[wxWidgets.git] / docs / latex / wx / tconstr.tex

\section{Constraints overview}\label{constraintsoverview}

Classes: \helpref{wxLayoutConstraints}{wxlayoutconstraints}, \helpref{wxIndividualLayoutConstraint}{wxindividuallayoutconstraint}.

Objects of class wxLayoutConstraint can be associated with a window to define
the way it is laid out, with respect to its siblings or the parent.

The class consists of the following eight constraints of class wxIndividualLayoutConstraint,
some or all of which should be accessed directly to set the appropriate
constraints.

\begin{itemize}\itemsep=0pt
\item {\bf left:} represents the left hand edge of the window
\item {\bf right:} represents the right hand edge of the window
\item {\bf top:} represents the top edge of the window
\item {\bf bottom:} represents the bottom edge of the window
\item {\bf width:} represents the width of the window
\item {\bf height:} represents the height of the window
\item {\bf centreX:} represents the horizontal centre point of the window
\item {\bf centreY:} represents the vertical centre point of the window
\end{itemize}

The constraints are initially set to have the relationship wxUnconstrained,
which means that their values should be calculated by looking at known constraints.
To calculate the position and size of the control, the layout algorithm needs to
know exactly 4 constraints (as it has 4 numbers to calculate from them), so you
should always set exactly 4 of the constraints from the above table.

If you want the controls height or width to have the default value, you may use
a special value for the constraint: wxAsIs. If the constraint is wxAsIs, the
dimension will not be changed which is useful for the dialog controls which
often have the default size (e.g. the buttons whose size is determined by their
label).

The constrains calculation is done in \helpref{wxWindow::Layout}{wxwindowlayout} 
function which evaluates constraints. To call it you can either call
\helpref{wxWindow::SetAutoLayout}{wxwindowsetautolayout} if the parent window
is a frame, panel or a dialog to tell default OnSize handlers to call Layout
automatically whenever the window size changes, or override OnSize and call
Layout yourself (note that you do have to call 
\helpref{Layout}{wxwindowlayout} yourself if the parent window is not a
frame, panel or dialog).

\subsection{Constraint layout: more detail}

By default, windows do not have a wxLayoutConstraints object. In this case, much layout
must be done explicitly, by performing calculations in OnSize members, except
for the case of frames that have exactly one subwindow (not counting toolbar and
statusbar which are also positioned by the frame automatically), where wxFrame::OnSize
takes care of resizing the child to always fill the frame.

To avoid the need for these rather awkward calculations, the user can create
a wxLayoutConstraints object and associate it with a window with wxWindow::SetConstraints.
This object contains a constraint for each of the window edges, two for the centre point,
and two for the window size. By setting some or all of these constraints appropriately,
the user can achieve quite complex layout by defining relationships between windows.

In wxWindows, each window can be constrained relative to either its {\it
siblings} on the same window, or the {\it parent}. The layout algorithm
therefore operates in a top-down manner, finding the correct layout for
the children of a window, then the layout for the grandchildren, and so
on. Note that this differs markedly from native Motif layout, where
constraints can ripple upwards and can eventually change the frame
window or dialog box size. We assume in wxWindows that the {\it user} is
always `boss' and specifies the size of the outer window, to which
subwindows must conform. Obviously, this might be a limitation in some
circumstances, but it suffices for most situations, and the
simplification avoids some of the nightmarish problems associated with
programming Motif.

When the user sets constraints, many of the constraints for windows
edges and dimensions remain unconstrained. For a given window,
the wxWindow::Layout algorithm first resets all constraints
in all children to have unknown edge or dimension values, and then iterates through the constraints,
evaluating them. For unconstrained edges and dimensions, it
tries to find the value using known relationships that always hold. For example,
an unconstrained {\it width} may be calculated from the {\it left} and {\it right edges}, if
both are currently known. For edges and dimensions with user-supplied constraints, these
constraints are evaluated if the inputs of the constraint are known.

The algorithm stops when all child edges and dimension are known (success), or 
there are unknown edges or dimensions but there has been no change in this cycle (failure).

It then sets all the window positions and sizes according to the values it has found.

Because the algorithm is iterative, the order in which constraints are considered is
irrelevant, however you may reduce the number of iterations (and thus speed up
the layout calculations) by creating the controls in such order that as many
constraints as possible can be calculated during the first iteration. For example, if
you have 2 buttons which you'd like to position in the lower right corner, it is
slightly more efficient to first create the second button and specify that its
right border IsSameAs(parent, wxRight) and then create the first one by
specifying that it should be LeftOf() the second one than to do in a more
natural left-to-right order.

\subsection{Window layout examples}\label{layoutexamples}

\subsubsection{Example 1: subwindow layout}

This example specifies a panel and a window side by side,
with a text subwindow below it.

\begin{verbatim}
  frame->panel = new wxPanel(frame, -1, wxPoint(0, 0), wxSize(1000, 500), 0);
  frame->scrollWindow = new MyScrolledWindow(frame, -1, wxPoint(0, 0), wxSize(400, 400), wxRETAINED);
  frame->text_window = new MyTextWindow(frame, -1, wxPoint(0, 250), wxSize(400, 250));

  // Set constraints for panel subwindow
  wxLayoutConstraints *c1 = new wxLayoutConstraints;

  c1->left.SameAs       (frame, wxLeft);
  c1->top.SameAs        (frame, wxTop);
  c1->right.PercentOf   (frame, wxWidth, 50);
  c1->height.PercentOf  (frame, wxHeight, 50);

  frame->panel->SetConstraints(c1);

  // Set constraints for scrollWindow subwindow
  wxLayoutConstraints *c2 = new wxLayoutConstraints;

  c2->left.SameAs       (frame->panel, wxRight);
  c2->top.SameAs        (frame, wxTop);
  c2->right.SameAs      (frame, wxRight);
  c2->height.PercentOf  (frame, wxHeight, 50);

  frame->scrollWindow->SetConstraints(c2);

  // Set constraints for text subwindow
  wxLayoutConstraints *c3 = new wxLayoutConstraints;
  c3->left.SameAs       (frame, wxLeft);
  c3->top.Below         (frame->panel);
  c3->right.SameAs      (frame, wxRight);
  c3->bottom.SameAs     (frame, wxBottom);

  frame->text_window->SetConstraints(c3);
\end{verbatim}

\subsubsection{Example 2: panel item layout}

This example sizes a button width to 80 percent of the panel width, and centres
it horizontally. A listbox and multitext item are placed below it. The listbox
takes up 40 percent of the panel width, and the multitext item takes up
the remainder of the width. Margins of 5 pixels are used.

\begin{verbatim}
  // Create some panel items
  wxButton *btn1 = new wxButton(frame->panel, -1, "A button") ;

  wxLayoutConstraints *b1 = new wxLayoutConstraints;
  b1->centreX.SameAs    (frame->panel, wxCentreX);
  b1->top.SameAs        (frame->panel, wxTop, 5);
  b1->width.PercentOf   (frame->panel, wxWidth, 80);
  b1->height.PercentOf  (frame->panel, wxHeight, 10);
  btn1->SetConstraints(b1);

  wxListBox *list = new wxListBox(frame->panel, -1, "A list",
                                  wxPoint(-1, -1), wxSize(200, 100));

  wxLayoutConstraints *b2 = new wxLayoutConstraints;
  b2->top.Below         (btn1, 5);
  b2->left.SameAs       (frame->panel, wxLeft, 5);
  b2->width.PercentOf   (frame->panel, wxWidth, 40);
  b2->bottom.SameAs     (frame->panel, wxBottom, 5);
  list->SetConstraints(b2);

  wxTextCtrl *mtext = new wxTextCtrl(frame->panel, -1, "Multiline text", "Some text",
                        wxPoint(-1, -1), wxSize(150, 100), wxTE_MULTILINE);

  wxLayoutConstraints *b3 = new wxLayoutConstraints;
  b3->top.Below         (btn1, 5);
  b3->left.RightOf      (list, 5);
  b3->right.SameAs      (frame->panel, wxRight, 5);
  b3->bottom.SameAs     (frame->panel, wxBottom, 5);
  mtext->SetConstraints(b3);
\end{verbatim}
Commit	Line	Data
a660d684 KB	1	\section{Constraints overview}\label{constraintsoverview}
	2
	3	Classes: \helpref{wxLayoutConstraints}{wxlayoutconstraints}, \helpref{wxIndividualLayoutConstraint}{wxindividuallayoutconstraint}.
	4
3ca6a5f0 BP	5	Objects of class wxLayoutConstraint can be associated with a window to define
3ca6a5f0 BP	6	the way it is laid out, with respect to its siblings or the parent.
a660d684 KB	7
	8	The class consists of the following eight constraints of class wxIndividualLayoutConstraint,
	9	some or all of which should be accessed directly to set the appropriate
	10	constraints.
	11
	12	\begin{itemize}\itemsep=0pt
	13	\item {\bf left:} represents the left hand edge of the window
	14	\item {\bf right:} represents the right hand edge of the window
	15	\item {\bf top:} represents the top edge of the window
	16	\item {\bf bottom:} represents the bottom edge of the window
	17	\item {\bf width:} represents the width of the window
	18	\item {\bf height:} represents the height of the window
	19	\item {\bf centreX:} represents the horizontal centre point of the window
	20	\item {\bf centreY:} represents the vertical centre point of the window
	21	\end{itemize}
	22
945bda7d	23	The constraints are initially set to have the relationship wxUnconstrained,
a660d684	24	which means that their values should be calculated by looking at known constraints.
945bda7d VZ	25	To calculate the position and size of the control, the layout algorithm needs to
	26	know exactly 4 constraints (as it has 4 numbers to calculate from them), so you
	27	should always set exactly 4 of the constraints from the above table.
	28
	29	If you want the controls height or width to have the default value, you may use
	30	a special value for the constraint: wxAsIs. If the constraint is wxAsIs, the
	31	dimension will not be changed which is useful for the dialog controls which
	32	often have the default size (e.g. the buttons whose size is determined by their
	33	label).
	34
	35	The constrains calculation is done in \helpref{wxWindow::Layout}{wxwindowlayout}
	36	function which evaluates constraints. To call it you can either call
3ca6a5f0 BP	37	\helpref{wxWindow::SetAutoLayout}{wxwindowsetautolayout} if the parent window
	38	is a frame, panel or a dialog to tell default OnSize handlers to call Layout
	39	automatically whenever the window size changes, or override OnSize and call
	40	Layout yourself (note that you do have to call
	41	\helpref{Layout}{wxwindowlayout} yourself if the parent window is not a
	42	frame, panel or dialog).
a660d684 KB	43
	44	\subsection{Constraint layout: more detail}
	45
	46	By default, windows do not have a wxLayoutConstraints object. In this case, much layout
	47	must be done explicitly, by performing calculations in OnSize members, except
945bda7d VZ	48	for the case of frames that have exactly one subwindow (not counting toolbar and
	49	statusbar which are also positioned by the frame automatically), where wxFrame::OnSize
	50	takes care of resizing the child to always fill the frame.
a660d684 KB	51
	52	To avoid the need for these rather awkward calculations, the user can create
	53	a wxLayoutConstraints object and associate it with a window with wxWindow::SetConstraints.
	54	This object contains a constraint for each of the window edges, two for the centre point,
	55	and two for the window size. By setting some or all of these constraints appropriately,
	56	the user can achieve quite complex layout by defining relationships between windows.
	57
	58	In wxWindows, each window can be constrained relative to either its {\it
	59	siblings} on the same window, or the {\it parent}. The layout algorithm
	60	therefore operates in a top-down manner, finding the correct layout for
	61	the children of a window, then the layout for the grandchildren, and so
	62	on. Note that this differs markedly from native Motif layout, where
	63	constraints can ripple upwards and can eventually change the frame
	64	window or dialog box size. We assume in wxWindows that the {\it user} is
	65	always `boss' and specifies the size of the outer window, to which
	66	subwindows must conform. Obviously, this might be a limitation in some
	67	circumstances, but it suffices for most situations, and the
	68	simplification avoids some of the nightmarish problems associated with
	69	programming Motif.
	70
	71	When the user sets constraints, many of the constraints for windows
	72	edges and dimensions remain unconstrained. For a given window,
	73	the wxWindow::Layout algorithm first resets all constraints
	74	in all children to have unknown edge or dimension values, and then iterates through the constraints,
f6bcfd97	75	evaluating them. For unconstrained edges and dimensions, it
a660d684 KB	76	tries to find the value using known relationships that always hold. For example,
	77	an unconstrained {\it width} may be calculated from the {\it left} and {\it right edges}, if
	78	both are currently known. For edges and dimensions with user-supplied constraints, these
f6bcfd97	79	constraints are evaluated if the inputs of the constraint are known.
a660d684	80
f6bcfd97	81	The algorithm stops when all child edges and dimension are known (success), or
a660d684 KB	82	there are unknown edges or dimensions but there has been no change in this cycle (failure).
	83
	84	It then sets all the window positions and sizes according to the values it has found.
	85
	86	Because the algorithm is iterative, the order in which constraints are considered is
945bda7d VZ	87	irrelevant, however you may reduce the number of iterations (and thus speed up
	88	the layout calculations) by creating the controls in such order that as many
	89	constraints as possible can be calculated during the first iteration. For example, if
	90	you have 2 buttons which you'd like to position in the lower right corner, it is
f6bcfd97	91	slightly more efficient to first create the second button and specify that its
945bda7d VZ	92	right border IsSameAs(parent, wxRight) and then create the first one by
	93	specifying that it should be LeftOf() the second one than to do in a more
	94	natural left-to-right order.
a660d684 KB	95
	96	\subsection{Window layout examples}\label{layoutexamples}
	97
	98	\subsubsection{Example 1: subwindow layout}
	99
fe604ccd	100	This example specifies a panel and a window side by side,
945bda7d	101	with a text subwindow below it.
a660d684 KB	102
a660d684 KB	103	\begin{verbatim}
fe604ccd JS	104	frame->panel = new wxPanel(frame, -1, wxPoint(0, 0), wxSize(1000, 500), 0);
	105	frame->scrollWindow = new MyScrolledWindow(frame, -1, wxPoint(0, 0), wxSize(400, 400), wxRETAINED);
	106	frame->text_window = new MyTextWindow(frame, -1, wxPoint(0, 250), wxSize(400, 250));
a660d684 KB	107
	108	// Set constraints for panel subwindow
	109	wxLayoutConstraints *c1 = new wxLayoutConstraints;
	110
	111	c1->left.SameAs (frame, wxLeft);
	112	c1->top.SameAs (frame, wxTop);
	113	c1->right.PercentOf (frame, wxWidth, 50);
	114	c1->height.PercentOf (frame, wxHeight, 50);
	115
	116	frame->panel->SetConstraints(c1);
	117
fe604ccd	118	// Set constraints for scrollWindow subwindow
a660d684 KB	119	wxLayoutConstraints *c2 = new wxLayoutConstraints;
	120
	121	c2->left.SameAs (frame->panel, wxRight);
	122	c2->top.SameAs (frame, wxTop);
	123	c2->right.SameAs (frame, wxRight);
	124	c2->height.PercentOf (frame, wxHeight, 50);
	125
fe604ccd	126	frame->scrollWindow->SetConstraints(c2);
a660d684 KB	127
	128	// Set constraints for text subwindow
	129	wxLayoutConstraints *c3 = new wxLayoutConstraints;
	130	c3->left.SameAs (frame, wxLeft);
	131	c3->top.Below (frame->panel);
	132	c3->right.SameAs (frame, wxRight);
	133	c3->bottom.SameAs (frame, wxBottom);
	134
	135	frame->text_window->SetConstraints(c3);
	136	\end{verbatim}
	137
	138	\subsubsection{Example 2: panel item layout}
	139
	140	This example sizes a button width to 80 percent of the panel width, and centres
	141	it horizontally. A listbox and multitext item are placed below it. The listbox
	142	takes up 40 percent of the panel width, and the multitext item takes up
	143	the remainder of the width. Margins of 5 pixels are used.
	144
	145	\begin{verbatim}
	146	// Create some panel items
fe604ccd	147	wxButton *btn1 = new wxButton(frame->panel, -1, "A button") ;
a660d684 KB	148
	149	wxLayoutConstraints *b1 = new wxLayoutConstraints;
	150	b1->centreX.SameAs (frame->panel, wxCentreX);
	151	b1->top.SameAs (frame->panel, wxTop, 5);
	152	b1->width.PercentOf (frame->panel, wxWidth, 80);
	153	b1->height.PercentOf (frame->panel, wxHeight, 10);
	154	btn1->SetConstraints(b1);
	155
fe604ccd JS	156	wxListBox *list = new wxListBox(frame->panel, -1, "A list",
fe604ccd JS	157	wxPoint(-1, -1), wxSize(200, 100));
a660d684 KB	158
	159	wxLayoutConstraints *b2 = new wxLayoutConstraints;
	160	b2->top.Below (btn1, 5);
	161	b2->left.SameAs (frame->panel, wxLeft, 5);
	162	b2->width.PercentOf (frame->panel, wxWidth, 40);
	163	b2->bottom.SameAs (frame->panel, wxBottom, 5);
	164	list->SetConstraints(b2);
	165
fe604ccd JS	166	wxTextCtrl *mtext = new wxTextCtrl(frame->panel, -1, "Multiline text", "Some text",
fe604ccd JS	167	wxPoint(-1, -1), wxSize(150, 100), wxTE_MULTILINE);
945bda7d	168
a660d684 KB	169	wxLayoutConstraints *b3 = new wxLayoutConstraints;
	170	b3->top.Below (btn1, 5);
	171	b3->left.RightOf (list, 5);
	172	b3->right.SameAs (frame->panel, wxRight, 5);
	173	b3->bottom.SameAs (frame->panel, wxBottom, 5);
	174	mtext->SetConstraints(b3);
	175	\end{verbatim}
	176
	177