vector processZeros(vector data)
{
bool needProcess = false;
int start = 0;
int end = 0;
for (int i=0; i<data.x; i++)
{
end = i - 1;
if (getv(data, i) != 0 && needProcess)
{
needProcess = false;
for (int j=end; j>=start; j--)
{
setv(data, j, getv(data, i));
}
}
else if (getv(data, i) == 0 && !needProcess)
{
start = i;
needProcess = true;
}
}
if (needProcess)
{
end++;
for (int i=start; i<=end; i++)
{
setv(data, i, getv(data, start-1));
}
}
return data;
}
/*
* Re-markout segment by relative limit of segment max value
*/
Points relativeAlignSement(Points points, vector data, int relativeLimit, double scaleFactor)
{
int pointIndex = points.pointsCount - 1;
qDebug() << "relativeAlignSement" << LOG_DATA;
uint32_t startPosition = points.pointsOffset[pointIndex] / scaleFactor;
uint32_t stopPosition = startPosition + points.pointsLenght[pointIndex] / scaleFactor;
qDebug() << "startPosition: " << startPosition << LOG_DATA;
qDebug() << "stopPosition: " << stopPosition << LOG_DATA;
// Look for max value
double maxValue = 0.0;
for (int i = startPosition; i<=stopPosition; i++)
{
double value = getv(data, i);
if (maxValue < value)
maxValue = value;
}
qDebug() << "maxValue: " << maxValue << LOG_DATA;
// Calculate new absolute limit
double limit = maxValue * relativeLimit / 100.0;
qDebug() << "limit: " << limit << LOG_DATA;
// Recalculate start segments border
uint32_t newSegmentOffset = -1;
for (uint32_t i = startPosition; i<=stopPosition || newSegmentOffset == -1; i++)
{
double value = getv(data, i);
if (value > limit)
{
newSegmentOffset = i;
break;
}
}
// Recalculate stop segments border
uint32_t newSegmentLenght = -1;
for (uint32_t i = stopPosition; i>=startPosition || newSegmentLenght == -1; i--)
{
double value = getv(data, i);
if (value > limit)
{
newSegmentLenght = i - newSegmentOffset;
break;
}
}
qDebug() << "pointsOffset: " << points.pointsOffset[pointIndex] << LOG_DATA;
qDebug() << "pointsLenght: " << points.pointsLenght[pointIndex] << LOG_DATA;
points.pointsOffset[pointIndex] = newSegmentOffset * scaleFactor;
points.pointsLenght[pointIndex] = newSegmentLenght * scaleFactor;
qDebug() << "pointsOffset: " << points.pointsOffset[pointIndex] << LOG_DATA;
qDebug() << "pointsLenght: " << points.pointsLenght[pointIndex] << LOG_DATA;
return points;
}
pdd inser(int li1,int li2)
{
double dk = a[li1].X-a[li2].X;
double db = a[li2].Y-a[li1].Y;
double x = db/dk;
return MP(x,getv(li1,x));
}
pars_t getv(K &&s, V && ...pars) const {
if (_pars.count(s)) {
return _pars.at(s);
}
else {
return getv(pars...);
}
}
const char *getMainArg(PCStr(where),PCStr(name)){
const char *val;
if( MAIN_argv ){
if( val = getv(MAIN_argv,name) )
return val;
}
return getenv(name);
}
static Any
getIf(Any cell, Name method, Any def) /* can be optimised further */
{ Any rval;
if ( hasGetMethodObject(cell, method) &&
(rval = getv(cell, method, 0, NULL)) )
answer(rval);
answer(def);
}
static Any
getExecuteObtain(Obtain obt)
{ Any receiver;
Name selector;
Any rval = FAIL;
void *savedcontext;
if ( notNil(obt->context) &&
TheCallbackFunctions.setHostContext )
{ savedcontext =
(*TheCallbackFunctions.setHostContext)(obt->context);
} else
savedcontext = NIL;
if ( !(receiver = expandCodeArgument(obt->receiver)) )
goto out;
if ( !(selector = checkSelector(obt->selector)) )
goto out;
if ( isNil(obt->arguments) )
{ rval = getv(receiver, selector, 0, NULL);
} else
{ int n;
int argc = valInt(obt->arguments->size);
ArgVector(argv, argc);
Any *elms = obt->arguments->elements;
for(n = 0; n < argc; n++)
{ if ( !(argv[n] = expandCodeArgument(elms[n])) )
goto out;
}
rval = getv(receiver, selector, argc, argv);
}
out:
if ( notNil(savedcontext) )
(*TheCallbackFunctions.setHostContext)(savedcontext);
return rval;
}
bool validateMask(vector mask)
{
bool valid = false;
for (int i=0; i<mask.x; i++)
{
if (getv(mask, i) == 1)
{
valid = true;
}
}
return valid;
}
static void
sv_index_replace0(void)
{
svindex i;
t( sv_indexinit(&i) == 0 );
uint32_t key = 7;
svv *h = st_svv(&st_r.g, NULL, 0, 0, key);
svv *n = st_svv(&st_r.g, NULL, 1, 0, key);
t( sv_indexset(&i, &st_r.r, h) == 0 );
t( sv_indexset(&i, &st_r.r, n) == 0 );
svv *keyv = st_svv(&st_r.g, &st_r.gc, 0, 0, key);
svv *p = getv(&i, &st_r.r, 0, keyv);
t( p == h );
p = getv(&i, &st_r.r, 1, keyv);
t( p == n );
t( h->next == NULL );
sv_indexfree(&i, &st_r.r);
}
/*ARGSUSED*/
void
dover(Char **v, struct command *c)
{
Char *p;
setname(short2str(*v++));
if (!*v) {
if (!(p = tgetenv(STRSYSTYPE)))
stderror(ERR_NAME | ERR_STRING,
CGETS(23, 29, "System type is not set"));
xprintf("%S\n", p);
}
else {
tsetenv(STRSYSTYPE, getv(*v) ? STRbsd43 : STRsys53);
dohash(NULL, NULL);
}
}
/*
* Get new relative limit of segment max value
*/
double getRelativeLimitForSement(uint32_t startPosition, uint32_t stopPosition, vector data, int relativeLimit)
{
// Look for max value
double maxValue = 0.0;
double minValue = 1.0;
for (int i = startPosition; i<=stopPosition; i++)
{
double value = getv(data, i);
if (maxValue < value)
maxValue = value;
if (minValue > value)
minValue = value;
}
qDebug() << "maxValue: " << maxValue << LOG_DATA;
qDebug() << "minValue: " << minValue << LOG_DATA;
// Calculate new absolute limit
double limit = minValue + ((maxValue - minValue) * relativeLimit / 100.0);
return limit;
}
int main(int argc, char *argv[])
{
setIO("sample");
n = gi;
for(int i = 1;i<=n;++i) a[i].Y = gi,sou[i] = i;
for(int i = 1;i<=n;++i) a[i].X = gi;
sort(sou+1,sou+1+n,cmp2);
sort(a+1,a+n+1,cmp1);
stk[++top] = 1;
for(int i = 2;i<=n;++i)
{
if(dblcmp(a[stk[top]].X-a[i].X) == 0) continue;
while(top)
{
pdd pu = inser(stk[top],i);
if(pu.X<0) --top;
else if(top >= 2 && pu.Y<getv(stk[top-1],pu.X)) --top;
else break;
}
stk[++top] = i;
}
for(int i = 1;i<=top;++i)
{
int x = stk[i];
for(int j = x;j<=n;++j)
if(dblcmp(a[j].X - a[x].X) != 0 || dblcmp(a[j].Y - a[x].Y) != 0)
break;
else
ans.pb(sou[j]);
}
sort(ans.begin(),ans.end());
printf("%d\n",ans.size());
for(int i = 0;i<ans.size()-1;++i)
printf("%d ",ans[i]);
printf("%d\n",ans[ans.size()-1]);
closeIO();
return EXIT_SUCCESS;
}
static ssize_t
Sread_object(void *handle, char *buf, size_t size)
{ OpenObject h = handle;
Any argv[2];
CharArray sub;
int chread;
size_t advance;
if ( isFreedObj(h->object) )
{ errno = EIO;
return -1;
}
if ( h->encoding == ENC_WCHAR )
{ advance = size/sizeof(wchar_t);
} else if ( h->encoding == ENC_OCTET )
{ advance = size;
} else
{ assert(0);
errno = EIO;
return -1;
}
argv[0] = toInt(h->point);
argv[1] = toInt(advance);
if ( (sub = getv(h->object, NAME_readAsFile, 2, argv)) &&
instanceOfObject(sub, ClassCharArray) )
{ String s = &sub->data;
assert(s->size <= advance);
if ( h->encoding == ENC_WCHAR )
{ if ( isstrA(s) )
{ charW *dest = (charW*)buf;
const charA *f = s->s_textA;
const charA *e = &f[s->size];
while(f<e)
*dest++ = *f++;
} else
{ memcpy(buf, s->s_textW, s->size*sizeof(charW));
}
chread = s->size * sizeof(wchar_t);
} else
{ if ( isstrA(s) )
{ memcpy(buf, s->s_textA, s->size);
} else
{ errno = EIO;
chread = -1;
}
chread = s->size;
}
h->point += s->size;
} else
{ errno = EIO;
chread = -1;
}
return chread;
}
GraphData * ProcWave2Data(QString fname)
{
SPTK_SETTINGS * sptk_settings = SettingsDialog::getSPTKsettings();
QFile file(fname);
file.open(QIODevice::ReadOnly);
WaveFile * waveFile = waveOpenHFile(file.handle());
qDebug() << "waveOpenFile" << LOG_DATA;
int size = littleEndianBytesToUInt32(waveFile->dataChunk->chunkDataSize);
qDebug() << "chunkDataSize" << LOG_DATA;
short int bits = littleEndianBytesToUInt16(waveFile->formatChunk->significantBitsPerSample);
qDebug() << "significantBitsPerSample" << LOG_DATA;
vector wave = sptk_v2v(waveFile->dataChunk->waveformData, size, bits);
qDebug() << "wave" << LOG_DATA;
vector frame = sptk_frame(wave, sptk_settings->frame);
qDebug() << "frame" << LOG_DATA;
vector intensive = vector_intensive(frame, sptk_settings->frame->leng, sptk_settings->frame->shift);
qDebug() << "intensive" << LOG_DATA;
vector window = sptk_window(frame, sptk_settings->window);
qDebug() << "window" << LOG_DATA;
vector lpc = sptk_lpc(frame, sptk_settings->lpc);
qDebug() << "lpc" << LOG_DATA;
vector spec = sptk_spec(lpc, sptk_settings->spec);
qDebug() << "spec " << maxv(spec) << LOG_DATA;
vector spec_proc;
if (sptk_settings->spec->proc == 0){
spec_proc = vector_pow_log(spec, sptk_settings->spec->factor, sptk_settings->spec->min);
qDebug() << "spec_log" << LOG_DATA;
} else if (sptk_settings->spec->proc == 1){
spec_proc = vector_pow_exp(spec, sptk_settings->spec->factor, sptk_settings->spec->min);
qDebug() << "spec_exp" << LOG_DATA;
}
qDebug() << "spec_proc " << maxv(spec_proc) << LOG_DATA;
vector pitch = processZeros(sptk_pitch_spec(wave, sptk_settings->pitch, intensive.x));
qDebug() << "pitch" << LOG_DATA;
vector mask = getFileMask(waveFile, wave, pitch.x);
qDebug() << "mask" << LOG_DATA;
vector pitch_cutted = processZeros(vector_cut_by_mask(pitch, mask));
qDebug() << "pitch_cutted" << LOG_DATA;
double pitch_min = getv(pitch_cutted, minv(pitch_cutted));
double pitch_max = getv(pitch_cutted, maxv(pitch_cutted));
vector intensive_cutted = vector_cut_by_mask(intensive, mask);
qDebug() << "intensive_cutted" << LOG_DATA;
vector inverted_mask = vector_invert_mask(mask);
qDebug() << "inverted_mask" << LOG_DATA;
vector pitch_interpolate = vector_interpolate_by_mask(
pitch_cutted,
inverted_mask,
0,
sptk_settings->plotF0->interpolation_type
);
qDebug() << "pitch_interpolate" << LOG_DATA;
vector intensive_interpolate = vector_interpolate_by_mask(
intensive_cutted,
inverted_mask,
0,
sptk_settings->plotEnergy->interpolation_type
);
qDebug() << "intensive_interpolate" << LOG_DATA;
vector pitch_mid = vector_smooth_mid(pitch_interpolate, sptk_settings->plotF0->frame);
qDebug() << "pitch_mid" << LOG_DATA;
vector intensive_mid = vector_smooth_lin(intensive_interpolate, sptk_settings->plotEnergy->frame);
qDebug() << "intensive_mid" << LOG_DATA;
vector norm_wave = normalizev(wave, 0.0, 1.0);
MaskData md_p = getLabelsFromFile(waveFile, MARK_PRE_NUCLEUS);
MaskData md_n = getLabelsFromFile(waveFile, MARK_NUCLEUS);
MaskData md_t = getLabelsFromFile(waveFile, MARK_POST_NUCLEUS);
vector p_mask = readMaskFromFile(waveFile, wave.x, MARK_PRE_NUCLEUS);
qDebug() << "p_mask" << LOG_DATA;
vector n_mask = readMaskFromFile(waveFile, wave.x, MARK_NUCLEUS);
qDebug() << "n_mask" << LOG_DATA;
vector t_mask = readMaskFromFile(waveFile, wave.x, MARK_POST_NUCLEUS);
qDebug() << "t_mask" << LOG_DATA;
vector p_wave = zero_to_nan(vector_cut_by_mask(norm_wave, p_mask));
qDebug() << "p_mask" << LOG_DATA;
vector n_wave = zero_to_nan(vector_cut_by_mask(norm_wave, n_mask));
qDebug() << "n_mask" << LOG_DATA;
vector t_wave = zero_to_nan(vector_cut_by_mask(norm_wave, t_mask));
qDebug() << "t_mask" << LOG_DATA;
vector pnt_mask = onesv(norm_wave.x);
for (int i=0; i<p_mask.x && i<n_mask.x && i<t_mask.x && i<norm_wave.x; i++) {
if (getv(p_mask, i) == 1 || getv(n_mask, i) == 1 || getv(t_mask, i) == 1)
{
setv(pnt_mask, i, 0);
} else {
setv(pnt_mask, i, 1);
}
}
vector display_wave = zero_to_nan(vector_cut_by_mask(norm_wave, pnt_mask));
freev(frame);
freev(window);
freev(lpc);
freev(pitch_cutted);
freev(intensive_cutted);
freev(inverted_mask);
freev(pitch_interpolate);
freev(intensive_interpolate);
freev(wave);
qDebug() << "freev" << LOG_DATA;
file.close();
waveCloseFile(waveFile);
qDebug() << "waveCloseFile" << LOG_DATA;
GraphData * data = new GraphData();
data->d_full_wave = norm_wave;
data->d_wave = display_wave;
data->d_p_wave = p_wave;
data->d_n_wave = n_wave;
data->d_t_wave = t_wave;
data->d_pitch_original = pitch;
data->d_pitch = pitch_mid;
data->pitch_max = pitch_max;
data->pitch_min = pitch_min;
data->d_intensive_original = intensive;
data->d_intensive = intensive_mid;
data->d_spec_proc = spec_proc;
data->d_spec = spec;
data->d_mask = mask;
data->p_mask = p_mask;
data->n_mask = n_mask;
data->t_mask = t_mask;
data->pnt_mask = pnt_mask;
data->md_p = md_p;
data->md_t = md_t;
data->md_n = md_n;
return data;
}
static void advance(struct rnc_source *sp) {
sp->cur=!sp->cur;
for(;;) {
NXT(sp).line=sp->line; NXT(sp).col=sp->col;
if(newline(sp->v)||whitespace(sp->v)) {getv(sp); continue;}
switch(sp->v) {
case -1: NXT(sp).sym=SYM_EOF; return;
case '#':
getv(sp);
if(sp->v=='#') {
int i=0;
for(;;) {
do getv(sp); while(sp->v=='#');
if(whitespace(sp->v)) getv(sp);
for(;;) {
if(i+U_MAXLEN>NXT(sp).slen) realloc_s(&NXT(sp),2*(i+U_MAXLEN));
if(newline(sp->v)) {
do getv(sp); while(whitespace(sp->v));
if(sp->v=='#') {getv(sp);
if(sp->v=='#') {NXT(sp).s[i++]='\n'; break;}
skip_comment(sp);
}
NXT(sp).s[i]=0; NXT(sp).sym=SYM_DOCUMENTATION; return;
} else i+=u_put(NXT(sp).s+i,sp->v);
getv(sp);
}
}
} else {skip_comment(sp); continue;}
case '=': getv(sp); NXT(sp).sym=SYM_ASGN; return;
case ',': getv(sp); NXT(sp).sym=SYM_GROUP; return;
case '|': getv(sp);
if(sp->v=='=') {
getv(sp); NXT(sp).sym=SYM_ASGN_CHOICE; return;
} NXT(sp).sym=SYM_CHOICE; return;
case '&': getv(sp);
if(sp->v=='=') {getv(sp); NXT(sp).sym=SYM_ASGN_ILEAVE;} else NXT(sp).sym=SYM_ILEAVE; return;
case '?': getv(sp); NXT(sp).sym=SYM_OPTIONAL; return;
case '*': getv(sp); NXT(sp).sym=SYM_ZERO_OR_MORE; return; /* SYM_ANY_NAME */
case '+': getv(sp); NXT(sp).sym=SYM_ONE_OR_MORE; return;
case '-': getv(sp); NXT(sp).sym=SYM_EXCEPT; return;
case '~': getv(sp); NXT(sp).sym=SYM_CONCAT; return;
case '(': getv(sp); NXT(sp).sym=SYM_LPAR; return;
case ')': getv(sp); NXT(sp).sym=SYM_RPAR; return;
case '{': getv(sp); NXT(sp).sym=SYM_LCUR; return;
case '}': getv(sp); NXT(sp).sym=SYM_RCUR; return;
case '[': getv(sp); NXT(sp).sym=SYM_LSQU; return;
case ']': getv(sp); NXT(sp).sym=SYM_RSQU; return;
case '>': getv(sp);
if(sp->v!='>') error(0,sp,RNC_ER_LEXP,sp->fn,sp->line,sp->col,'>');
getv(sp); NXT(sp).sym=SYM_FOLLOW_ANNOTATION; return;
case '"': case '\'':
{ int q=sp->v;
int triple=0;
int i=0;
getv(sp);
if(sp->v==q) {getv(sp);
if(sp->v==q) { /* triply quoted string */
triple=1; getv(sp);
} else {
NXT(sp).s[0]='\0'; NXT(sp).sym=SYM_LITERAL; return;
}
}
for(;;) {
if(sp->v==q) {
if(triple) {
if(i>=2 && NXT(sp).s[i-2]==q && NXT(sp).s[i-1]==q) {
NXT(sp).s[i-2]='\0'; break;
} else i+=u_put(NXT(sp).s+i,sp->v);
} else {NXT(sp).s[i]='\0'; break;}
} else if(sp->v<=0) {
if(sp->v==-1 || !triple) {
error(0,sp,RNC_ER_LLIT,sp->fn,sp->line,sp->col);
NXT(sp).s[i]='\0'; break;
} else NXT(sp).s[i++]='\n';
} else i+=u_put(NXT(sp).s+i,sp->v);
getv(sp);
if(i+U_MAXLEN>NXT(sp).slen) realloc_s(&NXT(sp),2*(i+U_MAXLEN));
}
getv(sp); NXT(sp).sym=SYM_LITERAL; return;
}
default:
{ int escaped=0,prefixed=0;
if(sp->v=='\\') {escaped=1; getv(sp);}
if(name_start(sp->v)) {
int i=0;
for(;;) {
i+=u_put(NXT(sp).s+i,sp->v);
if(i+U_MAXLEN>NXT(sp).slen) realloc_s(&NXT(sp),2*(i+U_MAXLEN));
getv(sp);
if(!name_char(sp->v)) {NXT(sp).s[i]='\0'; break;}
if(sp->v==':') prefixed=1;
}
if(!(escaped||prefixed)) {
int kwd;
if((kwd=s_tab(NXT(sp).s,kwdtab,NKWD))!=NKWD) {
NXT(sp).sym=kwd;
return;
}
}
if(prefixed) {
if(NXT(sp).s[i-1]==':'&&sp->v=='*') {
getv(sp); NXT(sp).s[i-1]='\0';
NXT(sp).sym=SYM_NSNAME;
} else NXT(sp).sym=SYM_QNAME;
} else NXT(sp).sym=SYM_IDENT;
return;
} else {
error(0,sp,RNC_ER_LILL,sp->fn,sp->line,sp->col,sp->v);
getv(sp);
continue;
}
}
}
}
}
int
main(int argc, char *argv[])
{
struct QOP_MDWF_State *mdwf_state = NULL;
QMP_thread_level_t qt = QMP_THREAD_SINGLE;
int status = 1;
int vx[4];
int i;
if (QMP_init_msg_passing(&argc, &argv, qt, &qt) != QMP_SUCCESS) {
fprintf(stderr, "QMP_init() failed\n");
return 1;
}
for (i = 0; i < NELEM(b5); i++) {
b5[i] = 0.1 * i * (NELEM(b5) - i);
c5[i] = 0.1 * i * i * (NELEM(b5) - i);
}
self = QMP_get_node_number();
primary = QMP_is_primary_node();
for (i = 0; i < argc; i++)
zprint("arg[%d]=%s", i, argv[i]);
if (argc != 14) {
zprint("14 arguments expected, found %d", argc);
QMP_finalize_msg_passing();
return 1;
}
for (i = 0; i < 4; i++) {
mynetwork[i] = atoi(argv[i+1]);
mylocal[i] = atoi(argv[i+5]);
vx[i] = atoi(argv[i+10]);
mylattice[i] = mylocal[i] * mynetwork[i];
}
mylocal[4] = mylattice[4] = atoi(argv[9]);
zshowv4("network", mynetwork);
zshowv5("local lattice", mylocal);
zshowv5("lattice", mylattice);
getv(mynode, 0, 4, vx);
xshowv("node", mynode);
if (QOP_MDWF_init(&mdwf_state,
mylattice, mynetwork, mynode, primary,
getsub, NULL)) {
zprint("MDWF_init() failed");
goto end;
}
zprint("MDWF_init() done");
dump_state(mdwf_state);
QOP_MDWF_fini(&mdwf_state);
status = 0;
end:
QMP_finalize_msg_passing();
return status;
}
int
main(int argc, char *argv[])
{
struct QOP_MDWF_State *mdwf_state = NULL;
struct QOP_MDWF_Parameters *mdwf_params = NULL;
QMP_thread_level_t qt = QMP_THREAD_SINGLE;
int status = 1;
int i;
if (QMP_init_msg_passing(&argc, &argv, qt, &qt) != QMP_SUCCESS) {
fprintf(stderr, "QMP_init() failed\n");
return 1;
}
for (i = 0; i < NELEM(b5); i++) {
b5[i] = 0.1 * i * (NELEM(b5) - i);
c5[i] = 0.1 * i * i * (NELEM(b5) - i);
}
self = QMP_get_node_number();
primary = QMP_is_primary_node();
if (argc != 7) {
zprint("7 arguments expected, found %d", argc);
zprint("usage: localheat Lx Ly Lz Lt Ls time");
QMP_finalize_msg_passing();
return 1;
}
for (i = 0; i < 4; i++) {
mynetwork[i] = 1;
mylocal[i] = atoi(argv[i+1]);
mylattice[i] = mylocal[i] * mynetwork[i];
}
mylocal[4] = mylattice[4] = atoi(argv[5]);
total_sec = atoi(argv[6]);
zshowv4("network", mynetwork);
zshowv5("local lattice", mylocal);
zshowv5("lattice", mylattice);
zprint("total requested runtime %.0f sec", total_sec);
#if 0
if (QMP_declare_logical_topology(mynetwork, 4) != QMP_SUCCESS) {
zprint("declare_logical_top failed");
goto end;
}
getv(mynode, 0, QMP_get_logical_number_of_dimensions(),
QMP_get_logical_coordinates());
#else
{ int i;
for (i = 0; i < 4; i++)
mynode[i] = 0;
}
#endif
if (QOP_MDWF_init(&mdwf_state,
mylattice, mynetwork, mynode, primary,
getsub, NULL)) {
zprint("MDWF_init() failed");
goto end;
}
zprint("MDWF_init() done");
if (QOP_MDWF_set_generic(&mdwf_params, mdwf_state, b5, c5, 0.123, 0.05)) {
zprint("MDW_set_generic() failed");
goto end;
}
zprint("MDWF_set_generic() done");
if (do_run(mdwf_state, mdwf_params)) {
zprint("float test failed");
goto end;
}
QOP_MDWF_fini(&mdwf_state);
zprint("Heater test finished");
status = 0;
end:
QMP_finalize_msg_passing();
return status;
}
static void exp3g(int n0, cgraph ** c)
{
int n1, n2, n4, n5;
int e04, e05, e45;
cgraph * cg=*c;
/* expand 3G vertex (see figure) - 08/01/90 */
/* 14/03/99: Check tadpole before expanding */
# if (CDEBLEV > DEBLEV)
fprintf(stderr,".......Exp3G........\n");
# endif
n1 = findl(1,n0,cg);
if (istadpole(n0,cg) || istadpole(n1,cg))
{
cg->sgn=0;
cg->gl = 0;
cg->vl[n0-1].vt = zv;
cg->vl[n1-1].vt = zv;
# if (CDEBLEV > DEBLEV)
wrcg(cg);
# endif
return;
}
n1 = findl(1,n0,cg); /* v0 v4 v5 */
n2 = findl(2,n0,cg); /* v1..*...v2 v1..*-<-*..v2 */
/* : \ / */
n4 = getv(cg); /* : -> *v0 */
e45 = ++(cg->en); /* : : */
e04 = ++(cg->en); /* v3 v3 */
cg->vl[n4-1].vt = qg;
if (cg->vl[n1-1].vt == g3)
rev3g(cg->vl[n0-1].e[0],&cg->vl[n1-1]);
cg->vl[n4-1].e[0] = cg->vl[n1-1].e[0];
cg->vl[n4-1].e[1] = e45;
cg->vl[n4-1].e[2] = e04;
n5 = getv(cg);
e05 = ++(cg->en);
cg->vl[n5-1].vt = qg;
if (cg->vl[n2-1].vt == g3)
rev3g(cg->vl[n0-1].e[1],&cg->vl[n2-1]);
cg->vl[n5-1].e[0] = cg->vl[n2-1].e[0];
cg->vl[n5-1].e[1] = e05;
cg->vl[n5-1].e[2] = e45;
rev3g(cg->vl[n0-1].e[2],&cg->vl[n0-1]);
cg->vl[n0-1].vt = qg;
cg->vl[n0-1].e[1] = e04;
cg->vl[n0-1].e[2] = e05;
cg->sgn*=-1;
cg->pow2++;
cg=addcg(c); /* Second term */
cg->vl[n0-1].e[1] = e05;
cg->vl[n0-1].e[2] = e04;
cg->vl[n4-1].e[1] = e04;
cg->vl[n4-1].e[2] = e45;
cg->vl[n5-1].e[1] = e45;
cg->vl[n5-1].e[2] = e05;
cg->sgn*=-1;
# if (CDEBLEV > DEBLEV)
wrcg(cg);
wrcg(cg->next);
fprintf(stderr,".......end Exp3G........\n");
# endif
} /* Exp3G */
/*VARARGS 1*/
void
execute(struct command *t, volatile int wanttty, int *pipein, int *pipeout,
int do_glob)
{
int forked = 0;
const struct biltins * volatile bifunc;
pid_t pid = 0;
int pv[2];
sigset_t set;
static sigset_t csigset;
#ifdef VFORK
static int onosigchld = 0;
#endif /* VFORK */
static int nosigchld = 0;
(void) &wanttty;
(void) &forked;
(void) &bifunc;
if (t == 0)
return;
#ifdef WINNT_NATIVE
{
if ((varval(STRNTslowexec) == STRNULL) &&
!t->t_dcdr && !t->t_dcar && !t->t_dflg && !didfds &&
(intty || intact) && (t->t_dtyp == NODE_COMMAND) &&
!isbfunc(t)) {
if ((t->t_dcom[0][0] & (QUOTE | TRIM)) == QUOTE)
(void) Strcpy(t->t_dcom[0], t->t_dcom[0] + 1);
Dfix(t);
if (nt_try_fast_exec(t) == 0)
return;
}
}
#endif /* WINNT_NATIVE */
/*
* Ed [email protected] & Dominic [email protected]
* Sat Feb 25 03:13:11 PST 1995
* try implicit cd if we have a 1 word command
*/
if (implicit_cd && (intty || intact) && t->t_dcom && t->t_dcom[0] &&
t->t_dcom[0][0] && (blklen(t->t_dcom) == 1) && !noexec) {
Char *sCName;
struct stat stbuf;
char *pathname;
sCName = dollar(t->t_dcom[0]);
if (sCName != NULL && sCName[0] == '~') {
struct Strbuf buf = Strbuf_INIT;
const Char *name_end;
for (name_end = sCName + 1; *name_end != '\0' && *name_end != '/';
name_end++)
continue;
if (name_end != sCName + 1) {
Char *name, *home;
name = Strnsave(sCName + 1, name_end - (sCName + 1));
home = gethdir(name);
if (home != NULL) {
Strbuf_append(&buf, home);
xfree(home);
} else
Strbuf_append(&buf, name);
xfree(name);
} else
Strbuf_append(&buf, varval(STRhome));
Strbuf_append(&buf, name_end);
xfree(sCName);
sCName = Strbuf_finish(&buf);
}
pathname = short2str(sCName);
xfree(sCName);
/* if this is a dir, tack a "cd" on as the first arg */
if (pathname != NULL &&
((stat(pathname, &stbuf) != -1 && S_ISDIR(stbuf.st_mode))
#ifdef WINNT_NATIVE
|| (pathname[0] && pathname[1] == ':' && pathname[2] == '\0')
#endif /* WINNT_NATIVE */
)) {
Char *vCD[2];
Char **ot_dcom = t->t_dcom;
vCD[0] = Strsave(STRcd);
vCD[1] = NULL;
t->t_dcom = blkspl(vCD, ot_dcom);
xfree(ot_dcom);
if (implicit_cd > 1) {
blkpr(t->t_dcom);
xputchar( '\n' );
}
}
}
/*
* From: Michael Schroeder <*****@*****.**>
* Don't check for wantty > 0...
*/
if (t->t_dflg & F_AMPERSAND)
wanttty = 0;
switch (t->t_dtyp) {
case NODE_COMMAND:
if ((t->t_dcom[0][0] & (QUOTE | TRIM)) == QUOTE)
memmove(t->t_dcom[0], t->t_dcom[0] + 1,
(Strlen(t->t_dcom[0] + 1) + 1) * sizeof (*t->t_dcom[0]));
if ((t->t_dflg & F_REPEAT) == 0)
Dfix(t); /* $ " ' \ */
if (t->t_dcom[0] == 0) {
return;
}
/*FALLTHROUGH*/
case NODE_PAREN:
#ifdef BACKPIPE
if (t->t_dflg & F_PIPEIN)
mypipe(pipein);
#else /* !BACKPIPE */
if (t->t_dflg & F_PIPEOUT)
mypipe(pipeout);
#endif /* BACKPIPE */
/*
* Must do << early so parent will know where input pointer should be.
* If noexec then this is all we do.
*/
if (t->t_dflg & F_READ) {
xclose(0);
heredoc(t->t_dlef);
if (noexec)
xclose(0);
}
setcopy(STRstatus, STR0, VAR_READWRITE);
/*
* This mess is the necessary kludge to handle the prefix builtins:
* nice, nohup, time. These commands can also be used by themselves,
* and this is not handled here. This will also work when loops are
* parsed.
*/
while (t->t_dtyp == NODE_COMMAND)
if (eq(t->t_dcom[0], STRnice)) {
if (t->t_dcom[1]) {
if (strchr("+-", t->t_dcom[1][0])) {
if (t->t_dcom[2]) {
setname("nice");
t->t_nice = (unsigned char)getn(t->t_dcom[1]);
lshift(t->t_dcom, 2);
t->t_dflg |= F_NICE;
}
else
break;
}
else {
t->t_nice = 4;
lshift(t->t_dcom, 1);
t->t_dflg |= F_NICE;
}
}
else
break;
}
else if (eq(t->t_dcom[0], STRnohup)) {
if (t->t_dcom[1]) {
t->t_dflg |= F_NOHUP;
lshift(t->t_dcom, 1);
}
else
break;
}
else if (eq(t->t_dcom[0], STRhup)) {
if (t->t_dcom[1]) {
t->t_dflg |= F_HUP;
lshift(t->t_dcom, 1);
}
else
break;
}
else if (eq(t->t_dcom[0], STRtime)) {
if (t->t_dcom[1]) {
t->t_dflg |= F_TIME;
lshift(t->t_dcom, 1);
}
else
break;
}
#ifdef F_VER
else if (eq(t->t_dcom[0], STRver))
if (t->t_dcom[1] && t->t_dcom[2]) {
setname("ver");
t->t_systype = getv(t->t_dcom[1]);
lshift(t->t_dcom, 2);
t->t_dflg |= F_VER;
}
else
break;
#endif /* F_VER */
else
break;
/* is it a command */
if (t->t_dtyp == NODE_COMMAND) {
/*
* Check if we have a builtin function and remember which one.
*/
bifunc = isbfunc(t);
if (noexec) {
/*
* Continue for builtins that are part of the scripting language
*/
if (bifunc == NULL)
break;
if (bifunc->bfunct != (bfunc_t)dobreak &&
bifunc->bfunct != (bfunc_t)docontin &&
bifunc->bfunct != (bfunc_t)doelse &&
bifunc->bfunct != (bfunc_t)doend &&
bifunc->bfunct != (bfunc_t)doforeach&&
bifunc->bfunct != (bfunc_t)dogoto &&
bifunc->bfunct != (bfunc_t)doif &&
bifunc->bfunct != (bfunc_t)dorepeat &&
bifunc->bfunct != (bfunc_t)doswbrk &&
bifunc->bfunct != (bfunc_t)doswitch &&
bifunc->bfunct != (bfunc_t)dowhile &&
bifunc->bfunct != (bfunc_t)dozip)
break;
}
}
else { /* not a command */
bifunc = NULL;
if (noexec)
break;
}
/*
* GrP Executing a command - run jobcmd hook
* Don't run for builtins
* Don't run if we're not in a tty
* Don't run if we're not really executing
*/
/*
* CR - Charles Ross Aug 2005
* added "isoutatty".
* The new behavior is that the jobcmd won't be executed
* if stdout (SHOUT) isnt attached to a tty.. IE when
* redirecting, or using backquotes etc..
*/
if (t->t_dtyp == NODE_COMMAND && !bifunc && !noexec && intty && isoutatty) {
Char *cmd = unparse(t);
cleanup_push(cmd, xfree);
job_cmd(cmd);
cleanup_until(cmd);
}
/*
* We fork only if we are timed, or are not the end of a parenthesized
* list and not a simple builtin function. Simple meaning one that is
* not pipedout, niced, nohupped, or &'d. It would be nice(?) to not
* fork in some of these cases.
*/
#ifdef BACKPIPE
/*
* Can't have NOFORK for the tail of a pipe - because it is not the
* last command spawned (even if it is at the end of a parenthesised
* list).
*/
if (t->t_dflg & F_PIPEIN)
t->t_dflg &= ~(F_NOFORK);
#else
/*
* "command | builtin" may cause major misbehaviour as noted in
* in the BUGS file entry
* Subject: Redirected input to built-in functions misbehaves badly
* forking when the builtin is the end of the pipe corrects the
* problem.
*/
if (bifunc && (t->t_dflg & F_PIPEIN))
t->t_dflg &= ~(F_NOFORK);
#endif /* BACKPIPE */
/*
* Prevent forking cd, pushd, popd, chdir cause this will cause the
* shell not to change dir! (XXX: but only for nice?)
*/
if (bifunc && (bifunc->bfunct == (bfunc_t)dochngd ||
bifunc->bfunct == (bfunc_t)dopushd ||
bifunc->bfunct == (bfunc_t)dopopd))
t->t_dflg &= ~(F_NICE);
if (((t->t_dflg & F_TIME) || ((t->t_dflg & F_NOFORK) == 0 &&
(!bifunc || t->t_dflg &
(F_PIPEOUT | F_AMPERSAND | F_NICE | F_NOHUP | F_HUP)))) ||
/*
* We have to fork for eval too.
*/
(bifunc && (t->t_dflg & F_PIPEIN) != 0 &&
bifunc->bfunct == (bfunc_t)doeval)) {
#ifdef VFORK
if (t->t_dtyp == NODE_PAREN ||
t->t_dflg & (F_REPEAT | F_AMPERSAND) || bifunc)
#endif /* VFORK */
{
forked++;
/*
* We need to block SIGCHLD here, so that if the process does
* not die before we can set the process group
*/
if (wanttty >= 0 && !nosigchld) {
sigemptyset(&set);
sigaddset(&set, SIGCHLD);
(void)sigprocmask(SIG_BLOCK, &set, &csigset);
nosigchld = 1;
}
pid = pfork(t, wanttty);
if (pid == 0 && nosigchld) {
sigprocmask(SIG_SETMASK, &csigset, NULL);
nosigchld = 0;
}
else if (pid != 0 && (t->t_dflg & F_AMPERSAND))
backpid = pid;
}
#ifdef VFORK
else {
int ochild, osetintr, ohaderr, odidfds;
int oSHIN, oSHOUT, oSHDIAG, oOLDSTD, otpgrp;
int oisoutatty, oisdiagatty;
sigset_t oset, ocsigset;
# ifndef CLOSE_ON_EXEC
int odidcch;
# endif /* !CLOSE_ON_EXEC */
/*
* Prepare for the vfork by saving everything that the child
* corrupts before it exec's. Note that in some signal
* implementations which keep the signal info in user space
* (e.g. Sun's) it will also be necessary to save and restore
* the current sigvec's for the signals the child touches
* before it exec's.
*/
/*
* Sooooo true... If this is a Sun, save the sigvec's. (Skip
* Gilbrech - 11/22/87)
*/
# ifdef SAVESIGVEC
struct sigaction savesv[NSIGSAVED];
sigset_t savesm;
# endif /* SAVESIGVEC */
if (wanttty >= 0 && !nosigchld && !noexec) {
sigemptyset(&set);
sigaddset(&set, SIGCHLD);
(void)sigprocmask(SIG_BLOCK, &set, &csigset);
nosigchld = 1;
}
sigemptyset(&set);
sigaddset(&set, SIGCHLD);
sigaddset(&set, SIGINT);
(void)sigprocmask(SIG_BLOCK, &set, &oset);
ochild = child;
osetintr = setintr;
ohaderr = haderr;
odidfds = didfds;
# ifndef CLOSE_ON_EXEC
odidcch = didcch;
# endif /* !CLOSE_ON_EXEC */
oSHIN = SHIN;
oSHOUT = SHOUT;
oSHDIAG = SHDIAG;
oOLDSTD = OLDSTD;
otpgrp = tpgrp;
oisoutatty = isoutatty;
oisdiagatty = isdiagatty;
ocsigset = csigset;
onosigchld = nosigchld;
Vsav = Vdp = 0;
Vexpath = 0;
Vt = 0;
# ifdef SAVESIGVEC
savesigvec(savesv, savesm);
# endif /* SAVESIGVEC */
if (use_fork)
pid = fork();
else
pid = vfork();
if (pid < 0) {
# ifdef SAVESIGVEC
restoresigvec(savesv, savesm);
# endif /* SAVESIGVEC */
sigprocmask(SIG_SETMASK, &oset, NULL);
stderror(ERR_NOPROC);
}
forked++;
if (pid) { /* parent */
# ifdef SAVESIGVEC
restoresigvec(savesv, savesm);
# endif /* SAVESIGVEC */
child = ochild;
setintr = osetintr;
haderr = ohaderr;
didfds = odidfds;
SHIN = oSHIN;
# ifndef CLOSE_ON_EXEC
didcch = odidcch;
# endif /* !CLOSE_ON_EXEC */
SHOUT = oSHOUT;
SHDIAG = oSHDIAG;
OLDSTD = oOLDSTD;
tpgrp = otpgrp;
isoutatty = oisoutatty;
isdiagatty = oisdiagatty;
csigset = ocsigset;
nosigchld = onosigchld;
xfree(Vsav);
Vsav = 0;
xfree(Vdp);
Vdp = 0;
xfree(Vexpath);
Vexpath = 0;
blk_cleanup(Vt);
Vt = 0;
/* this is from pfork() */
palloc(pid, t);
sigprocmask(SIG_SETMASK, &oset, NULL);
}
else { /* child */
/* this is from pfork() */
pid_t pgrp;
int ignint = 0;
if (nosigchld) {
sigprocmask(SIG_SETMASK, &csigset, NULL);
nosigchld = 0;
}
if (setintr)
ignint = (tpgrp == -1 && (t->t_dflg & F_NOINTERRUPT))
|| (gointr && eq(gointr, STRminus));
pgrp = pcurrjob ? pcurrjob->p_jobid : getpid();
child++;
if (setintr) {
setintr = 0;
/*
* casts made right for SunOS 4.0 by Douglas C. Schmidt
* <*****@*****.**>
* (thanks! -- PWP)
*
* ignint ifs cleaned by Johan Widen <[email protected]>
* (thanks again)
*/
if (ignint) {
(void) signal(SIGINT, SIG_IGN);
(void) signal(SIGQUIT, SIG_IGN);
}
else {
(void) signal(SIGINT, vffree);
(void) signal(SIGQUIT, SIG_DFL);
}
# ifdef BSDJOBS
if (wanttty >= 0) {
(void) signal(SIGTSTP, SIG_DFL);
(void) signal(SIGTTIN, SIG_DFL);
(void) signal(SIGTTOU, SIG_DFL);
}
# endif /* BSDJOBS */
sigaction(SIGTERM, &parterm, NULL);
}
else if (tpgrp == -1 &&
(t->t_dflg & F_NOINTERRUPT)) {
(void) signal(SIGINT, SIG_IGN);
(void) signal(SIGQUIT, SIG_IGN);
}
pgetty(wanttty, pgrp);
if (t->t_dflg & F_NOHUP)
(void) signal(SIGHUP, SIG_IGN);
if (t->t_dflg & F_HUP)
(void) signal(SIGHUP, SIG_DFL);
if (t->t_dflg & F_NICE) {
int nval = SIGN_EXTEND_CHAR(t->t_nice);
# if defined(HAVE_SETPRIORITY) && defined(PRIO_PROCESS)
if (setpriority(PRIO_PROCESS, 0, nval) == -1 && errno)
stderror(ERR_SYSTEM, "setpriority",
strerror(errno));
# else /* !HAVE_SETPRIORITY || !PRIO_PROCESS */
(void) nice(nval);
# endif /* HAVE_SETPRIORITY && PRIO_PROCESS */
}
# ifdef F_VER
if (t->t_dflg & F_VER) {
tsetenv(STRSYSTYPE, t->t_systype ? STRbsd43 : STRsys53);
dohash(NULL, NULL);
}
# endif /* F_VER */
}
}
#endif /* VFORK */
}
if (pid != 0) {
/*
* It would be better if we could wait for the whole job when we
* knew the last process had been started. Pwait, in fact, does
* wait for the whole job anyway, but this test doesn't really
* express our intentions.
*/
#ifdef BACKPIPE
if (didfds == 0 && t->t_dflg & F_PIPEOUT) {
xclose(pipeout[0]);
xclose(pipeout[1]);
}
if ((t->t_dflg & F_PIPEIN) != 0)
break;
#else /* !BACKPIPE */
if (didfds == 0 && t->t_dflg & F_PIPEIN) {
xclose(pipein[0]);
xclose(pipein[1]);
}
if ((t->t_dflg & F_PIPEOUT) != 0)
break;
#endif /* BACKPIPE */
if (nosigchld) {
sigprocmask(SIG_SETMASK, &csigset, NULL);
nosigchld = 0;
}
if ((t->t_dflg & F_AMPERSAND) == 0)
pwait();
break;
}
doio(t, pipein, pipeout);
#ifdef BACKPIPE
if (t->t_dflg & F_PIPEIN) {
xclose(pipein[0]);
xclose(pipein[1]);
}
#else /* !BACKPIPE */
if (t->t_dflg & F_PIPEOUT) {
xclose(pipeout[0]);
xclose(pipeout[1]);
}
#endif /* BACKPIPE */
/*
* Perform a builtin function. If we are not forked, arrange for
* possible stopping
*/
if (bifunc) {
if (forked) {
func(t, bifunc);
exitstat();
} else {
jmp_buf_t oldexit;
int ohaderr = haderr;
getexit(oldexit);
if (setexit() == 0)
func(t, bifunc);
resexit(oldexit);
haderr = ohaderr;
if (adrof(STRprintexitvalue)) {
int rv = getn(varval(STRstatus));
if (rv != 0)
xprintf(CGETS(17, 2, "Exit %d\n"), rv);
}
}
break;
}
if (t->t_dtyp != NODE_PAREN) {
doexec(t, do_glob);
/* NOTREACHED */
}
/*
* For () commands must put new 0,1,2 in FSH* and recurse
*/
if ((OLDSTD = dcopy(0, FOLDSTD)) >= 0)
(void)close_on_exec(OLDSTD, 1);
if ((SHOUT = dcopy(1, FSHOUT)) >= 0) {
(void)close_on_exec(SHOUT, 1);
isoutatty = isatty(SHOUT);
}
if ((SHDIAG = dcopy(2, FSHDIAG)) >= 0) {
(void)close_on_exec(SHDIAG, 1);
isdiagatty = isatty(SHDIAG);
}
xclose(SHIN);
SHIN = -1;
#ifndef CLOSE_ON_EXEC
didcch = 0;
#else
(void) close_on_exec(FSHOUT, 1);
(void) close_on_exec(FSHDIAG, 1);
(void) close_on_exec(FOLDSTD, 1);
#endif /* !CLOSE_ON_EXEC */
didfds = 0;
wanttty = -1;
t->t_dspr->t_dflg |= t->t_dflg & (F_NOINTERRUPT | F_BACKQ);
execute(t->t_dspr, wanttty, NULL, NULL, do_glob);
exitstat();
case NODE_PIPE:
#ifdef BACKPIPE
t->t_dcdr->t_dflg |= F_PIPEIN | (t->t_dflg &
(F_PIPEOUT | F_AMPERSAND | F_NOFORK | F_NOINTERRUPT | F_BACKQ));
execute(t->t_dcdr, wanttty, pv, pipeout, do_glob);
t->t_dcar->t_dflg |= F_PIPEOUT | (t->t_dflg &
(F_PIPEIN | F_AMPERSAND | F_STDERR | F_NOINTERRUPT | F_BACKQ));
execute(t->t_dcar, wanttty, pipein, pv, do_glob);
#else /* !BACKPIPE */
t->t_dcar->t_dflg |= F_PIPEOUT | (t->t_dflg &
(F_PIPEIN | F_AMPERSAND | F_STDERR | F_NOINTERRUPT | F_BACKQ));
execute(t->t_dcar, wanttty, pipein, pv, do_glob);
t->t_dcdr->t_dflg |= F_PIPEIN | (t->t_dflg &
(F_PIPEOUT | F_AMPERSAND | F_NOFORK | F_NOINTERRUPT | F_BACKQ));
execute(t->t_dcdr, wanttty, pv, pipeout, do_glob);
#endif /* BACKPIPE */
break;
case NODE_LIST:
if (t->t_dcar) {
t->t_dcar->t_dflg |= t->t_dflg & (F_NOINTERRUPT | F_BACKQ);
execute(t->t_dcar, wanttty, NULL, NULL, do_glob);
/*
* In strange case of A&B make a new job after A
*/
if (t->t_dcar->t_dflg & F_AMPERSAND && t->t_dcdr &&
(t->t_dcdr->t_dflg & F_AMPERSAND) == 0)
pendjob();
}
if (t->t_dcdr) {
t->t_dcdr->t_dflg |= t->t_dflg &
(F_NOFORK | F_NOINTERRUPT | F_BACKQ);
execute(t->t_dcdr, wanttty, NULL, NULL, do_glob);
}
break;
case NODE_OR:
case NODE_AND:
if (t->t_dcar) {
t->t_dcar->t_dflg |= t->t_dflg & (F_NOINTERRUPT | F_BACKQ);
execute(t->t_dcar, wanttty, NULL, NULL, do_glob);
if ((getn(varval(STRstatus)) == 0) !=
(t->t_dtyp == NODE_AND)) {
return;
}
}
if (t->t_dcdr) {
t->t_dcdr->t_dflg |= t->t_dflg &
(F_NOFORK | F_NOINTERRUPT | F_BACKQ);
execute(t->t_dcdr, wanttty, NULL, NULL, do_glob);
}
break;
default:
break;
}
/*
* Fall through for all breaks from switch
*
* If there will be no more executions of this command, flush all file
* descriptors. Places that turn on the F_REPEAT bit are responsible for
* doing donefds after the last re-execution
*/
if (didfds && !(t->t_dflg & F_REPEAT))
donefds();
}
WaveFile * markOutFileByA0Integral(SimpleGraphData *data)
{
SPTK_SETTINGS * sptk_settings = SettingsDialog::getSPTKsettings();
WaveFile * waveFile = data->file_data;
qDebug() << "waveOpenHFile" << LOG_DATA;
int size = littleEndianBytesToUInt32(waveFile->dataChunk->chunkDataSize);
qDebug() << "file size " << size << LOG_DATA;
vector intensive = data_get_intensive_norm(data);
qDebug() << "intensive " << intensive.x << LOG_DATA;
vector intensive_smooth = data_get_intensive_smooth(data);
qDebug() << "intensive_smooth " << intensive_smooth.x << LOG_DATA;
double scaleFactor = 1.0 * size / CHAR_BIT_RECORD / intensive.x;
qDebug() << "scaleFactor " << scaleFactor << LOG_DATA;
double intensiveAbsLimit = sptk_settings->dp->markoutA0IntA0abs / 100.0;
qDebug() << "intensiveAbsLimit " << intensiveAbsLimit << LOG_DATA;
int segmentLimit = sptk_settings->dp->segmentsMinLength * RECORD_FREQ * CHAR_BIT_RECORD / 1000 / scaleFactor;
qDebug() << "segmentLimit " << segmentLimit << LOG_DATA;
Points points;
uint8_t gotIt = 0;
double intensive_value = 0.0;
double smooth_value = 0.0;
uint32_t startPosition = 0;
uint32_t stopPosition = 0;
for (uint32_t i=0; i<intensive.x; i++)
{
intensive_value = getv(intensive, i);
smooth_value = getv(intensive_smooth, i);
if (gotIt == 0 && intensive_value > smooth_value && intensive_value > intensiveAbsLimit)
{
gotIt = 1;
startPosition = i;
} else if (gotIt == 1 && (intensive_value <= smooth_value || intensive_value <= intensiveAbsLimit))
{
gotIt = 0;
stopPosition = i;
if (segmentLimit < (stopPosition - startPosition))
{
points.pointsCount++;
points = addOffset(points, scaleFactor * startPosition);
points = addLenght(points, scaleFactor * (stopPosition - startPosition));
points = addLabel(points, points.pointsCount);
}
}
}
if (gotIt == 1)
{
if (segmentLimit < (intensive.x - 1 - startPosition))
{
points.pointsCount++;
points = addOffset(points, scaleFactor * startPosition);
points = addLenght(points, scaleFactor * (intensive.x - 1 - startPosition));
points = addLabel(points, points.pointsCount);
}
}
int waveDataSize = littleEndianBytesToUInt32(waveFile->dataChunk->chunkDataSize);
char* waveData = (char*) malloc(waveDataSize);
memcpy(waveData, waveFile->dataChunk->waveformData, waveDataSize);
qDebug() << "waveData " << waveData << LOG_DATA;
qDebug() << "waveDataSize " << waveDataSize << LOG_DATA;
qDebug() << "NUMBER_OF_CHANNELS " << NUMBER_OF_CHANNELS << LOG_DATA;
qDebug() << "RECORD_FREQ " << RECORD_FREQ << LOG_DATA;
qDebug() << "SIGNIFICANT_BITS_PER_SAMPLE " << SIGNIFICANT_BITS_PER_SAMPLE << LOG_DATA;
qDebug() << "pointsCount " << points.pointsCount << LOG_DATA;
qDebug() << "pointsOffset " << points.pointsOffset << LOG_DATA;
qDebug() << "pointsLenght " << points.pointsLenght << LOG_DATA;
qDebug() << "pointsLabel " << points.pointsLabels << LOG_DATA;
return makeWaveFileFromRawData(
waveData,
waveDataSize,
NUMBER_OF_CHANNELS,
RECORD_FREQ,
SIGNIFICANT_BITS_PER_SAMPLE,
points.pointsCount,
points.pointsOffset,
points.pointsLenght,
points.pointsLabels
);
}
Points getPoints(int dataSize, vector data, double scaleFactor, double limit, int relativeLimit = DEFAULT_RELATIVE)
{
Points points;
uint8_t gotIt = 0;
uint32_t lenght = 0;
double initialLimit = limit;
int useRelative = 0;
if (relativeLimit != DEFAULT_RELATIVE)
useRelative = 1;
int isRelative = 0;
int offset = 0;
uint32_t startRelativePosition = 0;
uint32_t stopRelativePosition = 0;
for (uint32_t i=0; i<dataSize; i++)
{
double value = getv(data, i);
// Found segment end
if (((value < limit || i==(dataSize-1)) && gotIt == 1)
|| (useRelative && isRelative && i > stopRelativePosition))
{
qDebug() << "found end: " << i << " relative " << isRelative << limit << LOG_DATA;
// Add point if don't use relative or it's 2nd-gen segmant
if ((!useRelative || isRelative) && gotIt == 1)
{
points.pointsCount++;
points = addOffset(points, scaleFactor * offset);
points = addLenght(points, scaleFactor * lenght);
points = addLabel(points, points.pointsCount);
}
gotIt = 0;
// Calculate relative limit for 1st-gen segment
if (useRelative && !isRelative)
{
stopRelativePosition = i;
isRelative = 1;
limit = getRelativeLimitForSement(startRelativePosition, stopRelativePosition, data, relativeLimit);
qDebug() << "limit relative: " << limit << LOG_DATA;
i = startRelativePosition;
}
// Finish scan for 1st-gen segment, go find next one
if (useRelative && isRelative && i > stopRelativePosition)
{
isRelative = 0;
startRelativePosition = i;
stopRelativePosition = i;
limit = initialLimit;
qDebug() << "limit original: " << limit << LOG_DATA;
}
}
// It's segment, go on
if (value > limit && gotIt == 1)
{
lenght++;
}
// Found segment start
if (value > limit && gotIt == 0)
{
qDebug() << "found start: " << i << " relative " << isRelative << limit << LOG_DATA;
if (useRelative && !isRelative)
startRelativePosition = i;
gotIt = 1;
lenght = 0;
offset = i;
}
}
qDebug() << "pointsOffset size " << points.pointsCount << LOG_DATA;
return points;
}
void deriveNSfractions(bool data, int mode, bool bjet = false)
{
if (mode==0) {
for (unsigned i=0;i<binbounds.size()-1;i++)
NSfrac.push_back(1);
return;
}
if (mode==2) {
for (unsigned i=0;i<binbounds.size()-1;i++)
NSfrac.push_back(0.7);
return;
}
if (mode==4) {
for (unsigned i=0;i<binbounds.size()-1;i++)
NSfrac.push_back(1.3);
return;
}
TString fnpp;
if (bjet)
fnpp = data ? "dtppjpf" : "mcppbfa";
else
fnpp = data ? "dtppjpf" : "mcppqcd";
auto filepp = config.getfile_djt(fnpp);
seth(1,0,PI);
auto hppNS = geth("hppNS");
auto hppAS = geth("hppAS");
Fill(filepp,[&] (dict &d) {
if (bjet && !(d["discr_csvV1_1"]>0.9 && d["discr_csvV1_2"]>0.9)) return;
if (d["jtpt1"]>pt1cut && d["jtpt2"]>pt2cut && d["dphi21"]<PI13) hppNS->Fill(d["dphi21"],d["weight"]);
if (d["jtpt1"]>pt1cut && d["jtpt2"]>pt2cut && d["dphi21"]>PI23) hppAS->Fill(d["dphi21"],d["weight"]);
});
float a_pp = hppNS->Integral()/hppAS->Integral();
cout<<"a_pp "<<a_pp<<endl;
TString fnPbPb;
if (bjet)
fnPbPb = data ? "dtPbbjt" : "mcPbbfa";
else
fnPbPb = data ? "dtPbjcl" : "mcPbqcd";
auto file = config.getfile_djt(fnPbPb);
vector<TString> histn;
for (unsigned i=0;i<binbounds.size()-1;i++)
histn.push_back(Form("PbPb%d%d",binbounds[i],binbounds[i+1]));
setv(histn);
auto hPbPbNS = getv("hPbPbNS");
auto hPbPbAS = getv("hPbPbAS");
auto hPbPbNSsig = getv("hPbPbNSsig");
Fill(file,[&] (dict &d) {
int b = getbin(d["bin"]);
float w = d["weight"];
if (bjet && !(d["discr_csvV1_1"]>0.9 && d["discr_csvV1_2"]>0.9)) return;
if (bjet && d["pairCode21"]==0) w*=processweight((int)d["bProdCode"]);
if (!data && d["pthat"]<50) return;
if (d["jtpt1"]>pt1cut && d["jtpt2"]>pt2cut && d["dphi21"]<PI13) hPbPbNS[b]->Fill(d["dphi21"],d["weight"]);
if (d["jtpt1"]>pt1cut && d["jtpt2"]>pt2cut && d["dphi21"]>PI23) hPbPbAS[b]->Fill(d["dphi21"],d["weight"]);
if (!data && d["jtpt1"]>pt1cut && d["jtpt2"]>pt2cut && d["dphi21"]<PI13 && (d["subid2"]==0 && d["refpt2"]>20))
hPbPbNSsig[b]->Fill(d["dphi21"],d["weight"]);
});
vector<double> binmean;
vector<double> nsfractrue;
vector<double> nsfracest;
for (unsigned i=0;i<binbounds.size()-1;i++) {
float a_PbPb = hPbPbNS[i]->Integral()/hPbPbAS[i]->Integral();
float x = (1-a_pp/a_PbPb)/(1-a_pp);
NSfrac.push_back(mode==1 ? x : -1);// = old stupid adding of the signal : 2-x);
// cout<<binbounds[i]<<" - "<<binbounds[i+1]<<" = "<<NSfrac[i]<<endl;
nsfractrue.push_back(1-hPbPbNSsig[i]->Integral()/hPbPbNS[i]->Integral());
nsfracest.push_back(NSfrac[NSfrac.size()-1]);
binmean.push_back((binbounds[i]+binbounds[i+1])/2);
}
auto c = getc();
TGraph *g = new TGraph(binbounds.size()-1,&binmean[0],&nsfractrue[0]);
g->Draw();
SavePlot(c,bjet ? "bjetfractionofNS" : "incfractionofNS");
auto c2 = getc();
TGraph *g2 = new TGraph(binbounds.size()-1,&binmean[0],&nsfracest[0]);
g2->Draw();
SavePlot(c2,bjet ? "bjetfractionofNSdata" : "incfractionofNSdata");
///////////////////////////// DATA:
// bin<20 : 0.93
// bin>=20 && bin<60 : 0.84
// bin>=60 : 0.39
////////////////////////////
}
