TkGetWindowFromObj(interp, tkwin, objv[2], &master) != TCL_OK) {
return TCL_ERROR;
}
listCopy = Tcl_DuplicateObj(objv[3]);
Tcl_IncrRefCount(listCopy);
if (Tcl_ListObjGetElements(interp, listCopy, &lObjc, &lObjv) != TCL_OK) {
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
string = Tcl_GetString(objv[1]);
slotType = (*string == 'c') ? COLUMN : ROW;
if (lObjc == 0) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf("no %s indices specified",
(slotType == COLUMN) ? "column" : "row"));
Tcl_SetErrorCode(interp, "TK", "GRID", "NO_INDEX", NULL);
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
masterPtr = GetGrid(master);
first = 0; /* lint */
last = 0; /* lint */
if ((objc == 4) || (objc == 5)) {
if (lObjc != 1) {
Tcl_SetObjResult(interp, Tcl_NewStringObj(
"must specify a single element on retrieval", -1));
Tcl_SetErrorCode(interp, "TK", "GRID", "USAGE", NULL);
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
if (Tcl_GetIntFromObj(interp, lObjv[0], &slot) != TCL_OK) {
Tcl_AppendResult(interp,
" (when retrieving options only integer indices are "
"allowed)", NULL);
Tcl_SetErrorCode(interp, "TK", "GRID", "INDEX_FORMAT", NULL);
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
ok = CheckSlotData(masterPtr, slot, slotType, /* checkOnly */ 1);
if (ok == TCL_OK) {
slotPtr = (slotType == COLUMN) ?
masterPtr->masterDataPtr->columnPtr :
masterPtr->masterDataPtr->rowPtr;
}
/*
* Return all of the options for this row or column. If the request is
* out of range, return all 0's.
*/
if (objc == 4) {
int minsize = 0, pad = 0, weight = 0;
Tk_Uid uniform = NULL;
Tcl_Obj *res = Tcl_NewListObj(0, NULL);
if (ok == TCL_OK) {
minsize = slotPtr[slot].minSize;
pad = slotPtr[slot].pad;
weight = slotPtr[slot].weight;
uniform = slotPtr[slot].uniform;
}
Tcl_ListObjAppendElement(interp, res,
Tcl_NewStringObj("-minsize", -1));
Tcl_ListObjAppendElement(interp, res, Tcl_NewIntObj(minsize));
Tcl_ListObjAppendElement(interp, res,
Tcl_NewStringObj("-pad", -1));
Tcl_ListObjAppendElement(interp, res, Tcl_NewIntObj(pad));
Tcl_ListObjAppendElement(interp, res,
Tcl_NewStringObj("-uniform", -1));
Tcl_ListObjAppendElement(interp, res,
Tcl_NewStringObj(uniform == NULL ? "" : uniform, -1));
Tcl_ListObjAppendElement(interp, res,
Tcl_NewStringObj("-weight", -1));
Tcl_ListObjAppendElement(interp, res, Tcl_NewIntObj(weight));
Tcl_SetObjResult(interp, res);
Tcl_DecrRefCount(listCopy);
return TCL_OK;
}
/*
* If only one option is given, with no value, the current value is
* returned.
*/
if (Tcl_GetIndexFromObjStruct(interp, objv[4], optionStrings,
sizeof(char *), "option", 0, &index) != TCL_OK) {
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
if (index == ROWCOL_MINSIZE) {
Tcl_SetObjResult(interp, Tcl_NewIntObj(
(ok == TCL_OK) ? slotPtr[slot].minSize : 0));
} else if (index == ROWCOL_WEIGHT) {
Tcl_SetObjResult(interp, Tcl_NewIntObj(
(ok == TCL_OK) ? slotPtr[slot].weight : 0));
} else if (index == ROWCOL_UNIFORM) {
Tk_Uid value = (ok == TCL_OK) ? slotPtr[slot].uniform : "";
Tcl_SetObjResult(interp, Tcl_NewStringObj(
(value == NULL) ? "" : value, -1));
} else if (index == ROWCOL_PAD) {
Tcl_SetObjResult(interp, Tcl_NewIntObj(
(ok == TCL_OK) ? slotPtr[slot].pad : 0));
}
Tcl_DecrRefCount(listCopy);
return TCL_OK;
}
for (j = 0; j < lObjc; j++) {
int allSlaves = 0;
if (Tcl_GetIntFromObj(NULL, lObjv[j], &slot) == TCL_OK) {
first = slot;
last = slot;
slavePtr = NULL;
} else if (strcmp(Tcl_GetString(lObjv[j]), "all") == 0) {
/*
* Make sure master is initialised.
*/
InitMasterData(masterPtr);
slavePtr = masterPtr->slavePtr;
if (slavePtr == NULL) {
continue;
}
allSlaves = 1;
} else if (TkGetWindowFromObj(NULL, tkwin, lObjv[j], &slave)
== TCL_OK) {
/*
* Is it gridded in this master?
*/
slavePtr = GetGrid(slave);
if (slavePtr->masterPtr != masterPtr) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"the window \"%s\" is not managed by \"%s\"",
Tcl_GetString(lObjv[j]), Tcl_GetString(objv[2])));
Tcl_SetErrorCode(interp, "TK", "GRID", "NOT_MASTER", NULL);
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
} else {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"illegal index \"%s\"", Tcl_GetString(lObjv[j])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "GRID_INDEX", NULL);
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
/*
* The outer loop is only to handle "all".
*/
do {
if (slavePtr != NULL) {
first = (slotType == COLUMN) ?
slavePtr->column : slavePtr->row;
last = first - 1 + ((slotType == COLUMN) ?
slavePtr->numCols : slavePtr->numRows);
}
for (slot = first; slot <= last; slot++) {
ok = CheckSlotData(masterPtr, slot, slotType, /*checkOnly*/ 0);
if (ok != TCL_OK) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"\"%s\" is out of range",
Tcl_GetString(lObjv[j])));
Tcl_SetErrorCode(interp, "TK", "GRID", "INDEX_RANGE",
NULL);
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
slotPtr = (slotType == COLUMN) ?
masterPtr->masterDataPtr->columnPtr :
masterPtr->masterDataPtr->rowPtr;
/*
* Loop through each option value pair, setting the values as
* required.
*/
for (i = 4; i < objc; i += 2) {
if (Tcl_GetIndexFromObjStruct(interp, objv[i], optionStrings,
sizeof(char *), "option", 0, &index) != TCL_OK) {
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
}
if (index == ROWCOL_MINSIZE) {
if (Tk_GetPixelsFromObj(interp, master, objv[i+1],
&size) != TCL_OK) {
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
} else {
slotPtr[slot].minSize = size;
}
} else if (index == ROWCOL_WEIGHT) {
int wt;
if (Tcl_GetIntFromObj(interp,objv[i+1],&wt)!=TCL_OK) {
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
} else if (wt < 0) {
Tcl_DecrRefCount(listCopy);
goto negativeIndex;
} else {
slotPtr[slot].weight = wt;
}
} else if (index == ROWCOL_UNIFORM) {
slotPtr[slot].uniform =
Tk_GetUid(Tcl_GetString(objv[i+1]));
if (slotPtr[slot].uniform != NULL &&
slotPtr[slot].uniform[0] == 0) {
slotPtr[slot].uniform = NULL;
}
} else if (index == ROWCOL_PAD) {
if (Tk_GetPixelsFromObj(interp, master, objv[i+1],
&size) != TCL_OK) {
Tcl_DecrRefCount(listCopy);
return TCL_ERROR;
} else if (size < 0) {
Tcl_DecrRefCount(listCopy);
goto negativeIndex;
} else {
slotPtr[slot].pad = size;
}
}
}
}
if (slavePtr != NULL) {
slavePtr = slavePtr->nextPtr;
}
} while ((allSlaves == 1) && (slavePtr != NULL));
}
Tcl_DecrRefCount(listCopy);
/*
* We changed a property, re-arrange the table, and check for constraint
* shrinkage. A null slotPtr will occur for 'all' checks.
*/
if (slotPtr != NULL) {
if (slotType == ROW) {
int last = masterPtr->masterDataPtr->rowMax - 1;
while ((last >= 0) && (slotPtr[last].weight == 0)
&& (slotPtr[last].pad == 0) && (slotPtr[last].minSize == 0)
&& (slotPtr[last].uniform == NULL)) {
last--;
}
masterPtr->masterDataPtr->rowMax = last+1;
} else {
int last = masterPtr->masterDataPtr->columnMax - 1;
while ((last >= 0) && (slotPtr[last].weight == 0)
&& (slotPtr[last].pad == 0) && (slotPtr[last].minSize == 0)
&& (slotPtr[last].uniform == NULL)) {
last--;
}
masterPtr->masterDataPtr->columnMax = last + 1;
}
}
if (masterPtr->abortPtr != NULL) {
*masterPtr->abortPtr = 1;
}
if (!(masterPtr->flags & REQUESTED_RELAYOUT)) {
masterPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, masterPtr);
}
return TCL_OK;
negativeIndex:
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"invalid arg \"%s\": should be non-negative",
Tcl_GetString(objv[i])));
Tcl_SetErrorCode(interp, "TK", "GRID", "NEG_INDEX", NULL);
return TCL_ERROR;
}
/*
*----------------------------------------------------------------------
*
* GridSizeCommand --
*
* Implementation of the [grid size] subcommand. See the user
* documentation for details on what it does.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* Puts grid size information in the interpreter's result.
*
*----------------------------------------------------------------------
*/
static int
GridSizeCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window master;
Gridder *masterPtr;
GridMaster *gridPtr; /* pointer to grid data */
if (objc != 3) {
Tcl_WrongNumArgs(interp, 2, objv, "window");
return TCL_ERROR;
}
if (TkGetWindowFromObj(interp, tkwin, objv[2], &master) != TCL_OK) {
return TCL_ERROR;
}
masterPtr = GetGrid(master);
if (masterPtr->masterDataPtr != NULL) {
SetGridSize(masterPtr);
gridPtr = masterPtr->masterDataPtr;
Tcl_SetObjResult(interp, NewPairObj(
MAX(gridPtr->columnEnd, gridPtr->columnMax),
MAX(gridPtr->rowEnd, gridPtr->rowMax)));
} else {
Tcl_SetObjResult(interp, NewPairObj(0, 0));
}
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* GridSlavesCommand --
*
* Implementation of the [grid slaves] subcommand. See the user
* documentation for details on what it does.
*
* Results:
* Standard Tcl result.
*
* Side effects:
* Places a list of slaves of the specified window in the interpreter's
* result field.
*
*----------------------------------------------------------------------
*/
static int
GridSlavesCommand(
Tk_Window tkwin, /* Main window of the application. */
Tcl_Interp *interp, /* Current interpreter. */
int objc, /* Number of arguments. */
Tcl_Obj *const objv[]) /* Argument objects. */
{
Tk_Window master;
Gridder *masterPtr; /* master grid record */
Gridder *slavePtr;
int i, value, index;
int row = -1, column = -1;
static const char *const optionStrings[] = {
"-column", "-row", NULL
};
enum options { SLAVES_COLUMN, SLAVES_ROW };
Tcl_Obj *res;
if ((objc < 3) || ((objc % 2) == 0)) {
Tcl_WrongNumArgs(interp, 2, objv, "window ?-option value ...?");
return TCL_ERROR;
}
for (i = 3; i < objc; i += 2) {
if (Tcl_GetIndexFromObjStruct(interp, objv[i], optionStrings,
sizeof(char *), "option", 0, &index) != TCL_OK) {
return TCL_ERROR;
}
if (Tcl_GetIntFromObj(interp, objv[i+1], &value) != TCL_OK) {
return TCL_ERROR;
}
if (value < 0) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"%d is an invalid value: should NOT be < 0", value));
Tcl_SetErrorCode(interp, "TK", "GRID", "NEG_INDEX", NULL);
return TCL_ERROR;
}
if (index == SLAVES_COLUMN) {
column = value;
} else {
row = value;
}
}
if (TkGetWindowFromObj(interp, tkwin, objv[2], &master) != TCL_OK) {
return TCL_ERROR;
}
masterPtr = GetGrid(master);
res = Tcl_NewListObj(0, NULL);
for (slavePtr = masterPtr->slavePtr; slavePtr != NULL;
slavePtr = slavePtr->nextPtr) {
if ((column >= 0) && (slavePtr->column > column
|| slavePtr->column+slavePtr->numCols-1 < column)) {
continue;
}
if ((row >= 0) && (slavePtr->row > row ||
slavePtr->row+slavePtr->numRows-1 < row)) {
continue;
}
Tcl_ListObjAppendElement(interp,res, TkNewWindowObj(slavePtr->tkwin));
}
Tcl_SetObjResult(interp, res);
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* GridReqProc --
*
* This procedure is invoked by Tk_GeometryRequest for windows managed by
* the grid.
*
* Results:
* None.
*
* Side effects:
* Arranges for tkwin, and all its managed siblings, to be re-arranged at
* the next idle point.
*
*----------------------------------------------------------------------
*/
static void
GridReqProc(
ClientData clientData, /* Grid's information about window that got
* new preferred geometry. */
Tk_Window tkwin) /* Other Tk-related information about the
* window. */
{
register Gridder *gridPtr = clientData;
gridPtr = gridPtr->masterPtr;
if (gridPtr && !(gridPtr->flags & REQUESTED_RELAYOUT)) {
gridPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, gridPtr);
}
}
/*
*----------------------------------------------------------------------
*
* GridLostSlaveProc --
*
* This procedure is invoked by Tk whenever some other geometry claims
* control over a slave that used to be managed by us.
*
* Results:
* None.
*
* Side effects:
* Forgets all grid-related information about the slave.
*
*----------------------------------------------------------------------
*/
static void
GridLostSlaveProc(
ClientData clientData, /* Grid structure for slave window that was
* stolen away. */
Tk_Window tkwin) /* Tk's handle for the slave window. */
{
register Gridder *slavePtr = clientData;
if (slavePtr->masterPtr->tkwin != Tk_Parent(slavePtr->tkwin)) {
Tk_UnmaintainGeometry(slavePtr->tkwin, slavePtr->masterPtr->tkwin);
}
Unlink(slavePtr);
Tk_UnmapWindow(slavePtr->tkwin);
}
/*
*----------------------------------------------------------------------
*
* AdjustOffsets --
*
* This procedure adjusts the size of the layout to fit in the space
* provided. If it needs more space, the extra is added according to the
* weights. If it needs less, the space is removed according to the
* weights, but at no time does the size drop below the minsize specified
* for that slot.
*
* Results:
* The size used by the layout.
*
* Side effects:
* The slot offsets are modified to shrink the layout.
*
*----------------------------------------------------------------------
*/
static int
AdjustOffsets(
int size, /* The total layout size (in pixels). */
int slots, /* Number of slots. */
register SlotInfo *slotPtr) /* Pointer to slot array. */
{
register int slot; /* Current slot. */
int diff; /* Extra pixels needed to add to the layout. */
int totalWeight; /* Sum of the weights for all the slots. */
int weight; /* Sum of the weights so far. */
int minSize; /* Minimum possible layout size. */
int newDiff; /* The most pixels that can be added on the
* current pass. */
diff = size - slotPtr[slots-1].offset;
/*
* The layout is already the correct size; all done.
*/
if (diff == 0) {
return size;
}
/*
* If all the weights are zero, there is nothing more to do.
*/
totalWeight = 0;
for (slot = 0; slot < slots; slot++) {
totalWeight += slotPtr[slot].weight;
}
if (totalWeight == 0) {
return slotPtr[slots-1].offset;
}
/*
* Add extra space according to the slot weights. This is done
* cumulatively to prevent round-off error accumulation.
*/
if (diff > 0) {
weight = 0;
for (slot = 0; slot < slots; slot++) {
weight += slotPtr[slot].weight;
slotPtr[slot].offset += diff * weight / totalWeight;
}
return size;
}
/*
* The layout must shrink below its requested size. Compute the minimum
* possible size by looking at the slot minSizes. Store each slot's
* minimum size in temp.
*/
minSize = 0;
for (slot = 0; slot < slots; slot++) {
if (slotPtr[slot].weight > 0) {
slotPtr[slot].temp = slotPtr[slot].minSize;
} else if (slot > 0) {
slotPtr[slot].temp = slotPtr[slot].offset - slotPtr[slot-1].offset;
} else {
slotPtr[slot].temp = slotPtr[slot].offset;
}
minSize += slotPtr[slot].temp;
}
/*
* If the requested size is less than the minimum required size, set the
* slot sizes to their minimum values.
*/
if (size <= minSize) {
int offset = 0;
for (slot = 0; slot < slots; slot++) {
offset += slotPtr[slot].temp;
slotPtr[slot].offset = offset;
}
return minSize;
}
/*
* Remove space from slots according to their weights. The weights get
* renormalized anytime a slot shrinks to its minimum size.
*/
while (diff < 0) {
/*
* Find the total weight for the shrinkable slots.
*/
totalWeight = 0;
for (slot = 0; slot < slots; slot++) {
int current = (slot == 0) ? slotPtr[slot].offset :
slotPtr[slot].offset - slotPtr[slot-1].offset;
if (current > slotPtr[slot].minSize) {
totalWeight += slotPtr[slot].weight;
slotPtr[slot].temp = slotPtr[slot].weight;
} else {
slotPtr[slot].temp = 0;
}
}
if (totalWeight == 0) {
break;
}
/*
* Find the maximum amount of space we can distribute this pass.
*/
newDiff = diff;
for (slot = 0; slot < slots; slot++) {
int current; /* Current size of this slot. */
int maxDiff; /* Maximum diff that would cause this slot to
* equal its minsize. */
if (slotPtr[slot].temp == 0) {
continue;
}
current = (slot == 0) ? slotPtr[slot].offset :
slotPtr[slot].offset - slotPtr[slot-1].offset;
maxDiff = totalWeight * (slotPtr[slot].minSize - current)
/ slotPtr[slot].temp;
if (maxDiff > newDiff) {
newDiff = maxDiff;
}
}
/*
* Now distribute the space.
*/
weight = 0;
for (slot = 0; slot < slots; slot++) {
weight += slotPtr[slot].temp;
slotPtr[slot].offset += newDiff * weight / totalWeight;
}
diff -= newDiff;
}
return size;
}
/*
*----------------------------------------------------------------------
*
* AdjustForSticky --
*
* This procedure adjusts the size of a slave in its cavity based on its
* "sticky" flags.
*
* Results:
* The input x, y, width, and height are changed to represent the desired
* coordinates of the slave.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
static void
AdjustForSticky(
Gridder *slavePtr, /* Slave window to arrange in its cavity. */
int *xPtr, /* Pixel location of the left edge of the cavity. */
int *yPtr, /* Pixel location of the top edge of the cavity. */
int *widthPtr, /* Width of the cavity (in pixels). */
int *heightPtr) /* Height of the cavity (in pixels). */
{
int diffx = 0; /* Cavity width - slave width. */
int diffy = 0; /* Cavity hight - slave height. */
int sticky = slavePtr->sticky;
*xPtr += slavePtr->padLeft;
*widthPtr -= slavePtr->padX;
*yPtr += slavePtr->padTop;
*heightPtr -= slavePtr->padY;
if (*widthPtr > (Tk_ReqWidth(slavePtr->tkwin) + slavePtr->iPadX)) {
diffx = *widthPtr - (Tk_ReqWidth(slavePtr->tkwin) + slavePtr->iPadX);
*widthPtr = Tk_ReqWidth(slavePtr->tkwin) + slavePtr->iPadX;
}
if (*heightPtr > (Tk_ReqHeight(slavePtr->tkwin) + slavePtr->iPadY)) {
diffy = *heightPtr - (Tk_ReqHeight(slavePtr->tkwin) + slavePtr->iPadY);
*heightPtr = Tk_ReqHeight(slavePtr->tkwin) + slavePtr->iPadY;
}
if (sticky&STICK_EAST && sticky&STICK_WEST) {
*widthPtr += diffx;
}
if (sticky&STICK_NORTH && sticky&STICK_SOUTH) {
*heightPtr += diffy;
}
if (!(sticky&STICK_WEST)) {
*xPtr += (sticky&STICK_EAST) ? diffx : diffx/2;
}
if (!(sticky&STICK_NORTH)) {
*yPtr += (sticky&STICK_SOUTH) ? diffy : diffy/2;
}
}
/*
*----------------------------------------------------------------------
*
* ArrangeGrid --
*
* This procedure is invoked (using the Tcl_DoWhenIdle mechanism) to
* re-layout a set of windows managed by the grid. It is invoked at idle
* time so that a series of grid requests can be merged into a single
* layout operation.
*
* Results:
* None.
*
* Side effects:
* The slaves of masterPtr may get resized or moved.
*
*----------------------------------------------------------------------
*/
static void
ArrangeGrid(
ClientData clientData) /* Structure describing master whose slaves
* are to be re-layed out. */
{
register Gridder *masterPtr = clientData;
register Gridder *slavePtr;
GridMaster *slotPtr = masterPtr->masterDataPtr;
int abort;
int width, height; /* Requested size of layout, in pixels. */
int realWidth, realHeight; /* Actual size layout should take-up. */
int usedX, usedY;
masterPtr->flags &= ~REQUESTED_RELAYOUT;
/*
* If the master has no slaves anymore, then don't do anything at all:
* just leave the master's size as-is. Otherwise there is no way to
* "relinquish" control over the master so another geometry manager can
* take over.
*/
if (masterPtr->slavePtr == NULL) {
return;
}
if (masterPtr->masterDataPtr == NULL) {
return;
}
/*
* Abort any nested call to ArrangeGrid for this window, since we'll do
* everything necessary here, and set up so this call can be aborted if
* necessary.
*/
if (masterPtr->abortPtr != NULL) {
*masterPtr->abortPtr = 1;
}
masterPtr->abortPtr = &abort;
abort = 0;
Tcl_Preserve(masterPtr);
/*
* Call the constraint engine to fill in the row and column offsets.
*/
SetGridSize(masterPtr);
width = ResolveConstraints(masterPtr, COLUMN, 0);
height = ResolveConstraints(masterPtr, ROW, 0);
width += Tk_InternalBorderLeft(masterPtr->tkwin) +
Tk_InternalBorderRight(masterPtr->tkwin);
height += Tk_InternalBorderTop(masterPtr->tkwin) +
Tk_InternalBorderBottom(masterPtr->tkwin);
if (width < Tk_MinReqWidth(masterPtr->tkwin)) {
width = Tk_MinReqWidth(masterPtr->tkwin);
}
if (height < Tk_MinReqHeight(masterPtr->tkwin)) {
height = Tk_MinReqHeight(masterPtr->tkwin);
}
if (((width != Tk_ReqWidth(masterPtr->tkwin))
|| (height != Tk_ReqHeight(masterPtr->tkwin)))
&& !(masterPtr->flags & DONT_PROPAGATE)) {
Tk_GeometryRequest(masterPtr->tkwin, width, height);
if (width>1 && height>1) {
masterPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, masterPtr);
}
masterPtr->abortPtr = NULL;
Tcl_Release(masterPtr);
return;
}
/*
* If the currently requested layout size doesn't match the master's
* window size, then adjust the slot offsets according to the weights. If
* all of the weights are zero, place the layout according to the anchor
* value.
*/
realWidth = Tk_Width(masterPtr->tkwin) -
Tk_InternalBorderLeft(masterPtr->tkwin) -
Tk_InternalBorderRight(masterPtr->tkwin);
realHeight = Tk_Height(masterPtr->tkwin) -
Tk_InternalBorderTop(masterPtr->tkwin) -
Tk_InternalBorderBottom(masterPtr->tkwin);
usedX = AdjustOffsets(realWidth,
MAX(slotPtr->columnEnd, slotPtr->columnMax), slotPtr->columnPtr);
usedY = AdjustOffsets(realHeight, MAX(slotPtr->rowEnd, slotPtr->rowMax),
slotPtr->rowPtr);
TkComputeAnchor(masterPtr->masterDataPtr->anchor, masterPtr->tkwin,
0, 0, usedX, usedY, &slotPtr->startX, &slotPtr->startY);
/*
* Now adjust the actual size of the slave to its cavity by computing the
* cavity size, and adjusting the widget according to its stickyness.
*/
for (slavePtr = masterPtr->slavePtr; slavePtr != NULL && !abort;
slavePtr = slavePtr->nextPtr) {
int x, y; /* Top left coordinate */
int width, height; /* Slot or slave size */
int col = slavePtr->column;
int row = slavePtr->row;
x = (col>0) ? slotPtr->columnPtr[col-1].offset : 0;
y = (row>0) ? slotPtr->rowPtr[row-1].offset : 0;
width = slotPtr->columnPtr[slavePtr->numCols+col-1].offset - x;
height = slotPtr->rowPtr[slavePtr->numRows+row-1].offset - y;
x += slotPtr->startX;
y += slotPtr->startY;
AdjustForSticky(slavePtr, &x, &y, &width, &height);
/*
* Now put the window in the proper spot. (This was taken directly
* from tkPack.c.) If the slave is a child of the master, then do this
* here. Otherwise let Tk_MaintainGeometry do the work.
*/
if (masterPtr->tkwin == Tk_Parent(slavePtr->tkwin)) {
if ((width <= 0) || (height <= 0)) {
Tk_UnmapWindow(slavePtr->tkwin);
} else {
if ((x != Tk_X(slavePtr->tkwin))
|| (y != Tk_Y(slavePtr->tkwin))
|| (width != Tk_Width(slavePtr->tkwin))
|| (height != Tk_Height(slavePtr->tkwin))) {
Tk_MoveResizeWindow(slavePtr->tkwin, x, y, width, height);
}
if (abort) {
break;
}
/*
* Don't map the slave if the master isn't mapped: wait until
* the master gets mapped later.
*/
if (Tk_IsMapped(masterPtr->tkwin)) {
Tk_MapWindow(slavePtr->tkwin);
}
}
} else if ((width <= 0) || (height <= 0)) {
Tk_UnmaintainGeometry(slavePtr->tkwin, masterPtr->tkwin);
Tk_UnmapWindow(slavePtr->tkwin);
} else {
Tk_MaintainGeometry(slavePtr->tkwin, masterPtr->tkwin, x, y,
width, height);
}
}
masterPtr->abortPtr = NULL;
Tcl_Release(masterPtr);
}
/*
*----------------------------------------------------------------------
*
* ResolveConstraints --
*
* Resolve all of the column and row boundaries. Most of the calculations
* are identical for rows and columns, so this procedure is called twice,
* once for rows, and again for columns.
*
* Results:
* The offset (in pixels) from the left/top edge of this layout is
* returned.
*
* Side effects:
* The slot offsets are copied into the SlotInfo structure for the
* geometry master.
*
*----------------------------------------------------------------------
*/
static int
ResolveConstraints(
Gridder *masterPtr, /* The geometry master for this grid. */
int slotType, /* Either ROW or COLUMN. */
int maxOffset) /* The actual maximum size of this layout in
* pixels, or 0 (not currently used). */
{
register SlotInfo *slotPtr; /* Pointer to row/col constraints. */
register Gridder *slavePtr; /* List of slave windows in this grid. */
int constraintCount; /* Count of rows or columns that have
* constraints. */
int slotCount; /* Last occupied row or column. */
int gridCount; /* The larger of slotCount and
* constraintCount. */
GridLayout *layoutPtr; /* Temporary layout structure. */
int requiredSize; /* The natural size of the grid (pixels).
* This is the minimum size needed to
* accomodate all of the slaves at their
* requested sizes. */
int offset; /* The pixel offset of the right edge of the
* current slot from the beginning of the
* layout. */
int slot; /* The current slot. */
int start; /* The first slot of a contiguous set whose
* constraints are not yet fully resolved. */
int end; /* The Last slot of a contiguous set whose
* constraints are not yet fully resolved. */
UniformGroup uniformPre[UNIFORM_PREALLOC];
/* Pre-allocated space for uniform groups. */
UniformGroup *uniformGroupPtr;
/* Uniform groups data. */
int uniformGroups; /* Number of currently used uniform groups. */
int uniformGroupsAlloced; /* Size of allocated space for uniform
* groups. */
int weight, minSize;
int prevGrow, accWeight, grow;
/*
* For typical sized tables, we'll use stack space for the layout data to
* avoid the overhead of a malloc and free for every layout.
*/
GridLayout layoutData[TYPICAL_SIZE + 1];
if (slotType == COLUMN) {
constraintCount = masterPtr->masterDataPtr->columnMax;
slotCount = masterPtr->masterDataPtr->columnEnd;
slotPtr = masterPtr->masterDataPtr->columnPtr;
} else {
constraintCount = masterPtr->masterDataPtr->rowMax;
slotCount = masterPtr->masterDataPtr->rowEnd;
slotPtr = masterPtr->masterDataPtr->rowPtr;
}
/*
* Make sure there is enough memory for the layout.
*/
gridCount = MAX(constraintCount, slotCount);
if (gridCount >= TYPICAL_SIZE) {
layoutPtr = ckalloc(sizeof(GridLayout) * (1+gridCount));
} else {
layoutPtr = layoutData;
}
/*
* Allocate an extra layout slot to represent the left/top edge of the 0th
* slot to make it easier to calculate slot widths from offsets without
* special case code.
*
* Initialize the "dummy" slot to the left/top of the table. This slot
* avoids special casing the first slot.
*/
layoutPtr->minOffset = 0;
layoutPtr->maxOffset = 0;
layoutPtr++;
/*
* Step 1.
* Copy the slot constraints into the layout structure, and initialize the
* rest of the fields.
*/
for (slot=0; slot < constraintCount; slot++) {
layoutPtr[slot].minSize = slotPtr[slot].minSize;
layoutPtr[slot].weight = slotPtr[slot].weight;
layoutPtr[slot].uniform = slotPtr[slot].uniform;
layoutPtr[slot].pad = slotPtr[slot].pad;
layoutPtr[slot].binNextPtr = NULL;
}
for (; slot<gridCount; slot++) {
layoutPtr[slot].minSize = 0;
layoutPtr[slot].weight = 0;
layoutPtr[slot].uniform = NULL;
layoutPtr[slot].pad = 0;
layoutPtr[slot].binNextPtr = NULL;
}
/*
* Step 2.
* Slaves with a span of 1 are used to determine the minimum size of each
* slot. Slaves whose span is two or more slots don't contribute to the
* minimum size of each slot directly, but can cause slots to grow if
* their size exceeds the the sizes of the slots they span.
*
* Bin all slaves whose spans are > 1 by their right edges. This allows
* the computation on minimum and maximum possible layout sizes at each
* slot boundary, without the need to re-sort the slaves.
*/
switch (slotType) {
case COLUMN:
for (slavePtr = masterPtr->slavePtr; slavePtr != NULL;
slavePtr = slavePtr->nextPtr) {
int rightEdge = slavePtr->column + slavePtr->numCols - 1;
slavePtr->size = Tk_ReqWidth(slavePtr->tkwin) + slavePtr->padX
+ slavePtr->iPadX + slavePtr->doubleBw;
if (slavePtr->numCols > 1) {
slavePtr->binNextPtr = layoutPtr[rightEdge].binNextPtr;
layoutPtr[rightEdge].binNextPtr = slavePtr;
} else if (rightEdge >= 0) {
int size = slavePtr->size + layoutPtr[rightEdge].pad;
if (size > layoutPtr[rightEdge].minSize) {
layoutPtr[rightEdge].minSize = size;
}
}
}
break;
case ROW:
for (slavePtr = masterPtr->slavePtr; slavePtr != NULL;
slavePtr = slavePtr->nextPtr) {
int rightEdge = slavePtr->row + slavePtr->numRows - 1;
slavePtr->size = Tk_ReqHeight(slavePtr->tkwin) + slavePtr->padY
+ slavePtr->iPadY + slavePtr->doubleBw;
if (slavePtr->numRows > 1) {
slavePtr->binNextPtr = layoutPtr[rightEdge].binNextPtr;
layoutPtr[rightEdge].binNextPtr = slavePtr;
} else if (rightEdge >= 0) {
int size = slavePtr->size + layoutPtr[rightEdge].pad;
if (size > layoutPtr[rightEdge].minSize) {
layoutPtr[rightEdge].minSize = size;
}
}
}
break;
}
/*
* Step 2b.
* Consider demands on uniform sizes.
*/
uniformGroupPtr = uniformPre;
uniformGroupsAlloced = UNIFORM_PREALLOC;
uniformGroups = 0;
for (slot = 0; slot < gridCount; slot++) {
if (layoutPtr[slot].uniform != NULL) {
for (start = 0; start < uniformGroups; start++) {
if (uniformGroupPtr[start].group == layoutPtr[slot].uniform) {
break;
}
}
if (start >= uniformGroups) {
/*
* Have not seen that group before, set up data for it.
*/
if (uniformGroups >= uniformGroupsAlloced) {
/*
* We need to allocate more space.
*/
size_t oldSize = uniformGroupsAlloced
* sizeof(UniformGroup);
size_t newSize = (uniformGroupsAlloced + UNIFORM_PREALLOC)
* sizeof(UniformGroup);
UniformGroup *newUG = ckalloc(newSize);
UniformGroup *oldUG = uniformGroupPtr;
memcpy(newUG, oldUG, oldSize);
if (oldUG != uniformPre) {
ckfree(oldUG);
}
uniformGroupPtr = newUG;
uniformGroupsAlloced += UNIFORM_PREALLOC;
}
uniformGroups++;
uniformGroupPtr[start].group = layoutPtr[slot].uniform;
uniformGroupPtr[start].minSize = 0;
}
weight = layoutPtr[slot].weight;
weight = weight > 0 ? weight : 1;
minSize = (layoutPtr[slot].minSize + weight - 1) / weight;
if (minSize > uniformGroupPtr[start].minSize) {
uniformGroupPtr[start].minSize = minSize;
}
}
}
/*
* Data has been gathered about uniform groups. Now relayout accordingly.
*/
if (uniformGroups > 0) {
for (slot = 0; slot < gridCount; slot++) {
if (layoutPtr[slot].uniform != NULL) {
for (start = 0; start < uniformGroups; start++) {
if (uniformGroupPtr[start].group ==
layoutPtr[slot].uniform) {
weight = layoutPtr[slot].weight;
weight = weight > 0 ? weight : 1;
layoutPtr[slot].minSize =
uniformGroupPtr[start].minSize * weight;
break;
}
}
}
}
}
if (uniformGroupPtr != uniformPre) {
ckfree(uniformGroupPtr);
}
/*
* Step 3.
* Determine the minimum slot offsets going from left to right that would
* fit all of the slaves. This determines the minimum
*/
for (offset=0,slot=0; slot < gridCount; slot++) {
layoutPtr[slot].minOffset = layoutPtr[slot].minSize + offset;
for (slavePtr = layoutPtr[slot].binNextPtr; slavePtr != NULL;
slavePtr = slavePtr->binNextPtr) {
int span = (slotType == COLUMN) ?
slavePtr->numCols : slavePtr->numRows;
int required = slavePtr->size + layoutPtr[slot - span].minOffset;
if (required > layoutPtr[slot].minOffset) {
layoutPtr[slot].minOffset = required;
}
}
offset = layoutPtr[slot].minOffset;
}
/*
* At this point, we know the minimum required size of the entire layout.
* It might be prudent to stop here if our "master" will resize itself to
* this size.
*/
requiredSize = offset;
if (maxOffset > offset) {
offset=maxOffset;
}
/*
* Step 4.
* Determine the minimum slot offsets going from right to left, bounding
* the pixel range of each slot boundary. Pre-fill all of the right
* offsets with the actual size of the table; they will be reduced as
* required.
*/
for (slot=0; slot < gridCount; slot++) {
layoutPtr[slot].maxOffset = offset;
}
for (slot=gridCount-1; slot > 0;) {
for (slavePtr = layoutPtr[slot].binNextPtr; slavePtr != NULL;
slavePtr = slavePtr->binNextPtr) {
int span = (slotType == COLUMN) ?
slavePtr->numCols : slavePtr->numRows;
int require = offset - slavePtr->size;
int startSlot = slot - span;
if (startSlot >=0 && require < layoutPtr[startSlot].maxOffset) {
layoutPtr[startSlot].maxOffset = require;
}
}
offset -= layoutPtr[slot].minSize;
slot--;
if (layoutPtr[slot].maxOffset < offset) {
offset = layoutPtr[slot].maxOffset;
} else {
layoutPtr[slot].maxOffset = offset;
}
}
/*
* Step 5.
* At this point, each slot boundary has a range of values that will
* satisfy the overall layout size. Make repeated passes over the layout
* structure looking for spans of slot boundaries where the minOffsets are
* less than the maxOffsets, and adjust the offsets according to the slot
* weights. At each pass, at least one slot boundary will have its range
* of possible values fixed at a single value.
*/
for (start = 0; start < gridCount;) {
int totalWeight = 0; /* Sum of the weights for all of the slots in
* this span. */
int need = 0; /* The minimum space needed to layout this
* span. */
int have; /* The actual amount of space that will be
* taken up by this span. */
int weight; /* Cumulative weights of the columns in this
* span. */
int noWeights = 0; /* True if the span has no weights. */
/*
* Find a span by identifying ranges of slots whose edges are already
* constrained at fixed offsets, but whose internal slot boundaries
* have a range of possible positions.
*/
if (layoutPtr[start].minOffset == layoutPtr[start].maxOffset) {
start++;
continue;
}
for (end = start + 1; end < gridCount; end++) {
if (layoutPtr[end].minOffset == layoutPtr[end].maxOffset) {
break;
}
}
/*
* We found a span. Compute the total weight, minumum space required,
* for this span, and the actual amount of space the span should use.
*/
for (slot = start; slot <= end; slot++) {
totalWeight += layoutPtr[slot].weight;
need += layoutPtr[slot].minSize;
}
have = layoutPtr[end].maxOffset - layoutPtr[start-1].minOffset;
/*
* If all the weights in the span are zero, then distribute the extra
* space evenly.
*/
if (totalWeight == 0) {
noWeights++;
totalWeight = end - start + 1;
}
/*
* It might not be possible to give the span all of the space
* available on this pass without violating the size constraints of
* one or more of the internal slot boundaries. Try to determine the
* maximum amount of space that when added to the entire span, would
* cause a slot boundary to have its possible range reduced to one
* value, and reduce the amount of extra space allocated on this pass
* accordingly.
*
* The calculation is done cumulatively to avoid accumulating roundoff
* errors.
*/
do {
int prevMinOffset = layoutPtr[start - 1].minOffset;
prevGrow = 0;
accWeight = 0;
for (slot = start; slot <= end; slot++) {
weight = noWeights ? 1 : layoutPtr[slot].weight;
accWeight += weight;
grow = (have - need) * accWeight / totalWeight - prevGrow;
prevGrow += grow;
if ((weight > 0) &&
((prevMinOffset + layoutPtr[slot].minSize + grow)
> layoutPtr[slot].maxOffset)) {
int newHave;
/*
* There is not enough room to grow that much. Calculate
* how much this slot can grow and how much "have" that
* corresponds to.
*/
grow = layoutPtr[slot].maxOffset -
layoutPtr[slot].minSize - prevMinOffset;
newHave = grow * totalWeight / weight;
if (newHave > totalWeight) {
/*
* By distributing multiples of totalWeight we
* minimize rounding errors since they will only
* happen in the last loop(s).
*/
newHave = newHave / totalWeight * totalWeight;
}
if (newHave <= 0) {
/*
* We can end up with a "have" of 0 here if the
* previous slots have taken all the space. In that
* case we cannot guess an appropriate "have" so we
* just try some lower "have" that is >= 1, to make
* sure this terminates.
*/
newHave = (have - need) - 1;
if (newHave > (3 * totalWeight)) {
/*
* Go down 25% for large values.
*/
newHave = newHave * 3 / 4;
}
if (newHave > totalWeight) {
/*
* Round down to a multiple of totalWeight.
*/
newHave = newHave / totalWeight * totalWeight;
}
if (newHave <= 0) {
newHave = 1;
}
}
have = newHave + need;
/*
* Restart loop to check if the new "have" will fit.
*/
break;
}
prevMinOffset += layoutPtr[slot].minSize + grow;
if (prevMinOffset < layoutPtr[slot].minOffset) {
prevMinOffset = layoutPtr[slot].minOffset;
}
}
/*
* Quit the outer loop if the inner loop ran all the way.
*/
} while (slot <= end);
/*
* Now distribute the extra space among the slots by adjusting the
* minSizes and minOffsets.
*/
prevGrow = 0;
accWeight = 0;
for (slot = start; slot <= end; slot++) {
accWeight += noWeights ? 1 : layoutPtr[slot].weight;
grow = (have - need) * accWeight / totalWeight - prevGrow;
prevGrow += grow;
layoutPtr[slot].minSize += grow;
if ((layoutPtr[slot-1].minOffset + layoutPtr[slot].minSize)
> layoutPtr[slot].minOffset) {
layoutPtr[slot].minOffset = layoutPtr[slot-1].minOffset +
layoutPtr[slot].minSize;
}
}
/*
* Having pushed the top/left boundaries of the slots to take up extra
* space, the bottom/right space is recalculated to propagate the new
* space allocation.
*/
for (slot = end; slot > start; slot--) {
/*
* maxOffset may not go up.
*/
if ((layoutPtr[slot].maxOffset-layoutPtr[slot].minSize)
< layoutPtr[slot-1].maxOffset) {
layoutPtr[slot-1].maxOffset =
layoutPtr[slot].maxOffset-layoutPtr[slot].minSize;
}
}
}
/*
* Step 6.
* All of the space has been apportioned; copy the layout information back
* into the master.
*/
for (slot=0; slot < gridCount; slot++) {
slotPtr[slot].offset = layoutPtr[slot].minOffset;
}
--layoutPtr;
if (layoutPtr != layoutData) {
ckfree(layoutPtr);
}
return requiredSize;
}
/*
*----------------------------------------------------------------------
*
* GetGrid --
*
* This internal procedure is used to locate a Grid structure for a given
* window, creating one if one doesn't exist already.
*
* Results:
* The return value is a pointer to the Grid structure corresponding to
* tkwin.
*
* Side effects:
* A new grid structure may be created. If so, then a callback is set up
* to clean things up when the window is deleted.
*
*----------------------------------------------------------------------
*/
static Gridder *
GetGrid(
Tk_Window tkwin) /* Token for window for which grid structure
* is desired. */
{
register Gridder *gridPtr;
Tcl_HashEntry *hPtr;
int isNew;
TkDisplay *dispPtr = ((TkWindow *) tkwin)->dispPtr;
if (!dispPtr->gridInit) {
Tcl_InitHashTable(&dispPtr->gridHashTable, TCL_ONE_WORD_KEYS);
dispPtr->gridInit = 1;
}
/*
* See if there's already grid for this window. If not, then create a new
* one.
*/
hPtr = Tcl_CreateHashEntry(&dispPtr->gridHashTable, (char*) tkwin, &isNew);
if (!isNew) {
return Tcl_GetHashValue(hPtr);
}
gridPtr = ckalloc(sizeof(Gridder));
gridPtr->tkwin = tkwin;
gridPtr->masterPtr = NULL;
gridPtr->masterDataPtr = NULL;
gridPtr->nextPtr = NULL;
gridPtr->slavePtr = NULL;
gridPtr->binNextPtr = NULL;
gridPtr->column = -1;
gridPtr->row = -1;
gridPtr->numCols = 1;
gridPtr->numRows = 1;
gridPtr->padX = 0;
gridPtr->padY = 0;
gridPtr->padLeft = 0;
gridPtr->padTop = 0;
gridPtr->iPadX = 0;
gridPtr->iPadY = 0;
gridPtr->doubleBw = 2 * Tk_Changes(tkwin)->border_width;
gridPtr->abortPtr = NULL;
gridPtr->flags = 0;
gridPtr->sticky = 0;
gridPtr->size = 0;
gridPtr->in = NULL;
gridPtr->masterDataPtr = NULL;
Tcl_SetHashValue(hPtr, gridPtr);
Tk_CreateEventHandler(tkwin, StructureNotifyMask,
GridStructureProc, gridPtr);
return gridPtr;
}
/*
*----------------------------------------------------------------------
*
* SetGridSize --
*
* This internal procedure sets the size of the grid occupied by slaves.
*
* Results:
* None
*
* Side effects:
* The width and height arguments are filled in the master data
* structure. Additional space is allocated for the constraints to
* accomodate the offsets.
*
*----------------------------------------------------------------------
*/
static void
SetGridSize(
Gridder *masterPtr) /* The geometry master for this grid. */
{
register Gridder *slavePtr; /* Current slave window. */
int maxX = 0, maxY = 0;
for (slavePtr = masterPtr->slavePtr; slavePtr != NULL;
slavePtr = slavePtr->nextPtr) {
maxX = MAX(maxX, slavePtr->numCols + slavePtr->column);
maxY = MAX(maxY, slavePtr->numRows + slavePtr->row);
}
masterPtr->masterDataPtr->columnEnd = maxX;
masterPtr->masterDataPtr->rowEnd = maxY;
CheckSlotData(masterPtr, maxX, COLUMN, CHECK_SPACE);
CheckSlotData(masterPtr, maxY, ROW, CHECK_SPACE);
}
/*
*----------------------------------------------------------------------
*
* SetSlaveColumn --
*
* Update column data for a slave, checking that MAX_ELEMENT bound
* is not passed.
*
* Results:
* TCL_ERROR if out of bounds, TCL_OK otherwise
*
* Side effects:
* Slave fields are updated.
*
*----------------------------------------------------------------------
*/
static int
SetSlaveColumn(
Tcl_Interp *interp, /* Interp for error message. */
Gridder *slavePtr, /* Slave to be updated. */
int column, /* New column or -1 to be unchanged. */
int numCols) /* New columnspan or -1 to be unchanged. */
{
int newColumn, newNumCols, lastCol;
newColumn = (column >= 0) ? column : slavePtr->column;
newNumCols = (numCols >= 1) ? numCols : slavePtr->numCols;
lastCol = ((newColumn >= 0) ? newColumn : 0) + newNumCols;
if (lastCol >= MAX_ELEMENT) {
Tcl_SetObjResult(interp, Tcl_NewStringObj("column out of bounds",-1));
Tcl_SetErrorCode(interp, "TK", "GRID", "BAD_COLUMN", NULL);
return TCL_ERROR;
}
slavePtr->column = newColumn;
slavePtr->numCols = newNumCols;
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* SetSlaveRow --
*
* Update row data for a slave, checking that MAX_ELEMENT bound
* is not passed.
*
* Results:
* TCL_ERROR if out of bounds, TCL_OK otherwise
*
* Side effects:
* Slave fields are updated.
*
*----------------------------------------------------------------------
*/
static int
SetSlaveRow(
Tcl_Interp *interp, /* Interp for error message. */
Gridder *slavePtr, /* Slave to be updated. */
int row, /* New row or -1 to be unchanged. */
int numRows) /* New rowspan or -1 to be unchanged. */
{
int newRow, newNumRows, lastRow;
newRow = (row >= 0) ? row : slavePtr->row;
newNumRows = (numRows >= 1) ? numRows : slavePtr->numRows;
lastRow = ((newRow >= 0) ? newRow : 0) + newNumRows;
if (lastRow >= MAX_ELEMENT) {
Tcl_SetObjResult(interp, Tcl_NewStringObj("row out of bounds", -1));
Tcl_SetErrorCode(interp, "TK", "GRID", "BAD_ROW", NULL);
return TCL_ERROR;
}
slavePtr->row = newRow;
slavePtr->numRows = newNumRows;
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* CheckSlotData --
*
* This internal procedure is used to manage the storage for row and
* column (slot) constraints.
*
* Results:
* TRUE if the index is OK, False otherwise.
*
* Side effects:
* A new master grid structure may be created. If so, then it is
* initialized. In addition, additional storage for a row or column
* constraints may be allocated, and the constraint maximums are
* adjusted.
*
*----------------------------------------------------------------------
*/
static int
CheckSlotData(
Gridder *masterPtr, /* The geometry master for this grid. */
int slot, /* Which slot to look at. */
int slotType, /* ROW or COLUMN. */
int checkOnly) /* Don't allocate new space if true. */
{
int numSlot; /* Number of slots already allocated (Space) */
int end; /* Last used constraint. */
/*
* If slot is out of bounds, return immediately.
*/
if (slot < 0 || slot >= MAX_ELEMENT) {
return TCL_ERROR;
}
if ((checkOnly == CHECK_ONLY) && (masterPtr->masterDataPtr == NULL)) {
return TCL_ERROR;
}
/*
* If we need to allocate more space, allocate a little extra to avoid
* repeated re-alloc's for large tables. We need enough space to hold all
* of the offsets as well.
*/
InitMasterData(masterPtr);
end = (slotType == ROW) ? masterPtr->masterDataPtr->rowMax :
masterPtr->masterDataPtr->columnMax;
if (checkOnly == CHECK_ONLY) {
return ((end < slot) ? TCL_ERROR : TCL_OK);
} else {
numSlot = (slotType == ROW) ? masterPtr->masterDataPtr->rowSpace
: masterPtr->masterDataPtr->columnSpace;
if (slot >= numSlot) {
int newNumSlot = slot + PREALLOC;
size_t oldSize = numSlot * sizeof(SlotInfo);
size_t newSize = newNumSlot * sizeof(SlotInfo);
SlotInfo *newSI = ckalloc(newSize);
SlotInfo *oldSI = (slotType == ROW)
? masterPtr->masterDataPtr->rowPtr
: masterPtr->masterDataPtr->columnPtr;
memcpy(newSI, oldSI, oldSize);
memset(newSI+numSlot, 0, newSize - oldSize);
ckfree(oldSI);
if (slotType == ROW) {
masterPtr->masterDataPtr->rowPtr = newSI;
masterPtr->masterDataPtr->rowSpace = newNumSlot;
} else {
masterPtr->masterDataPtr->columnPtr = newSI;
masterPtr->masterDataPtr->columnSpace = newNumSlot;
}
}
if (slot >= end && checkOnly != CHECK_SPACE) {
if (slotType == ROW) {
masterPtr->masterDataPtr->rowMax = slot+1;
} else {
masterPtr->masterDataPtr->columnMax = slot+1;
}
}
return TCL_OK;
}
}
/*
*----------------------------------------------------------------------
*
* InitMasterData --
*
* This internal procedure is used to allocate and initialize the data
* for a geometry master, if the data doesn't exist already.
*
* Results:
* none
*
* Side effects:
* A new master grid structure may be created. If so, then it is
* initialized.
*
*----------------------------------------------------------------------
*/
static void
InitMasterData(
Gridder *masterPtr)
{
if (masterPtr->masterDataPtr == NULL) {
GridMaster *gridPtr = masterPtr->masterDataPtr =
ckalloc(sizeof(GridMaster));
size_t size = sizeof(SlotInfo) * TYPICAL_SIZE;
gridPtr->columnEnd = 0;
gridPtr->columnMax = 0;
gridPtr->columnPtr = ckalloc(size);
gridPtr->columnSpace = TYPICAL_SIZE;
gridPtr->rowEnd = 0;
gridPtr->rowMax = 0;
gridPtr->rowPtr = ckalloc(size);
gridPtr->rowSpace = TYPICAL_SIZE;
gridPtr->startX = 0;
gridPtr->startY = 0;
gridPtr->anchor = GRID_DEFAULT_ANCHOR;
memset(gridPtr->columnPtr, 0, size);
memset(gridPtr->rowPtr, 0, size);
}
}
/*
*----------------------------------------------------------------------
*
* Unlink --
*
* Remove a grid from its master's list of slaves.
*
* Results:
* None.
*
* Side effects:
* The master will be scheduled for re-arranging, and the size of the
* grid will be adjusted accordingly
*
*----------------------------------------------------------------------
*/
static void
Unlink(
register Gridder *slavePtr) /* Window to unlink. */
{
register Gridder *masterPtr, *slavePtr2;
masterPtr = slavePtr->masterPtr;
if (masterPtr == NULL) {
return;
}
if (masterPtr->slavePtr == slavePtr) {
masterPtr->slavePtr = slavePtr->nextPtr;
} else {
for (slavePtr2=masterPtr->slavePtr ; ; slavePtr2=slavePtr2->nextPtr) {
if (slavePtr2 == NULL) {
Tcl_Panic("Unlink couldn't find previous window");
}
if (slavePtr2->nextPtr == slavePtr) {
slavePtr2->nextPtr = slavePtr->nextPtr;
break;
}
}
}
if (!(masterPtr->flags & REQUESTED_RELAYOUT)) {
masterPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, masterPtr);
}
if (masterPtr->abortPtr != NULL) {
*masterPtr->abortPtr = 1;
}
SetGridSize(slavePtr->masterPtr);
slavePtr->masterPtr = NULL;
/*
* If we have emptied this master from slaves it means we are no longer
* handling it and should mark it as free.
*/
if ((masterPtr->slavePtr == NULL) && (masterPtr->flags & ALLOCED_MASTER)) {
TkFreeGeometryMaster(masterPtr->tkwin, "grid");
masterPtr->flags &= ~ALLOCED_MASTER;
}
}
/*
*----------------------------------------------------------------------
*
* DestroyGrid --
*
* This procedure is invoked by Tcl_EventuallyFree or Tcl_Release to
* clean up the internal structure of a grid at a safe time (when no-one
* is using it anymore). Cleaning up the grid involves freeing the main
* structure for all windows and the master structure for geometry
* managers.
*
* Results:
* None.
*
* Side effects:
* Everything associated with the grid is freed up.
*
*----------------------------------------------------------------------
*/
static void
DestroyGrid(
void *memPtr) /* Info about window that is now dead. */
{
register Gridder *gridPtr = memPtr;
if (gridPtr->masterDataPtr != NULL) {
if (gridPtr->masterDataPtr->rowPtr != NULL) {
ckfree(gridPtr->masterDataPtr -> rowPtr);
}
if (gridPtr->masterDataPtr->columnPtr != NULL) {
ckfree(gridPtr->masterDataPtr -> columnPtr);
}
ckfree(gridPtr->masterDataPtr);
}
if (gridPtr->in != NULL) {
Tcl_DecrRefCount(gridPtr->in);
}
ckfree(gridPtr);
}
/*
*----------------------------------------------------------------------
*
* GridStructureProc --
*
* This procedure is invoked by the Tk event dispatcher in response to
* StructureNotify events.
*
* Results:
* None.
*
* Side effects:
* If a window was just deleted, clean up all its grid-related
* information. If it was just resized, re-configure its slaves, if any.
*
*----------------------------------------------------------------------
*/
static void
GridStructureProc(
ClientData clientData, /* Our information about window referred to by
* eventPtr. */
XEvent *eventPtr) /* Describes what just happened. */
{
register Gridder *gridPtr = clientData;
TkDisplay *dispPtr = ((TkWindow *) gridPtr->tkwin)->dispPtr;
if (eventPtr->type == ConfigureNotify) {
if ((gridPtr->slavePtr != NULL)
&& !(gridPtr->flags & REQUESTED_RELAYOUT)) {
gridPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, gridPtr);
}
if ((gridPtr->masterPtr != NULL) &&
(gridPtr->doubleBw != 2*Tk_Changes(gridPtr->tkwin)->border_width)) {
if (!(gridPtr->masterPtr->flags & REQUESTED_RELAYOUT)) {
gridPtr->doubleBw = 2*Tk_Changes(gridPtr->tkwin)->border_width;
gridPtr->masterPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, gridPtr->masterPtr);
}
}
} else if (eventPtr->type == DestroyNotify) {
register Gridder *gridPtr2, *nextPtr;
if (gridPtr->masterPtr != NULL) {
Unlink(gridPtr);
}
for (gridPtr2 = gridPtr->slavePtr; gridPtr2 != NULL;
gridPtr2 = nextPtr) {
Tk_UnmapWindow(gridPtr2->tkwin);
gridPtr2->masterPtr = NULL;
nextPtr = gridPtr2->nextPtr;
gridPtr2->nextPtr = NULL;
}
Tcl_DeleteHashEntry(Tcl_FindHashEntry(&dispPtr->gridHashTable,
(char *) gridPtr->tkwin));
if (gridPtr->flags & REQUESTED_RELAYOUT) {
Tcl_CancelIdleCall(ArrangeGrid, gridPtr);
}
gridPtr->tkwin = NULL;
Tcl_EventuallyFree(gridPtr, (Tcl_FreeProc *)DestroyGrid);
} else if (eventPtr->type == MapNotify) {
if ((gridPtr->slavePtr != NULL)
&& !(gridPtr->flags & REQUESTED_RELAYOUT)) {
gridPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, gridPtr);
}
} else if (eventPtr->type == UnmapNotify) {
register Gridder *gridPtr2;
for (gridPtr2 = gridPtr->slavePtr; gridPtr2 != NULL;
gridPtr2 = gridPtr2->nextPtr) {
Tk_UnmapWindow(gridPtr2->tkwin);
}
}
}
/*
*----------------------------------------------------------------------
*
* ConfigureSlaves --
*
* This implements the guts of the "grid configure" command. Given a list
* of slaves and configuration options, it arranges for the grid to
* manage the slaves and sets the specified options. Arguments consist
* of windows or window shortcuts followed by "-option value" pairs.
*
* Results:
* TCL_OK is returned if all went well. Otherwise, TCL_ERROR is returned
* and the interp's result is set to contain an error message.
*
* Side effects:
* Slave windows get taken over by the grid.
*
*----------------------------------------------------------------------
*/
static int
ConfigureSlaves(
Tcl_Interp *interp, /* Interpreter for error reporting. */
Tk_Window tkwin, /* Any window in application containing
* slaves. Used to look up slave names. */
int objc, /* Number of elements in argv. */
Tcl_Obj *const objv[]) /* Argument objects: contains one or more
* window names followed by any number of
* "option value" pairs. Caller must make sure
* that there is at least one window name. */
{
Gridder *masterPtr = NULL;
Gridder *slavePtr;
Tk_Window other, slave, parent, ancestor;
int i, j, tmp;
int numWindows;
int width;
int defaultRow = -1;
int defaultColumn = 0; /* Default column number */
int defaultColumnSpan = 1; /* Default number of columns */
const char *lastWindow; /* Use this window to base current row/col
* on */
int numSkip; /* Number of 'x' found */
static const char *const optionStrings[] = {
"-column", "-columnspan", "-in", "-ipadx", "-ipady",
"-padx", "-pady", "-row", "-rowspan", "-sticky", NULL
};
enum options {
CONF_COLUMN, CONF_COLUMNSPAN, CONF_IN, CONF_IPADX, CONF_IPADY,
CONF_PADX, CONF_PADY, CONF_ROW, CONF_ROWSPAN, CONF_STICKY };
int index;
const char *string;
char firstChar;
int positionGiven;
/*
* Count the number of windows, or window short-cuts.
*/
firstChar = 0;
for (numWindows=0, i=0; i < objc; i++) {
int length;
char prevChar = firstChar;
string = Tcl_GetStringFromObj(objv[i], &length);
firstChar = string[0];
if (firstChar == '.') {
/*
* Check that windows are valid, and locate the first slave's
* parent window (default for -in).
*/
if (TkGetWindowFromObj(interp, tkwin, objv[i], &slave) != TCL_OK) {
return TCL_ERROR;
}
if (masterPtr == NULL) {
/*
* Is there any saved -in from a removed slave?
* If there is, it becomes default for -in.
* If the stored master does not exist, just ignore it.
*/
struct Gridder *slavePtr = GetGrid(slave);
if (slavePtr->in != NULL) {
if (TkGetWindowFromObj(interp, slave, slavePtr->in, &parent)
== TCL_OK) {
masterPtr = GetGrid(parent);
InitMasterData(masterPtr);
}
}
}
if (masterPtr == NULL) {
parent = Tk_Parent(slave);
if (parent != NULL) {
masterPtr = GetGrid(parent);
InitMasterData(masterPtr);
}
}
numWindows++;
continue;
}
if (length > 1 && i == 0) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad argument \"%s\": must be name of window", string));
Tcl_SetErrorCode(interp, "TK", "GRID", "BAD_PARAMETER", NULL);
return TCL_ERROR;
}
if (length > 1 && firstChar == '-') {
break;
}
if (length > 1) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"unexpected parameter \"%s\" in configure list:"
" should be window name or option", string));
Tcl_SetErrorCode(interp, "TK", "GRID", "BAD_PARAMETER", NULL);
return TCL_ERROR;
}
if ((firstChar == REL_HORIZ) && ((numWindows == 0) ||
(prevChar == REL_SKIP) || (prevChar == REL_VERT))) {
Tcl_SetObjResult(interp, Tcl_NewStringObj(
"must specify window before shortcut '-'", -1));
Tcl_SetErrorCode(interp, "TK", "GRID", "SHORTCUT_USAGE", NULL);
return TCL_ERROR;
}
if ((firstChar == REL_VERT) || (firstChar == REL_SKIP)
|| (firstChar == REL_HORIZ)) {
continue;
}
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"invalid window shortcut, \"%s\" should be '-', 'x', or '^'",
string));
Tcl_SetErrorCode(interp, "TK", "GRID", "SHORTCUT_USAGE", NULL);
return TCL_ERROR;
}
numWindows = i;
if ((objc - numWindows) & 1) {
Tcl_SetObjResult(interp, Tcl_NewStringObj(
"extra option or option with no value", -1));
Tcl_SetErrorCode(interp, "TK", "GRID", "BAD_PARAMETER", NULL);
return TCL_ERROR;
}
/*
* Go through all options looking for -in and -row, which are needed to be
* found first to handle the special case where ^ is used on a row without
* windows names, but with an -in option. Since all options are checked
* here, we do not need to handle the error case again later.
*/
for (i = numWindows; i < objc; i += 2) {
if (Tcl_GetIndexFromObjStruct(interp, objv[i], optionStrings,
sizeof(char *), "option", 0, &index) != TCL_OK) {
return TCL_ERROR;
}
if (index == CONF_IN) {
if (TkGetWindowFromObj(interp, tkwin, objv[i+1], &other) !=
TCL_OK) {
return TCL_ERROR;
}
masterPtr = GetGrid(other);
InitMasterData(masterPtr);
} else if (index == CONF_ROW) {
if (Tcl_GetIntFromObj(interp, objv[i+1], &tmp) != TCL_OK
|| tmp < 0) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad row value \"%s\": must be a non-negative integer",
Tcl_GetString(objv[i+1])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "POSITIVE_INT", NULL);
return TCL_ERROR;
}
defaultRow = tmp;
}
}
/*
* If no -row is given, use the next row after the highest occupied row
* of the master.
*/
if (defaultRow < 0) {
if (masterPtr != NULL && masterPtr->masterDataPtr != NULL) {
SetGridSize(masterPtr);
defaultRow = masterPtr->masterDataPtr->rowEnd;
} else {
defaultRow = 0;
}
}
/*
* Iterate over all of the slave windows and short-cuts, parsing options
* for each slave. It's a bit wasteful to re-parse the options for each
* slave, but things get too messy if we try to parse the arguments just
* once at the beginning. For example, if a slave already is managed we
* want to just change a few existing values without resetting everything.
* If there are multiple windows, the -in option only gets processed for
* the first window.
*/
positionGiven = 0;
for (j = 0; j < numWindows; j++) {
string = Tcl_GetString(objv[j]);
firstChar = string[0];
/*
* '^' and 'x' cause us to skip a column. '-' is processed as part of
* its preceeding slave.
*/
if ((firstChar == REL_VERT) || (firstChar == REL_SKIP)) {
defaultColumn++;
continue;
}
if (firstChar == REL_HORIZ) {
continue;
}
for (defaultColumnSpan = 1; j + defaultColumnSpan < numWindows;
defaultColumnSpan++) {
const char *string = Tcl_GetString(objv[j + defaultColumnSpan]);
if (*string != REL_HORIZ) {
break;
}
}
if (TkGetWindowFromObj(interp, tkwin, objv[j], &slave) != TCL_OK) {
return TCL_ERROR;
}
if (Tk_TopWinHierarchy(slave)) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"can't manage \"%s\": it's a top-level window",
Tcl_GetString(objv[j])));
Tcl_SetErrorCode(interp, "TK", "GEOMETRY", "TOPLEVEL", NULL);
return TCL_ERROR;
}
slavePtr = GetGrid(slave);
/*
* The following statement is taken from tkPack.c:
*
* "If the slave isn't currently managed, reset all of its
* configuration information to default values (there could be old
* values left from a previous packer)."
*
* I [D.S.] disagree with this statement. If a slave is disabled
* (using "forget") and then re-enabled, I submit that 90% of the time
* the programmer will want it to retain its old configuration
* information. If the programmer doesn't want this behavior, then the
* defaults can be reestablished by hand, without having to worry
* about keeping track of the old state.
*/
for (i = numWindows; i < objc; i += 2) {
Tcl_GetIndexFromObjStruct(interp, objv[i], optionStrings,
sizeof(char *), "option", 0, &index);
switch ((enum options) index) {
case CONF_COLUMN:
if (Tcl_GetIntFromObj(NULL, objv[i+1], &tmp) != TCL_OK
|| tmp < 0) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad column value \"%s\": must be a non-negative integer",
Tcl_GetString(objv[i+1])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "COLUMN", NULL);
return TCL_ERROR;
}
if (SetSlaveColumn(interp, slavePtr, tmp, -1) != TCL_OK) {
return TCL_ERROR;
}
break;
case CONF_COLUMNSPAN:
if (Tcl_GetIntFromObj(NULL, objv[i+1], &tmp) != TCL_OK
|| tmp <= 0) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad columnspan value \"%s\": must be a positive integer",
Tcl_GetString(objv[i+1])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "SPAN", NULL);
return TCL_ERROR;
}
if (SetSlaveColumn(interp, slavePtr, -1, tmp) != TCL_OK) {
return TCL_ERROR;
}
break;
case CONF_IN:
if (TkGetWindowFromObj(interp, tkwin, objv[i+1],
&other) != TCL_OK) {
return TCL_ERROR;
}
if (other == slave) {
Tcl_SetObjResult(interp, Tcl_NewStringObj(
"window can't be managed in itself", -1));
Tcl_SetErrorCode(interp, "TK", "GEOMETRY", "SELF", NULL);
return TCL_ERROR;
}
positionGiven = 1;
masterPtr = GetGrid(other);
InitMasterData(masterPtr);
break;
case CONF_STICKY: {
int sticky = StringToSticky(Tcl_GetString(objv[i+1]));
if (sticky == -1) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad stickyness value \"%s\": must be"
" a string containing n, e, s, and/or w",
Tcl_GetString(objv[i+1])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "STICKY", NULL);
return TCL_ERROR;
}
slavePtr->sticky = sticky;
break;
}
case CONF_IPADX:
if ((Tk_GetPixelsFromObj(NULL, slave, objv[i+1],
&tmp) != TCL_OK) || (tmp < 0)) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad ipadx value \"%s\": must be positive screen distance",
Tcl_GetString(objv[i+1])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "INT_PAD", NULL);
return TCL_ERROR;
}
slavePtr->iPadX = tmp * 2;
break;
case CONF_IPADY:
if ((Tk_GetPixelsFromObj(NULL, slave, objv[i+1],
&tmp) != TCL_OK) || (tmp < 0)) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad ipady value \"%s\": must be positive screen distance",
Tcl_GetString(objv[i+1])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "INT_PAD", NULL);
return TCL_ERROR;
}
slavePtr->iPadY = tmp * 2;
break;
case CONF_PADX:
if (TkParsePadAmount(interp, tkwin, objv[i+1],
&slavePtr->padLeft, &slavePtr->padX) != TCL_OK) {
return TCL_ERROR;
}
break;
case CONF_PADY:
if (TkParsePadAmount(interp, tkwin, objv[i+1],
&slavePtr->padTop, &slavePtr->padY) != TCL_OK) {
return TCL_ERROR;
}
break;
case CONF_ROW:
if (Tcl_GetIntFromObj(NULL, objv[i+1], &tmp) != TCL_OK
|| tmp < 0) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad row value \"%s\": must be a non-negative integer",
Tcl_GetString(objv[i+1])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "COLUMN", NULL);
return TCL_ERROR;
}
if (SetSlaveRow(interp, slavePtr, tmp, -1) != TCL_OK) {
return TCL_ERROR;
}
break;
case CONF_ROWSPAN:
if ((Tcl_GetIntFromObj(NULL, objv[i+1], &tmp) != TCL_OK)
|| tmp <= 0) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"bad rowspan value \"%s\": must be a positive integer",
Tcl_GetString(objv[i+1])));
Tcl_SetErrorCode(interp, "TK", "VALUE", "SPAN", NULL);
return TCL_ERROR;
}
if (SetSlaveRow(interp, slavePtr, -1, tmp) != TCL_OK) {
return TCL_ERROR;
}
break;
}
}
/*
* If no position was specified via -in and the slave is already
* packed, then leave it in its current location.
*/
if (!positionGiven && (slavePtr->masterPtr != NULL)) {
masterPtr = slavePtr->masterPtr;
goto scheduleLayout;
}
/*
* If the same -in window is passed in again, then just leave it in
* its current location.
*/
if (positionGiven && (masterPtr == slavePtr->masterPtr)) {
goto scheduleLayout;
}
/*
* Make sure we have a geometry master. We look at:
* 1) the -in flag
* 2) the parent of the first slave.
*/
parent = Tk_Parent(slave);
if (masterPtr == NULL) {
masterPtr = GetGrid(parent);
InitMasterData(masterPtr);
}
if (slavePtr->masterPtr != NULL && slavePtr->masterPtr != masterPtr) {
if (slavePtr->masterPtr->tkwin != Tk_Parent(slavePtr->tkwin)) {
Tk_UnmaintainGeometry(slavePtr->tkwin, slavePtr->masterPtr->tkwin);
}
Unlink(slavePtr);
slavePtr->masterPtr = NULL;
}
if (slavePtr->masterPtr == NULL) {
Gridder *tempPtr = masterPtr->slavePtr;
slavePtr->masterPtr = masterPtr;
masterPtr->slavePtr = slavePtr;
slavePtr->nextPtr = tempPtr;
}
/*
* Make sure that the slave's parent is either the master or an
* ancestor of the master, and that the master and slave aren't the
* same.
*/
for (ancestor = masterPtr->tkwin; ; ancestor = Tk_Parent(ancestor)) {
if (ancestor == parent) {
break;
}
if (Tk_TopWinHierarchy(ancestor)) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"can't put %s inside %s", Tcl_GetString(objv[j]),
Tk_PathName(masterPtr->tkwin)));
Tcl_SetErrorCode(interp, "TK", "GEOMETRY", "HIERARCHY", NULL);
Unlink(slavePtr);
return TCL_ERROR;
}
}
/*
* Try to make sure our master isn't managed by us.
*/
if (masterPtr->masterPtr == slavePtr) {
Tcl_SetObjResult(interp, Tcl_ObjPrintf(
"can't put %s inside %s, would cause management loop",
Tcl_GetString(objv[j]), Tk_PathName(masterPtr->tkwin)));
Tcl_SetErrorCode(interp, "TK", "GEOMETRY", "LOOP", NULL);
Unlink(slavePtr);
return TCL_ERROR;
}
Tk_ManageGeometry(slave, &gridMgrType, slavePtr);
if (!(masterPtr->flags & DONT_PROPAGATE)) {
if (TkSetGeometryMaster(interp, masterPtr->tkwin, "grid")
!= TCL_OK) {
Tk_ManageGeometry(slave, NULL, NULL);
Unlink(slavePtr);
return TCL_ERROR;
}
masterPtr->flags |= ALLOCED_MASTER;
}
/*
* Assign default position information.
*/
if (slavePtr->column == -1) {
if (SetSlaveColumn(interp, slavePtr, defaultColumn,-1) != TCL_OK){
return TCL_ERROR;
}
}
if (SetSlaveColumn(interp, slavePtr, -1,
slavePtr->numCols + defaultColumnSpan - 1) != TCL_OK) {
return TCL_ERROR;
}
if (slavePtr->row == -1) {
if (SetSlaveRow(interp, slavePtr, defaultRow, -1) != TCL_OK) {
return TCL_ERROR;
}
}
defaultColumn += slavePtr->numCols;
defaultColumnSpan = 1;
/*
* Arrange for the master to be re-arranged at the first idle moment.
*/
scheduleLayout:
if (masterPtr->abortPtr != NULL) {
*masterPtr->abortPtr = 1;
}
if (!(masterPtr->flags & REQUESTED_RELAYOUT)) {
masterPtr->flags |= REQUESTED_RELAYOUT;
Tcl_DoWhenIdle(ArrangeGrid, masterPtr);
}
}
/*
* Now look for all the "^"'s.
*/
lastWindow = NULL;
numSkip = 0;
for (j = 0; j < numWindows; j++) {
struct Gridder *otherPtr;
int match; /* Found a match for the ^ */
int lastRow, lastColumn; /* Implied end of table. */
string = Tcl_GetString(objv[j]);
firstChar = string[0];
if (firstChar == '.') {
lastWindow = string;
numSkip = 0;
}
if (firstChar == REL_SKIP) {
numSkip++;
}
if (firstChar != REL_VERT) {
continue;
}
if (masterPtr == NULL) {
Tcl_SetObjResult(interp, Tcl_NewStringObj(
"can't use '^', cant find master", -1));
Tcl_SetErrorCode(interp, "TK", "GRID", "SHORTCUT_USAGE", NULL);
return TCL_ERROR;
}
/*
* Count the number of consecutive ^'s starting from this position.
*/
for (width = 1; width + j < numWindows; width++) {
const char *string = Tcl_GetString(objv[j+width]);
if (*string != REL_VERT) {
break;
}
}
/*
* Find the implied grid location of the ^
*/
if (lastWindow == NULL) {
lastRow = defaultRow - 1;
lastColumn = 0;
} else {
other = Tk_NameToWindow(interp, lastWindow, tkwin);
otherPtr = GetGrid(other);
lastRow = otherPtr->row + otherPtr->numRows - 2;
lastColumn = otherPtr->column + otherPtr->numCols;
}
lastColumn += numSkip;
match = 0;
for (slavePtr = masterPtr->slavePtr; slavePtr != NULL;
slavePtr = slavePtr->nextPtr) {
if (slavePtr->column == lastColumn
&& slavePtr->row + slavePtr->numRows - 1 == lastRow) {
if (slavePtr->numCols <= width) {
if (SetSlaveRow(interp, slavePtr, -1,
slavePtr->numRows + 1) != TCL_OK) {
return TCL_ERROR;
}
match++;
j += slavePtr->numCols - 1;
lastWindow = Tk_PathName(slavePtr->tkwin);
numSkip = 0;
break;
}
}
}
if (!match) {
Tcl_SetObjResult(interp, Tcl_NewStringObj(
"can't find slave to extend with \"^\"", -1));
Tcl_SetErrorCode(interp, "TK", "GRID", "SHORTCUT_USAGE", NULL);
return TCL_ERROR;
}
}
if (masterPtr == NULL) {
Tcl_SetObjResult(interp, Tcl_NewStringObj(
"can't determine master window", -1));
Tcl_SetErrorCode(interp, "TK", "GRID", "SHORTCUT_USAGE", NULL);
return TCL_ERROR;
}
SetGridSize(masterPtr);
/*
* If we have emptied this master from slaves it means we are no longer
* handling it and should mark it as free.
*/
if (masterPtr->slavePtr == NULL && masterPtr->flags & ALLOCED_MASTER) {
TkFreeGeometryMaster(masterPtr->tkwin, "grid");
masterPtr->flags &= ~ALLOCED_MASTER;
}
return TCL_OK;
}
/*
*----------------------------------------------------------------------
*
* StickyToObj
*
* Converts the internal boolean combination of "sticky" bits onto a Tcl
* list element containing zero or more of n, s, e, or w.
*
* Results:
* A new object is returned that holds the sticky representation.
*
* Side effects:
* none.
*
*----------------------------------------------------------------------
*/
static Tcl_Obj *
StickyToObj(
int flags) /* The sticky flags. */
{
int count = 0;
char buffer[4];
if (flags & STICK_NORTH) {
buffer[count++] = 'n';
}
if (flags & STICK_EAST) {
buffer[count++] = 'e';
}
if (flags & STICK_SOUTH) {
buffer[count++] = 's';
}
if (flags & STICK_WEST) {
buffer[count++] = 'w';
}
return Tcl_NewStringObj(buffer, count);
}
/*
*----------------------------------------------------------------------
*
* StringToSticky --
*
* Converts an ascii string representing a widgets stickyness into the
* boolean result.
*
* Results:
* The boolean combination of the "sticky" bits is retuned. If an error
* occurs, such as an invalid character, -1 is returned instead.
*
* Side effects:
* none
*
*----------------------------------------------------------------------
*/
static int
StringToSticky(
const char *string)
{
int sticky = 0;
char c;
while ((c = *string++) != '\0') {
switch (c) {
case 'n': case 'N':
sticky |= STICK_NORTH;
break;
case 'e': case 'E':
sticky |= STICK_EAST;
break;
case 's': case 'S':
sticky |= STICK_SOUTH;
break;
case 'w': case 'W':
sticky |= STICK_WEST;
break;
case ' ': case ',': case '\t': case '\r': case '\n':
break;
default:
return -1;
}
}
return sticky;
}
/*
*----------------------------------------------------------------------
*
* NewPairObj --
*
* Creates a new list object and fills it with two integer objects.
*
* Results:
* The newly created list object is returned.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
static Tcl_Obj *
NewPairObj(
int val1, int val2)
{
Tcl_Obj *ary[2];
ary[0] = Tcl_NewIntObj(val1);
ary[1] = Tcl_NewIntObj(val2);
return Tcl_NewListObj(2, ary);
}
/*
*----------------------------------------------------------------------
*
* NewQuadObj --
*
* Creates a new list object and fills it with four integer objects.
*
* Results:
* The newly created list object is returned.
*
* Side effects:
* None.
*
*----------------------------------------------------------------------
*/
static Tcl_Obj *
NewQuadObj(
int val1, int val2, int val3, int val4)
{
Tcl_Obj *ary[4];
ary[0] = Tcl_NewIntObj(val1);
ary[1] = Tcl_NewIntObj(val2);
ary[2] = Tcl_NewIntObj(val3);
ary[3] = Tcl_NewIntObj(val4);
return Tcl_NewListObj(4, ary);
}
/*
* Local Variables:
* mode: c
* c-basic-offset: 4
* fill-column: 78
* End:
*/
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