void nsht_legmat_api(const mxArray * const prhs[3], const mxArray *plhs[2])
{
emxArray_real_T *thetas;
emxArray_real_T *P;
emxArray_real_T *Sc;
real_T L;
real_T m;
emlrtHeapReferenceStackEnterFcnR2012b(emlrtRootTLSGlobal);
emxInit_real_T(&thetas, 2, &b_emlrtRTEI, TRUE);
emxInit_real_T(&P, 2, &b_emlrtRTEI, TRUE);
emxInit_real_T(&Sc, 2, &b_emlrtRTEI, TRUE);
/* Marshall function inputs */
emlrt_marshallIn(emlrtAlias(prhs[0]), "thetas", thetas);
L = c_emlrt_marshallIn(emlrtAliasP(prhs[1]), "L");
m = c_emlrt_marshallIn(emlrtAliasP(prhs[2]), "m");
/* Invoke the target function */
nsht_legmat(thetas, L, m, P, Sc);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(P);
plhs[1] = emlrt_marshallOut(Sc);
Sc->canFreeData = FALSE;
emxFree_real_T(&Sc);
P->canFreeData = FALSE;
emxFree_real_T(&P);
thetas->canFreeData = FALSE;
emxFree_real_T(&thetas);
emlrtHeapReferenceStackLeaveFcnR2012b(emlrtRootTLSGlobal);
}
void julia_v4_1_api(const mxArray * const prhs[3], const mxArray *plhs[2])
{
emxArray_creal_T *vz;
emxArray_real_T *iter;
creal_T c;
real_T maxiter;
emlrtHeapReferenceStackEnterFcnR2012b(emlrtRootTLSGlobal);
emxInit_creal_T(&vz, 2, &c_emlrtRTEI, TRUE);
emxInit_real_T(&iter, 2, &c_emlrtRTEI, TRUE);
/* Marshall function inputs */
emlrt_marshallIn(emlrtAliasP(prhs[0]), "vz", vz);
c = c_emlrt_marshallIn(emlrtAliasP(prhs[1]), "c");
maxiter = e_emlrt_marshallIn(emlrtAliasP(prhs[2]), "maxiter");
/* Invoke the target function */
julia_v4_1(vz, c, maxiter, iter);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(iter);
plhs[1] = b_emlrt_marshallOut(vz);
iter->canFreeData = FALSE;
emxFree_real_T(&iter);
emxFree_creal_T(&vz);
emlrtHeapReferenceStackLeaveFcnR2012b(emlrtRootTLSGlobal);
}
void BoneStar_api(const mxArray * const prhs[4], const mxArray *plhs[1])
{
real_T (*vals)[2];
emxArray_real_T *spacePoints;
emxArray_real_T *timePoints;
real_T k;
real_T t;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
vals = (real_T (*)[2])mxMalloc(sizeof(real_T [2]));
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &spacePoints, 2, &ub_emlrtRTEI, true);
emxInit_real_T(&st, &timePoints, 2, &ub_emlrtRTEI, true);
/* Marshall function inputs */
k = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "k");
e_emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "spacePoints", spacePoints);
t = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "t");
e_emlrt_marshallIn(&st, emlrtAlias(prhs[3]), "timePoints", timePoints);
/* Invoke the target function */
BoneStar(&st, k, spacePoints, t, timePoints, *vals);
/* Marshall function outputs */
plhs[0] = c_emlrt_marshallOut(*vals);
timePoints->canFreeData = false;
emxFree_real_T(&timePoints);
spacePoints->canFreeData = false;
emxFree_real_T(&spacePoints);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void Bcoeff_api(const mxArray * const prhs[5], const mxArray *plhs[1])
{
emxArray_real_T *timePoints;
real_T ksi;
real_T j;
real_T x;
real_T t;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &timePoints, 2, &ub_emlrtRTEI, true);
/* Marshall function inputs */
ksi = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "ksi");
j = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "j");
x = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "x");
t = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]), "t");
e_emlrt_marshallIn(&st, emlrtAlias(prhs[4]), "timePoints", timePoints);
/* Invoke the target function */
ksi = Bcoeff(&st, ksi, j, x, t, timePoints);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(ksi);
timePoints->canFreeData = false;
emxFree_real_T(&timePoints);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void Ccoeff_api(const mxArray * const prhs[4], const mxArray *plhs[1])
{
emxArray_real_T *x;
emxArray_real_T *vals;
real_T k;
real_T t;
real_T spacePoints;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &x, 2, &ub_emlrtRTEI, true);
emxInit_real_T(&st, &vals, 2, &ub_emlrtRTEI, true);
/* Marshall function inputs */
k = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "k");
e_emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "x", x);
t = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "t");
spacePoints = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]), "spacePoints");
/* Invoke the target function */
Ccoeff(&st, k, x, t, spacePoints, vals);
/* Marshall function outputs */
plhs[0] = d_emlrt_marshallOut(vals);
vals->canFreeData = false;
emxFree_real_T(&vals);
x->canFreeData = false;
emxFree_real_T(&x);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void Done_api(const mxArray * const prhs[5], const mxArray *plhs[1])
{
emxArray_real_T *spacePoints;
emxArray_real_T *timePoints;
emxArray_real_T *f;
real_T k;
real_T t;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &spacePoints, 2, &ub_emlrtRTEI, true);
emxInit_real_T(&st, &timePoints, 2, &ub_emlrtRTEI, true);
emxInit_real_T(&st, &f, 2, &ub_emlrtRTEI, true);
/* Marshall function inputs */
k = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "k");
e_emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "spacePoints", spacePoints);
t = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "t");
e_emlrt_marshallIn(&st, emlrtAlias(prhs[3]), "timePoints", timePoints);
g_emlrt_marshallIn(&st, emlrtAlias(prhs[4]), "f", f);
/* Invoke the target function */
k = Done(&st, k, spacePoints, t, timePoints, f);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(k);
f->canFreeData = false;
emxFree_real_T(&f);
timePoints->canFreeData = false;
emxFree_real_T(&timePoints);
spacePoints->canFreeData = false;
emxFree_real_T(&spacePoints);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void GetRegularizationTerm_api(const mxArray * const prhs[2], const mxArray
*plhs[1])
{
emxArray_real_T *regTerm;
real_T N;
real_T order;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, ®Term, 2, &ub_emlrtRTEI, true);
/* Marshall function inputs */
N = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "N");
order = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "order");
/* Invoke the target function */
GetRegularizationTerm(&st, N, order, regTerm);
/* Marshall function outputs */
plhs[0] = e_emlrt_marshallOut(regTerm);
regTerm->canFreeData = false;
emxFree_real_T(®Term);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void makeHistFutTablewithRearrange_api(const mxArray * const prhs[4], const
mxArray *plhs[1])
{
emxArray_uint8_T *testm;
emxArray_real_T *rmat;
emxArray_real_T *y;
real_T range;
real_T dims;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_uint8_T(&st, &testm, 2, &h_emlrtRTEI, true);
emxInit_real_T1(&st, &rmat, 1, &h_emlrtRTEI, true);
emxInit_real_T(&st, &y, 2, &h_emlrtRTEI, true);
/* Marshall function inputs */
emlrt_marshallIn(&st, emlrtAlias((const mxArray *)prhs[0]), "testm", testm);
range = c_emlrt_marshallIn(&st, emlrtAliasP((const mxArray *)prhs[1]), "range");
dims = c_emlrt_marshallIn(&st, emlrtAliasP((const mxArray *)prhs[2]), "dims");
e_emlrt_marshallIn(&st, emlrtAlias((const mxArray *)prhs[3]), "rmat", rmat);
/* Invoke the target function */
makeHistFutTablewithRearrange(&st, testm, range, dims, rmat, y);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(y);
y->canFreeData = false;
emxFree_real_T(&y);
rmat->canFreeData = false;
emxFree_real_T(&rmat);
testm->canFreeData = false;
emxFree_uint8_T(&testm);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void util_sub_jaccard_index_api(const mxArray * const prhs[2], const mxArray
*plhs[1])
{
real_T a;
real_T b;
/* Marshall function inputs */
a = emlrt_marshallIn(emlrtAliasP(prhs[0]), "a");
b = emlrt_marshallIn(emlrtAliasP(prhs[1]), "b");
/* Invoke the target function */
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(util_sub_jaccard_index(a, b));
}
void transceive102_api(transceive102StackData *SD, const mxArray * const prhs[8],
const mxArray *plhs[2])
{
creal_T d2s[1408];
boolean_T ft;
real_T txGain;
real_T rxGain;
real_T centerFreqTx;
real_T centerFreqRx;
real_T intFactor;
real_T decFactor;
uint32_T ns;
creal_T dr[1408];
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
/* Marshall function inputs */
emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "d2s", d2s);
ft = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "ft");
txGain = e_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "txGain");
rxGain = e_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]), "rxGain");
centerFreqTx = e_emlrt_marshallIn(&st, emlrtAliasP(prhs[4]), "centerFreqTx");
centerFreqRx = e_emlrt_marshallIn(&st, emlrtAliasP(prhs[5]), "centerFreqRx");
intFactor = e_emlrt_marshallIn(&st, emlrtAliasP(prhs[6]), "intFactor");
decFactor = e_emlrt_marshallIn(&st, emlrtAliasP(prhs[7]), "decFactor");
/* Invoke the target function */
transceive102(SD, &st, d2s, ft, txGain, rxGain, centerFreqTx, centerFreqRx,
intFactor, decFactor, dr, &ns);
/* Marshall function outputs */
plhs[0] = d_emlrt_marshallOut(&st, dr);
plhs[1] = e_emlrt_marshallOut(ns);
}
void features_ufb_api(const mxArray *prhs[7], const mxArray *plhs[1])
{
emxArray_real_T *ftvec;
emxArray_real_T *wvec;
emxArray_real_T *ilog;
emxArray_real_T *ftmin;
emxArray_real_T *ftmax;
real_T fbmin;
real_T fbmax;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
b_emxInit_real_T(&st, &ftvec, 2, true);
emxInit_real_T(&st, &wvec, 1, true);
b_emxInit_real_T(&st, &ilog, 2, true);
b_emxInit_real_T(&st, &ftmin, 2, true);
b_emxInit_real_T(&st, &ftmax, 2, true);
prhs[0] = emlrtProtectR2012b(prhs[0], 0, false, -1);
prhs[1] = emlrtProtectR2012b(prhs[1], 1, false, -1);
prhs[2] = emlrtProtectR2012b(prhs[2], 2, false, -1);
prhs[3] = emlrtProtectR2012b(prhs[3], 3, false, -1);
prhs[4] = emlrtProtectR2012b(prhs[4], 4, false, -1);
/* Marshall function inputs */
i_emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "ftvec", ftvec);
emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "wvec", wvec);
i_emlrt_marshallIn(&st, emlrtAlias(prhs[2]), "ilog", ilog);
i_emlrt_marshallIn(&st, emlrtAlias(prhs[3]), "ftmin", ftmin);
i_emlrt_marshallIn(&st, emlrtAlias(prhs[4]), "ftmax", ftmax);
fbmin = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[5]), "fbmin");
fbmax = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[6]), "fbmax");
/* Invoke the target function */
fbmin = features_ufb(ftvec, wvec, ilog, ftmin, ftmax, fbmin, fbmax);
/* Marshall function outputs */
plhs[0] = b_emlrt_marshallOut(fbmin);
ftmax->canFreeData = false;
emxFree_real_T(&ftmax);
ftmin->canFreeData = false;
emxFree_real_T(&ftmin);
ilog->canFreeData = false;
emxFree_real_T(&ilog);
wvec->canFreeData = false;
emxFree_real_T(&wvec);
ftvec->canFreeData = false;
emxFree_real_T(&ftvec);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void JenkinsCompare_api(JenkinsCompareStackData *SD, const mxArray * const prhs
[2], const mxArray *plhs[1])
{
emxArray_real_T *y;
real_T (*x)[78596];
real_T sampleRate;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &y, 2, &gb_emlrtRTEI, true);
/* Marshall function inputs */
x = emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "x");
sampleRate = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "sampleRate");
/* Invoke the target function */
JenkinsCompare(SD, &st, *x, sampleRate, y);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(y);
y->canFreeData = false;
emxFree_real_T(&y);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void ekf_update_api(const mxArray * const prhs[7], const mxArray *plhs[2])
{
real_T (*x_k_k)[5];
real_T (*P_k_k)[25];
real_T (*x_kk_kk)[5];
real_T (*zm_k)[5];
real_T (*m0)[2];
real_T (*P_kk_kk)[25];
real_T (*Q)[25];
real_T (*R)[36];
real_T dt;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
x_k_k = (real_T (*)[5])mxMalloc(sizeof(real_T [5]));
P_k_k = (real_T (*)[25])mxMalloc(sizeof(real_T [25]));
/* Marshall function inputs */
x_kk_kk = c_emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "x_kk_kk");
zm_k = c_emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "zm_k");
m0 = e_emlrt_marshallIn(&st, emlrtAlias(prhs[2]), "m0");
P_kk_kk = g_emlrt_marshallIn(&st, emlrtAlias(prhs[3]), "P_kk_kk");
Q = g_emlrt_marshallIn(&st, emlrtAlias(prhs[4]), "Q");
R = i_emlrt_marshallIn(&st, emlrtAlias(prhs[5]), "R");
dt = k_emlrt_marshallIn(&st, emlrtAliasP(prhs[6]), "dt");
/* Invoke the target function */
ekf_update(&st, *x_kk_kk, *zm_k, *m0, *P_kk_kk, *Q, *R, dt, *x_k_k, *P_k_k);
/* Marshall function outputs */
plhs[0] = c_emlrt_marshallOut(*x_k_k);
plhs[1] = d_emlrt_marshallOut(*P_k_k);
}
void BERCalculationSIMO_api(const mxArray * const prhs[2], const mxArray *plhs[1])
{
emxArray_real_T *bitsRX;
real_T type;
const mxArray *tmp;
emlrtHeapReferenceStackEnterFcnR2012b(emlrtRootTLSGlobal);
emxInit_real_T(&bitsRX, 1, &b_emlrtRTEI, TRUE);
/* Marshall function inputs */
c_emlrt_marshallIn(emlrtAlias(prhs[0]), "bitsRX", bitsRX);
type = emlrt_marshallIn(emlrtAliasP(prhs[1]), "type");
/* Marshall in global variables */
tmp = mexGetVariable("global", "d");
if (tmp) {
e_emlrt_marshallIn(tmp, "d", &d);
d_dirty = 0U;
}
/* Invoke the target function */
type = BERCalculationSIMO(bitsRX, type);
/* Marshall out global variables */
mexPutVariable("global", "d", b_emlrt_marshallOut(&d));
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(type);
bitsRX->canFreeData = FALSE;
emxFree_real_T(&bitsRX);
emlrtHeapReferenceStackLeaveFcnR2012b(emlrtRootTLSGlobal);
}
/*
* Arguments : const mxArray *prhs[3]
* const mxArray *plhs[2]
* Return Type : void
*/
void get_coherence_api(const mxArray *prhs[3], const mxArray *plhs[2])
{
real_T (*mscxy)[513];
real_T (*frequency_list)[513];
real_T (*x)[768];
real_T (*y)[768];
real_T fs;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
mscxy = (real_T (*)[513])mxMalloc(sizeof(real_T [513]));
frequency_list = (real_T (*)[513])mxMalloc(sizeof(real_T [513]));
prhs[0] = emlrtProtectR2012b(prhs[0], 0, false, -1);
prhs[1] = emlrtProtectR2012b(prhs[1], 1, false, -1);
/* Marshall function inputs */
x = emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "x");
y = emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "y");
fs = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "fs");
/* Invoke the target function */
get_coherence(*x, *y, fs, *mscxy, *frequency_list);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(*mscxy);
plhs[1] = b_emlrt_marshallOut(*frequency_list);
}
void dummy_api(const mxArray * const prhs[2], const mxArray *plhs[1])
{
real_T a;
real_T b;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
/* Marshall function inputs */
a = emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "a");
b = emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "b");
/* Invoke the target function */
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(dummy(a, b));
}
void features_bvav2_api(const mxArray *prhs[2], const mxArray *plhs[1])
{
real_T (*ft)[13];
emxArray_real_T *audio;
real_T srate;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
ft = (real_T (*)[13])mxMalloc(sizeof(real_T [13]));
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &audio, 1, true);
prhs[0] = emlrtProtectR2012b(prhs[0], 0, false, -1);
/* Marshall function inputs */
emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "audio", audio);
srate = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "srate");
/* Invoke the target function */
features_bvav2(audio, srate, *ft);
/* Marshall function outputs */
plhs[0] = g_emlrt_marshallOut(*ft);
audio->canFreeData = false;
emxFree_real_T(&audio);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void lomb_api(const mxArray *prhs[4], const mxArray *plhs[3])
{
emxArray_real_T *t;
emxArray_real_T *h;
emxArray_real_T *f;
emxArray_real_T *P;
emxArray_real_T *prob;
real_T ofac;
real_T hifac;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &t, 1, true);
emxInit_real_T(&st, &h, 1, true);
emxInit_real_T(&st, &f, 1, true);
emxInit_real_T(&st, &P, 1, true);
emxInit_real_T(&st, &prob, 1, true);
prhs[0] = emlrtProtectR2012b(prhs[0], 0, false, -1);
prhs[1] = emlrtProtectR2012b(prhs[1], 1, false, -1);
/* Marshall function inputs */
emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "t", t);
emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "h", h);
ofac = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "ofac");
hifac = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]), "hifac");
/* Invoke the target function */
lomb(t, h, ofac, hifac, f, P, prob);
/* Marshall function outputs */
plhs[0] = c_emlrt_marshallOut(f);
plhs[1] = c_emlrt_marshallOut(P);
plhs[2] = c_emlrt_marshallOut(prob);
prob->canFreeData = false;
emxFree_real_T(&prob);
P->canFreeData = false;
emxFree_real_T(&P);
f->canFreeData = false;
emxFree_real_T(&f);
h->canFreeData = false;
emxFree_real_T(&h);
t->canFreeData = false;
emxFree_real_T(&t);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
/*
* Arguments : const mxArray *prhs[7]
* const mxArray *plhs[1]
* Return Type : void
*/
void classifyNotes_api(const mxArray *prhs[7], const mxArray *plhs[1])
{
emxArray_real_T *notes_gt;
emxArray_real_T *notes_tr;
struct0_T Results;
real_T onset_lim;
real_T dur_percent_range;
real_T min_dur_dist;
real_T f0_range_in_cents;
real_T hopsize;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, ¬es_gt, 2, true);
emxInit_real_T(&st, ¬es_tr, 2, true);
emxInitStruct_struct0_T(&st, &Results, true);
prhs[0] = emlrtProtectR2012b(prhs[0], 0, false, -1);
prhs[1] = emlrtProtectR2012b(prhs[1], 1, false, -1);
/* Marshall function inputs */
emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "notes_gt", notes_gt);
emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "notes_tr", notes_tr);
onset_lim = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "onset_lim");
dur_percent_range = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]),
"dur_percent_range");
min_dur_dist = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[4]), "min_dur_dist");
f0_range_in_cents = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[5]),
"f0_range_in_cents");
hopsize = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[6]), "hopsize");
/* Invoke the target function */
classifyNotes(notes_gt, notes_tr, onset_lim, dur_percent_range, min_dur_dist,
f0_range_in_cents, hopsize, &Results);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(&Results);
emxFreeStruct_struct0_T(&Results);
notes_tr->canFreeData = false;
emxFree_real_T(¬es_tr);
notes_gt->canFreeData = false;
emxFree_real_T(¬es_gt);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void lg1_api(const mxArray * const prhs[1])
{
real_T scale;
/* Marshall function inputs */
scale = emlrt_marshallIn(emlrtAliasP(prhs[0]), "scale");
/* Invoke the target function */
lg1(scale);
}
static void info_helper(const mxArray **info)
{
const mxArray *rhs0 = NULL;
const mxArray *lhs0 = NULL;
const mxArray *rhs1 = NULL;
const mxArray *lhs1 = NULL;
emlrtAddField(*info, emlrt_marshallOut(
"[E]/Users/spnba/Dropbox (MIT)/MIT/uygar/code/variations under dev/get_unique_counts.m"),
"context", 0);
emlrtAddField(*info, emlrt_marshallOut("nnz"), "name", 0);
emlrtAddField(*info, emlrt_marshallOut("logical"), "dominantType", 0);
emlrtAddField(*info, emlrt_marshallOut(
"[ILXE]/Applications/MIT/MATLAB_R2015b.app/toolbox/eml/lib/matlab/sparfun/nnz.m"),
"resolved", 0);
emlrtAddField(*info, b_emlrt_marshallOut(1415929542U), "fileTimeLo", 0);
emlrtAddField(*info, b_emlrt_marshallOut(0U), "fileTimeHi", 0);
emlrtAddField(*info, b_emlrt_marshallOut(0U), "mFileTimeLo", 0);
emlrtAddField(*info, b_emlrt_marshallOut(0U), "mFileTimeHi", 0);
emlrtAssign(&rhs0, emlrtCreateCellMatrix(0, 1));
emlrtAssign(&lhs0, emlrtCreateCellMatrix(0, 1));
emlrtAddField(*info, emlrtAliasP(rhs0), "rhs", 0);
emlrtAddField(*info, emlrtAliasP(lhs0), "lhs", 0);
emlrtAddField(*info, emlrt_marshallOut(
"[ILXE]/Applications/MIT/MATLAB_R2015b.app/toolbox/eml/lib/matlab/sparfun/nnz.m!intnnz"),
"context", 1);
emlrtAddField(*info, emlrt_marshallOut("coder.internal.indexPlus"), "name", 1);
emlrtAddField(*info, emlrt_marshallOut("double"), "dominantType", 1);
emlrtAddField(*info, emlrt_marshallOut(
"[ILXE]/Applications/MIT/MATLAB_R2015b.app/toolbox/eml/eml/+coder/+internal/indexPlus.m"),
"resolved", 1);
emlrtAddField(*info, b_emlrt_marshallOut(1372604760U), "fileTimeLo", 1);
emlrtAddField(*info, b_emlrt_marshallOut(0U), "fileTimeHi", 1);
emlrtAddField(*info, b_emlrt_marshallOut(0U), "mFileTimeLo", 1);
emlrtAddField(*info, b_emlrt_marshallOut(0U), "mFileTimeHi", 1);
emlrtAssign(&rhs1, emlrtCreateCellMatrix(0, 1));
emlrtAssign(&lhs1, emlrtCreateCellMatrix(0, 1));
emlrtAddField(*info, emlrtAliasP(rhs1), "rhs", 1);
emlrtAddField(*info, emlrtAliasP(lhs1), "lhs", 1);
emlrtDestroyArray(&rhs0);
emlrtDestroyArray(&lhs0);
emlrtDestroyArray(&rhs1);
emlrtDestroyArray(&lhs1);
}
void util_sub_normalized_dot_product_api(const mxArray * const prhs[2], const
mxArray *plhs[1])
{
int32_T a_size[1];
real_T a_data[100];
int32_T b_size[1];
real_T b_data[100];
real_T result;
/* Marshall function inputs */
emlrt_marshallIn(emlrtAliasP(prhs[0]), "a", a_data, a_size);
emlrt_marshallIn(emlrtAliasP(prhs[1]), "b", b_data, b_size);
/* Invoke the target function */
result = util_sub_normalized_dot_product(a_data, a_size, b_data, b_size);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(result);
}
void Dcoeff_api(const mxArray * const prhs[6], const mxArray *plhs[1])
{
emxArray_real_T *y;
emxArray_real_T *x;
emxArray_real_T *timePoints;
emxArray_real_T *f;
real_T j;
real_T t;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &y, 2, &ub_emlrtRTEI, true);
emxInit_real_T(&st, &x, 2, &ub_emlrtRTEI, true);
emxInit_real_T(&st, &timePoints, 2, &ub_emlrtRTEI, true);
emxInit_real_T(&st, &f, 2, &ub_emlrtRTEI, true);
/* Marshall function inputs */
e_emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "y", y);
j = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "j");
e_emlrt_marshallIn(&st, emlrtAlias(prhs[2]), "x", x);
t = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]), "t");
e_emlrt_marshallIn(&st, emlrtAlias(prhs[4]), "timePoints", timePoints);
e_emlrt_marshallIn(&st, emlrtAlias(prhs[5]), "f", f);
/* Invoke the target function */
j = Dcoeff(&st, y, j, x, t, timePoints, f);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(j);
f->canFreeData = false;
emxFree_real_T(&f);
timePoints->canFreeData = false;
emxFree_real_T(&timePoints);
x->canFreeData = false;
emxFree_real_T(&x);
y->canFreeData = false;
emxFree_real_T(&y);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
void lambert_api(const mxArray *prhs[5], const mxArray *plhs[4])
{
real_T (*V1)[3];
real_T (*V2)[3];
real_T (*extremal_distances)[2];
real_T (*r1vec)[3];
real_T (*r2vec)[3];
real_T tf;
real_T m;
real_T muC;
real_T exitflag;
emlrtStack st = { NULL, /* site */
NULL, /* tls */
NULL /* prev */
};
st.tls = emlrtRootTLSGlobal;
V1 = (real_T (*)[3])mxMalloc(sizeof(real_T [3]));
V2 = (real_T (*)[3])mxMalloc(sizeof(real_T [3]));
extremal_distances = (real_T (*)[2])mxMalloc(sizeof(real_T [2]));
prhs[0] = emlrtProtectR2012b(prhs[0], 0, false, -1);
prhs[1] = emlrtProtectR2012b(prhs[1], 1, false, -1);
/* Marshall function inputs */
r1vec = emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "r1vec");
r2vec = emlrt_marshallIn(&st, emlrtAlias(prhs[1]), "r2vec");
tf = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "tf");
m = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]), "m");
muC = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[4]), "muC");
/* Invoke the target function */
lambert(&st, *r1vec, *r2vec, tf, m, muC, *V1, *V2, *extremal_distances,
&exitflag);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(*V1);
plhs[1] = emlrt_marshallOut(*V2);
plhs[2] = b_emlrt_marshallOut(*extremal_distances);
plhs[3] = c_emlrt_marshallOut(exitflag);
}
void testMACRouter_api(testMACRouterStackData *SD, emlrtStack *sp, const
mxArray * const prhs[2])
{
real_T (*offsets)[3];
real_T nodeNum;
/* Marshall function inputs */
offsets = e_emlrt_marshallIn(sp, emlrtAlias(prhs[0]), "offsets");
nodeNum = c_emlrt_marshallIn(sp, emlrtAliasP(prhs[1]), "nodeNum");
/* Invoke the target function */
testMACRouter(SD, sp, *offsets, nodeNum);
}
/*
* Arguments : const mxArray *prhs[3]
* const mxArray *plhs[1]
* Return Type : void
*/
void Csetminmax_api(const mxArray *prhs[3], const mxArray *plhs[1])
{
real_T (*value)[1302];
real_T lowlim;
real_T uplim;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
prhs[0] = emlrtProtectR2012b(prhs[0], 0, true, -1);
/* Marshall function inputs */
value = emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "value");
lowlim = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "lowlim");
uplim = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "uplim");
/* Invoke the target function */
Csetminmax(*value, lowlim, uplim);
/* Marshall function outputs */
emlrt_marshallOut(*value, prhs[0]);
plhs[0] = prhs[0];
}
void TestBemHeatEq_optimized_api(const mxArray * const prhs[4], const mxArray
*plhs[2])
{
emxArray_real_T *sigIn;
emxArray_real_T *u;
emxArray_real_T *r;
real_T regOrder;
real_T lambda;
boolean_T plotFlag;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &sigIn, 2, &ub_emlrtRTEI, true);
emxInit_real_T(&st, &u, 2, &ub_emlrtRTEI, true);
b_emxInit_real_T(&st, &r, 1, &ub_emlrtRTEI, true);
/* Marshall function inputs */
e_emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "sigIn", sigIn);
regOrder = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "regOrder");
lambda = c_emlrt_marshallIn(&st, emlrtAliasP(prhs[2]), "lambda");
plotFlag = k_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]), "plotFlag");
/* Invoke the target function */
TestBemHeatEq_optimized(&st, sigIn, regOrder, lambda, plotFlag, u, r);
/* Marshall function outputs */
plhs[0] = f_emlrt_marshallOut(u);
plhs[1] = g_emlrt_marshallOut(r);
r->canFreeData = false;
emxFree_real_T(&r);
u->canFreeData = false;
emxFree_real_T(&u);
sigIn->canFreeData = false;
emxFree_real_T(&sigIn);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
/*
* Arguments : const mxArray * const prhs[1]
* const mxArray *plhs[1]
* Return Type : void
*/
void test_api(const mxArray * const prhs[1], const mxArray *plhs[1])
{
double b;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
/* Marshall function inputs */
b = emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "b");
/* Invoke the target function */
b = test(b);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(b);
}
void cic_fixpt_api(const mxArray * const prhs[1], const mxArray *plhs[1])
{
int16_T x;
int64_T y;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
/* Marshall function inputs */
x = emlrt_marshallIn(&st, emlrtAliasP(prhs[0]), "x");
/* Invoke the target function */
y = cic_fixpt(&st, x);
/* Marshall function outputs */
plhs[0] = emlrt_marshallOut(&st, y);
}
void swipep_api(const mxArray *prhs[8], const mxArray *plhs[3])
{
emxArray_real_T *x;
emxArray_real_T *p;
emxArray_real_T *t;
emxArray_real_T *s;
real_T fs;
real_T (*plim)[2];
real_T dt;
real_T dlog2p;
real_T dERBs;
real_T woverlap;
real_T sTHR;
emlrtStack st = { NULL, NULL, NULL };
st.tls = emlrtRootTLSGlobal;
emlrtHeapReferenceStackEnterFcnR2012b(&st);
emxInit_real_T(&st, &x, 1, true);
emxInit_real_T(&st, &p, 1, true);
emxInit_real_T(&st, &t, 1, true);
emxInit_real_T(&st, &s, 1, true);
prhs[0] = emlrtProtectR2012b(prhs[0], 0, false, -1);
prhs[2] = emlrtProtectR2012b(prhs[2], 2, false, -1);
/* Marshall function inputs */
emlrt_marshallIn(&st, emlrtAlias(prhs[0]), "x", x);
fs = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[1]), "fs");
plim = k_emlrt_marshallIn(&st, emlrtAlias(prhs[2]), "plim");
dt = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[3]), "dt");
dlog2p = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[4]), "dlog2p");
dERBs = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[5]), "dERBs");
woverlap = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[6]), "woverlap");
sTHR = g_emlrt_marshallIn(&st, emlrtAliasP(prhs[7]), "sTHR");
/* Invoke the target function */
swipep(x, fs, *plim, dt, dlog2p, dERBs, woverlap, sTHR, p, t, s);
/* Marshall function outputs */
plhs[0] = c_emlrt_marshallOut(p);
plhs[1] = c_emlrt_marshallOut(t);
plhs[2] = c_emlrt_marshallOut(s);
s->canFreeData = false;
emxFree_real_T(&s);
t->canFreeData = false;
emxFree_real_T(&t);
p->canFreeData = false;
emxFree_real_T(&p);
x->canFreeData = false;
emxFree_real_T(&x);
emlrtHeapReferenceStackLeaveFcnR2012b(&st);
}
