/*
* Copyright (C) 2007 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
package android.view;
import android.text.method.MetaKeyKeyListener;
import android.util.AndroidRuntimeException;
import android.util.SparseIntArray;
import android.os.RemoteException;
import android.os.ServiceManager;
import android.util.SparseArray;
import java.lang.Character;
/**
* Describes the keys provided by a keyboard device and their associated labels.
*/
public class KeyCharacterMap {
/**
* The id of the device's primary built in keyboard is always 0.
*
* @deprecated This constant should no longer be used because there is no
* guarantee that a device has a built-in keyboard that can be used for
* typing text. There might not be a built-in keyboard, the built-in keyboard
* might be a {@link #NUMERIC} or {@link #SPECIAL_FUNCTION} keyboard, or there
* might be multiple keyboards installed including external keyboards.
* When interpreting key presses received from the framework, applications should
* use the device id specified in the {@link KeyEvent} received.
* When synthesizing key presses for delivery elsewhere or when translating key presses
* from unknown keyboards, applications should use the special {@link #VIRTUAL_KEYBOARD}
* device id.
*/
@Deprecated
public static final int BUILT_IN_KEYBOARD = 0;
/**
* The id of a generic virtual keyboard with a full layout that can be used to
* synthesize key events. Typically used with {@link #getEvents}.
*/
public static final int VIRTUAL_KEYBOARD = -1;
/**
* A numeric (12-key) keyboard.
* <p>
* A numeric keyboard supports text entry using a multi-tap approach.
* It may be necessary to tap a key multiple times to generate the desired letter
* or symbol.
* </p><p>
* This type of keyboard is generally designed for thumb typing.
* </p>
*/
public static final int NUMERIC = 1;
/**
* A keyboard with all the letters, but with more than one letter per key.
* <p>
* This type of keyboard is generally designed for thumb typing.
* </p>
*/
public static final int PREDICTIVE = 2;
/**
* A keyboard with all the letters, and maybe some numbers.
* <p>
* An alphabetic keyboard supports text entry directly but may have a condensed
* layout with a small form factor. In contrast to a {@link #FULL full keyboard}, some
* symbols may only be accessible using special on-screen character pickers.
* In addition, to improve typing speed and accuracy, the framework provides
* special affordances for alphabetic keyboards such as auto-capitalization
* and toggled / locked shift and alt keys.
* </p><p>
* This type of keyboard is generally designed for thumb typing.
* </p>
*/
public static final int ALPHA = 3;
/**
* A full PC-style keyboard.
* <p>
* A full keyboard behaves like a PC keyboard. All symbols are accessed directly
* by pressing keys on the keyboard without on-screen support or affordances such
* as auto-capitalization.
* </p><p>
* This type of keyboard is generally designed for full two hand typing.
* </p>
*/
public static final int FULL = 4;
/**
* A keyboard that is only used to control special functions rather than for typing.
* <p>
* A special function keyboard consists only of non-printing keys such as
* HOME and POWER that are not actually used for typing.
* </p>
*/
public static final int SPECIAL_FUNCTION = 5;
/**
* This private-use character is used to trigger Unicode character
* input by hex digits.
*/
public static final char HEX_INPUT = '\uEF00';
/**
* This private-use character is used to bring up a character picker for
* miscellaneous symbols.
*/
public static final char PICKER_DIALOG_INPUT = '\uEF01';
/**
* Modifier keys may be chorded with character keys.
*
* @see {#link #getModifierBehavior()} for more details.
*/
public static final int MODIFIER_BEHAVIOR_CHORDED = 0;
/**
* Modifier keys may be chorded with character keys or they may toggle
* into latched or locked states when pressed independently.
*
* @see {#link #getModifierBehavior()} for more details.
*/
public static final int MODIFIER_BEHAVIOR_CHORDED_OR_TOGGLED = 1;
private static SparseArray<KeyCharacterMap> sInstances = new SparseArray<KeyCharacterMap>();
private final int mDeviceId;
private int mPtr;
private static native int nativeLoad(int id);
private static native void nativeDispose(int ptr);
private static native char nativeGetCharacter(int ptr, int keyCode, int metaState);
private static native boolean nativeGetFallbackAction(int ptr, int keyCode, int metaState,
FallbackAction outFallbackAction);
private static native char nativeGetNumber(int ptr, int keyCode);
private static native char nativeGetMatch(int ptr, int keyCode, char[] chars, int metaState);
private static native char nativeGetDisplayLabel(int ptr, int keyCode);
private static native int nativeGetKeyboardType(int ptr);
private static native KeyEvent[] nativeGetEvents(int ptr, int deviceId, char[] chars);
private KeyCharacterMap(int deviceId, int ptr) {
mDeviceId = deviceId;
mPtr = ptr;
}
@Override
protected void finalize() throws Throwable {
if (mPtr != 0) {
nativeDispose(mPtr);
mPtr = 0;
}
}
/**
* Loads the key character maps for the keyboard with the specified device id.
*
* @param deviceId The device id of the keyboard.
* @return The associated key character map.
* @throws {@link UnavailableException} if the key character map
* could not be loaded because it was malformed or the default key character map
* is missing from the system.
*/
public static KeyCharacterMap load(int deviceId) {
synchronized (sInstances) {
KeyCharacterMap map = sInstances.get(deviceId);
if (map == null) {
int ptr = nativeLoad(deviceId); // might throw
map = new KeyCharacterMap(deviceId, ptr);
sInstances.put(deviceId, map);
}
return map;
}
}
/**
* Gets the Unicode character generated by the specified key and meta
* key state combination.
* <p>
* Returns the Unicode character that the specified key would produce
* when the specified meta bits (see {@link MetaKeyKeyListener})
* were active.
* </p><p>
* Returns 0 if the key is not one that is used to type Unicode
* characters.
* </p><p>
* If the return value has bit {@link #COMBINING_ACCENT} set, the
* key is a "dead key" that should be combined with another to
* actually produce a character -- see {@link #getDeadChar} --
* after masking with {@link #COMBINING_ACCENT_MASK}.
* </p>
*
* @param keyCode The key code.
* @param metaState The meta key modifier state.
* @return The associated character or combining accent, or 0 if none.
*/
public int get(int keyCode, int metaState) {
metaState = KeyEvent.normalizeMetaState(metaState);
char ch = nativeGetCharacter(mPtr, keyCode, metaState);
int map = COMBINING.get(ch);
if (map != 0) {
return map;
} else {
return ch;
}
}
/**
* Gets the fallback action to perform if the application does not
* handle the specified key.
* <p>
* When an application does not handle a particular key, the system may
* translate the key to an alternate fallback key (specified in the
* fallback action) and dispatch it to the application.
* The event containing the fallback key is flagged
* with {@link KeyEvent#FLAG_FALLBACK}.
* </p>
*
* @param keyCode The key code.
* @param metaState The meta key modifier state.
* @param outFallbackAction The fallback action object to populate.
* @return True if a fallback action was found, false otherwise.
*
* @hide
*/
public boolean getFallbackAction(int keyCode, int metaState,
FallbackAction outFallbackAction) {
if (outFallbackAction == null) {
throw new IllegalArgumentException("fallbackAction must not be null");
}
metaState = KeyEvent.normalizeMetaState(metaState);
return nativeGetFallbackAction(mPtr, keyCode, metaState, outFallbackAction);
}
/**
* Gets the number or symbol associated with the key.
* <p>
* The character value is returned, not the numeric value.
* If the key is not a number, but is a symbol, the symbol is retuned.
* </p><p>
* This method is intended to to support dial pads and other numeric or
* symbolic entry on keyboards where certain keys serve dual function
* as alphabetic and symbolic keys. This method returns the number
* or symbol associated with the key independent of whether the user
* has pressed the required modifier.
* </p><p>
* For example, on one particular keyboard the keys on the top QWERTY row generate
* numbers when ALT is pressed such that ALT-Q maps to '1'. So for that keyboard
* when {@link #getNumber} is called with {@link KeyEvent#KEYCODE_Q} it returns '1'
* so that the user can type numbers without pressing ALT when it makes sense.
* </p>
*
* @param keyCode The key code.
* @return The associated numeric or symbolic character, or 0 if none.
*/
public char getNumber(int keyCode) {
return nativeGetNumber(mPtr, keyCode);
}
/**
* Gets the first character in the character array that can be generated
* by the specified key code.
* <p>
* This is a convenience function that returns the same value as
* {@link #getMatch(int,char[],int) getMatch(keyCode, chars, 0)}.
* </p>
*
* @param keyCode The keycode.
* @param chars The array of matching characters to consider.
* @return The matching associated character, or 0 if none.
*/
public char getMatch(int keyCode, char[] chars) {
return getMatch(keyCode, chars, 0);
}
/**
* Gets the first character in the character array that can be generated
* by the specified key code. If there are multiple choices, prefers
* the one that would be generated with the specified meta key modifier state.
*
* @param keyCode The key code.
* @param chars The array of matching characters to consider.
* @param metaState The preferred meta key modifier state.
* @return The matching associated character, or 0 if none.
*/
public char getMatch(int keyCode, char[] chars, int metaState) {
if (chars == null) {
throw new IllegalArgumentException("chars must not be null.");
}
metaState = KeyEvent.normalizeMetaState(metaState);
return nativeGetMatch(mPtr, keyCode, chars, metaState);
}
/**
* Gets the primary character for this key.
* In other words, the label that is physically printed on it.
*
* @param keyCode The key code.
* @return The display label character, or 0 if none (eg. for non-printing keys).
*/
public char getDisplayLabel(int keyCode) {
return nativeGetDisplayLabel(mPtr, keyCode);
}
/**
* Get the character that is produced by putting accent on the character c.
* For example, getDeadChar('`', 'e') returns è.
*
* @param accent The accent character. eg. '`'
* @param c The basic character.
* @return The combined character, or 0 if the characters cannot be combined.
*/
public static int getDeadChar(int accent, int c) {
return DEAD.get((accent << 16) | c);
}
/**
* Describes the character mappings associated with a key.
*
* @deprecated instead use {@link KeyCharacterMap#getDisplayLabel(int)},
* {@link KeyCharacterMap#getNumber(int)} and {@link KeyCharacterMap#get(int, int)}.
*/
@Deprecated
public static class KeyData {
public static final int META_LENGTH = 4;
/**
* The display label (see {@link #getDisplayLabel}).
*/
public char displayLabel;
/**
* The "number" value (see {@link #getNumber}).
*/
public char number;
/**
* The character that will be generated in various meta states
* (the same ones used for {@link #get} and defined as
* {@link KeyEvent#META_SHIFT_ON} and {@link KeyEvent#META_ALT_ON}).
* <table>
* <tr><th>Index</th><th align="left">Value</th></tr>
* <tr><td>0</td><td>no modifiers</td></tr>
* <tr><td>1</td><td>caps</td></tr>
* <tr><td>2</td><td>alt</td></tr>
* <tr><td>3</td><td>caps + alt</td></tr>
* </table>
*/
public char[] meta = new char[META_LENGTH];
}
/**
* Get the character conversion data for a given key code.
*
* @param keyCode The keyCode to query.
* @param results A {@link KeyData} instance that will be filled with the results.
* @return True if the key was mapped. If the key was not mapped, results is not modified.
*
* @deprecated instead use {@link KeyCharacterMap#getDisplayLabel(int)},
* {@link KeyCharacterMap#getNumber(int)} or {@link KeyCharacterMap#get(int, int)}.
*/
@Deprecated
public boolean getKeyData(int keyCode, KeyData results) {
if (results.meta.length < KeyData.META_LENGTH) {
throw new IndexOutOfBoundsException(
"results.meta.length must be >= " + KeyData.META_LENGTH);
}
char displayLabel = nativeGetDisplayLabel(mPtr, keyCode);
if (displayLabel == 0) {
return false;
}
results.displayLabel = displayLabel;
results.number = nativeGetNumber(mPtr, keyCode);
results.meta[0] = nativeGetCharacter(mPtr, keyCode, 0);
results.meta[1] = nativeGetCharacter(mPtr, keyCode, KeyEvent.META_SHIFT_ON);
results.meta[2] = nativeGetCharacter(mPtr, keyCode, KeyEvent.META_ALT_ON);
results.meta[3] = nativeGetCharacter(mPtr, keyCode,
KeyEvent.META_ALT_ON | KeyEvent.META_SHIFT_ON);
return true;
}
/**
* Get an array of KeyEvent objects that if put into the input stream
* could plausibly generate the provided sequence of characters. It is
* not guaranteed that the sequence is the only way to generate these
* events or that it is optimal.
* <p>
* This function is primarily offered for instrumentation and testing purposes.
* It may fail to map characters to key codes. In particular, the key character
* map for the {@link #BUILT_IN_KEYBOARD built-in keyboard} device id may be empty.
* Consider using the key character map associated with the
* {@link #VIRTUAL_KEYBOARD virtual keyboard} device id instead.
* </p><p>
* For robust text entry, do not use this function. Instead construct a
* {@link KeyEvent} with action code {@link KeyEvent#ACTION_MULTIPLE} that contains
* the desired string using {@link KeyEvent#KeyEvent(long, String, int, int)}.
* </p>
*
* @param chars The sequence of characters to generate.
* @return An array of {@link KeyEvent} objects, or null if the given char array
* can not be generated using the current key character map.
*/
public KeyEvent[] getEvents(char[] chars) {
if (chars == null) {
throw new IllegalArgumentException("chars must not be null.");
}
return nativeGetEvents(mPtr, mDeviceId, chars);
}
/**
* Returns true if the specified key produces a glyph.
*
* @param keyCode The key code.
* @return True if the key is a printing key.
*/
public boolean isPrintingKey(int keyCode) {
int type = Character.getType(nativeGetDisplayLabel(mPtr, keyCode));
switch (type)
{
case Character.SPACE_SEPARATOR:
case Character.LINE_SEPARATOR:
case Character.PARAGRAPH_SEPARATOR:
case Character.CONTROL:
case Character.FORMAT:
return false;
default:
return true;
}
}
/**
* Gets the keyboard type.
* Returns {@link #NUMERIC}, {@link #PREDICTIVE}, {@link #ALPHA} or {@link #FULL}.
* <p>
* Different keyboard types have different semantics. Refer to the documentation
* associated with the keyboard type constants for details.
* </p>
*
* @return The keyboard type.
*/
public int getKeyboardType() {
return nativeGetKeyboardType(mPtr);
}
/**
* Gets a constant that describes the behavior of this keyboard's modifier keys
* such as {@link KeyEvent#KEYCODE_SHIFT_LEFT}.
* <p>
* Currently there are two behaviors that may be combined:
* </p>
* <ul>
* <li>Chorded behavior: When the modifier key is pressed together with one or more
* character keys, the keyboard inserts the modified keys and
* then resets the modifier state when the modifier key is released.</li>
* <li>Toggled behavior: When the modifier key is pressed and released on its own
* it first toggles into a latched state. When latched, the modifier will apply
* to next character key that is pressed and will then reset itself to the initial state.
* If the modifier is already latched and the modifier key is pressed and release on
* its own again, then it toggles into a locked state. When locked, the modifier will
* apply to all subsequent character keys that are pressed until unlocked by pressing
* the modifier key on its own one more time to reset it to the initial state.
* Toggled behavior is useful for small profile keyboards designed for thumb typing.
* </ul>
* <p>
* This function currently returns {@link #MODIFIER_BEHAVIOR_CHORDED} when the
* {@link #getKeyboardType() keyboard type} is {@link #FULL} or {@link #SPECIAL_FUNCTION} and
* {@link #MODIFIER_BEHAVIOR_CHORDED_OR_TOGGLED} otherwise.
* In the future, the function may also take into account global keyboard
* accessibility settings, other user preferences, or new device capabilities.
* </p>
*
* @return The modifier behavior for this keyboard.
*
* @see {@link #MODIFIER_BEHAVIOR_CHORDED}
* @see {@link #MODIFIER_BEHAVIOR_CHORDED_OR_TOGGLED}
*/
public int getModifierBehavior() {
switch (getKeyboardType()) {
case FULL:
case SPECIAL_FUNCTION:
return MODIFIER_BEHAVIOR_CHORDED;
default:
return MODIFIER_BEHAVIOR_CHORDED_OR_TOGGLED;
}
}
/**
* Queries the framework about whether any physical keys exist on the
* any keyboard attached to the device that are capable of producing the given key code.
*
* @param keyCode The key code to query.
* @return True if at least one attached keyboard supports the specified key code.
*/
public static boolean deviceHasKey(int keyCode) {
int[] codeArray = new int[1];
codeArray[0] = keyCode;
boolean[] ret = deviceHasKeys(codeArray);
return ret[0];
}
/**
* Queries the framework about whether any physical keys exist on the
* any keyboard attached to the device that are capable of producing the given
* array of key codes.
*
* @param keyCodes The array of key codes to query.
* @return A new array of the same size as the key codes array whose elements
* are set to true if at least one attached keyboard supports the corresponding key code
* at the same index in the key codes array.
*/
public static boolean[] deviceHasKeys(int[] keyCodes) {
boolean[] ret = new boolean[keyCodes.length];
IWindowManager wm = Display.getWindowManager();
try {
wm.hasKeys(keyCodes, ret);
} catch (RemoteException e) {
// no fallback; just return the empty array
}
return ret;
}
/**
* Maps Unicode combining diacritical to display-form dead key
* (display character shifted left 16 bits).
*/
private static SparseIntArray COMBINING = new SparseIntArray();
/**
* Maps combinations of (display-form) dead key and second character
* to combined output character.
*/
private static SparseIntArray DEAD = new SparseIntArray();
/*
* TODO: Change the table format to support full 21-bit-wide
* accent characters and combined characters if ever necessary.
*/
private static final int ACUTE = '\u00B4' << 16;
private static final int GRAVE = '`' << 16;
private static final int CIRCUMFLEX = '^' << 16;
private static final int TILDE = '~' << 16;
private static final int UMLAUT = '\u00A8' << 16;
/*
* This bit will be set in the return value of {@link #get(int, int)} if the
* key is a "dead key."
*/
public static final int COMBINING_ACCENT = 0x80000000;
/**
* Mask the return value from {@link #get(int, int)} with this value to get
* a printable representation of the accent character of a "dead key."
*/
public static final int COMBINING_ACCENT_MASK = 0x7FFFFFFF;
static {
COMBINING.put('\u0300', (GRAVE >> 16) | COMBINING_ACCENT);
COMBINING.put('\u0301', (ACUTE >> 16) | COMBINING_ACCENT);
COMBINING.put('\u0302', (CIRCUMFLEX >> 16) | COMBINING_ACCENT);
COMBINING.put('\u0303', (TILDE >> 16) | COMBINING_ACCENT);
COMBINING.put('\u0308', (UMLAUT >> 16) | COMBINING_ACCENT);
DEAD.put(ACUTE | 'A', '\u00C1');
DEAD.put(ACUTE | 'C', '\u0106');
DEAD.put(ACUTE | 'E', '\u00C9');
DEAD.put(ACUTE | 'G', '\u01F4');
DEAD.put(ACUTE | 'I', '\u00CD');
DEAD.put(ACUTE | 'K', '\u1E30');
DEAD.put(ACUTE | 'L', '\u0139');
DEAD.put(ACUTE | 'M', '\u1E3E');
DEAD.put(ACUTE | 'N', '\u0143');
DEAD.put(ACUTE | 'O', '\u00D3');
DEAD.put(ACUTE | 'P', '\u1E54');
DEAD.put(ACUTE | 'R', '\u0154');
DEAD.put(ACUTE | 'S', '\u015A');
DEAD.put(ACUTE | 'U', '\u00DA');
DEAD.put(ACUTE | 'W', '\u1E82');
DEAD.put(ACUTE | 'Y', '\u00DD');
DEAD.put(ACUTE | 'Z', '\u0179');
DEAD.put(ACUTE | 'a', '\u00E1');
DEAD.put(ACUTE | 'c', '\u0107');
DEAD.put(ACUTE | 'e', '\u00E9');
DEAD.put(ACUTE | 'g', '\u01F5');
DEAD.put(ACUTE | 'i', '\u00ED');
DEAD.put(ACUTE | 'k', '\u1E31');
DEAD.put(ACUTE | 'l', '\u013A');
DEAD.put(ACUTE | 'm', '\u1E3F');
DEAD.put(ACUTE | 'n', '\u0144');
DEAD.put(ACUTE | 'o', '\u00F3');
DEAD.put(ACUTE | 'p', '\u1E55');
DEAD.put(ACUTE | 'r', '\u0155');
DEAD.put(ACUTE | 's', '\u015B');
DEAD.put(ACUTE | 'u', '\u00FA');
DEAD.put(ACUTE | 'w', '\u1E83');
DEAD.put(ACUTE | 'y', '\u00FD');
DEAD.put(ACUTE | 'z', '\u017A');
DEAD.put(CIRCUMFLEX | 'A', '\u00C2');
DEAD.put(CIRCUMFLEX | 'C', '\u0108');
DEAD.put(CIRCUMFLEX | 'E', '\u00CA');
DEAD.put(CIRCUMFLEX | 'G', '\u011C');
DEAD.put(CIRCUMFLEX | 'H', '\u0124');
DEAD.put(CIRCUMFLEX | 'I', '\u00CE');
DEAD.put(CIRCUMFLEX | 'J', '\u0134');
DEAD.put(CIRCUMFLEX | 'O', '\u00D4');
DEAD.put(CIRCUMFLEX | 'S', '\u015C');
DEAD.put(CIRCUMFLEX | 'U', '\u00DB');
DEAD.put(CIRCUMFLEX | 'W', '\u0174');
DEAD.put(CIRCUMFLEX | 'Y', '\u0176');
DEAD.put(CIRCUMFLEX | 'Z', '\u1E90');
DEAD.put(CIRCUMFLEX | 'a', '\u00E2');
DEAD.put(CIRCUMFLEX | 'c', '\u0109');
DEAD.put(CIRCUMFLEX | 'e', '\u00EA');
DEAD.put(CIRCUMFLEX | 'g', '\u011D');
DEAD.put(CIRCUMFLEX | 'h', '\u0125');
DEAD.put(CIRCUMFLEX | 'i', '\u00EE');
DEAD.put(CIRCUMFLEX | 'j', '\u0135');
DEAD.put(CIRCUMFLEX | 'o', '\u00F4');
DEAD.put(CIRCUMFLEX | 's', '\u015D');
DEAD.put(CIRCUMFLEX | 'u', '\u00FB');
DEAD.put(CIRCUMFLEX | 'w', '\u0175');
DEAD.put(CIRCUMFLEX | 'y', '\u0177');
DEAD.put(CIRCUMFLEX | 'z', '\u1E91');
DEAD.put(GRAVE | 'A', '\u00C0');
DEAD.put(GRAVE | 'E', '\u00C8');
DEAD.put(GRAVE | 'I', '\u00CC');
DEAD.put(GRAVE | 'N', '\u01F8');
DEAD.put(GRAVE | 'O', '\u00D2');
DEAD.put(GRAVE | 'U', '\u00D9');
DEAD.put(GRAVE | 'W', '\u1E80');
DEAD.put(GRAVE | 'Y', '\u1EF2');
DEAD.put(GRAVE | 'a', '\u00E0');
DEAD.put(GRAVE | 'e', '\u00E8');
DEAD.put(GRAVE | 'i', '\u00EC');
DEAD.put(GRAVE | 'n', '\u01F9');
DEAD.put(GRAVE | 'o', '\u00F2');
DEAD.put(GRAVE | 'u', '\u00F9');
DEAD.put(GRAVE | 'w', '\u1E81');
DEAD.put(GRAVE | 'y', '\u1EF3');
DEAD.put(TILDE | 'A', '\u00C3');
DEAD.put(TILDE | 'E', '\u1EBC');
DEAD.put(TILDE | 'I', '\u0128');
DEAD.put(TILDE | 'N', '\u00D1');
DEAD.put(TILDE | 'O', '\u00D5');
DEAD.put(TILDE | 'U', '\u0168');
DEAD.put(TILDE | 'V', '\u1E7C');
DEAD.put(TILDE | 'Y', '\u1EF8');
DEAD.put(TILDE | 'a', '\u00E3');
DEAD.put(TILDE | 'e', '\u1EBD');
DEAD.put(TILDE | 'i', '\u0129');
DEAD.put(TILDE | 'n', '\u00F1');
DEAD.put(TILDE | 'o', '\u00F5');
DEAD.put(TILDE | 'u', '\u0169');
DEAD.put(TILDE | 'v', '\u1E7D');
DEAD.put(TILDE | 'y', '\u1EF9');
DEAD.put(UMLAUT | 'A', '\u00C4');
DEAD.put(UMLAUT | 'E', '\u00CB');
DEAD.put(UMLAUT | 'H', '\u1E26');
DEAD.put(UMLAUT | 'I', '\u00CF');
DEAD.put(UMLAUT | 'O', '\u00D6');
DEAD.put(UMLAUT | 'U', '\u00DC');
DEAD.put(UMLAUT | 'W', '\u1E84');
DEAD.put(UMLAUT | 'X', '\u1E8C');
DEAD.put(UMLAUT | 'Y', '\u0178');
DEAD.put(UMLAUT | 'a', '\u00E4');
DEAD.put(UMLAUT | 'e', '\u00EB');
DEAD.put(UMLAUT | 'h', '\u1E27');
DEAD.put(UMLAUT | 'i', '\u00EF');
DEAD.put(UMLAUT | 'o', '\u00F6');
DEAD.put(UMLAUT | 't', '\u1E97');
DEAD.put(UMLAUT | 'u', '\u00FC');
DEAD.put(UMLAUT | 'w', '\u1E85');
DEAD.put(UMLAUT | 'x', '\u1E8D');
DEAD.put(UMLAUT | 'y', '\u00FF');
}
/**
* Thrown by {@link KeyCharacterMap#load} when a key character map could not be loaded.
*/
public static class UnavailableException extends AndroidRuntimeException {
public UnavailableException(String msg) {
super(msg);
}
}
/**
* Specifies a substitute key code and meta state as a fallback action
* for an unhandled key.
* @hide
*/
public static final class FallbackAction {
public int keyCode;
public int metaState;
}
}