lyx_mirror/src/frontends/controllers/ButtonPolicies.h

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// -*- C++ -*-
/**
* \file ButtonPolicies.h
* This file is part of LyX, the document processor.
* Licence details can be found in the file COPYING.
*
* \author Allan Rae
*
* Full author contact details are available in file CREDITS.
*
* Provides a state machine implementation of the various button policies
* used by the dialogs.
*/
#ifndef BUTTONPOLICIES_H
#define BUTTONPOLICIES_H
#include <vector>
#include <boost/utility.hpp>
#include "support/std_ostream.h"
namespace lyx {
namespace frontend {
/** An abstract base class for button policies.
A state machine implementation of the various button policies used by the
dialogs. Only the policy is implemented here. Separate ButtonController
classes are needed for each GUI implementation.
Policy | ReadOnly | Apply Button | Repeated Apply
========================================================================
OkCancel | N | N | -
OkCancelReadOnly | Y | N | -
OkApplyCancel | N | Y | Y
OkApplyCancelReadOnly | Y | Y | Y
NoRepeatedApply | N | Y | N
NoRepeatedApplyReadOnly | Y | Y | N
Preferences | N | Y | No (Ok-Close)
Ignorant | N/A | N/A | N/A
========================================================================
Policy
The name of the policy
ReadOnly
Does the policy treat read-only docs differently to read-write docs?
This usually means that when an SMI_READ_ONLY input arrives then
all the buttons are disabled except Cancel/Close. The state
machine tracks the inputs (valid/invalid) and has states for all
combinations. When an SMI_READ_WRITE input arrives the appropriate
machine state is entered (just as if the document had always been
read-write).
NOTE: If a dialog doesn't care about the read-only status of a document
(and uses an appropriate policy) it can never get into a read-only state
so isReadOnly() can only ever return false even though the document may
be read-only.
Repeated Apply
Simply means that it is alright to use the Apply button multiple times
without requiring a change of the dialog contents. If no repeating is
allowed the Ok+Apply buttons are deactivated. The Preferences dialog
has its own special version of repeated apply handling because its Ok
button is actually a Save button -- its always reasonable to Save the
preferences if the dialog has changed since the last save.
The IgnorantPolicy is a special case that allows anything.
*/
class ButtonPolicy : boost::noncopyable {
public:
///
virtual ~ButtonPolicy() {}
/** The various possible state names.
Not all state-machines have this many states. However, we need
to define them all here so we can share the code.
*/
enum State {
///
INITIAL = 0,
///
VALID,
///
INVALID,
///
APPLIED,
///
RO_INITIAL,
///
RO_VALID,
///
RO_INVALID,
///
RO_APPLIED,
///
BOGUS = 55
};
/// The various button types.
enum Button {
///
CLOSE = 0, // Not a real button, but effectively !CANCEL
///
OKAY = 1,
///
APPLY = 2,
///
CANCEL = 4,
///
RESTORE = 8
};
///
static const Button ALL_BUTTONS =
Button(OKAY | APPLY | CANCEL | RESTORE);
/** State machine inputs.
All the policies so far have both CANCEL and HIDE always going to
INITIAL. This won't necessarily be true for all [future] policies
though so I'll leave those two as distinct inputs rather than merge
them. For example, a dialog that doesn't update it's input fields
when reshown after being hidden needs a policy where CANCEL and
HIDE are treated differently.
*/
enum SMInput {
/// the dialog contents are now valid
SMI_VALID = 0,
/// the dialog contents are now invalid
SMI_INVALID,
/// an apply-and-hide action has happened
SMI_OKAY,
/// an apply action has happened
SMI_APPLY,
/// a cancel action has happened
SMI_CANCEL,
/// a restore action has happened
SMI_RESTORE,
/// the dialog has been hidden
SMI_HIDE,
/// the dialog contents are read-only
SMI_READ_ONLY,
/// the dialog contents can be modified
SMI_READ_WRITE,
/// the state of the dialog contents has not changed
SMI_NOOP,
/// for internal use
SMI_TOTAL
};
/// Trigger a transition with this input.
virtual void input(SMInput) = 0;
/// Activation status of a button
virtual bool buttonStatus(Button) const = 0;
/// Are we in a read-only state?
virtual bool isReadOnly() const = 0;
/// Transition map of the state machine.
typedef std::vector<State> StateArray;
///
typedef std::vector<StateArray> StateMachine;
/// The state outputs are the status of the buttons.
typedef std::vector<int> StateOutputs;
};
inline
std::ostream & operator<<(std::ostream & os, ButtonPolicy::State st)
{
os << int(st);
return os;
}
inline
std::ostream & operator<<(std::ostream & os, ButtonPolicy::SMInput smi)
{
os << int(smi);
return os;
}
//--------------------- Actual Policy Classes -----------------------------
/** Ok and Cancel buttons for dialogs with read-only operation.
Note: This scheme supports the relabelling of Cancel to Close and
vice versa.
This is based on the value of the bool state of the Button::CANCEL.
true == Cancel, false == Close
*/
class OkCancelPolicy : public ButtonPolicy {
public:
///
OkCancelPolicy();
///
//virtual ~OkCancelPolicy() {}
/// Trigger a transition with this input.
virtual void input(SMInput);
/** Activation status of a button.
We assume that we haven't gotten into an undefined state.
This is reasonable since we can only reach states defined
in the state machine and they should all have been defined in
the outputs_ variable. Perhaps we can do something at compile
time to check that all the states have corresponding outputs.
*/
virtual bool buttonStatus(Button button) const {
return button & outputs_[state_];
}
/// Are we in a read-only state?
virtual bool isReadOnly() const {
return false;
}
private:
/// Current state.
State state_;
/// Which buttons are active for a given state.
StateOutputs outputs_;
///
StateMachine state_machine_;
};
/** Ok and Cancel buttons for dialogs where read-only operation is blocked.
The state machine design for this policy allows changes to occur within
the dialog while a file is read-only -- the okay button is disabled until
a read-write input is given. When the file is made read-write the dialog
will then be in the correct state (as if the file had always been
read-write).
Note: This scheme supports the relabelling of Cancel to Close
and vice versa.
This is based on the value of the bool state of the Button::CANCEL.
true == Cancel, false == Close
*/
class OkCancelReadOnlyPolicy : public ButtonPolicy {
public:
///
OkCancelReadOnlyPolicy();
///
//virtual ~OkCancelReadOnlyPolicy() {}
/// Trigger a transition with this input.
virtual void input(SMInput);
/// Activation status of a button.
virtual bool buttonStatus(Button button) const {
return button & outputs_[state_];
}
/// Are we in a read-only state?
virtual bool isReadOnly() const {
return RO_INITIAL == state_
|| RO_VALID == state_
|| RO_INVALID == state_
|| RO_APPLIED == state_;
}
private:
/// Current state.
State state_;
/// Which buttons are active for a given state.
StateOutputs outputs_;
///
StateMachine state_machine_;
};
/** Ok, Apply and Cancel buttons for dialogs where read-only operation
is blocked.
Repeated Apply are not allowed. Likewise, Ok cannot follow Apply without
some valid input. That is, the dialog contents must change between
each Apply or Apply and Ok.
The state machine design for this policy allows changes to occur within
the dialog while a file is read-only -- the Ok+Apply buttons are disabled
until a read-write input is given. When the file is made read-write the
dialog will then be in the correct state (as if the file had always been
read-write).
Note: This scheme supports the relabelling of Cancel to Close
and vice versa.
This is based on the value of the bool state of the Button::CANCEL.
true == Cancel, false == Close
*/
class NoRepeatedApplyReadOnlyPolicy : public ButtonPolicy {
public:
///
NoRepeatedApplyReadOnlyPolicy();
///
//virtual ~NoRepeatedApplyReadOnlyPolicy() {}
/// Trigger a transition with this input.
virtual void input(SMInput);
/// Activation status of a button.
virtual bool buttonStatus(Button button) const {
return button & outputs_[state_];
}
/// Are we in a read-only state?
virtual bool isReadOnly() const {
return RO_INITIAL == state_
|| RO_VALID == state_
|| RO_INVALID == state_
|| RO_APPLIED == state_;
}
private:
/// Current state.
State state_;
/// Which buttons are active for a given state.
StateOutputs outputs_;
///
StateMachine state_machine_;
};
/** Ok, Apply and Cancel buttons for dialogs where read-only
operation is blocked.
Repeated Apply is allowed. Likewise, Ok can follow Apply.
The state machine design for this policy allows changes to occur within
the dialog while a file is read-only -- the Ok+Apply buttons are disabled
until a read-write input is given. When the file is made read-write the
dialog will then be in the correct state (as if the file had always been
read-write).
Note: This scheme supports the relabelling of Cancel to Close
and vice versa.
This is based on the value of the bool state of the Button::CANCEL.
true == Cancel, false == Close
*/
class OkApplyCancelReadOnlyPolicy : public ButtonPolicy {
public:
///
OkApplyCancelReadOnlyPolicy();
///
//virtual ~OkApplyCancelReadOnlyPolicy() {}
/// Trigger a transition with this input.
virtual void input(SMInput);
/// Activation status of a button.
virtual bool buttonStatus(Button button) const {
return button & outputs_[state_];
}
/// Are we in a read-only state?
virtual bool isReadOnly() const {
return RO_INITIAL == state_
|| RO_VALID == state_
|| RO_INVALID == state_
|| RO_APPLIED == state_;
}
private:
/// Current state.
State state_;
/// Which buttons are active for a given state.
StateOutputs outputs_;
///
StateMachine state_machine_;
};
/** Ok, Apply and Cancel buttons for dialogs where repeated Apply is allowed.
Note: This scheme supports the relabelling of Cancel to Close
and vice versa.
This is based on the value of the bool state of the Button::CANCEL.
true == Cancel, false == Close
*/
class OkApplyCancelPolicy : public ButtonPolicy {
public:
///
OkApplyCancelPolicy();
///
//virtual ~OkApplyCancelPolicy() {}
/// Trigger a transition with this input.
virtual void input(SMInput);
/// Activation status of a button.
virtual bool buttonStatus(Button button) const {
return button & outputs_[state_];
}
/// Are we in a read-only state?
virtual bool isReadOnly() const {
return false;
}
private:
/// Current state.
State state_;
/// Which buttons are active for a given state.
StateOutputs outputs_;
///
StateMachine state_machine_;
};
/** Ok, Apply and Cancel buttons for dialogs with no repeated Apply.
Note: This scheme supports the relabelling of Cancel to Close
and vice versa.
This is based on the value of the bool state of the Button::CANCEL.
true == Cancel, false == Close
*/
class NoRepeatedApplyPolicy : public ButtonPolicy {
public:
///
NoRepeatedApplyPolicy();
///
//virtual ~NoRepeatedApplyPolicy() {}
/// Trigger a transition with this input.
virtual void input(SMInput);
/// Activation status of a button.
virtual bool buttonStatus(Button button) const {
return button & outputs_[state_];
}
/// Are we in a read-only state?
virtual bool isReadOnly() const {
return false;
}
private:
/// Current state.
State state_;
/// Which buttons are active for a given state.
StateOutputs outputs_;
///
StateMachine state_machine_;
};
/** Defines the policy used by the Preferences dialog.
Four buttons: Ok (Save), Apply, Cancel/Close, Restore.
Note: This scheme supports the relabelling of Cancel to Close
and vice versa.
This is based on the value of the bool state of the Button::CANCEL.
true == Cancel, false == Close
*/
class PreferencesPolicy : public ButtonPolicy {
public:
///
PreferencesPolicy();
///
//virtual ~PreferencesPolicy() {}
/// Trigger a transition with this input.
virtual void input(SMInput);
/// Activation status of a button.
virtual bool buttonStatus(Button button) const {
return button & outputs_[state_];
}
/// Are we in a read-only state?
virtual bool isReadOnly() const {
return false;
}
private:
/// Current state.
State state_;
/// Which buttons are active for a given state.
StateOutputs outputs_;
///
StateMachine state_machine_;
};
/** Defines the policy used by dialogs that are forced to support a button
controller when they either don't have a use for one or are not ready to
use one. This may be useful when testing a new button policy but wishing
to minimise problems to users by supplying an anything-goes policy via a
preprocessor directive.
*/
class IgnorantPolicy : public ButtonPolicy {
public:
//virtual ~IgnorantPolicy() {}
/// Trigger a transition with this input.
virtual void input(SMInput) {}
/// Activation status of a button.
virtual bool buttonStatus(Button) const {
return true;
}
/// Are we in a read-only state?
virtual bool isReadOnly() const {
return false;
}
};
} // namespace frontend
} // namespace lyx
#endif