ZTimerFreeglut::ZTimerFreeglut() : interval(25), started(false) {
static int globalID = 0;
while (mapTimers.find(globalID) != mapTimers.end()) {
globalID++;
}
timerID = globalID;
mapTimers[timerID] = this;
}
static void _TimerFunc(int value)
{
hmap::iterator it = mapTimers.find(value);
if (it == mapTimers.end())
return;
ZTimerFreeglut* t = (*it).second;
if (t->IsTimerStarted()) {
glutTimerFunc(t->GetTimerInterval(), _TimerFunc, value);
t->OnTimer();
}
}
uint Synth::walk(DdNode *a_dd) {
/**
Walk given DdNode node (recursively).
If a given node requires intermediate AND gates for its representation, the function adds them.
Literal representing given input node is `not` added to the spec.
:returns: literal representing input node
**/
// caching
static hmap<DdNode*, uint> cache;
{
auto cached_lit = cache.find(Cudd_Regular(a_dd));
if (cached_lit != cache.end())
return Cudd_IsComplement(a_dd) ? NEGATED(cached_lit->second) : cached_lit->second;
}
// end of caching
if (Cudd_IsConstant(a_dd))
return (uint) (a_dd == cudd.bddOne().getNode()); // in aiger: 0 is False and 1 is True
// get an index of the variable
uint a_lit = aiger_by_cudd[Cudd_NodeReadIndex(a_dd)];
DdNode *t_bdd = Cudd_T(a_dd);
DdNode *e_bdd = Cudd_E(a_dd);
uint t_lit = walk(t_bdd);
uint e_lit = walk(e_bdd);
// ite(a_bdd, then_bdd, else_bdd)
// = a*then + !a*else
// = !(!(a*then) * !(!a*else))
// -> in general case we need 3 more ANDs
uint a_t_lit = get_optimized_and_lit(a_lit, t_lit);
uint na_e_lit = get_optimized_and_lit(NEGATED(a_lit), e_lit);
uint n_a_t_lit = NEGATED(a_t_lit);
uint n_na_e_lit = NEGATED(na_e_lit);
uint and_lit = get_optimized_and_lit(n_a_t_lit, n_na_e_lit);
uint res = NEGATED(and_lit);
cache[Cudd_Regular(a_dd)] = res;
if (Cudd_IsComplement(a_dd))
res = NEGATED(res);
return res;
}
Key android2april(int androidKeyCode)
{
if (gKeyMap.hasKey(androidKeyCode))
{
return gKeyMap[androidKeyCode];
}
#ifdef _DEBUG
hlog::writef(logTag, "Unknown key code: %u", androidKeyCode);
#endif
return april::AK_NONE;
}
Key kd2april(int kdKeyCode)
{
if (gKeyMap.has_key(kdKeyCode))
{
return gKeyMap[kdKeyCode];
}
#ifdef _DEBUG
hlog::writef(logTag, "Unknown key code: %u", kdKeyCode);
#endif
return april::AK_NONE;
}
hidx (const Json& json) {
const string expnFile = json["expnFile"].string_value();
cx_mat expn_gam;
if (expn_gam.load (expnFile, arma_ascii)) {
expn = vectorise(expn_gam,1);
} else {
printf ("Error: expn_gam is not loaded!\n");
}
nind = expn.n_elem;
lmax = json["lmax"].int_value();
nmax = json["nmax"].int_value();
ferr = json["ferr"].number_value();
nddo = 1;
lddo = 0;
int ntot = static_cast<int>(get_nmax(nind,lmax));
if (ntot < nmax) {
nmax = ntot;
}
keys.set_size(nmax);
keys(0) = string (nind,'0');
for (int i=1; i<nmax; ++i) {
keys(i) = string (nind,'!');
}
if (!maps.empty()) {
printf ("Madan! maps is not empty!");
}
maps.emplace(keys(0),hnod());
printf ("$InitHidx\n");
printf ("nind = %d\n", nind);
printf ("lddo = %d\n", lddo);
printf ("nddo = %d\n", nddo);
printf ("lmax = %d\n", lmax);
printf ("nmax = %d\n", nmax);
printf ("ferr = %g\n", ferr);
printf ("$InitHidx\n\n");
}
void _makeButtonLabels(hstr* ok, hstr* yes, hstr* no, hstr* cancel,
MessageBoxButton buttonMask, hmap<MessageBoxButton, hstr> customButtonTitles)
{
if ((buttonMask & MESSAGE_BUTTON_OK) && (buttonMask & MESSAGE_BUTTON_CANCEL))
{
*ok = customButtonTitles.tryGet(MESSAGE_BUTTON_OK, "OK");
*cancel = customButtonTitles.tryGet(MESSAGE_BUTTON_CANCEL, "Cancel");
}
else if ((buttonMask & MESSAGE_BUTTON_YES) && (buttonMask & MESSAGE_BUTTON_NO) && (buttonMask & MESSAGE_BUTTON_CANCEL))
{
*yes = customButtonTitles.tryGet(MESSAGE_BUTTON_YES, "Yes");
*no = customButtonTitles.tryGet(MESSAGE_BUTTON_NO, "No");
*cancel = customButtonTitles.tryGet(MESSAGE_BUTTON_CANCEL, "Cancel");
}
else if (buttonMask & MESSAGE_BUTTON_OK)
{
*ok = customButtonTitles.tryGet(MESSAGE_BUTTON_OK, "OK");
}
else if ((buttonMask & MESSAGE_BUTTON_YES) && (buttonMask & MESSAGE_BUTTON_NO))
{
*yes = customButtonTitles.tryGet(MESSAGE_BUTTON_YES, "Yes");
*no = customButtonTitles.tryGet(MESSAGE_BUTTON_NO, "No");
}
}
namespace april
{
static hmap<int, Key> gKeyMap;
Key android2april(int androidKeyCode)
{
if (gKeyMap.hasKey(androidKeyCode))
{
return gKeyMap[androidKeyCode];
}
#ifdef _DEBUG
hlog::writef(logTag, "Unknown key code: %u", androidKeyCode);
#endif
return april::AK_NONE;
}
void initAndroidKeyMap()
{
hmap<int, Key>& m = gKeyMap;
// codes obtained from http://developer.android.com/reference/android/view/KeyEvent.html#KEYCODE_0
m[-1] = AK_UNKNOWN;
m[0] = AK_NONE;
// LBUTTON and RBUTTON are necessary
m[1] = AK_LBUTTON;
m[2] = AK_RBUTTON;
// these mostly don't exist on Android
//m[0] = AK_CANCEL;
//m[0] = AK_MBUTTON;
//m[168] = AK_WHEELUP; // ZOOM_IN
//m[169] = AK_WHEELDN; // ZOOM_OUT
//m[0] = AK_DOUBLETAP;
// most common keys; some not supported
m[67] = AK_BACK;
m[61] = AK_TAB;
m[28] = AK_CLEAR;
m[66] = AK_RETURN;
//m[0] = AK_SHIFT;
//m[0] = AK_CONTROL;
m[82] = AK_MENU;
//m[0] = AK_PAUSE;
m[115] = AK_CAPITAL;
// various keys for asian keyboards not supported
//m[0] = AK_KANA;
//m[0] = AK_HANGEUL;
//m[0] = AK_HANGUL;
//m[0] = AK_JUNJA;
//m[0] = AK_FINAL;
//m[0] = AK_HANJA;
//m[0] = AK_KANJI;
m[4] = AK_ESCAPE; // using Android's back button for this
//m[0] = AK_CONVERT;
//m[0] = AK_NONCONVERT;
//m[0] = AK_ACCEPT;
//m[0] = AK_MODECHANGE;
// Mac CMD keys; they aren't used so they will act like CTRL
//m[113] = AK_LCOMMAND;
//m[114] = AK_RCOMMAND;
// space
m[62] = AK_SPACE;
// don't exist on Android
//m[0] = AK_PRIOR;
//m[0] = AK_NEXT;
//m[0] = AK_END;
//m[0] = AK_HOME;
// don't exist on Android
//m[0] = AK_LEFT;
//m[0] = AK_UP;
//m[0] = AK_RIGHT;
//m[0] = AK_DOWN;
// don't exist on Android
//m[0] = AK_SELECT;
//m[0] = AK_PRINT;
//m[0] = AK_EXECUTE;
//m[0] = AK_SNAPSHOT;
// some more keys
m[124] = AK_INSERT;
m[112] = AK_DELETE;
//m[0] = AK_HELP;
// '0'-'9'
m[7] = AK_0;
m[8] = AK_1;
m[9] = AK_2;
m[10] = AK_3;
m[11] = AK_4;
m[12] = AK_5;
m[13] = AK_6;
m[14] = AK_7;
m[15] = AK_8;
m[16] = AK_9;
// 'A'-'Z'
m[29] = AK_A;
m[30] = AK_B;
m[31] = AK_C;
m[32] = AK_D;
m[33] = AK_E;
m[34] = AK_F;
m[35] = AK_G;
m[36] = AK_H;
m[37] = AK_I;
m[38] = AK_J;
m[39] = AK_K;
m[40] = AK_L;
m[41] = AK_M;
m[42] = AK_N;
m[43] = AK_O;
m[44] = AK_P;
m[45] = AK_Q;
m[46] = AK_R;
m[47] = AK_S;
m[48] = AK_T;
m[49] = AK_U;
m[50] = AK_V;
m[51] = AK_W;
m[52] = AK_X;
m[53] = AK_Y;
m[54] = AK_Z;
// don't exist on Android
//m[0] = AK_LWIN 0;
//m[0] = AK_RWIN 0;
//m[0] = AK_APPS 0;
//m[0] = AK_SLEEP 0;
// numpad
m[144] = AK_NUMPAD0;
m[145] = AK_NUMPAD1;
m[146] = AK_NUMPAD2;
m[147] = AK_NUMPAD3;
m[148] = AK_NUMPAD4;
m[149] = AK_NUMPAD5;
m[150] = AK_NUMPAD6;
m[151] = AK_NUMPAD7;
m[152] = AK_NUMPAD8;
m[153] = AK_NUMPAD9;
m[155] = AK_MULTIPLY;
m[157] = AK_ADD;
m[159] = AK_SEPARATOR;
m[156] = AK_SUBTRACT;
m[158] = AK_DECIMAL;
m[154] = AK_DIVIDE;
// F-keys
m[131] = AK_F1;
m[132] = AK_F2;
m[133] = AK_F3;
m[134] = AK_F4;
m[135] = AK_F5;
m[136] = AK_F6;
m[137] = AK_F7;
m[138] = AK_F8;
m[139] = AK_F9;
m[140] = AK_F10;
m[141] = AK_F11;
m[142] = AK_F12;
// don't exist on Android
m[0] = AK_F13;
m[0] = AK_F14;
m[0] = AK_F15;
m[0] = AK_F16;
m[0] = AK_F17;
m[0] = AK_F18;
m[0] = AK_F19;
m[0] = AK_F20;
m[0] = AK_F21;
m[0] = AK_F22;
m[0] = AK_F23;
m[0] = AK_F24;
// don't exist on Android
m[143] = AK_NUMLOCK;
m[116] = AK_SCROLL;
// specific left-and-right-shift keys
m[59] = AK_LSHIFT;
m[60] = AK_RSHIFT;
m[113] = AK_LCONTROL;
m[114] = AK_RCONTROL;
m[57] = AK_LMENU;
m[58] = AK_RMENU;
// browser control keys
//m[4] = AK_BROWSER_BACK;
//m[125] = AK_BROWSER_FORWARD;
//m[0] = AK_BROWSER_REFRESH;
//m[0] = AK_BROWSER_STOP;
//m[84] = AK_BROWSER_SEARCH;
//m[0] = AK_BROWSER_FAVORITES;
//m[0] = AK_BROWSER_HOME;
// volume keys
m[164] = AK_VOLUME_MUTE;
m[25] = AK_VOLUME_DOWN;
m[24] = AK_VOLUME_UP;
// don't exist on Android
//m[0] = AK_MEDIA_NEXT_TRACK;
//m[0] = AK_MEDIA_PREV_TRACK;
//m[0] = AK_MEDIA_STOP;
//m[0] = AK_MEDIA_PLAY_PAUSE;
// don't exist on Android
//m[0] = AK_LAUNCH_MAIL;
//m[0] = AK_LAUNCH_MEDIA_SELECT;
//m[0] = AK_LAUNCH_APP1;
//m[0] = AK_LAUNCH_APP2;
// don't exist on Android
//m[0] = AK_OEM_2;
//m[0] = AK_OEM_3;
//m[0] = AK_OEM_4;
//m[0] = AK_OEM_5;
//m[0] = AK_OEM_6;
//m[0] = AK_OEM_7;
//m[0] = AK_OEM_8;
//m[0] = AK_OEM_102;
// don't exist on Android
//m[0] = AK_PACKET;
//m[0] = AK_ATTN;
//m[0] = AK_CRSEL;
//m[0] = AK_EXSEL;
//m[0] = AK_EREOF;
// don't exist on Android
//m[0] = AK_PLAY;
//m[0] = AK_ZOOM;
// don't exist on Android
//m[0] = AK_NONAME;
//m[0] = AK_PA1;
//m[0] = AK_OEM_CLEAR;
}
}
ZTimerFreeglut::~ZTimerFreeglut() {
mapTimers.erase(timerID);
}
namespace april
{
static hmap<int, Key> gKeyMap;
Key kd2april(int kdKeyCode)
{
if (gKeyMap.has_key(kdKeyCode))
{
return gKeyMap[kdKeyCode];
}
#ifdef _DEBUG
hlog::writef(logTag, "Unknown key code: %u", kdKeyCode);
#endif
return april::AK_NONE;
}
void initOpenKODEKeyMap()
{
hmap<int, Key>& m = gKeyMap;
m[KD_INPUT_KEYS_LBUTTON] = AK_LBUTTON;
m[KD_INPUT_KEYS_RBUTTON] = AK_RBUTTON;
m[KD_INPUT_KEYS_MBUTTON] = AK_MBUTTON;
m[KD_INPUT_KEYS_ESCAPE] = AK_ESCAPE;
m[KD_INPUT_KEYS_BACKSPACE] = AK_BACK;
m[KD_INPUT_KEYS_TAB] = AK_TAB;
m[KD_INPUT_KEYS_ENTER] = AK_RETURN;
m[KD_INPUT_KEYS_SPACE] = AK_SPACE;
m[KD_INPUT_KEYS_SHIFT] = AK_SHIFT;
m[KD_INPUT_KEYS_CTRL] = AK_CONTROL;
m[KD_INPUT_KEYS_ALT] = AK_MENU;
m[KD_INPUT_KEYS_LWIN] = AK_LCOMMAND;
m[KD_INPUT_KEYS_RWIN] = AK_RCOMMAND;
m[KD_INPUT_KEYS_APPS] = AK_APPS;
m[KD_INPUT_KEYS_PAUSE] = AK_PAUSE;
m[KD_INPUT_KEYS_CAPSLOCK] = AK_CAPITAL;
m[KD_INPUT_KEYS_NUMLOCK] = AK_NUMLOCK;
m[KD_INPUT_KEYS_PGUP] = AK_PRIOR;
m[KD_INPUT_KEYS_PGDN] = AK_NEXT;
m[KD_INPUT_KEYS_HOME] = AK_HOME;
m[KD_INPUT_KEYS_END] = AK_END;
m[KD_INPUT_KEYS_INSERT] = AK_INSERT;
m[KD_INPUT_KEYS_DELETE] = AK_DELETE;
m[KD_INPUT_KEYS_LEFT] = AK_LEFT;
m[KD_INPUT_KEYS_UP] = AK_UP;
m[KD_INPUT_KEYS_RIGHT] = AK_RIGHT;
m[KD_INPUT_KEYS_DOWN] = AK_DOWN;
m[KD_INPUT_KEYS_0] = AK_0;
m[KD_INPUT_KEYS_1] = AK_1;
m[KD_INPUT_KEYS_2] = AK_2;
m[KD_INPUT_KEYS_3] = AK_3;
m[KD_INPUT_KEYS_4] = AK_4;
m[KD_INPUT_KEYS_5] = AK_5;
m[KD_INPUT_KEYS_6] = AK_6;
m[KD_INPUT_KEYS_7] = AK_7;
m[KD_INPUT_KEYS_8] = AK_8;
m[KD_INPUT_KEYS_9] = AK_9;
m[KD_INPUT_KEYS_A] = AK_A;
m[KD_INPUT_KEYS_B] = AK_B;
m[KD_INPUT_KEYS_C] = AK_C;
m[KD_INPUT_KEYS_D] = AK_D;
m[KD_INPUT_KEYS_E] = AK_E;
m[KD_INPUT_KEYS_F] = AK_F;
m[KD_INPUT_KEYS_G] = AK_G;
m[KD_INPUT_KEYS_H] = AK_H;
m[KD_INPUT_KEYS_I] = AK_I;
m[KD_INPUT_KEYS_J] = AK_J;
m[KD_INPUT_KEYS_K] = AK_K;
m[KD_INPUT_KEYS_L] = AK_L;
m[KD_INPUT_KEYS_M] = AK_M;
m[KD_INPUT_KEYS_N] = AK_N;
m[KD_INPUT_KEYS_O] = AK_O;
m[KD_INPUT_KEYS_P] = AK_P;
m[KD_INPUT_KEYS_Q] = AK_Q;
m[KD_INPUT_KEYS_R] = AK_R;
m[KD_INPUT_KEYS_S] = AK_S;
m[KD_INPUT_KEYS_T] = AK_T;
m[KD_INPUT_KEYS_U] = AK_U;
m[KD_INPUT_KEYS_V] = AK_V;
m[KD_INPUT_KEYS_W] = AK_W;
m[KD_INPUT_KEYS_X] = AK_X;
m[KD_INPUT_KEYS_Y] = AK_Y;
m[KD_INPUT_KEYS_Z] = AK_Z;
m[KD_INPUT_KEYS_NUMPAD0] = AK_NUMPAD0;
m[KD_INPUT_KEYS_NUMPAD1] = AK_NUMPAD1;
m[KD_INPUT_KEYS_NUMPAD2] = AK_NUMPAD2;
m[KD_INPUT_KEYS_NUMPAD3] = AK_NUMPAD3;
m[KD_INPUT_KEYS_NUMPAD4] = AK_NUMPAD4;
m[KD_INPUT_KEYS_NUMPAD5] = AK_NUMPAD5;
m[KD_INPUT_KEYS_NUMPAD6] = AK_NUMPAD6;
m[KD_INPUT_KEYS_NUMPAD7] = AK_NUMPAD7;
m[KD_INPUT_KEYS_NUMPAD8] = AK_NUMPAD8;
m[KD_INPUT_KEYS_NUMPAD9] = AK_NUMPAD9;
m[KD_INPUT_KEYS_MULTIPLY] = AK_MULTIPLY;
m[KD_INPUT_KEYS_DIVIDE] = AK_DIVIDE;
m[KD_INPUT_KEYS_ADD] = AK_ADD;
m[KD_INPUT_KEYS_SUBTRACT] = AK_SUBTRACT;
m[KD_INPUT_KEYS_DECIMAL] = AK_DECIMAL;
m[KD_INPUT_KEYS_F1] = AK_F1;
m[KD_INPUT_KEYS_F2] = AK_F2;
m[KD_INPUT_KEYS_F3] = AK_F3;
m[KD_INPUT_KEYS_F4] = AK_F4;
m[KD_INPUT_KEYS_F5] = AK_F5;
m[KD_INPUT_KEYS_F6] = AK_F6;
m[KD_INPUT_KEYS_F7] = AK_F7;
m[KD_INPUT_KEYS_F8] = AK_F8;
m[KD_INPUT_KEYS_F9] = AK_F9;
m[KD_INPUT_KEYS_F10] = AK_F10;
m[KD_INPUT_KEYS_F11] = AK_F11;
m[KD_INPUT_KEYS_F12] = AK_F12;
m[KD_INPUT_KEYS_UNKNOWN] = AK_UNKNOWN;
// m[KD_INPUT_KEYS_SCROLLLOCK] = AK_;
// m[KD_INPUT_KEYS_GRAVE] = AK_;
// m[KD_INPUT_KEYS_MINUS] = AK_;
// m[KD_INPUT_KEYS_EQUALS] = AK_;
// m[KD_INPUT_KEYS_BACKSLASH] = AK_;
// m[KD_INPUT_KEYS_LBRACKET] = AK_;
// m[KD_INPUT_KEYS_RBRACKET] = AK_;
// m[KD_INPUT_KEYS_SEMICOLON] = AK_;
// m[KD_INPUT_KEYS_APOSTROPHE] = AK_;
// m[KD_INPUT_KEYS_COMMA] = AK_;
// m[KD_INPUT_KEYS_PERIOD] = AK_;
// m[KD_INPUT_KEYS_SLASH] = AK_;
}
}
