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gtk2/gtk/gtkcurve.c
Tim Janik 9595c55184 documented necessary changes for 1.4 transition. 
Fri May 12 17:13:32 2000  Tim Janik  <timj@gtk.org>

	* docs/Changes-1.4.txt: documented necessary changes for 1.4 transition.

	* gtk/gtktext.c: made the adjustments no-construct args, simply
	provide default adjustments.
	(gtk_text_destroy): release adjustments.

	* gtk/gtkprogressbar.c (gtk_progress_bar_class_init): made the
	adjustment argument non-construct.

	* gtk/gtkprogress.c (gtk_progress_destroy): release adjustment here,
	instead of in finalize.
	(gtk_progress_get_text_from_value):
	(gtk_progress_get_current_text):
	(gtk_progress_set_value):
	(gtk_progress_get_percentage_from_value):
	(gtk_progress_get_current_percentage):
	(gtk_progress_set_percentage):
	(gtk_progress_configure): ensure an adjustment is present.

Thu May 11 01:24:08 2000  Tim Janik  <timj@gtk.org>

	* gtk/gtkcolorsel.[hc]:
	* gtk/gtkcolorseldialog.[hc]:
	* gtk/gtkhsv.[hc]: major code cleanups, destroy handlers need to chain
	their parent implementation, use bit fields for boolean values, don't
	create unused widgets, usage of glib types, braces go on their own
	lines, function argument alignment, #include directives etc. etc. etc..

	* gtk/Makefile.am (gtk_public_h_sources): install gtkhsv.h.

Wed May 10 23:29:52 2000  Tim Janik  <timj@gtk.org>

	* gtk/gtktoolbar.c (gtk_toolbar_destroy): don't unref a NULL tooltips.

	* gtk/gtkfilesel.c (gtk_file_selection_destroy): don't free a cmpl_state
	of NULL.

	* gtk/gtkcombo.c (gtk_combo_item_destroy): don#t keep references
	to freed data.
	(gtk_combo_destroy): don't keep a pointer to a destroyed window.

	* gtk/gtkmenu.c (gtk_menu_init): reset the menu's toplevel pointer
	to NULL when the toplevel is getting destroyed.
	(gtk_menu_set_tearoff_state): same here for the tearoff_window.
	(gtk_menu_destroy):
	(gtk_menu_init): store the information of whether we have to
	readd the initial child ref_count during destruction in a new
	GtkMenu field needs_destruction_ref_count.

	* gtk/gtkviewport.c: SHAME! ok this one is tricky, so i note it
	here, those reading: learn from my mistake! ;)
	in order for set_?adjustment to support a default adjustemnt if
	invoked with an adjustment pointer of NULL, the code read (pseudo):
	if (v->adjustment) unref (v->adjustment);
	if (!adjustment) adjustment = adjustment_new ();
	if (v->adjustment != adjustment) v->adjustment = ref (adjustment);
	now imagine the first unref to actually free the old adjustment and
	adjustment_new() creating a new adjustment from the very same memory
	portion. here, the latter comparision will unintendedly fail, and
	all hell breaks loose.
	(gtk_viewport_set_hadjustment):
	(gtk_viewport_set_vadjustment): reset viewport->?adjustment to NULL
	after unreferencing it.

	* gtk/gtkcontainer.[hc]: removed toplevel registration
	functions: gtk_container_register_toplevel(),
	gtk_container_unregister_toplevel() and
	gtk_container_get_toplevels() which had wrong semantics
	anyways: it didn't reference and copy the list.

	* gtk/gtkwindow.c: we take over the container toplevel registration
	bussiness now. windows are registered across multiple destructions,
	untill they are finalized. the initial implicit reference count
	users are holding on windows is removed with the first destruction
	though.
	(gtk_window_init): ref & sink and set has_user_ref_count, got
	rid of gtk_container_register_toplevel() call. add window to
	toplevel_list.
	(gtk_window_destroy): unref the window if has_user_ref_count
	is still set, got rid of call to
	gtk_container_unregister_toplevel().
	(gtk_window_finalize): remove window from toplevel list.
	(gtk_window_list_toplevels): new function to return a newly
	created list with referenced toplevels.
	(gtk_window_read_rcfiles): use gtk_window_list_toplevels().

	* gtk/gtkhscale.c (gtk_hscale_class_init): made the GtkRange
	adjustment a non-construct arg.
	* gtk/gtkvscale.c (gtk_vscale_class_init): likewise.
	* gtk/gtkhscrollbar.c (gtk_vscrollbar_class_init): likewise.
	* gtk/gtkvscrollbar.c (gtk_vscrollbar_class_init): likewise.

	* gtk/gtkrange.c: added some realized checks.
	(gtk_range_destroy): get rid of the h/v adjustments in the
	destroy handler instead of finalize. remove timer.
	(gtk_range_get_adjustment): demand create adjustment.

	* gtk/gtkviewport.c: made h/v adjustment non-construct args.
	we simply create them on demand now and get rid of them in
	the destroy handler.
	(gtk_viewport_destroy): get rid of the h/v adjustments in the
	destroy handler instead of finalize.
	(gtk_viewport_get_hadjustment):
	(gtk_viewport_get_vadjustment):
	(gtk_viewport_size_allocate): demand create h/v adjustment
	if required.

	* gtk/gtkwidget.c (gtk_widget_finalize): duplicate part of the
	gtk_widget_real_destroy () functionality.
	(gtk_widget_real_destroy): reinitialize with a new style, instead
	of setting widget->style to NULL.

Fri May  5 13:02:09 2000  Tim Janik  <timj@gtk.org>

	* gtk/gtkcalendar.c:
	* gtk/gtkbutton.c: ported _get_type() implementation over to
	GType, either to preserve memchunks allocation facilities,
	or because Gtk+ 1.0 GtkTypeInfo was still being used.

	* gtk/gtkobject.[hc]: derive from GObject. ported various functions
	over. prepare for ::destroy to be emitted multiple times.
	removed reference tracer magic. chain into GObjectClass.shutdown()
	to emit ::destroy signal.

	* gtk/gtksignal.c: removed assumptions about GTK_TYPE_OBJECT being
	fundamental.

	* gtk/gtkmain.c: removed gtk_object_post_arg_parsing_init()
	cludge.

	* gtk/gtksocket.c:
	* gtk/gtkplug.c:
	* gtk/gtklayout.c:
	* gtk/gtklabel.c:
	* gtk/gtkargcollector.c:
	* gtk/gtkarg.c: various fixups to work with GTK_TYPE_OBJECT
	not being a fundamental anymore, and to work with the new
	type system (nuked fundamental type varargs clutter).

	* gtk/*.c: install finalize handlers in the GObjectClass
	part of the class structure.
	changed direct GTK_OBJECT()->klass accesses to
	GTK_*_GET_CLASS().
	changed direct object_class->type accesses to GTK_CLASS_TYPE().

	* gtktypeutils.[hc]: use the reserved fundamental ids provided by
	GType. made most of the GTK_*() type macros and Gtk* typedefs
	simple wrappers around macros and types provided by GType.
	most notably, a significant portion of the old API vanished:
	GTK_TYPE_MAKE(),
	GTK_TYPE_SEQNO(),
	GTK_TYPE_FLAT_FIRST, GTK_TYPE_FLAT_LAST,
	GTK_TYPE_STRUCTURED_FIRST, GTK_TYPE_STRUCTURED_LAST,
	GTK_TYPE_ARGS,
	GTK_TYPE_CALLBACK,
	GTK_TYPE_C_CALLBACK,
	GTK_TYPE_FOREIGN,
	GtkTypeQuery,
	gtk_type_query(),
	gtk_type_set_varargs_type(),
	gtk_type_get_varargs_type(),
	gtk_type_check_object_cast(),
	gtk_type_check_class_cast(),
	gtk_type_describe_tree(),
	gtk_type_describe_heritage(),
	gtk_type_free(),
	gtk_type_children_types(),
	gtk_type_set_chunk_alloc(),
	gtk_type_register_enum(),
	gtk_type_register_flags(),
	gtk_type_parent_class().
	replacements, where available are described in ../docs/Changes-1.4.txt.
	implemented compatibility functions for the remaining API.

	* configure.in: depend on glib 1.3.1, use gobject module.
2000-05-12 15:25:50 +00:00

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/* GTK - The GIMP Toolkit
* Copyright (C) 1997 David Mosberger
*
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Library General Public
* License as published by the Free Software Foundation; either
* version 2 of the License, or (at your option) any later version.
*
* This library is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* Library General Public License for more details.
*
* You should have received a copy of the GNU Library General Public
* License along with this library; if not, write to the
* Free Software Foundation, Inc., 59 Temple Place - Suite 330,
* Boston, MA 02111-1307, USA.
*/
/*
* Modified by the GTK+ Team and others 1997-1999. See the AUTHORS
* file for a list of people on the GTK+ Team. See the ChangeLog
* files for a list of changes. These files are distributed with
* GTK+ at ftp://ftp.gtk.org/pub/gtk/.
*/
#include <stdlib.h>
#include <string.h>
#include <math.h>
#include "gtkcurve.h"
#include "gtkdrawingarea.h"
#include "gtkmain.h"
#include "gtkradiobutton.h"
#include "gtksignal.h"
#include "gtktable.h"
#define RADIUS 3 /* radius of the control points */
#define MIN_DISTANCE 8 /* min distance between control points */
#define GRAPH_MASK (GDK_EXPOSURE_MASK | \
GDK_POINTER_MOTION_MASK | \
GDK_POINTER_MOTION_HINT_MASK | \
GDK_ENTER_NOTIFY_MASK | \
GDK_BUTTON_PRESS_MASK | \
GDK_BUTTON_RELEASE_MASK | \
GDK_BUTTON1_MOTION_MASK)
enum {
ARG_0,
ARG_CURVE_TYPE,
ARG_MIN_X,
ARG_MAX_X,
ARG_MIN_Y,
ARG_MAX_Y
};
static GtkDrawingAreaClass *parent_class = NULL;
static guint curve_type_changed_signal = 0;
/* forward declarations: */
static void gtk_curve_class_init (GtkCurveClass *class);
static void gtk_curve_init (GtkCurve *curve);
static void gtk_curve_set_arg (GtkObject *object,
GtkArg *arg,
guint arg_id);
static void gtk_curve_get_arg (GtkObject *object,
GtkArg *arg,
guint arg_id);
static void gtk_curve_finalize (GObject *object);
static gint gtk_curve_graph_events (GtkWidget *widget,
GdkEvent *event,
GtkCurve *c);
static void gtk_curve_size_graph (GtkCurve *curve);
GtkType
gtk_curve_get_type (void)
{
static GtkType curve_type = 0;
if (!curve_type)
{
static const GtkTypeInfo curve_info =
{
"GtkCurve",
sizeof (GtkCurve),
sizeof (GtkCurveClass),
(GtkClassInitFunc) gtk_curve_class_init,
(GtkObjectInitFunc) gtk_curve_init,
/* reserved_1 */ NULL,
/* reserved_2 */ NULL,
(GtkClassInitFunc) NULL,
};
curve_type = gtk_type_unique (GTK_TYPE_DRAWING_AREA, &curve_info);
}
return curve_type;
}
static void
gtk_curve_class_init (GtkCurveClass *class)
{
GObjectClass *gobject_class = G_OBJECT_CLASS (class);
GtkObjectClass *object_class = GTK_OBJECT_CLASS (class);
parent_class = gtk_type_class (GTK_TYPE_DRAWING_AREA);
gobject_class->finalize = gtk_curve_finalize;
object_class->set_arg = gtk_curve_set_arg;
object_class->get_arg = gtk_curve_get_arg;
curve_type_changed_signal =
gtk_signal_new ("curve_type_changed", GTK_RUN_FIRST, GTK_CLASS_TYPE (object_class),
GTK_SIGNAL_OFFSET (GtkCurveClass, curve_type_changed),
gtk_marshal_NONE__NONE, GTK_TYPE_NONE, 0);
gtk_object_class_add_signals (object_class, &curve_type_changed_signal, 1);
gtk_object_add_arg_type ("GtkCurve::curve_type", GTK_TYPE_CURVE_TYPE,
GTK_ARG_READWRITE, ARG_CURVE_TYPE);
gtk_object_add_arg_type ("GtkCurve::min_x", GTK_TYPE_FLOAT,
GTK_ARG_READWRITE, ARG_MIN_X);
gtk_object_add_arg_type ("GtkCurve::max_x", GTK_TYPE_FLOAT,
GTK_ARG_READWRITE, ARG_MAX_X);
gtk_object_add_arg_type ("GtkCurve::min_y", GTK_TYPE_FLOAT,
GTK_ARG_READWRITE, ARG_MIN_Y);
gtk_object_add_arg_type ("GtkCurve::max_y", GTK_TYPE_FLOAT,
GTK_ARG_READWRITE, ARG_MAX_Y);
}
static void
gtk_curve_init (GtkCurve *curve)
{
gint old_mask;
curve->cursor_type = GDK_TOP_LEFT_ARROW;
curve->pixmap = NULL;
curve->curve_type = GTK_CURVE_TYPE_SPLINE;
curve->height = 0;
curve->grab_point = -1;
curve->num_points = 0;
curve->point = 0;
curve->num_ctlpoints = 0;
curve->ctlpoint = NULL;
curve->min_x = 0.0;
curve->max_x = 1.0;
curve->min_y = 0.0;
curve->max_y = 1.0;
old_mask = gtk_widget_get_events (GTK_WIDGET (curve));
gtk_widget_set_events (GTK_WIDGET (curve), old_mask | GRAPH_MASK);
gtk_signal_connect (GTK_OBJECT (curve), "event",
(GtkSignalFunc) gtk_curve_graph_events, curve);
gtk_curve_size_graph (curve);
}
static void
gtk_curve_set_arg (GtkObject *object,
GtkArg *arg,
guint arg_id)
{
GtkCurve *curve = GTK_CURVE (object);
switch (arg_id)
{
case ARG_CURVE_TYPE:
gtk_curve_set_curve_type (curve, GTK_VALUE_ENUM (*arg));
break;
case ARG_MIN_X:
gtk_curve_set_range (curve, GTK_VALUE_FLOAT (*arg), curve->max_x,
curve->min_y, curve->max_y);
break;
case ARG_MAX_X:
gtk_curve_set_range (curve, curve->min_x, GTK_VALUE_FLOAT (*arg),
curve->min_y, curve->max_y);
break;
case ARG_MIN_Y:
gtk_curve_set_range (curve, curve->min_x, curve->max_x,
GTK_VALUE_FLOAT (*arg), curve->max_y);
break;
case ARG_MAX_Y:
gtk_curve_set_range (curve, curve->min_x, curve->max_x,
curve->min_y, GTK_VALUE_FLOAT (*arg));
break;
}
}
static void
gtk_curve_get_arg (GtkObject *object,
GtkArg *arg,
guint arg_id)
{
GtkCurve *curve = GTK_CURVE (object);
switch (arg_id)
{
case ARG_CURVE_TYPE:
GTK_VALUE_ENUM (*arg) = curve->curve_type;
break;
case ARG_MIN_X:
GTK_VALUE_FLOAT (*arg) = curve->min_x;
break;
case ARG_MAX_X:
GTK_VALUE_FLOAT (*arg) = curve->max_x;
break;
case ARG_MIN_Y:
GTK_VALUE_FLOAT (*arg) = curve->min_y;
break;
case ARG_MAX_Y:
GTK_VALUE_FLOAT (*arg) = curve->max_y;
break;
default:
arg->type = GTK_TYPE_INVALID;
break;
}
}
static int
project (gfloat value, gfloat min, gfloat max, int norm)
{
return (norm - 1) * ((value - min) / (max - min)) + 0.5;
}
static gfloat
unproject (gint value, gfloat min, gfloat max, int norm)
{
return value / (gfloat) (norm - 1) * (max - min) + min;
}
/* Solve the tridiagonal equation system that determines the second
derivatives for the interpolation points. (Based on Numerical
Recipies 2nd Edition.) */
static void
spline_solve (int n, gfloat x[], gfloat y[], gfloat y2[])
{
gfloat p, sig, *u;
gint i, k;
u = g_malloc ((n - 1) * sizeof (u[0]));
y2[0] = u[0] = 0.0; /* set lower boundary condition to "natural" */
for (i = 1; i < n - 1; ++i)
{
sig = (x[i] - x[i - 1]) / (x[i + 1] - x[i - 1]);
p = sig * y2[i - 1] + 2.0;
y2[i] = (sig - 1.0) / p;
u[i] = ((y[i + 1] - y[i])
/ (x[i + 1] - x[i]) - (y[i] - y[i - 1]) / (x[i] - x[i - 1]));
u[i] = (6.0 * u[i] / (x[i + 1] - x[i - 1]) - sig * u[i - 1]) / p;
}
y2[n - 1] = 0.0;
for (k = n - 2; k >= 0; --k)
y2[k] = y2[k] * y2[k + 1] + u[k];
g_free (u);
}
static gfloat
spline_eval (int n, gfloat x[], gfloat y[], gfloat y2[], gfloat val)
{
gint k_lo, k_hi, k;
gfloat h, b, a;
/* do a binary search for the right interval: */
k_lo = 0; k_hi = n - 1;
while (k_hi - k_lo > 1)
{
k = (k_hi + k_lo) / 2;
if (x[k] > val)
k_hi = k;
else
k_lo = k;
}
h = x[k_hi] - x[k_lo];
g_assert (h > 0.0);
a = (x[k_hi] - val) / h;
b = (val - x[k_lo]) / h;
return a*y[k_lo] + b*y[k_hi] +
((a*a*a - a)*y2[k_lo] + (b*b*b - b)*y2[k_hi]) * (h*h)/6.0;
}
static void
gtk_curve_interpolate (GtkCurve *c, gint width, gint height)
{
gfloat *vector;
int i;
vector = g_malloc (width * sizeof (vector[0]));
gtk_curve_get_vector (c, width, vector);
c->height = height;
if (c->num_points != width)
{
c->num_points = width;
if (c->point)
g_free (c->point);
c->point = g_malloc (c->num_points * sizeof (c->point[0]));
}
for (i = 0; i < width; ++i)
{
c->point[i].x = RADIUS + i;
c->point[i].y = RADIUS + height
- project (vector[i], c->min_y, c->max_y, height);
}
g_free (vector);
}
static void
gtk_curve_draw (GtkCurve *c, gint width, gint height)
{
GtkStateType state;
GtkStyle *style;
gint i;
if (!c->pixmap)
return;
if (c->height != height || c->num_points != width)
gtk_curve_interpolate (c, width, height);
state = GTK_STATE_NORMAL;
if (!GTK_WIDGET_IS_SENSITIVE (GTK_WIDGET (c)))
state = GTK_STATE_INSENSITIVE;
style = GTK_WIDGET (c)->style;
/* clear the pixmap: */
gtk_paint_flat_box (style, c->pixmap, GTK_STATE_NORMAL, GTK_SHADOW_NONE,
NULL, GTK_WIDGET(c), "curve_bg",
0, 0, width + RADIUS * 2, height + RADIUS * 2);
/* draw the grid lines: (XXX make more meaningful) */
for (i = 0; i < 5; i++)
{
gdk_draw_line (c->pixmap, style->dark_gc[state],
RADIUS, i * (height / 4.0) + RADIUS,
width + RADIUS, i * (height / 4.0) + RADIUS);
gdk_draw_line (c->pixmap, style->dark_gc[state],
i * (width / 4.0) + RADIUS, RADIUS,
i * (width / 4.0) + RADIUS, height + RADIUS);
}
gdk_draw_points (c->pixmap, style->fg_gc[state], c->point, c->num_points);
if (c->curve_type != GTK_CURVE_TYPE_FREE)
for (i = 0; i < c->num_ctlpoints; ++i)
{
gint x, y;
if (c->ctlpoint[i][0] < c->min_x)
continue;
x = project (c->ctlpoint[i][0], c->min_x, c->max_x,
width);
y = height -
project (c->ctlpoint[i][1], c->min_y, c->max_y,
height);
/* draw a bullet: */
gdk_draw_arc (c->pixmap, style->fg_gc[state], TRUE, x, y,
RADIUS * 2, RADIUS*2, 0, 360*64);
}
gdk_draw_pixmap (GTK_WIDGET (c)->window, style->fg_gc[state], c->pixmap,
0, 0, 0, 0, width + RADIUS * 2, height + RADIUS * 2);
}
static gint
gtk_curve_graph_events (GtkWidget *widget, GdkEvent *event, GtkCurve *c)
{
GdkCursorType new_type = c->cursor_type;
gint i, src, dst, leftbound, rightbound;
GdkEventButton *bevent;
GdkEventMotion *mevent;
GtkWidget *w;
gint tx, ty;
gint cx, x, y, width, height;
gint closest_point = 0;
gfloat rx, ry, min_x;
guint distance;
gint x1, x2, y1, y2;
w = GTK_WIDGET (c);
width = w->allocation.width - RADIUS * 2;
height = w->allocation.height - RADIUS * 2;
if ((width < 0) || (height < 0))
return FALSE;
/* get the pointer position */
gdk_window_get_pointer (w->window, &tx, &ty, NULL);
x = CLAMP ((tx - RADIUS), 0, width-1);
y = CLAMP ((ty - RADIUS), 0, height-1);
min_x = c->min_x;
distance = ~0U;
for (i = 0; i < c->num_ctlpoints; ++i)
{
cx = project (c->ctlpoint[i][0], min_x, c->max_x, width);
if ((guint) abs (x - cx) < distance)
{
distance = abs (x - cx);
closest_point = i;
}
}
switch (event->type)
{
case GDK_CONFIGURE:
if (c->pixmap)
gdk_pixmap_unref (c->pixmap);
c->pixmap = 0;
/* fall through */
case GDK_EXPOSE:
if (!c->pixmap)
c->pixmap = gdk_pixmap_new (w->window,
w->allocation.width,
w->allocation.height, -1);
gtk_curve_draw (c, width, height);
break;
case GDK_BUTTON_PRESS:
gtk_grab_add (widget);
bevent = (GdkEventButton *) event;
new_type = GDK_TCROSS;
switch (c->curve_type)
{
case GTK_CURVE_TYPE_LINEAR:
case GTK_CURVE_TYPE_SPLINE:
if (distance > MIN_DISTANCE)
{
/* insert a new control point */
if (c->num_ctlpoints > 0)
{
cx = project (c->ctlpoint[closest_point][0], min_x,
c->max_x, width);
if (x > cx)
++closest_point;
}
++c->num_ctlpoints;
c->ctlpoint =
g_realloc (c->ctlpoint,
c->num_ctlpoints * sizeof (*c->ctlpoint));
for (i = c->num_ctlpoints - 1; i > closest_point; --i)
memcpy (c->ctlpoint + i, c->ctlpoint + i - 1,
sizeof (*c->ctlpoint));
}
c->grab_point = closest_point;
c->ctlpoint[c->grab_point][0] =
unproject (x, min_x, c->max_x, width);
c->ctlpoint[c->grab_point][1] =
unproject (height - y, c->min_y, c->max_y, height);
gtk_curve_interpolate (c, width, height);
break;
case GTK_CURVE_TYPE_FREE:
c->point[x].x = RADIUS + x;
c->point[x].y = RADIUS + y;
c->grab_point = x;
c->last = y;
break;
}
gtk_curve_draw (c, width, height);
break;
case GDK_BUTTON_RELEASE:
gtk_grab_remove (widget);
/* delete inactive points: */
if (c->curve_type != GTK_CURVE_TYPE_FREE)
{
for (src = dst = 0; src < c->num_ctlpoints; ++src)
{
if (c->ctlpoint[src][0] >= min_x)
{
memcpy (c->ctlpoint + dst, c->ctlpoint + src,
sizeof (*c->ctlpoint));
++dst;
}
}
if (dst < src)
{
c->num_ctlpoints -= (src - dst);
if (c->num_ctlpoints <= 0)
{
c->num_ctlpoints = 1;
c->ctlpoint[0][0] = min_x;
c->ctlpoint[0][1] = c->min_y;
gtk_curve_interpolate (c, width, height);
gtk_curve_draw (c, width, height);
}
c->ctlpoint =
g_realloc (c->ctlpoint,
c->num_ctlpoints * sizeof (*c->ctlpoint));
}
}
new_type = GDK_FLEUR;
c->grab_point = -1;
break;
case GDK_MOTION_NOTIFY:
mevent = (GdkEventMotion *) event;
switch (c->curve_type)
{
case GTK_CURVE_TYPE_LINEAR:
case GTK_CURVE_TYPE_SPLINE:
if (c->grab_point == -1)
{
/* if no point is grabbed... */
if (distance <= MIN_DISTANCE)
new_type = GDK_FLEUR;
else
new_type = GDK_TCROSS;
}
else
{
/* drag the grabbed point */
new_type = GDK_TCROSS;
leftbound = -MIN_DISTANCE;
if (c->grab_point > 0)
leftbound = project (c->ctlpoint[c->grab_point - 1][0],
min_x, c->max_x, width);
rightbound = width + RADIUS * 2 + MIN_DISTANCE;
if (c->grab_point + 1 < c->num_ctlpoints)
rightbound = project (c->ctlpoint[c->grab_point + 1][0],
min_x, c->max_x, width);
if (tx <= leftbound || tx >= rightbound
|| ty > height + RADIUS * 2 + MIN_DISTANCE
|| ty < -MIN_DISTANCE)
c->ctlpoint[c->grab_point][0] = min_x - 1.0;
else
{
rx = unproject (x, min_x, c->max_x, width);
ry = unproject (height - y, c->min_y, c->max_y, height);
c->ctlpoint[c->grab_point][0] = rx;
c->ctlpoint[c->grab_point][1] = ry;
}
gtk_curve_interpolate (c, width, height);
gtk_curve_draw (c, width, height);
}
break;
case GTK_CURVE_TYPE_FREE:
if (c->grab_point != -1)
{
if (c->grab_point > x)
{
x1 = x;
x2 = c->grab_point;
y1 = y;
y2 = c->last;
}
else
{
x1 = c->grab_point;
x2 = x;
y1 = c->last;
y2 = y;
}
if (x2 != x1)
for (i = x1; i <= x2; i++)
{
c->point[i].x = RADIUS + i;
c->point[i].y = RADIUS +
(y1 + ((y2 - y1) * (i - x1)) / (x2 - x1));
}
else
{
c->point[x].x = RADIUS + x;
c->point[x].y = RADIUS + y;
}
c->grab_point = x;
c->last = y;
gtk_curve_draw (c, width, height);
}
if (mevent->state & GDK_BUTTON1_MASK)
new_type = GDK_TCROSS;
else
new_type = GDK_PENCIL;
break;
}
if (new_type != (GdkCursorType) c->cursor_type)
{
GdkCursor *cursor;
c->cursor_type = new_type;
cursor = gdk_cursor_new (c->cursor_type);
gdk_window_set_cursor (w->window, cursor);
gdk_cursor_destroy (cursor);
}
break;
default:
break;
}
return FALSE;
}
void
gtk_curve_set_curve_type (GtkCurve *c, GtkCurveType new_type)
{
gfloat rx, dx;
gint x, i;
if (new_type != c->curve_type)
{
gint width, height;
width = GTK_WIDGET(c)->allocation.width - RADIUS * 2;
height = GTK_WIDGET(c)->allocation.height - RADIUS * 2;
if (new_type == GTK_CURVE_TYPE_FREE)
{
gtk_curve_interpolate (c, width, height);
c->curve_type = new_type;
}
else if (c->curve_type == GTK_CURVE_TYPE_FREE)
{
if (c->ctlpoint)
g_free (c->ctlpoint);
c->num_ctlpoints = 9;
c->ctlpoint = g_malloc (c->num_ctlpoints * sizeof (*c->ctlpoint));
rx = 0.0;
dx = (width - 1) / (gfloat) (c->num_ctlpoints - 1);
for (i = 0; i < c->num_ctlpoints; ++i, rx += dx)
{
x = (int) (rx + 0.5);
c->ctlpoint[i][0] =
unproject (x, c->min_x, c->max_x, width);
c->ctlpoint[i][1] =
unproject (RADIUS + height - c->point[x].y,
c->min_y, c->max_y, height);
}
c->curve_type = new_type;
gtk_curve_interpolate (c, width, height);
}
else
{
c->curve_type = new_type;
gtk_curve_interpolate (c, width, height);
}
gtk_signal_emit (GTK_OBJECT (c), curve_type_changed_signal);
gtk_curve_draw (c, width, height);
}
}
static void
gtk_curve_size_graph (GtkCurve *curve)
{
gint width, height;
gfloat aspect;
width = (curve->max_x - curve->min_x) + 1;
height = (curve->max_y - curve->min_y) + 1;
aspect = width / (gfloat) height;
if (width > gdk_screen_width () / 4)
width = gdk_screen_width () / 4;
if (height > gdk_screen_height () / 4)
height = gdk_screen_height () / 4;
if (aspect < 1.0)
width = height * aspect;
else
height = width / aspect;
gtk_drawing_area_size (GTK_DRAWING_AREA (curve),
width + RADIUS * 2, height + RADIUS * 2);
}
static void
gtk_curve_reset_vector (GtkCurve *curve)
{
if (curve->ctlpoint)
g_free (curve->ctlpoint);
curve->num_ctlpoints = 2;
curve->ctlpoint = g_malloc (2 * sizeof (curve->ctlpoint[0]));
curve->ctlpoint[0][0] = curve->min_x;
curve->ctlpoint[0][1] = curve->min_y;
curve->ctlpoint[1][0] = curve->max_x;
curve->ctlpoint[1][1] = curve->max_y;
if (curve->pixmap)
{
gint width, height;
width = GTK_WIDGET (curve)->allocation.width - RADIUS * 2;
height = GTK_WIDGET (curve)->allocation.height - RADIUS * 2;
if (curve->curve_type == GTK_CURVE_TYPE_FREE)
{
curve->curve_type = GTK_CURVE_TYPE_LINEAR;
gtk_curve_interpolate (curve, width, height);
curve->curve_type = GTK_CURVE_TYPE_FREE;
}
else
gtk_curve_interpolate (curve, width, height);
gtk_curve_draw (curve, width, height);
}
}
void
gtk_curve_reset (GtkCurve *c)
{
GtkCurveType old_type;
old_type = c->curve_type;
c->curve_type = GTK_CURVE_TYPE_SPLINE;
gtk_curve_reset_vector (c);
if (old_type != GTK_CURVE_TYPE_SPLINE)
gtk_signal_emit (GTK_OBJECT (c), curve_type_changed_signal);
}
void
gtk_curve_set_gamma (GtkCurve *c, gfloat gamma)
{
gfloat x, one_over_gamma, height, one_over_width;
GtkCurveType old_type;
gint i;
if (c->num_points < 2)
return;
old_type = c->curve_type;
c->curve_type = GTK_CURVE_TYPE_FREE;
if (gamma <= 0)
one_over_gamma = 1.0;
else
one_over_gamma = 1.0 / gamma;
one_over_width = 1.0 / (c->num_points - 1);
height = c->height;
for (i = 0; i < c->num_points; ++i)
{
x = (gfloat) i / (c->num_points - 1);
c->point[i].x = RADIUS + i;
c->point[i].y =
RADIUS + (height * (1.0 - pow (x, one_over_gamma)) + 0.5);
}
if (old_type != GTK_CURVE_TYPE_FREE)
gtk_signal_emit (GTK_OBJECT (c), curve_type_changed_signal);
gtk_curve_draw (c, c->num_points, c->height);
}
void
gtk_curve_set_range (GtkCurve *curve,
gfloat min_x, gfloat max_x, gfloat min_y, gfloat max_y)
{
curve->min_x = min_x;
curve->max_x = max_x;
curve->min_y = min_y;
curve->max_y = max_y;
gtk_curve_size_graph (curve);
gtk_curve_reset_vector (curve);
}
void
gtk_curve_set_vector (GtkCurve *c, int veclen, gfloat vector[])
{
GtkCurveType old_type;
gfloat rx, dx, ry;
gint i, height;
old_type = c->curve_type;
c->curve_type = GTK_CURVE_TYPE_FREE;
if (c->point)
height = GTK_WIDGET (c)->allocation.height - RADIUS * 2;
else
{
height = (c->max_y - c->min_y);
if (height > gdk_screen_height () / 4)
height = gdk_screen_height () / 4;
c->height = height;
c->num_points = veclen;
c->point = g_malloc (c->num_points * sizeof (c->point[0]));
}
rx = 0;
dx = (veclen - 1.0) / (c->num_points - 1.0);
for (i = 0; i < c->num_points; ++i, rx += dx)
{
ry = vector[(int) (rx + 0.5)];
if (ry > c->max_y) ry = c->max_y;
if (ry < c->min_y) ry = c->min_y;
c->point[i].x = RADIUS + i;
c->point[i].y =
RADIUS + height - project (ry, c->min_y, c->max_y, height);
}
if (old_type != GTK_CURVE_TYPE_FREE)
gtk_signal_emit (GTK_OBJECT (c), curve_type_changed_signal);
gtk_curve_draw (c, c->num_points, height);
}
void
gtk_curve_get_vector (GtkCurve *c, int veclen, gfloat vector[])
{
gfloat rx, ry, dx, dy, min_x, delta_x, *mem, *xv, *yv, *y2v, prev;
gint dst, i, x, next, num_active_ctlpoints = 0, first_active = -1;
min_x = c->min_x;
if (c->curve_type != GTK_CURVE_TYPE_FREE)
{
/* count active points: */
prev = min_x - 1.0;
for (i = num_active_ctlpoints = 0; i < c->num_ctlpoints; ++i)
if (c->ctlpoint[i][0] > prev)
{
if (first_active < 0)
first_active = i;
prev = c->ctlpoint[i][0];
++num_active_ctlpoints;
}
/* handle degenerate case: */
if (num_active_ctlpoints < 2)
{
if (num_active_ctlpoints > 0)
ry = c->ctlpoint[first_active][1];
else
ry = c->min_y;
if (ry < c->min_y) ry = c->min_y;
if (ry > c->max_y) ry = c->max_y;
for (x = 0; x < veclen; ++x)
vector[x] = ry;
return;
}
}
switch (c->curve_type)
{
case GTK_CURVE_TYPE_SPLINE:
mem = g_malloc (3 * num_active_ctlpoints * sizeof (gfloat));
xv = mem;
yv = mem + num_active_ctlpoints;
y2v = mem + 2*num_active_ctlpoints;
prev = min_x - 1.0;
for (i = dst = 0; i < c->num_ctlpoints; ++i)
if (c->ctlpoint[i][0] > prev)
{
prev = c->ctlpoint[i][0];
xv[dst] = c->ctlpoint[i][0];
yv[dst] = c->ctlpoint[i][1];
++dst;
}
spline_solve (num_active_ctlpoints, xv, yv, y2v);
rx = min_x;
dx = (c->max_x - min_x) / (veclen - 1);
for (x = 0; x < veclen; ++x, rx += dx)
{
ry = spline_eval (num_active_ctlpoints, xv, yv, y2v, rx);
if (ry < c->min_y) ry = c->min_y;
if (ry > c->max_y) ry = c->max_y;
vector[x] = ry;
}
g_free (mem);
break;
case GTK_CURVE_TYPE_LINEAR:
dx = (c->max_x - min_x) / (veclen - 1);
rx = min_x;
ry = c->min_y;
dy = 0.0;
i = first_active;
for (x = 0; x < veclen; ++x, rx += dx)
{
if (rx >= c->ctlpoint[i][0])
{
if (rx > c->ctlpoint[i][0])
ry = c->min_y;
dy = 0.0;
next = i + 1;
while (next < c->num_ctlpoints
&& c->ctlpoint[next][0] <= c->ctlpoint[i][0])
++next;
if (next < c->num_ctlpoints)
{
delta_x = c->ctlpoint[next][0] - c->ctlpoint[i][0];
dy = ((c->ctlpoint[next][1] - c->ctlpoint[i][1])
/ delta_x);
dy *= dx;
ry = c->ctlpoint[i][1];
i = next;
}
}
vector[x] = ry;
ry += dy;
}
break;
case GTK_CURVE_TYPE_FREE:
if (c->point)
{
rx = 0.0;
dx = c->num_points / (double) veclen;
for (x = 0; x < veclen; ++x, rx += dx)
vector[x] = unproject (RADIUS + c->height - c->point[(int) rx].y,
c->min_y, c->max_y,
c->height);
}
else
memset (vector, 0, veclen * sizeof (vector[0]));
break;
}
}
GtkWidget*
gtk_curve_new (void)
{
return gtk_type_new (gtk_curve_get_type ());
}
static void
gtk_curve_finalize (GObject *object)
{
GtkCurve *curve;
g_return_if_fail (object != NULL);
g_return_if_fail (GTK_IS_CURVE (object));
curve = GTK_CURVE (object);
if (curve->pixmap)
gdk_pixmap_unref (curve->pixmap);
if (curve->point)
g_free (curve->point);
if (curve->ctlpoint)
g_free (curve->ctlpoint);
G_OBJECT_CLASS (parent_class)->finalize (object);
}
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