Exemplo n.º 1
0
/* Function Definitions */
real_T util_sub_jaccard_index(real_T a, real_T b)
{
  real_T result;
  real_T dotproduct;

  /*  JACCARD_INDEX Calculating the Jaccard Coefficient Index between a and b. */
  /*  */
  /*    This is the extented jaccard index, a.k.a. Tanimoto coefficient */
  /*  */
  /*    Created on Aug/28/2010 By Pu Jiangbo */
  /*    Britton Chance Center for Biomedical Photonics */
  /*        PJB#2012-07-04  Adding assert for codegen */
  /*  Assert Class for Codegen */
  /*  This is slow */
  /*  dotproduct = dot(a, b); */
  /*  Because when a and b are both column vectors, a'*b is the same as dot(a,b) */
  dotproduct = a * b;

  /*  Avoid nan (0/0 = NaN) */
  if (!(dotproduct != 0.0)) {
    result = 0.0;
  } else {
    result = dotproduct / ((muDoubleScalarPower(muDoubleScalarAbs(a), 2.0) +
      muDoubleScalarPower(muDoubleScalarAbs(b), 2.0)) - dotproduct);
  }

  return result;
}
Exemplo n.º 2
0
return ( true ) ; } real_T Deadbeat_CUK_acc_rt_TDelayInterpolate ( real_T
tMinusDelay , real_T tStart , real_T * tBuf , real_T * uBuf , int_T bufSz ,
int_T * lastIdx , int_T oldestIdx , int_T newIdx , real_T initOutput ,
boolean_T discrete , boolean_T minorStepAndTAtLastMajorOutput ) { int_T i ;
real_T yout , t1 , t2 , u1 , u2 ; if ( ( newIdx == 0 ) && ( oldestIdx == 0 )
&& ( tMinusDelay > tStart ) ) return initOutput ; if ( tMinusDelay <= tStart
) return initOutput ; if ( ( tMinusDelay <= tBuf [ oldestIdx ] ) ) { if (
discrete ) { return ( uBuf [ oldestIdx ] ) ; } else { int_T tempIdx =
oldestIdx + 1 ; if ( oldestIdx == bufSz - 1 ) tempIdx = 0 ; t1 = tBuf [
oldestIdx ] ; t2 = tBuf [ tempIdx ] ; u1 = uBuf [ oldestIdx ] ; u2 = uBuf [
tempIdx ] ; if ( t2 == t1 ) { if ( tMinusDelay >= t2 ) { yout = u2 ; } else {
yout = u1 ; } } else { real_T f1 = ( t2 - tMinusDelay ) / ( t2 - t1 ) ;
real_T f2 = 1.0 - f1 ; yout = f1 * u1 + f2 * u2 ; } return yout ; } } if (
minorStepAndTAtLastMajorOutput ) { if ( newIdx != 0 ) { if ( * lastIdx ==
newIdx ) { ( * lastIdx ) -- ; } newIdx -- ; } else { if ( * lastIdx == newIdx
) { * lastIdx = bufSz - 1 ; } newIdx = bufSz - 1 ; } } i = * lastIdx ; if (
tBuf [ i ] < tMinusDelay ) { while ( tBuf [ i ] < tMinusDelay ) { if ( i ==
newIdx ) break ; i = ( i < ( bufSz - 1 ) ) ? ( i + 1 ) : 0 ; } } else { while
( tBuf [ i ] >= tMinusDelay ) { i = ( i > 0 ) ? i - 1 : ( bufSz - 1 ) ; } i =
( i < ( bufSz - 1 ) ) ? ( i + 1 ) : 0 ; } * lastIdx = i ; if ( discrete ) {
double tempEps = ( DBL_EPSILON ) * 128.0 ; double localEps = tempEps *
muDoubleScalarAbs ( tBuf [ i ] ) ; if ( tempEps > localEps ) { localEps =
tempEps ; } localEps = localEps / 2.0 ; if ( tMinusDelay >= ( tBuf [ i ] -
localEps ) ) { yout = uBuf [ i ] ; } else { if ( i == 0 ) { yout = uBuf [
bufSz - 1 ] ; } else { yout = uBuf [ i - 1 ] ; } } } else { if ( i == 0 ) {
t1 = tBuf [ bufSz - 1 ] ; u1 = uBuf [ bufSz - 1 ] ; } else { t1 = tBuf [ i -
1 ] ; u1 = uBuf [ i - 1 ] ; } t2 = tBuf [ i ] ; u2 = uBuf [ i ] ; if ( t2 ==
t1 ) { if ( tMinusDelay >= t2 ) { yout = u2 ; } else { yout = u1 ; } } else {
real_T f1 = ( t2 - tMinusDelay ) / ( t2 - t1 ) ; real_T f2 = 1.0 - f1 ; yout
= f1 * u1 + f2 * u2 ; } } return ( yout ) ; } void e0hptcctem ( mvw1gbh0c1 *
Exemplo n.º 3
0
static real_T c3_norm(SFc3_ErdMondInstanceStruct *chartInstance, real_T c3_x[2])
{
  real_T c3_y;
  real_T c3_scale;
  int32_T c3_k;
  int32_T c3_b_k;
  real_T c3_b_x;
  real_T c3_c_x;
  real_T c3_absxk;
  real_T c3_t;
  c3_y = 0.0;
  c3_scale = 2.2250738585072014E-308;
  c3_eml_int_forloop_overflow_check(chartInstance);
  for (c3_k = 1; c3_k < 3; c3_k++) {
    c3_b_k = c3_k;
    c3_b_x = c3_x[_SFD_EML_ARRAY_BOUNDS_CHECK("", (int32_T)_SFD_INTEGER_CHECK("",
      (real_T)c3_b_k), 1, 2, 1, 0) - 1];
    c3_c_x = c3_b_x;
    c3_absxk = muDoubleScalarAbs(c3_c_x);
    if (c3_absxk > c3_scale) {
      c3_t = c3_scale / c3_absxk;
      c3_y = 1.0 + c3_y * c3_t * c3_t;
      c3_scale = c3_absxk;
    } else {
      c3_t = c3_absxk / c3_scale;
      c3_y += c3_t * c3_t;
    }
  }

  return c3_scale * muDoubleScalarSqrt(c3_y);
}
Exemplo n.º 4
0
real_T bisection2(real_T a, real_T b, real_T tol)
{
  real_T p;
  const mxArray *y;
  static const int32_T iv0[2] = { 1, 16 };

  const mxArray *m0;
  static const char_T cv0[16] = { 'W', 'r', 'o', 'n', 'g', ' ', 'c', 'h', 'o',
    'i', 'c', 'e', ' ', 'b', 'r', 'o' };

  real_T err;

  /*  provide the equation you want to solve with R.H.S = 0 form.  */
  /*  Write the L.H.S by using inline function */
  /*  Give initial guesses. */
  /*  Solves it by method of bisection. */
  /*  A very simple code and very handy! */
  if ((muDoubleScalarPower(a - 1.5, 3.0) + 10.0) * (muDoubleScalarPower(b - 1.5,
        3.0) + 10.0) > 0.0) {
    EMLRTPUSHRTSTACK(&emlrtRSI);
    EMLRTPUSHRTSTACK(&b_emlrtRSI);
    y = NULL;
    m0 = mxCreateCharArray(2, iv0);
    emlrtInitCharArray(16, m0, cv0);
    emlrtAssign(&y, m0);
    error(y, &emlrtMCI);
    EMLRTPOPRTSTACK(&b_emlrtRSI);
    EMLRTPOPRTSTACK(&emlrtRSI);
  } else {
    p = (a + b) / 2.0;
    err = muDoubleScalarAbs(b - a);
    while (err >= tol) {
      if ((muDoubleScalarPower(a - 1.5, 3.0) + 10.0) * (muDoubleScalarPower(p -
            1.5, 3.0) + 10.0) < 0.0) {
        b = p;
      } else {
        a = p;
      }

      p = (a + b) / 2.0;
      err = muDoubleScalarAbs(b - a);
      emlrtBreakCheck();
    }
  }

  return p;
}
Exemplo n.º 5
0
/* Function Definitions */
void b_abs(const emxArray_real_T *x, emxArray_real_T *y)
{
  uint32_T unnamed_idx_0;
  int32_T k;
  unnamed_idx_0 = (uint32_T)x->size[0];
  k = y->size[0];
  y->size[0] = (int32_T)unnamed_idx_0;
  emxEnsureCapacity((emxArray__common *)y, k, (int32_T)sizeof(real_T),
                    &gb_emlrtRTEI);
  for (k = 0; k < x->size[0]; k++) {
    y->data[k] = muDoubleScalarAbs(x->data[k]);
  }
}
void transceive102_energy(transceive102_energyStackData *SD, const emlrtStack
  *sp, const 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,
  real_T swapFreqFlag, creal_T dr[1408], uint32_T *ns)
{
  emlrtStack st;
  st.prev = sp;
  st.tls = sp->tls;
  memset(&dr[0], 0, 1408U * sizeof(creal_T));
  *ns = 0U;
  if (!htx_not_empty) {
    st.site = &emlrtRSI;
    SDRuTransmitter_SDRuTransmitter(&st, &htx, centerFreqTx, txGain, intFactor);
    htx_not_empty = true;
  }

  if (!hrx_not_empty) {
    st.site = &b_emlrtRSI;
    SDRuReceiver_SDRuReceiver(&st, &hrx, centerFreqRx, decFactor, rxGain);
    hrx_not_empty = true;
  }

  /* listening mode: */
  if (muDoubleScalarAbs(centerFreqTx - centerFreqRx) > 0.0) {
    /* if Rx and Tx is different, switch for Listening mode */
    if (swapFreqFlag != 0.0) {
      st.site = &c_emlrtRSI;
      SDRuBase_set_CenterFrequency(&hrx, centerFreqTx);
    } else {
      st.site = &d_emlrtRSI;
      SDRuBase_set_CenterFrequency(&hrx, centerFreqRx);
    }
  }

  if (ft) {
    st.site = &e_emlrtRSI;
    SystemCore_release(&st, &hrx);
    st.site = &f_emlrtRSI;
    b_SystemCore_release(&st, &htx);
  } else {
    st.site = &g_emlrtRSI;
    SystemCore_step(&st, &htx, d2s);
    while (*ns < 1U) {
      st.site = &h_emlrtRSI;
      b_SystemCore_step(SD, &st, &hrx, dr, ns);
      if (*emlrtBreakCheckR2012bFlagVar != 0) {
        emlrtBreakCheckR2012b(sp);
      }
    }
  }
}
Exemplo n.º 7
0
real_T c_norm(const emxArray_real_T *x)
{
    real_T y;
    int32_T j;
    int32_T i;
    boolean_T exitg1;
    real_T s;
    if ((x->size[0] == 1) || (x->size[1] == 1)) {
        y = 0.0;
        j = x->size[0] * x->size[1];
        for (i = 0; i < j; i++) {
            y += muDoubleScalarAbs(x->data[i]);
        }
    } else {
        y = 0.0;
        j = 0;
        exitg1 = FALSE;
        while ((exitg1 == FALSE) && (j <= x->size[1] - 1)) {
            s = 0.0;
            for (i = 0; i < x->size[0]; i++) {
                s += muDoubleScalarAbs(x->data[i + x->size[0] * j]);
            }

            if (muDoubleScalarIsNaN(s)) {
                y = rtNaN;
                exitg1 = TRUE;
            } else {
                if (s > y) {
                    y = s;
                }

                j++;
            }
        }
    }

    return y;
}
Exemplo n.º 8
0
void c_abs(const emxArray_real_T *x, emxArray_real_T *y)
{
  uint32_T uv2[2];
  int32_T k;
  for (k = 0; k < 2; k++) {
    uv2[k] = (uint32_T)x->size[k];
  }

  k = y->size[0] * y->size[1];
  y->size[0] = 1;
  y->size[1] = (int32_T)uv2[1];
  emxEnsureCapacity((emxArray__common *)y, k, (int32_T)sizeof(real_T));
  for (k = 0; k < x->size[1]; k++) {
    y->data[k] = muDoubleScalarAbs(x->data[k]);
  }
}
Exemplo n.º 9
0
/* Function Definitions */
void b_abs(const emxArray_real_T *x, emxArray_real_T *y)
{
  uint32_T uv0[2];
  int32_T i4;
  int32_T k;
  for (i4 = 0; i4 < 2; i4++) {
    uv0[i4] = (uint32_T)x->size[i4];
  }

  i4 = y->size[0] * y->size[1];
  y->size[0] = (int32_T)uv0[0];
  y->size[1] = (int32_T)uv0[1];
  emxEnsureCapacity((emxArray__common *)y, i4, (int32_T)sizeof(real_T));
  i4 = x->size[0] * x->size[1];
  for (k = 0; k < i4; k++) {
    y->data[k] = muDoubleScalarAbs(x->data[k]);
  }
}
Exemplo n.º 10
0
/* Function Definitions */
real_T norm(const real_T x[3])
{
  real_T y;
  real_T scale;
  int32_T k;
  real_T absxk;
  real_T t;
  y = 0.0;
  scale = 3.3121686421112381E-170;
  for (k = 0; k < 3; k++) {
    absxk = muDoubleScalarAbs(x[k]);
    if (absxk > scale) {
      t = scale / absxk;
      y = 1.0 + y * t * t;
      scale = absxk;
    } else {
      t = absxk / scale;
      y += t * t;
    }
  }

  return scale * muDoubleScalarSqrt(y);
}
Exemplo n.º 11
0
/* Function Definitions */
real_T norm(const real_T x[4])
{
  real_T y;
  real_T scale;
  int32_T k;
  real_T absxk;
  real_T t;
  y = 0.0;
  scale = 2.2250738585072014E-308;
  for (k = 0; k < 4; k++) {
    absxk = muDoubleScalarAbs(x[k]);
    if (absxk > scale) {
      t = scale / absxk;
      y = 1.0 + y * t * t;
      scale = absxk;
    } else {
      t = absxk / scale;
      y += t * t;
    }
  }

  return scale * muDoubleScalarSqrt(y);
}
Exemplo n.º 12
0
/* Function Definitions */
void linearODESSEP2X4(const emxArray_real_T *T, const emxArray_real_T *I)
{
  int32_T i;
  real_T hoistedGlobal[17];
  int32_T j;
  int32_T b_i;
  real_T normA;
  real_T y[289];
  real_T F[289];
  boolean_T exitg2;
  real_T s;
  boolean_T exitg1;
  static const real_T theta[5] = { 0.01495585217958292, 0.253939833006323,
    0.95041789961629319, 2.097847961257068, 5.3719203511481517 };

  static const int8_T iv2[5] = { 3, 5, 7, 9, 13 };

  int32_T eint;
  real_T b_y[289];
  real_T beta1;
  char_T TRANSB;
  char_T TRANSA;
  ptrdiff_t m_t;
  ptrdiff_t n_t;
  ptrdiff_t k_t;
  ptrdiff_t lda_t;
  ptrdiff_t ldb_t;
  ptrdiff_t ldc_t;
  double * alpha1_t;
  double * Aia0_t;
  double * Bib0_t;
  double * beta1_t;
  double * Cic0_t;
  emlrtPushRtStackR2012b(&db_emlrtRSI, emlrtRootTLSGlobal);
  Q[0] = -k2 * A - L2 * J;
  Q[17] = k2 * A;
  Q[34] = L2 * J;
  Q[51] = 0.0;
  Q[68] = 0.0;
  Q[85] = 0.0;
  Q[102] = 0.0;
  Q[119] = 0.0;
  Q[136] = 0.0;
  Q[153] = 0.0;
  Q[170] = 0.0;
  Q[187] = 0.0;
  Q[204] = 0.0;
  Q[221] = 0.0;
  Q[238] = 0.0;
  Q[255] = 0.0;
  Q[272] = 0.0;
  Q[1] = k1;
  Q[18] = ((-k1 - k4 * A) - H2) - L2 * J;
  Q[35] = 0.0;
  Q[52] = L2 * J;
  Q[69] = 0.0;
  Q[86] = 0.0;
  Q[103] = k4 * A;
  Q[120] = 0.0;
  Q[137] = 0.0;
  Q[154] = 0.0;
  Q[171] = 0.0;
  Q[188] = 0.0;
  Q[205] = 0.0;
  Q[222] = H2;
  Q[239] = 0.0;
  Q[256] = 0.0;
  Q[273] = 0.0;
  Q[2] = L1;
  Q[19] = 0.0;
  Q[36] = (-k8 * A - L1) - L4 * J;
  Q[53] = k8 * A;
  Q[70] = L4 * J;
  Q[87] = 0.0;
  Q[104] = 0.0;
  Q[121] = 0.0;
  Q[138] = 0.0;
  Q[155] = 0.0;
  Q[172] = 0.0;
  Q[189] = 0.0;
  Q[206] = 0.0;
  Q[223] = 0.0;
  Q[240] = 0.0;
  Q[257] = 0.0;
  Q[274] = 0.0;
  Q[3] = 0.0;
  Q[20] = L1;
  Q[37] = k7;
  Q[54] = ((-k7 - k10 * A) - L1) - L4 * J;
  Q[71] = 0.0;
  Q[88] = L4 * J;
  Q[105] = 0.0;
  Q[122] = 0.0;
  Q[139] = k10 * A;
  Q[156] = 0.0;
  Q[173] = 0.0;
  Q[190] = 0.0;
  Q[207] = 0.0;
  Q[224] = 0.0;
  Q[241] = 0.0;
  Q[258] = 0.0;
  Q[275] = 0.0;
  Q[4] = 0.0;
  Q[21] = 0.0;
  Q[38] = L3;
  Q[55] = 0.0;
  Q[72] = -k8 * alpha * A - L3;
  Q[89] = k8 * alpha * A;
  Q[106] = 0.0;
  Q[123] = 0.0;
  Q[140] = 0.0;
  Q[157] = 0.0;
  Q[174] = 0.0;
  Q[191] = 0.0;
  Q[208] = 0.0;
  Q[225] = 0.0;
  Q[242] = 0.0;
  Q[259] = 0.0;
  Q[276] = 0.0;
  Q[5] = 0.0;
  Q[22] = 0.0;
  Q[39] = 0.0;
  Q[56] = L3;
  Q[73] = k7;
  Q[90] = (-k7 - k10 * alpha * A) - L3;
  Q[107] = 0.0;
  Q[124] = 0.0;
  Q[141] = 0.0;
  Q[158] = 0.0;
  Q[175] = k10 * alpha * A;
  Q[192] = 0.0;
  Q[209] = 0.0;
  Q[226] = 0.0;
  Q[243] = 0.0;
  Q[260] = 0.0;
  Q[277] = 0.0;
  Q[6] = 0.0;
  Q[23] = k3;
  Q[40] = 0.0;
  Q[57] = 0.0;
  Q[74] = 0.0;
  Q[91] = 0.0;
  Q[108] = ((-k3 - k6 * A) - H2) - L2 * J;
  Q[125] = k6 * A;
  Q[142] = L2 * J;
  Q[159] = 0.0;
  Q[176] = 0.0;
  Q[193] = 0.0;
  Q[210] = 0.0;
  Q[227] = 0.0;
  Q[244] = H2;
  Q[261] = 0.0;
  Q[278] = 0.0;
  Q[7] = 0.0;
  Q[24] = 0.0;
  Q[41] = 0.0;
  Q[58] = 0.0;
  Q[75] = 0.0;
  Q[92] = 0.0;
  Q[109] = k5;
  Q[126] = (-k5 - H2) - L2 * J;
  Q[143] = 0.0;
  Q[160] = L2 * J;
  Q[177] = 0.0;
  Q[194] = 0.0;
  Q[211] = 0.0;
  Q[228] = 0.0;
  Q[245] = 0.0;
  Q[262] = H2;
  Q[279] = 0.0;
  Q[8] = 0.0;
  Q[25] = 0.0;
  Q[42] = 0.0;
  Q[59] = k9;
  Q[76] = 0.0;
  Q[93] = 0.0;
  Q[110] = L1;
  Q[127] = 0.0;
  Q[144] = ((-k9 - k12 * A) - L1) - L4 * J;
  Q[161] = k12 * A;
  Q[178] = L4 * J;
  Q[195] = 0.0;
  Q[212] = 0.0;
  Q[229] = 0.0;
  Q[246] = 0.0;
  Q[263] = 0.0;
  Q[280] = 0.0;
  Q[9] = 0.0;
  Q[26] = 0.0;
  Q[43] = 0.0;
  Q[60] = 0.0;
  Q[77] = 0.0;
  Q[94] = 0.0;
  Q[111] = 0.0;
  Q[128] = L1;
  Q[145] = k11;
  Q[162] = (-k11 - L1) - L4 * J;
  Q[179] = 0.0;
  Q[196] = L4 * J;
  Q[213] = 0.0;
  Q[230] = 0.0;
  Q[247] = 0.0;
  Q[264] = 0.0;
  Q[281] = 0.0;
  Q[10] = 0.0;
  Q[27] = 0.0;
  Q[44] = 0.0;
  Q[61] = 0.0;
  Q[78] = 0.0;
  Q[95] = k9;
  Q[112] = 0.0;
  Q[129] = 0.0;
  Q[146] = L3;
  Q[163] = 0.0;
  Q[180] = (-k9 - k12 * alpha * A) - L3;
  Q[197] = k12 * alpha * A;
  Q[214] = 0.0;
  Q[231] = 0.0;
  Q[248] = 0.0;
  Q[265] = 0.0;
  Q[282] = 0.0;
  Q[11] = 0.0;
  Q[28] = 0.0;
  Q[45] = 0.0;
  Q[62] = 0.0;
  Q[79] = 0.0;
  Q[96] = 0.0;
  Q[113] = 0.0;
  Q[130] = 0.0;
  Q[147] = 0.0;
  Q[164] = L3;
  Q[181] = k11;
  Q[198] = -k11 - L3;
  Q[215] = 0.0;
  Q[232] = 0.0;
  Q[249] = 0.0;
  Q[266] = 0.0;
  Q[283] = 0.0;
  Q[12] = H1;
  Q[29] = 0.0;
  Q[46] = 0.0;
  Q[63] = 0.0;
  Q[80] = 0.0;
  Q[97] = 0.0;
  Q[114] = 0.0;
  Q[131] = 0.0;
  Q[148] = 0.0;
  Q[165] = 0.0;
  Q[182] = 0.0;
  Q[199] = 0.0;
  Q[216] = -k2 * A - H1;
  Q[233] = k2 * A;
  Q[250] = 0.0;
  Q[267] = 0.0;
  Q[284] = 0.0;
  Q[13] = 0.0;
  Q[30] = 0.0;
  Q[47] = 0.0;
  Q[64] = 0.0;
  Q[81] = 0.0;
  Q[98] = 0.0;
  Q[115] = 0.0;
  Q[132] = 0.0;
  Q[149] = 0.0;
  Q[166] = 0.0;
  Q[183] = 0.0;
  Q[200] = 0.0;
  Q[217] = k1;
  Q[234] = -k1 - k4 * A;
  Q[251] = k4 * A;
  Q[268] = 0.0;
  Q[285] = 0.0;
  Q[14] = 0.0;
  Q[31] = 0.0;
  Q[48] = 0.0;
  Q[65] = 0.0;
  Q[82] = 0.0;
  Q[99] = 0.0;
  Q[116] = 0.0;
  Q[133] = 0.0;
  Q[150] = 0.0;
  Q[167] = 0.0;
  Q[184] = 0.0;
  Q[201] = 0.0;
  Q[218] = 0.0;
  Q[235] = k3;
  Q[252] = -k3 - k6 * A;
  Q[269] = k6 * A;
  Q[286] = 0.0;
  Q[15] = 0.0;
  Q[32] = 0.0;
  Q[49] = 0.0;
  Q[66] = 0.0;
  Q[83] = 0.0;
  Q[100] = 0.0;
  Q[117] = 0.0;
  Q[134] = 0.0;
  Q[151] = 0.0;
  Q[168] = 0.0;
  Q[185] = 0.0;
  Q[202] = 0.0;
  Q[219] = 0.0;
  Q[236] = 0.0;
  Q[253] = k5;
  Q[270] = -k5 - H3;
  Q[287] = H3;
  Q[16] = H4;
  Q[33] = 0.0;
  Q[50] = 0.0;
  Q[67] = 0.0;
  Q[84] = 0.0;
  Q[101] = 0.0;
  Q[118] = 0.0;
  Q[135] = 0.0;
  Q[152] = 0.0;
  Q[169] = 0.0;
  Q[186] = 0.0;
  Q[203] = 0.0;
  Q[220] = 0.0;
  Q[237] = 0.0;
  Q[254] = 0.0;
  Q[271] = 0.0;
  Q[288] = -H4;
  Q_dirty |= 1U;
  emlrtPopRtStackR2012b(&db_emlrtRSI, emlrtRootTLSGlobal);
  i = 0;
  while (i <= T->size[0] - 1) {
    emlrtPushRtStackR2012b(&eb_emlrtRSI, emlrtRootTLSGlobal);
    memcpy(&hoistedGlobal[0], &p0[0], 17U * sizeof(real_T));
    j = T->size[0];
    b_i = (int32_T)(1.0 + (real_T)i);
    emlrtDynamicBoundsCheckFastR2012b(b_i, 1, j, &bd_emlrtBCI,
      emlrtRootTLSGlobal);
    normA = T->data[i];
    for (j = 0; j < 289; j++) {
      y[j] = Q[j] * normA;
    }

    normA = 0.0;
    j = 0;
    exitg2 = FALSE;
    while ((exitg2 == FALSE) && (j < 17)) {
      s = 0.0;
      for (b_i = 0; b_i < 17; b_i++) {
        s += muDoubleScalarAbs(y[b_i + 17 * j]);
      }

      if (muDoubleScalarIsNaN(s)) {
        normA = rtNaN;
        exitg2 = TRUE;
      } else {
        if (s > normA) {
          normA = s;
        }

        j++;
      }
    }

    if (normA <= 5.3719203511481517) {
      b_i = 0;
      exitg1 = FALSE;
      while ((exitg1 == FALSE) && (b_i < 5)) {
        if (normA <= theta[b_i]) {
          emlrtPushRtStackR2012b(&fb_emlrtRSI, emlrtRootTLSGlobal);
          PadeApproximantOfDegree(y, iv2[b_i], F);
          emlrtPopRtStackR2012b(&fb_emlrtRSI, emlrtRootTLSGlobal);
          exitg1 = TRUE;
        } else {
          b_i++;
        }
      }
    } else {
      normA /= 5.3719203511481517;
      if ((!muDoubleScalarIsInf(normA)) && (!muDoubleScalarIsNaN(normA))) {
        normA = frexp(normA, &eint);
        j = eint;
      } else {
        j = 0;
      }

      s = j;
      if (normA == 0.5) {
        s = (real_T)j - 1.0;
      }

      normA = muDoubleScalarPower(2.0, s);
      emlrtPushRtStackR2012b(&gb_emlrtRSI, emlrtRootTLSGlobal);
      for (j = 0; j < 289; j++) {
        b_y[j] = y[j] / normA;
      }

      PadeApproximantOfDegree(b_y, 13.0, F);
      emlrtPopRtStackR2012b(&gb_emlrtRSI, emlrtRootTLSGlobal);
      emlrtForLoopVectorCheckR2012b(1.0, 1.0, s, mxDOUBLE_CLASS, (int32_T)s,
        &l_emlrtRTEI, emlrtRootTLSGlobal);
      for (j = 0; j < (int32_T)s; j++) {
        emlrtPushRtStackR2012b(&hb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&tb_emlrtRSI, emlrtRootTLSGlobal);
        memcpy(&y[0], &F[0], 289U * sizeof(real_T));
        emlrtPushRtStackR2012b(&ub_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&vb_emlrtRSI, emlrtRootTLSGlobal);
        normA = 1.0;
        beta1 = 0.0;
        TRANSB = 'N';
        TRANSA = 'N';
        memset(&F[0], 0, 289U * sizeof(real_T));
        emlrtPushRtStackR2012b(&wb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        m_t = (ptrdiff_t)(17);
        emlrtPopRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&wb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&xb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        n_t = (ptrdiff_t)(17);
        emlrtPopRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&xb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&yb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        k_t = (ptrdiff_t)(17);
        emlrtPopRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&yb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&ac_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        lda_t = (ptrdiff_t)(17);
        emlrtPopRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&ac_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&bc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        ldb_t = (ptrdiff_t)(17);
        emlrtPopRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&bc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&cc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        ldc_t = (ptrdiff_t)(17);
        emlrtPopRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&cc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&dc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        alpha1_t = (double *)(&normA);
        emlrtPopRtStackR2012b(&dc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&ec_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        Aia0_t = (double *)(&y[0]);
        emlrtPopRtStackR2012b(&ec_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&fc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        Bib0_t = (double *)(&y[0]);
        emlrtPopRtStackR2012b(&fc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&gc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        beta1_t = (double *)(&beta1);
        emlrtPopRtStackR2012b(&gc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&hc_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        Cic0_t = (double *)(&F[0]);
        emlrtPopRtStackR2012b(&hc_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&ic_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        dgemm(&TRANSA, &TRANSB, &m_t, &n_t, &k_t, alpha1_t, Aia0_t, &lda_t,
              Bib0_t, &ldb_t, beta1_t, Cic0_t, &ldc_t);
        emlrtPopRtStackR2012b(&ic_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&vb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&ub_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&tb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&hb_emlrtRSI, emlrtRootTLSGlobal);
      }
    }

    for (j = 0; j < 17; j++) {
      p0[j] = 0.0;
      for (b_i = 0; b_i < 17; b_i++) {
        p0[j] += hoistedGlobal[b_i] * F[b_i + 17 * j];
      }
    }

    p0_dirty |= 1U;
    emlrtPopRtStackR2012b(&eb_emlrtRSI, emlrtRootTLSGlobal);
    j = I->size[0];
    b_i = 1 + i;
    normA = Acell * 1.0E+12 * (g1 * (p0[6] + p0[7]) * (V - E1) + g2 * (((p0[8] +
      p0[9]) + p0[10]) + p0[11]) * (V - E2)) - I->
      data[emlrtDynamicBoundsCheckFastR2012b(b_i, 1, j, &cd_emlrtBCI,
      emlrtRootTLSGlobal) - 1];
    normA = muDoubleScalarAbs(normA);
    err += normA * normA;
    err_dirty |= 1U;
    i++;
    emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, emlrtRootTLSGlobal);
  }
}
Exemplo n.º 13
0
/* Function Definitions */
void do_vectors(const emlrtStack *sp, const real_T a_data[1224], const int32_T
                a_size[1], const real_T b[8], real_T c_data[8], int32_T c_size[1],
                int32_T ia_data[8], int32_T ia_size[1], int32_T ib_data[8],
                int32_T ib_size[1])
{
  int32_T ncmax;
  boolean_T y;
  int32_T ialast;
  boolean_T exitg4;
  boolean_T guard9 = FALSE;
  boolean_T p;
  boolean_T exitg3;
  boolean_T guard8 = FALSE;
  int32_T nc;
  int32_T iafirst;
  int32_T ibfirst;
  int32_T iblast;
  int32_T b_ialast;
  real_T ak;
  boolean_T exitg2;
  real_T absxk;
  int32_T exponent;
  boolean_T guard6 = FALSE;
  boolean_T guard7 = FALSE;
  int32_T b_iblast;
  real_T bk;
  boolean_T exitg1;
  int32_T b_exponent;
  boolean_T guard4 = FALSE;
  boolean_T guard5 = FALSE;
  int32_T c_exponent;
  boolean_T guard2 = FALSE;
  boolean_T guard3 = FALSE;
  boolean_T guard1 = FALSE;
  const mxArray *b_y;
  const mxArray *m20;
  int32_T b_ia_data[8];
  const mxArray *c_y;
  const mxArray *d_y;
  real_T b_c_data[8];
  emlrtStack st;
  st.prev = sp;
  st.tls = sp->tls;
  st.site = &fp_emlrtRSI;
  ncmax = muIntScalarMin_sint32(a_size[0], 8);
  c_size[0] = (int8_T)ncmax;
  ia_size[0] = ncmax;
  ib_size[0] = ncmax;
  st.site = &gp_emlrtRSI;
  y = TRUE;
  if (a_size[0] == 0) {
  } else {
    ialast = 1;
    exitg4 = FALSE;
    while ((exitg4 == FALSE) && (ialast <= a_size[0] - 1)) {
      guard9 = FALSE;
      if (a_data[ialast - 1] <= a_data[ialast]) {
        guard9 = TRUE;
      } else if (muDoubleScalarIsNaN(a_data[ialast])) {
        guard9 = TRUE;
      } else {
        p = FALSE;
      }

      if (guard9 == TRUE) {
        p = TRUE;
      }

      if (!p) {
        y = FALSE;
        exitg4 = TRUE;
      } else {
        ialast++;
      }
    }
  }

  if (!y) {
    st.site = &hp_emlrtRSI;
    eml_error(&st);
  }

  st.site = &ip_emlrtRSI;
  y = TRUE;
  ialast = 1;
  exitg3 = FALSE;
  while ((exitg3 == FALSE) && (ialast < 8)) {
    guard8 = FALSE;
    if (b[ialast - 1] <= b[ialast]) {
      guard8 = TRUE;
    } else if (muDoubleScalarIsNaN(b[ialast])) {
      guard8 = TRUE;
    } else {
      p = FALSE;
    }

    if (guard8 == TRUE) {
      p = TRUE;
    }

    if (!p) {
      y = FALSE;
      exitg3 = TRUE;
    } else {
      ialast++;
    }
  }

  if (!y) {
    st.site = &jp_emlrtRSI;
    b_eml_error(&st);
  }

  nc = 0;
  iafirst = 0;
  ialast = 0;
  ibfirst = 0;
  iblast = 0;
  while ((ialast + 1 <= a_size[0]) && (iblast + 1 <= 8)) {
    st.site = &kp_emlrtRSI;
    b_ialast = ialast + 1;
    ak = a_data[ialast];
    exitg2 = FALSE;
    while ((exitg2 == FALSE) && (b_ialast < a_size[0])) {
      absxk = muDoubleScalarAbs(a_data[ialast] / 2.0);
      if ((!muDoubleScalarIsInf(absxk)) && (!muDoubleScalarIsNaN(absxk))) {
        if (absxk <= 2.2250738585072014E-308) {
          absxk = 4.94065645841247E-324;
        } else {
          frexp(absxk, &exponent);
          absxk = ldexp(1.0, exponent - 53);
        }
      } else {
        absxk = rtNaN;
      }

      guard6 = FALSE;
      guard7 = FALSE;
      if (muDoubleScalarAbs(a_data[ialast] - a_data[b_ialast]) < absxk) {
        guard7 = TRUE;
      } else if (muDoubleScalarIsInf(a_data[b_ialast])) {
        if (muDoubleScalarIsInf(a_data[ialast]) && ((a_data[b_ialast] > 0.0) ==
             (a_data[ialast] > 0.0))) {
          guard7 = TRUE;
        } else {
          guard6 = TRUE;
        }
      } else {
        guard6 = TRUE;
      }

      if (guard7 == TRUE) {
        p = TRUE;
      }

      if (guard6 == TRUE) {
        p = FALSE;
      }

      if (p) {
        b_ialast++;
      } else {
        exitg2 = TRUE;
      }
    }

    ialast = b_ialast - 1;
    st.site = &lp_emlrtRSI;
    b_iblast = iblast + 1;
    bk = b[iblast];
    exitg1 = FALSE;
    while ((exitg1 == FALSE) && (b_iblast < 8)) {
      absxk = muDoubleScalarAbs(b[iblast] / 2.0);
      if ((!muDoubleScalarIsInf(absxk)) && (!muDoubleScalarIsNaN(absxk))) {
        if (absxk <= 2.2250738585072014E-308) {
          absxk = 4.94065645841247E-324;
        } else {
          frexp(absxk, &b_exponent);
          absxk = ldexp(1.0, b_exponent - 53);
        }
      } else {
        absxk = rtNaN;
      }

      guard4 = FALSE;
      guard5 = FALSE;
      if (muDoubleScalarAbs(b[iblast] - b[b_iblast]) < absxk) {
        guard5 = TRUE;
      } else if (muDoubleScalarIsInf(b[b_iblast])) {
        if (muDoubleScalarIsInf(b[iblast]) && ((b[b_iblast] > 0.0) == (b[iblast]
              > 0.0))) {
          guard5 = TRUE;
        } else {
          guard4 = TRUE;
        }
      } else {
        guard4 = TRUE;
      }

      if (guard5 == TRUE) {
        p = TRUE;
      }

      if (guard4 == TRUE) {
        p = FALSE;
      }

      if (p) {
        b_iblast++;
      } else {
        exitg1 = TRUE;
      }
    }

    iblast = b_iblast - 1;
    st.site = &mp_emlrtRSI;
    absxk = muDoubleScalarAbs(bk / 2.0);
    if ((!muDoubleScalarIsInf(absxk)) && (!muDoubleScalarIsNaN(absxk))) {
      if (absxk <= 2.2250738585072014E-308) {
        absxk = 4.94065645841247E-324;
      } else {
        frexp(absxk, &c_exponent);
        absxk = ldexp(1.0, c_exponent - 53);
      }
    } else {
      absxk = rtNaN;
    }

    guard2 = FALSE;
    guard3 = FALSE;
    if (muDoubleScalarAbs(bk - ak) < absxk) {
      guard3 = TRUE;
    } else if (muDoubleScalarIsInf(ak)) {
      if (muDoubleScalarIsInf(bk) && ((ak > 0.0) == (bk > 0.0))) {
        guard3 = TRUE;
      } else {
        guard2 = TRUE;
      }
    } else {
      guard2 = TRUE;
    }

    if (guard3 == TRUE) {
      p = TRUE;
    }

    if (guard2 == TRUE) {
      p = FALSE;
    }

    if (p) {
      st.site = &np_emlrtRSI;
      nc++;
      c_data[nc - 1] = ak;
      ia_data[nc - 1] = iafirst + 1;
      ib_data[nc - 1] = ibfirst + 1;
      st.site = &op_emlrtRSI;
      ialast = b_ialast;
      iafirst = b_ialast;
      st.site = &pp_emlrtRSI;
      iblast = b_iblast;
      ibfirst = b_iblast;
    } else {
      st.site = &qp_emlrtRSI;
      guard1 = FALSE;
      if (ak < bk) {
        guard1 = TRUE;
      } else if (muDoubleScalarIsNaN(bk)) {
        guard1 = TRUE;
      } else {
        p = FALSE;
      }

      if (guard1 == TRUE) {
        p = TRUE;
      }

      if (p) {
        st.site = &rp_emlrtRSI;
        ialast = b_ialast;
        iafirst = b_ialast;
      } else {
        st.site = &sp_emlrtRSI;
        iblast = b_iblast;
        ibfirst = b_iblast;
      }
    }
  }

  if (ncmax > 0) {
    if (nc <= ncmax) {
    } else {
      b_y = NULL;
      m20 = mxCreateString("Assertion failed.");
      emlrtAssign(&b_y, m20);
      st.site = &yt_emlrtRSI;
      b_error(&st, b_y, &y_emlrtMCI);
    }

    if (1 > nc) {
      ialast = 0;
    } else {
      ialast = nc;
    }

    for (iafirst = 0; iafirst < ialast; iafirst++) {
      b_ia_data[iafirst] = ia_data[iafirst];
    }

    ia_size[0] = ialast;
    for (iafirst = 0; iafirst < ialast; iafirst++) {
      ia_data[iafirst] = b_ia_data[iafirst];
    }
  }

  if (ncmax > 0) {
    if (nc <= ncmax) {
    } else {
      c_y = NULL;
      m20 = mxCreateString("Assertion failed.");
      emlrtAssign(&c_y, m20);
      st.site = &xt_emlrtRSI;
      b_error(&st, c_y, &ab_emlrtMCI);
    }

    if (1 > nc) {
      ialast = 0;
    } else {
      ialast = nc;
    }

    for (iafirst = 0; iafirst < ialast; iafirst++) {
      b_ia_data[iafirst] = ib_data[iafirst];
    }

    ib_size[0] = ialast;
    for (iafirst = 0; iafirst < ialast; iafirst++) {
      ib_data[iafirst] = b_ia_data[iafirst];
    }
  }

  if (ncmax > 0) {
    if (nc <= ncmax) {
    } else {
      d_y = NULL;
      m20 = mxCreateString("Assertion failed.");
      emlrtAssign(&d_y, m20);
      st.site = &wt_emlrtRSI;
      b_error(&st, d_y, &bb_emlrtMCI);
    }

    if (1 > nc) {
      ialast = 0;
    } else {
      ialast = nc;
    }

    for (iafirst = 0; iafirst < ialast; iafirst++) {
      b_c_data[iafirst] = c_data[iafirst];
    }

    c_size[0] = ialast;
    for (iafirst = 0; iafirst < ialast; iafirst++) {
      c_data[iafirst] = b_c_data[iafirst];
    }
  }
}
/* Function Definitions */
void mldivide(const emlrtStack *sp, const real_T A[16], real_T B[4])
{
  real_T b_A[16];
  int8_T ipiv[4];
  int32_T kAcol;
  int32_T info;
  int32_T j;
  int32_T c;
  int32_T ix;
  real_T temp;
  int32_T k;
  real_T s;
  int32_T b;
  int32_T jy;
  boolean_T b_kAcol;
  int32_T ijA;
  emlrtStack st;
  emlrtStack b_st;
  emlrtStack c_st;
  emlrtStack d_st;
  emlrtStack e_st;
  emlrtStack f_st;
  emlrtStack g_st;
  emlrtStack h_st;
  emlrtStack i_st;
  emlrtStack j_st;
  emlrtStack k_st;
  emlrtStack l_st;
  st.prev = sp;
  st.tls = sp->tls;
  st.site = &g_emlrtRSI;
  b_st.prev = &st;
  b_st.tls = st.tls;
  c_st.prev = &b_st;
  c_st.tls = b_st.tls;
  d_st.prev = &c_st;
  d_st.tls = c_st.tls;
  e_st.prev = &d_st;
  e_st.tls = d_st.tls;
  f_st.prev = &e_st;
  f_st.tls = e_st.tls;
  g_st.prev = &f_st;
  g_st.tls = f_st.tls;
  h_st.prev = &g_st;
  h_st.tls = g_st.tls;
  i_st.prev = &h_st;
  i_st.tls = h_st.tls;
  j_st.prev = &i_st;
  j_st.tls = i_st.tls;
  k_st.prev = &j_st;
  k_st.tls = j_st.tls;
  l_st.prev = &k_st;
  l_st.tls = k_st.tls;
  b_st.site = &h_emlrtRSI;
  c_st.site = &j_emlrtRSI;
  d_st.site = &k_emlrtRSI;
  e_st.site = &l_emlrtRSI;
  memcpy(&b_A[0], &A[0], sizeof(real_T) << 4);
  for (kAcol = 0; kAcol < 4; kAcol++) {
    ipiv[kAcol] = (int8_T)(1 + kAcol);
  }

  info = 0;
  for (j = 0; j < 3; j++) {
    c = j * 5;
    f_st.site = &m_emlrtRSI;
    g_st.site = &p_emlrtRSI;
    h_st.site = &q_emlrtRSI;
    kAcol = 0;
    ix = c;
    temp = muDoubleScalarAbs(b_A[c]);
    i_st.site = &r_emlrtRSI;
    for (k = 2; k <= 4 - j; k++) {
      ix++;
      s = muDoubleScalarAbs(b_A[ix]);
      if (s > temp) {
        kAcol = k - 1;
        temp = s;
      }
    }

    if (b_A[c + kAcol] != 0.0) {
      if (kAcol != 0) {
        ipiv[j] = (int8_T)((j + kAcol) + 1);
        ix = j;
        kAcol += j;
        for (k = 0; k < 4; k++) {
          temp = b_A[ix];
          b_A[ix] = b_A[kAcol];
          b_A[kAcol] = temp;
          ix += 4;
          kAcol += 4;
        }
      }

      b = (c - j) + 4;
      f_st.site = &n_emlrtRSI;
      for (jy = c + 1; jy + 1 <= b; jy++) {
        b_A[jy] /= b_A[c];
      }
    } else {
      info = j + 1;
    }

    f_st.site = &o_emlrtRSI;
    g_st.site = &t_emlrtRSI;
    h_st.site = &u_emlrtRSI;
    i_st.site = &v_emlrtRSI;
    j_st.site = &w_emlrtRSI;
    kAcol = c;
    jy = c + 4;
    for (k = 1; k <= 3 - j; k++) {
      temp = b_A[jy];
      if (b_A[jy] != 0.0) {
        ix = c + 1;
        b = (kAcol - j) + 8;
        k_st.site = &x_emlrtRSI;
        if (kAcol + 6 > b) {
          b_kAcol = false;
        } else {
          b_kAcol = (b > 2147483646);
        }

        if (b_kAcol) {
          l_st.site = &s_emlrtRSI;
          check_forloop_overflow_error(&l_st);
        }

        for (ijA = kAcol + 5; ijA + 1 <= b; ijA++) {
          b_A[ijA] += b_A[ix] * -temp;
          ix++;
        }
      }

      jy += 4;
      kAcol += 4;
    }
  }

  if ((info == 0) && (!(b_A[15] != 0.0))) {
    info = 4;
  }

  if (info > 0) {
    c_st.site = &i_emlrtRSI;
    d_st.site = &y_emlrtRSI;
    eml_warning(&d_st);
  }

  for (kAcol = 0; kAcol < 3; kAcol++) {
    if (ipiv[kAcol] != kAcol + 1) {
      temp = B[kAcol];
      B[kAcol] = B[ipiv[kAcol] - 1];
      B[ipiv[kAcol] - 1] = temp;
    }
  }

  for (k = 0; k < 4; k++) {
    kAcol = k << 2;
    if (B[k] != 0.0) {
      for (jy = k + 1; jy + 1 < 5; jy++) {
        B[jy] -= B[k] * b_A[jy + kAcol];
      }
    }
  }

  for (k = 3; k > -1; k += -1) {
    kAcol = k << 2;
    if (B[k] != 0.0) {
      B[k] /= b_A[k + kAcol];
      for (jy = 0; jy + 1 <= k; jy++) {
        B[jy] -= B[k] * b_A[jy + kAcol];
      }
    }
  }
}
Exemplo n.º 15
0
/* Function Definitions */
void xgetrf(const emlrtStack *sp, real_T A[16], int32_T ipiv[4])
{
  int32_T iy;
  int32_T j;
  int32_T c;
  int32_T ix;
  real_T smax;
  int32_T jy;
  real_T s;
  int32_T b;
  int32_T b_j;
  boolean_T b_iy;
  int32_T ijA;
  emlrtStack st;
  emlrtStack b_st;
  emlrtStack c_st;
  emlrtStack d_st;
  emlrtStack e_st;
  emlrtStack f_st;
  emlrtStack g_st;
  st.prev = sp;
  st.tls = sp->tls;
  st.site = &v_emlrtRSI;
  b_st.prev = &st;
  b_st.tls = st.tls;
  c_st.prev = &b_st;
  c_st.tls = b_st.tls;
  d_st.prev = &c_st;
  d_st.tls = c_st.tls;
  e_st.prev = &d_st;
  e_st.tls = d_st.tls;
  f_st.prev = &e_st;
  f_st.tls = e_st.tls;
  g_st.prev = &f_st;
  g_st.tls = f_st.tls;
  for (iy = 0; iy < 4; iy++) {
    ipiv[iy] = 1 + iy;
  }

  for (j = 0; j < 3; j++) {
    c = j * 5;
    b_st.site = &w_emlrtRSI;
    c_st.site = &ab_emlrtRSI;
    iy = 0;
    ix = c;
    smax = muDoubleScalarAbs(A[c]);
    d_st.site = &bb_emlrtRSI;
    for (jy = 2; jy <= 4 - j; jy++) {
      ix++;
      s = muDoubleScalarAbs(A[ix]);
      if (s > smax) {
        iy = jy - 1;
        smax = s;
      }
    }

    if (A[c + iy] != 0.0) {
      if (iy != 0) {
        ipiv[j] = (j + iy) + 1;
        ix = j;
        iy += j;
        for (jy = 0; jy < 4; jy++) {
          smax = A[ix];
          A[ix] = A[iy];
          A[iy] = smax;
          ix += 4;
          iy += 4;
        }
      }

      b = (c - j) + 4;
      b_st.site = &x_emlrtRSI;
      for (iy = c + 1; iy + 1 <= b; iy++) {
        A[iy] /= A[c];
      }
    }

    b_st.site = &y_emlrtRSI;
    c_st.site = &db_emlrtRSI;
    d_st.site = &eb_emlrtRSI;
    e_st.site = &fb_emlrtRSI;
    iy = c;
    jy = c + 4;
    f_st.site = &gb_emlrtRSI;
    for (b_j = 1; b_j <= 3 - j; b_j++) {
      smax = A[jy];
      if (A[jy] != 0.0) {
        ix = c + 1;
        b = (iy - j) + 8;
        f_st.site = &hb_emlrtRSI;
        if (iy + 6 > b) {
          b_iy = false;
        } else {
          b_iy = (b > 2147483646);
        }

        if (b_iy) {
          g_st.site = &cb_emlrtRSI;
          check_forloop_overflow_error(&g_st, true);
        }

        for (ijA = iy + 5; ijA + 1 <= b; ijA++) {
          A[ijA] += A[ix] * -smax;
          ix++;
        }
      }

      jy += 4;
      iy += 4;
    }
  }
}
Exemplo n.º 16
0
/* Function Definitions */
static boolean_T b_MACLayerTransmitter(testMACTransmitterStackData *SD, const
  emlrtStack *sp, comm_AGC *ObjAGC, comm_SDRuReceiver *ObjSDRuReceiver,
  comm_SDRuTransmitter *ObjSDRuTransmitter, commcodegen_CRCDetector *ObjDetect,
  OFDMDemodulator_1 *ObjPreambleDemod, OFDMDemodulator_1 *ObjDataDemod, const
  c_struct_T *estimate, const e_struct_T *tx, const real_T messageBits_data[563],
  char_T previousMessage_data[77], int32_T previousMessage_size[2])
{
  boolean_T msgStatus;
  int32_T tries;
  int32_T state;
  real_T decisions[10];
  real_T destNodeID;
  int16_T i36;
  comm_SDRuTransmitter *obj;
  boolean_T flag;
  boolean_T exitg1;
  comm_AGC *b_ObjAGC;
  comm_SDRuReceiver *b_ObjSDRuReceiver;
  commcodegen_CRCDetector *b_ObjDetect;
  OFDMDemodulator_1 *b_ObjPreambleDemod;
  OFDMDemodulator_1 *b_ObjDataDemod;
  int32_T originNodeID;
  real_T timeouts;
  int32_T Response_size[2];
  int32_T exitg10;
  boolean_T guard1 = FALSE;
  static const char_T b[7] = { 'T', 'i', 'm', 'e', 'o', 'u', 't' };

  char_T Response_data[80];
  int32_T messageBits_size[2];
  real_T b_messageBits_data[563];
  int8_T sza[2];
  int32_T exitg16;
  int32_T exitg15;
  static const char_T cv343[7] = { 'T', 'i', 'm', 'e', 'o', 'u', 't' };

  int32_T exitg14;
  int32_T exitg13;
  static const char_T cv344[9] = { 'C', 'R', 'C', ' ', 'E', 'r', 'r', 'o', 'r' };

  int8_T szb[2];
  int32_T exitg12;
  int32_T exitg11;
  int32_T loop_ub;
  static const char_T b_b[9] = { 'D', 'u', 'p', 'l', 'i', 'c', 'a', 't', 'e' };

  char_T b_Response_data[80];
  int32_T exitg9;
  int32_T exitg8;
  boolean_T b_guard1 = FALSE;
  int32_T exitg7;
  int32_T exitg6;
  static const char_T cv345[9] = { 'D', 'u', 'p', 'l', 'i', 'c', 'a', 't', 'e' };

  int32_T exitg5;
  int32_T exitg4;
  int32_T exitg3;
  int32_T exitg2;
  static const char_T cv346[3] = { 'A', 'C', 'K' };

  emlrtStack st;
  emlrtStack b_st;
  emlrtStack c_st;
  st.prev = sp;
  st.tls = sp->tls;
  b_st.prev = &st;
  b_st.tls = st.tls;
  c_st.prev = &b_st;
  c_st.tls = b_st.tls;

  /*            %Objects */
  /*          %Structs */
  /*   %Values/Vectors */
  /* % This function is called when the node wants to transmit something */
  /*  % Sense spectrum and wait until it is unoccupied */
  for (tries = 0; tries < 4; tries++) {
    /*  try only so many times */
    for (state = 0; state < 10; state++) {
      st.site = &xl_emlrtRSI;
      SpectrumSenseP25(SD, &st, ObjAGC, ObjSDRuReceiver, decisions);
      destNodeID = muDoubleScalarRound(decisions[state]);
      if (destNodeID < 32768.0) {
        if (destNodeID >= -32768.0) {
          i36 = (int16_T)destNodeID;
        } else {
          i36 = MIN_int16_T;
        }
      } else if (destNodeID >= 32768.0) {
        i36 = MAX_int16_T;
      } else {
        i36 = 0;
      }

      st.site = &yl_emlrtRSI;
      d_fprintf(&st, (int16_T)(1 + state), i36);
      emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, sp);
    }

    /*      if occupied */
    /*          fprintf('MAC| Spectrum occupied, listening...\n'); */
    /*          %Recover signal and/or wait */
    /*          lookingForACK = false; */
    /*          %MACLayerReceiver(PHY,lookingForACK); */
    /*      else% Yay we can transmit now */
    /*          break; */
    /*      end     */
    /*      if tries >=4 */
    /*          fprintf('MAC| Spectrum Busy, try again later\n'); */
    /*          return; */
    /*      end */
    emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, sp);
  }

  msgStatus = FALSE;

  /*  Adjust offset for node */
  st.site = &am_emlrtRSI;
  f_fprintf(&st, 1, tx->offsetTable[0]);
  st.site = &bm_emlrtRSI;
  obj = ObjSDRuTransmitter;
  b_st.site = &gb_emlrtRSI;
  obj->CenterFrequency = 2.24E+9 + tx->offsetTable[0];
  c_st.site = &ck_emlrtRSI;
  b_st.site = &gb_emlrtRSI;
  if (obj->isInitialized && (!obj->isReleased)) {
    flag = TRUE;
  } else {
    flag = FALSE;
  }

  if (flag) {
    obj->TunablePropsChanged = TRUE;
    obj->tunablePropertyChanged[1] = TRUE;
  }

  /* % Spectrum clear, send message */
  tries = 0;
  exitg1 = FALSE;
  while ((exitg1 == FALSE) && (tries < 4)) {
    /*  Send message */
    /* %originator */
    /* %destination */
    st.site = &cm_emlrtRSI;
    PHYTransmit(SD, &st, ObjSDRuTransmitter, ObjSDRuReceiver, tx->nodeNum);

    /*  Listen for acknowledgement */
    /* fprintf('###########################################\n'); */
    st.site = &dm_emlrtRSI;
    h_fprintf(&st);

    /*  Call Receiver */
    /*            %Objects */
    /*          %Structs */
    /*   %Values/Vectors */
    st.site = &em_emlrtRSI;
    b_ObjAGC = ObjAGC;
    b_ObjSDRuReceiver = ObjSDRuReceiver;
    obj = ObjSDRuTransmitter;
    b_ObjDetect = ObjDetect;
    b_ObjPreambleDemod = ObjPreambleDemod;
    b_ObjDataDemod = ObjDataDemod;

    /*            %Objects */
    /*          %Structs */
    /*   %Values/Vectors */
    /*  This function is called when the node is just listening to the spectrum */
    /*  waiting for a message to be transmitted to them */
    /* % Listen to the spectrum */
    /*  previousMessage will be updated for next run */
    /*            %Objects */
    /*          %Structs */
    /*   %Values/Vectors */
    b_st.site = &rt_emlrtRSI;

    /*            %Objects */
    /*          %Structs */
    /*   %Values/Vectors */
    /* Initialize values */
    originNodeID = -1;
    destNodeID = -1.0;

    /*  0 = Call PHY Receiver */
    /*  1 = Timeout */
    /*  2 = Corrupt Message */
    /*  3 = Message Reception Successfull */
    /*  Duplicates are checked at the last stage */
    state = 0;

    /*  Initial state */
    timeouts = 0.0;

    /*  Counter */
    /*  Message string holder */
    emlrtDimSizeGeqCheckFastR2012b(80, 0, &y_emlrtECI, &b_st);
    Response_size[0] = 1;
    Response_size[1] = 0;

    /*  Run system */
    do {
      exitg10 = 0;

      /*     %% Process Messages */
      guard1 = FALSE;
      switch (state) {
       case 0:
        /* Wait for message */
        if (timeouts > 10.0) {
          emlrtDimSizeGeqCheckFastR2012b(80, 7, &db_emlrtECI, &b_st);
          Response_size[0] = 1;
          Response_size[1] = 7;
          for (state = 0; state < 7; state++) {
            Response_data[state] = b[state];
          }

          exitg10 = 1;
        } else {
          /*  Call Physical Layer */
          /*            %Objects */
          /*          %Structs */
          /*   %Values/Vectors */
          SD->f15.estimate = *estimate;
          messageBits_size[0] = 1;
          messageBits_size[1] = 563;
          memcpy(&b_messageBits_data[0], &messageBits_data[0], 563U * sizeof
                 (real_T));
          c_st.site = &eu_emlrtRSI;
          PHYReceive(SD, &c_st, b_ObjAGC, b_ObjSDRuReceiver, b_ObjDetect,
                     b_ObjPreambleDemod, b_ObjDataDemod, &SD->f15.estimate,
                     tx->shortPreambleOFDM, tx->longPreamble, tx->pilots,
                     tx->pilotLocationsWithoutGuardbands,
                     tx->dataSubcarrierIndexies.data,
                     tx->dataSubcarrierIndexies.size, b_messageBits_data,
                     messageBits_size, Response_data, Response_size);

          /*  Choose next state */
          c_st.site = &fu_emlrtRSI;
          flag = FALSE;
          for (state = 0; state < 2; state++) {
            sza[state] = (int8_T)Response_size[state];
          }

          state = 0;
          do {
            exitg16 = 0;
            if (state < 2) {
              if (sza[state] != 1 + 6 * state) {
                exitg16 = 1;
              } else {
                state++;
              }
            } else {
              state = 0;
              exitg16 = 2;
            }
          } while (exitg16 == 0);

          if (exitg16 == 1) {
          } else {
            do {
              exitg15 = 0;
              if (state <= Response_size[1] - 1) {
                if (Response_data[state] != cv343[state]) {
                  exitg15 = 1;
                } else {
                  state++;
                }
              } else {
                flag = TRUE;
                exitg15 = 1;
              }
            } while (exitg15 == 0);
          }

          if (flag) {
            state = 1;
          } else {
            c_st.site = &gu_emlrtRSI;
            flag = FALSE;
            for (state = 0; state < 2; state++) {
              sza[state] = (int8_T)Response_size[state];
            }

            state = 0;
            do {
              exitg14 = 0;
              if (state < 2) {
                if (sza[state] != 1 + (state << 3)) {
                  exitg14 = 1;
                } else {
                  state++;
                }
              } else {
                state = 0;
                exitg14 = 2;
              }
            } while (exitg14 == 0);

            if (exitg14 == 1) {
            } else {
              do {
                exitg13 = 0;
                if (state <= Response_size[1] - 1) {
                  if (Response_data[state] != cv344[state]) {
                    exitg13 = 1;
                  } else {
                    state++;
                  }
                } else {
                  flag = TRUE;
                  exitg13 = 1;
                }
              } while (exitg13 == 0);
            }

            if (flag || (Response_size[1] == 0)) {
              state = 2;
            } else {
              /*  Successfully decoded */
              state = 3;
            }
          }

          /*  Timeout occured     */
          guard1 = TRUE;
        }
        break;

       case 1:
        timeouts++;
        if (timeouts > 10.0) {
          /* if DebugFlag;fprintf('DL| Max timeouts reached\n');end */
          c_st.site = &du_emlrtRSI;
          l_fprintf(&c_st);
          emlrtDimSizeGeqCheckFastR2012b(80, 7, &cb_emlrtECI, &b_st);
          Response_size[0] = 1;
          Response_size[1] = 7;
          for (state = 0; state < 7; state++) {
            Response_data[state] = b[state];
          }

          exitg10 = 1;
        } else {
          state = 0;

          /* Get another message */
          /*  Message corrupted     */
          guard1 = TRUE;
        }
        break;

       case 2:
        timeouts += 0.01;
        state = 0;

        /* Get another message */
        /*  Default: Message successfully received     */
        guard1 = TRUE;
        break;

       case 3:
        /* otherwise */
        /* disp(['DL| MSG: ',Response]) */
        /* disp(['DL| Timeouts: ',num2str(timeouts)]) */
        /*  Final Duplication check */
        c_st.site = &bu_emlrtRSI;
        flag = FALSE;
        for (state = 0; state < 2; state++) {
          sza[state] = (int8_T)previousMessage_size[state];
        }

        for (state = 0; state < 2; state++) {
          szb[state] = (int8_T)Response_size[state];
        }

        state = 0;
        do {
          exitg12 = 0;
          if (state < 2) {
            if (sza[state] != szb[state]) {
              exitg12 = 1;
            } else {
              state++;
            }
          } else {
            state = 0;
            exitg12 = 2;
          }
        } while (exitg12 == 0);

        if (exitg12 == 1) {
        } else {
          do {
            exitg11 = 0;
            if (state <= previousMessage_size[1] - 1) {
              if (previousMessage_data[state] != Response_data[state]) {
                exitg11 = 1;
              } else {
                state++;
              }
            } else {
              flag = TRUE;
              exitg11 = 1;
            }
          } while (exitg11 == 0);
        }

        if (flag) {
          /* Dupe */
          /* if DebugFlag;fprintf('DL| Duplicate Message\n');end */
          c_st.site = &cu_emlrtRSI;
          j_fprintf(&c_st);
          previousMessage_size[0] = 1;
          previousMessage_size[1] = Response_size[1];
          loop_ub = Response_size[1];
          for (state = 0; state < loop_ub; state++) {
            previousMessage_data[previousMessage_size[0] * state] =
              Response_data[Response_size[0] * state];
          }

          /* Update history for next iteration */
          state = Response_size[1] - 2;
          originNodeID = (uint8_T)
            Response_data[emlrtDynamicBoundsCheckFastR2012b(state, 1,
            Response_size[1], &wb_emlrtBCI, &b_st) - 1] - 48;

          /* extract node ID and convert char to number */
          state = Response_size[1] - 1;
          destNodeID = (real_T)(uint8_T)
            Response_data[emlrtDynamicBoundsCheckFastR2012b(state, 1,
            Response_size[1], &xb_emlrtBCI, &b_st) - 1] - 48.0;

          /* extract node ID and convert char to number */
          emlrtDimSizeGeqCheckFastR2012b(80, 9, &ab_emlrtECI, &b_st);
          Response_size[0] = 1;
          Response_size[1] = 9;
          for (state = 0; state < 9; state++) {
            Response_data[state] = b_b[state];
          }

          /* Tell upper layers duplicate */
        } else {
          /* No Dupe */
          previousMessage_size[0] = 1;
          previousMessage_size[1] = Response_size[1];
          loop_ub = Response_size[1];
          for (state = 0; state < loop_ub; state++) {
            previousMessage_data[previousMessage_size[0] * state] =
              Response_data[Response_size[0] * state];
          }

          /* Update history for next iteration */
          state = Response_size[1] - 2;
          originNodeID = (uint8_T)
            Response_data[emlrtDynamicBoundsCheckFastR2012b(state, 1,
            Response_size[1], &ub_emlrtBCI, &b_st) - 1] - 48;

          /* extract node ID and convert char to number */
          state = Response_size[1] - 1;
          destNodeID = (real_T)(uint8_T)
            Response_data[emlrtDynamicBoundsCheckFastR2012b(state, 1,
            Response_size[1], &vb_emlrtBCI, &b_st) - 1] - 48.0;

          /* extract node ID and convert char to number */
          if (1 > Response_size[1] - 3) {
            loop_ub = 0;
          } else {
            emlrtDynamicBoundsCheckFastR2012b(1, 1, Response_size[1],
              &tb_emlrtBCI, &b_st);
            state = Response_size[1] - 3;
            loop_ub = emlrtDynamicBoundsCheckFastR2012b(state, 1, Response_size
              [1], &tb_emlrtBCI, &b_st);
          }

          emlrtDimSizeGeqCheckFastR2012b(80, loop_ub, &bb_emlrtECI, &b_st);
          for (state = 0; state < loop_ub; state++) {
            b_Response_data[state] = Response_data[state];
          }

          Response_size[0] = 1;
          Response_size[1] = loop_ub;
          for (state = 0; state < loop_ub; state++) {
            Response_data[state] = b_Response_data[state];
          }

          /* Remove identifer key and nodeIDs */
        }

        exitg10 = 1;
        break;

       default:
        guard1 = TRUE;
        break;
      }

      if (guard1 == TRUE) {
        emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, &b_st);
      }
    } while (exitg10 == 0);

    /*  Final check */
    c_st.site = &hu_emlrtRSI;
    if (muDoubleScalarAbs(destNodeID) > 3.0) {
      destNodeID = tx->nodeNum;

      /*  Something went wrong, probably corrupt message, reset to self */
    }

    /* % Possible response messages */
    /*  1.) Timeout */
    /*  2.) Some message */
    b_st.site = &st_emlrtRSI;
    flag = FALSE;
    for (state = 0; state < 2; state++) {
      sza[state] = (int8_T)Response_size[state];
    }

    state = 0;
    do {
      exitg9 = 0;
      if (state < 2) {
        if (sza[state] != 1 + 6 * state) {
          exitg9 = 1;
        } else {
          state++;
        }
      } else {
        state = 0;
        exitg9 = 2;
      }
    } while (exitg9 == 0);

    if (exitg9 == 1) {
    } else {
      do {
        exitg8 = 0;
        if (state <= Response_size[1] - 1) {
          if (Response_data[state] != cv343[state]) {
            exitg8 = 1;
          } else {
            state++;
          }
        } else {
          flag = TRUE;
          exitg8 = 1;
        }
      } while (exitg8 == 0);
    }

    b_guard1 = FALSE;
    if (!flag) {
      b_st.site = &st_emlrtRSI;
      flag = FALSE;
      for (state = 0; state < 2; state++) {
        sza[state] = (int8_T)Response_size[state];
      }

      state = 0;
      do {
        exitg7 = 0;
        if (state < 2) {
          if (sza[state] != 1 + (state << 3)) {
            exitg7 = 1;
          } else {
            state++;
          }
        } else {
          state = 0;
          exitg7 = 2;
        }
      } while (exitg7 == 0);

      if (exitg7 == 1) {
      } else {
        do {
          exitg6 = 0;
          if (state <= Response_size[1] - 1) {
            if (Response_data[state] != cv345[state]) {
              exitg6 = 1;
            } else {
              state++;
            }
          } else {
            flag = TRUE;
            exitg6 = 1;
          }
        } while (exitg6 == 0);
      }

      if (!flag) {
        /* fprintf('###########################################\n'); */
        b_st.site = &tt_emlrtRSI;
        n_fprintf(&b_st, Response_data, Response_size);
        b_st.site = &ut_emlrtRSI;
        p_fprintf(&b_st, (int16_T)originNodeID);
      } else {
        b_guard1 = TRUE;
      }
    } else {
      b_guard1 = TRUE;
    }

    if (b_guard1 == TRUE) {
      b_st.site = &vt_emlrtRSI;
      flag = FALSE;
      for (state = 0; state < 2; state++) {
        sza[state] = (int8_T)Response_size[state];
      }

      state = 0;
      do {
        exitg5 = 0;
        if (state < 2) {
          if (sza[state] != 1 + (state << 3)) {
            exitg5 = 1;
          } else {
            state++;
          }
        } else {
          state = 0;
          exitg5 = 2;
        }
      } while (exitg5 == 0);

      if (exitg5 == 1) {
      } else {
        do {
          exitg4 = 0;
          if (state <= Response_size[1] - 1) {
            if (Response_data[state] != cv345[state]) {
              exitg4 = 1;
            } else {
              state++;
            }
          } else {
            flag = TRUE;
            exitg4 = 1;
          }
        } while (exitg4 == 0);
      }

      if (flag) {
        b_st.site = &wt_emlrtRSI;
        r_fprintf(&b_st);

        /*     %% Send ACK */
        b_st.site = &xt_emlrtRSI;
        f_fprintf(&b_st, (int16_T)originNodeID, tx->
                  offsetTable[emlrtDynamicBoundsCheckFastR2012b(originNodeID, 1,
                   3, &yb_emlrtBCI, &st) - 1]);
        b_st.site = &yt_emlrtRSI;
        c_st.site = &gb_emlrtRSI;
        obj->CenterFrequency = 2.24E+9 + tx->offsetTable[originNodeID - 1];
        c_st.site = &gb_emlrtRSI;
        if (obj->isInitialized && (!obj->isReleased)) {
          flag = TRUE;
        } else {
          flag = FALSE;
        }

        if (flag) {
          obj->TunablePropsChanged = TRUE;
          obj->tunablePropertyChanged[1] = TRUE;
        }

        /*  Adjust offset for node */
        b_st.site = &au_emlrtRSI;
        b_PHYTransmit(SD, &b_st, obj, b_ObjSDRuReceiver, originNodeID,
                      destNodeID);
      }
    }

    st.site = &fm_emlrtRSI;
    flag = FALSE;
    for (state = 0; state < 2; state++) {
      sza[state] = (int8_T)Response_size[state];
    }

    state = 0;
    do {
      exitg3 = 0;
      if (state < 2) {
        if (sza[state] != 1 + (state << 1)) {
          exitg3 = 1;
        } else {
          state++;
        }
      } else {
        state = 0;
        exitg3 = 2;
      }
    } while (exitg3 == 0);

    if (exitg3 == 1) {
    } else {
      do {
        exitg2 = 0;
        if (state <= Response_size[1] - 1) {
          if (Response_data[state] != cv346[state]) {
            exitg2 = 1;
          } else {
            state++;
          }
        } else {
          flag = TRUE;
          exitg2 = 1;
        }
      } while (exitg2 == 0);
    }

    if (flag) {
      st.site = &gm_emlrtRSI;
      t_fprintf(&st);
      msgStatus = TRUE;
      exitg1 = TRUE;
    } else {
      st.site = &hm_emlrtRSI;
      v_fprintf(&st);
      if (tries + 1 >= 4) {
        st.site = &im_emlrtRSI;
        x_fprintf(&st);
        st.site = &jm_emlrtRSI;
        ab_fprintf(&st);
        st.site = &km_emlrtRSI;
        x_fprintf(&st);
        exitg1 = TRUE;
      } else {
        tries++;
        emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, sp);
      }
    }
  }

  return msgStatus;
}
Exemplo n.º 17
0
void mldivide(const real_T A[289], real_T B[289])
{
  real_T b_A[289];
  int8_T ipiv[17];
  int32_T jA;
  int32_T info;
  int32_T j;
  int32_T c;
  int32_T ix;
  real_T temp;
  int32_T jy;
  real_T s;
  int32_T b;
  int32_T b_j;
  boolean_T b_jA;
  int32_T ijA;
  char_T DIAGA;
  char_T TRANSA;
  char_T UPLO;
  char_T SIDE;
  ptrdiff_t m_t;
  ptrdiff_t n_t;
  ptrdiff_t lda_t;
  ptrdiff_t ldb_t;
  double * Aia0_t;
  double * Bib0_t;
  double * alpha1_t;
  emlrtPushRtStackR2012b(&pb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&qb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&sb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&vb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&wb_emlrtRSI, emlrtRootTLSGlobal);
  memcpy(&b_A[0], &A[0], 289U * sizeof(real_T));
  for (jA = 0; jA < 17; jA++) {
    ipiv[jA] = (int8_T)(1 + jA);
  }

  info = 0;
  for (j = 0; j < 16; j++) {
    c = j * 18;
    emlrtPushRtStackR2012b(&xb_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&bc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&cc_emlrtRSI, emlrtRootTLSGlobal);
    jA = 1;
    ix = c;
    temp = muDoubleScalarAbs(b_A[c]);
    emlrtPushRtStackR2012b(&dc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&dc_emlrtRSI, emlrtRootTLSGlobal);
    for (jy = 2; jy <= 17 - j; jy++) {
      ix++;
      s = muDoubleScalarAbs(b_A[ix]);
      if (s > temp) {
        jA = jy;
        temp = s;
      }
    }

    emlrtPopRtStackR2012b(&cc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&bc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&xb_emlrtRSI, emlrtRootTLSGlobal);
    if (b_A[(c + jA) - 1] != 0.0) {
      if (jA - 1 != 0) {
        ipiv[j] = (int8_T)(j + jA);
        eml_xswap(b_A, j + 1, j + jA);
      }

      b = (c - j) + 17;
      emlrtPushRtStackR2012b(&yb_emlrtRSI, emlrtRootTLSGlobal);
      emlrtPopRtStackR2012b(&yb_emlrtRSI, emlrtRootTLSGlobal);
      for (jA = c + 1; jA + 1 <= b; jA++) {
        b_A[jA] /= b_A[c];
      }
    } else {
      info = j + 1;
    }

    emlrtPushRtStackR2012b(&ac_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&ec_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&fc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&gc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&hc_emlrtRSI, emlrtRootTLSGlobal);
    jA = c;
    jy = c + 17;
    emlrtPushRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&jc_emlrtRSI, emlrtRootTLSGlobal);
    for (b_j = 1; b_j <= 16 - j; b_j++) {
      temp = b_A[jy];
      if (b_A[jy] != 0.0) {
        ix = c + 1;
        b = (jA - j) + 34;
        emlrtPushRtStackR2012b(&ic_emlrtRSI, emlrtRootTLSGlobal);
        if (jA + 19 > b) {
          b_jA = FALSE;
        } else {
          b_jA = (b > 2147483646);
        }

        if (b_jA) {
          emlrtPushRtStackR2012b(&g_emlrtRSI, emlrtRootTLSGlobal);
          check_forloop_overflow_error();
          emlrtPopRtStackR2012b(&g_emlrtRSI, emlrtRootTLSGlobal);
        }

        emlrtPopRtStackR2012b(&ic_emlrtRSI, emlrtRootTLSGlobal);
        for (ijA = jA + 18; ijA + 1 <= b; ijA++) {
          b_A[ijA] += b_A[ix] * -temp;
          ix++;
        }
      }

      jy += 17;
      jA += 17;
    }

    emlrtPopRtStackR2012b(&hc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&gc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&fc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&ec_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&ac_emlrtRSI, emlrtRootTLSGlobal);
  }

  if ((info == 0) && (!(b_A[288] != 0.0))) {
    info = 17;
  }

  emlrtPopRtStackR2012b(&wb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&vb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&sb_emlrtRSI, emlrtRootTLSGlobal);
  if (info > 0) {
    emlrtPushRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&kc_emlrtRSI, emlrtRootTLSGlobal);
    eml_warning();
    emlrtPopRtStackR2012b(&kc_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
  }

  for (jA = 0; jA < 17; jA++) {
    if (ipiv[jA] != jA + 1) {
      for (j = 0; j < 17; j++) {
        temp = B[jA + 17 * j];
        B[jA + 17 * j] = B[(ipiv[jA] + 17 * j) - 1];
        B[(ipiv[jA] + 17 * j) - 1] = temp;
      }
    }
  }

  emlrtPushRtStackR2012b(&tb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&mc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&nc_emlrtRSI, emlrtRootTLSGlobal);
  temp = 1.0;
  DIAGA = 'U';
  TRANSA = 'N';
  UPLO = 'L';
  SIDE = 'L';
  emlrtPushRtStackR2012b(&oc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  m_t = (ptrdiff_t)(17);
  emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&oc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&pc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  n_t = (ptrdiff_t)(17);
  emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&pc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&qc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  lda_t = (ptrdiff_t)(17);
  emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&qc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&rc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  ldb_t = (ptrdiff_t)(17);
  emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&rc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&sc_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  Aia0_t = (double *)(&b_A[0]);
  emlrtPopRtStackR2012b(&sc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&tc_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  Bib0_t = (double *)(&B[0]);
  emlrtPopRtStackR2012b(&tc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&uc_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  alpha1_t = (double *)(&temp);
  emlrtPopRtStackR2012b(&uc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&vc_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  dtrsm(&SIDE, &UPLO, &TRANSA, &DIAGA, &m_t, &n_t, alpha1_t, Aia0_t, &lda_t,
        Bib0_t, &ldb_t);
  emlrtPopRtStackR2012b(&vc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&nc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&mc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&tb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ub_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&mc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&nc_emlrtRSI, emlrtRootTLSGlobal);
  temp = 1.0;
  DIAGA = 'N';
  TRANSA = 'N';
  UPLO = 'U';
  SIDE = 'L';
  emlrtPushRtStackR2012b(&oc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  m_t = (ptrdiff_t)(17);
  emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&oc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&pc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  n_t = (ptrdiff_t)(17);
  emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&pc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&qc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  lda_t = (ptrdiff_t)(17);
  emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&qc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&rc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  ldb_t = (ptrdiff_t)(17);
  emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&rc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&sc_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  Aia0_t = (double *)(&b_A[0]);
  emlrtPopRtStackR2012b(&sc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&tc_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  Bib0_t = (double *)(&B[0]);
  emlrtPopRtStackR2012b(&tc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&uc_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  alpha1_t = (double *)(&temp);
  emlrtPopRtStackR2012b(&uc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&vc_emlrtRSI, emlrtRootTLSGlobal);
  emlrt_checkEscapedGlobals();
  dtrsm(&SIDE, &UPLO, &TRANSA, &DIAGA, &m_t, &n_t, alpha1_t, Aia0_t, &lda_t,
        Bib0_t, &ldb_t);
  emlrtPopRtStackR2012b(&vc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&nc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&mc_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&ub_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&qb_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPopRtStackR2012b(&pb_emlrtRSI, emlrtRootTLSGlobal);
}
Exemplo n.º 18
0
/* Function Definitions */
real_T Bcoeff(const emlrtStack *sp, real_T ksi, real_T j, real_T x, real_T t,
              const emxArray_real_T *gridT)
{
  real_T vals;
  int32_T k;
  int32_T i1;
  boolean_T b_x[3];
  boolean_T y;
  boolean_T exitg2;
  boolean_T exitg1;
  real_T c_x;
  real_T d_x;
  emlrtStack st;
  emlrtStack b_st;
  st.prev = sp;
  st.tls = sp->tls;
  b_st.prev = &st;
  b_st.tls = st.tls;

  /*  evaluate the coefficient B at the  boundary ksi=0 or ksi=1; */
  /*  for the index j which describes the time steps timePoints_j, at time t and space */
  /*  point x */
  /*  timePoints is a vector describing the time descritized domain */
  k = gridT->size[1];
  i1 = (int32_T)emlrtIntegerCheckFastR2012b(j, &b_emlrtDCI, sp);
  if (t <= gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k, &n_emlrtBCI,
       sp) - 1]) {
    vals = 0.0;
  } else {
    k = gridT->size[1];
    i1 = (int32_T)j;
    b_x[0] = (t > gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k,
               &o_emlrtBCI, sp) - 1]);
    k = gridT->size[1];
    i1 = (int32_T)((uint32_T)j + 1U);
    b_x[1] = (t <= gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k,
               &p_emlrtBCI, sp) - 1]);
    b_x[2] = (x == ksi);
    y = true;
    k = 0;
    exitg2 = false;
    while ((!exitg2) && (k < 3)) {
      if (b_x[k] == 0) {
        y = false;
        exitg2 = true;
      } else {
        k++;
      }
    }

    if (y) {
      vals = 0.0;
    } else {
      k = gridT->size[1];
      i1 = (int32_T)j;
      b_x[0] = (t > gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k,
                 &q_emlrtBCI, sp) - 1]);
      k = gridT->size[1];
      i1 = (int32_T)((uint32_T)j + 1U);
      b_x[1] = (t <= gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k,
                 &r_emlrtBCI, sp) - 1]);
      b_x[2] = (x != ksi);
      y = true;
      k = 0;
      exitg1 = false;
      while ((!exitg1) && (k < 3)) {
        if (b_x[k] == 0) {
          y = false;
          exitg1 = true;
        } else {
          k++;
        }
      }

      if (y) {
        st.site = &g_emlrtRSI;
        k = gridT->size[1];
        i1 = (int32_T)j;
        c_x = t - gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k,
          &v_emlrtBCI, &st) - 1];
        if (c_x < 0.0) {
          b_st.site = &f_emlrtRSI;
          eml_error(&b_st);
        }

        vals = -scalar_erf(muDoubleScalarAbs(x - ksi) / (2.0 *
          muDoubleScalarSqrt(c_x))) / 2.0;
      } else {
        k = gridT->size[1];
        i1 = (int32_T)((uint32_T)j + 1U);
        if (t > gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k,
             &s_emlrtBCI, sp) - 1]) {
          st.site = &h_emlrtRSI;
          k = gridT->size[1];
          i1 = (int32_T)j;
          c_x = t - gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k,
            &t_emlrtBCI, &st) - 1];
          if (c_x < 0.0) {
            b_st.site = &f_emlrtRSI;
            eml_error(&b_st);
          }

          st.site = &i_emlrtRSI;
          k = gridT->size[1];
          i1 = (int32_T)((uint32_T)j + 1U);
          d_x = t - gridT->data[emlrtDynamicBoundsCheckFastR2012b(i1, 1, k,
            &u_emlrtBCI, &st) - 1];
          if (d_x < 0.0) {
            b_st.site = &f_emlrtRSI;
            eml_error(&b_st);
          }

          vals = (b_scalar_erf(muDoubleScalarAbs(x - ksi) / (2.0 *
                    muDoubleScalarSqrt(c_x))) - b_scalar_erf(muDoubleScalarAbs(x
                    - ksi) / (2.0 * muDoubleScalarSqrt(d_x)))) / 2.0;
        } else {
          vals = 0.0;
        }
      }
    }
  }

  return vals;
}
Exemplo n.º 19
0
/* Function Definitions */
real_T batFrcClc_tmp(real_T batPwr, real_T vel, real_T batRstDch, real_T
                     batRstChr, real_T batOcv)
{
  real_T batFrc;
  real_T batRst;
  real_T batFrcCpl_re;
  real_T yr;
  real_T yi;
  real_T ar;
  real_T ai;
  real_T br;
  real_T batFrcCpl_im;

  /*    Skalar - Batteriekraft (E') */
  /*           Skalar - Batterieklemmleistung */
  /*              Skalar - mittlere Geschwindigkeit im Intervall */
  /*        Skalar - Entladewiderstand */
  /*        Skalar - Ladewiderstand */
  /*            Skalar - battery open-circuit voltage */
  /* BATFRCCLC Calculating losses in battery */
  /*    Batteriekraft (E') aus Verlusten in der Batterie berechnen */
  /*        Calucluate battery power losses (E') */
  /*  */
  /*  Version vom 25.05.2016: Zero-Order-Hold (keine mittlere Geschwindigkeit) */
  /*                            Zero-Order-Hold (average velocity is NOT used) */
  /* % Initialisieren der Ausgabe der Funktion */
  /*    initializing the function output */
  batFrc = rtInf;

  /* % Berechnung der Verluste in der Batterie */
  /*    calculating battery losses */
  /*  Berechnung der Batterieenergienderung im Wegschritt in externer Funktion */
  /*  Fallunterscheidung, ob Batterie geladen oder entladen wird */
  /*     */
  /*    calculate the change in battery energy along path_idx in exterior func,   */
  /*    distinguished whether battery is charging or discharging. */
  /*    Assining battery resistance value */
  if (batPwr > 0.0) {
    batRst = batRstDch;
  } else {
    batRst = batRstChr;
  }

  /*  Batterieenergieänderung über dem Weg berechnen. Herleitung der Formel */
  /*  kann zum Beispiel dem Paper mit Chalmers entnommen werden */
  /*    calculate battery power charge for path_idx. Formula derivation can be  */
  /*    found from other papers (for example, Chalmers paper) */
  batFrcCpl_re = 1.0 - 4.0 * batRst / (batOcv * batOcv) * batPwr;
  if (batFrcCpl_re < 0.0) {
    yr = 0.0;
    yi = muDoubleScalarSqrt(muDoubleScalarAbs(batFrcCpl_re));
  } else {
    yr = muDoubleScalarSqrt(batFrcCpl_re);
    yi = 0.0;
  }

  ar = batOcv * batOcv * (yr - 1.0);
  ai = batOcv * batOcv * yi;
  br = 2.0 * batRst * vel;
  if (ai == 0.0) {
    batFrcCpl_re = ar / br;
    batFrcCpl_im = 0.0;
  } else if (ar == 0.0) {
    batFrcCpl_re = 0.0;
    batFrcCpl_im = ai / br;
  } else {
    batFrcCpl_re = ar / br;
    batFrcCpl_im = ai / br;
  }

  /*  Sollte die physikalisch mögliche Batterieleistung überschritten werden, */
  /*  wird der Term unter der Wurzel negativ. In diesem Fall wird die Ausgabe */
  /*  ungültig geschrieben. */
  /*    check to make sure that the battery capacity is not exceeded (when the */
  /*    root becomes negative, the output is no longer valid) (Quadrants 3, 4) */
  if (batFrcCpl_im != 0.0) {
  } else {
    batFrc = batFrcCpl_re;
  }

  return batFrc;
}
Exemplo n.º 20
0
/* Function Definitions */
void rsf2csf(const emxArray_real_T *Ur, const emxArray_real_T *Tr,
             emxArray_creal_T *U, emxArray_creal_T *T)
{
  int32_T y;
  int32_T loop_ub;
  int16_T varargin_1[2];
  int32_T mtmp;
  int32_T m;
  real_T c;
  real_T b;
  real_T temp;
  real_T p;
  real_T bcmax;
  real_T scale;
  real_T bb;
  real_T b_p;
  real_T cs;
  int32_T b_scale;
  real_T b_c;
  real_T mu1_re;
  emlrtPushRtStackR2012b(&bh_emlrtRSI, emlrtRootTLSGlobal);
  y = T->size[0] * T->size[1];
  T->size[0] = Tr->size[0];
  T->size[1] = Tr->size[1];
  emxEnsureCapacity((emxArray__common *)T, y, (int32_T)sizeof(creal_T),
                    &v_emlrtRTEI);
  loop_ub = Tr->size[0] * Tr->size[1];
  for (y = 0; y < loop_ub; y++) {
    T->data[y].re = Tr->data[y];
    T->data[y].im = 0.0;
  }

  y = U->size[0] * U->size[1];
  U->size[0] = Ur->size[0];
  U->size[1] = Ur->size[1];
  emxEnsureCapacity((emxArray__common *)U, y, (int32_T)sizeof(creal_T),
                    &v_emlrtRTEI);
  loop_ub = Ur->size[0] * Ur->size[1];
  for (y = 0; y < loop_ub; y++) {
    U->data[y].re = Ur->data[y];
    U->data[y].im = 0.0;
  }

  for (y = 0; y < 2; y++) {
    varargin_1[y] = (int16_T)Tr->size[y];
  }

  mtmp = varargin_1[0];
  if (varargin_1[1] < varargin_1[0]) {
    mtmp = varargin_1[1];
  }

  for (y = 0; y < 2; y++) {
    varargin_1[y] = (int16_T)Ur->size[y];
  }

  loop_ub = varargin_1[0];
  if (varargin_1[1] < varargin_1[0]) {
    loop_ub = varargin_1[1];
  }

  mtmp = (int32_T)muDoubleScalarMin(mtmp, loop_ub);
  if (mtmp == 0) {
  } else {
    for (m = mtmp - 1; m + 1 >= 2; m--) {
      if (Tr->data[m + Tr->size[0] * (m - 1)] != 0.0) {
        emlrtPushRtStackR2012b(&ch_emlrtRSI, emlrtRootTLSGlobal);
        c = Tr->data[m + Tr->size[0] * (m - 1)];
        b = Tr->data[(m + Tr->size[0] * m) - 1];
        temp = Tr->data[(m + Tr->size[0] * (m - 1)) - 1];
        if (Tr->data[m + Tr->size[0] * (m - 1)] == 0.0) {
        } else if (Tr->data[(m + Tr->size[0] * m) - 1] == 0.0) {
          temp = Tr->data[m + Tr->size[0] * m];
          b = -Tr->data[m + Tr->size[0] * (m - 1)];
          c = 0.0;
        } else if ((Tr->data[(m + Tr->size[0] * (m - 1)) - 1] - Tr->data[m +
                    Tr->size[0] * m] == 0.0) && ((Tr->data[(m + Tr->size[0] * m)
          - 1] < 0.0) != (Tr->data[m + Tr->size[0] * (m - 1)] < 0.0))) {
        } else {
          temp = Tr->data[(m + Tr->size[0] * (m - 1)) - 1] - Tr->data[m +
            Tr->size[0] * m];
          p = 0.5 * temp;
          bcmax = muDoubleScalarMax(muDoubleScalarAbs(Tr->data[(m + Tr->size[0] *
            m) - 1]), muDoubleScalarAbs(Tr->data[m + Tr->size[0] * (m - 1)]));
          if (!(Tr->data[(m + Tr->size[0] * m) - 1] < 0.0)) {
            loop_ub = 1;
          } else {
            loop_ub = -1;
          }

          if (!(Tr->data[m + Tr->size[0] * (m - 1)] < 0.0)) {
            y = 1;
          } else {
            y = -1;
          }

          scale = muDoubleScalarMax(muDoubleScalarAbs(p), bcmax);
          bcmax = p / scale * p + bcmax / scale * (muDoubleScalarMin
            (muDoubleScalarAbs(Tr->data[(m + Tr->size[0] * m) - 1]),
             muDoubleScalarAbs(Tr->data[m + Tr->size[0] * (m - 1)])) * (real_T)
            loop_ub * (real_T)y);
          if (bcmax >= 8.8817841970012523E-16) {
            emlrtPushRtStackR2012b(&gg_emlrtRSI, emlrtRootTLSGlobal);
            bb = muDoubleScalarSqrt(scale) * muDoubleScalarSqrt(bcmax);
            emlrtPopRtStackR2012b(&gg_emlrtRSI, emlrtRootTLSGlobal);
            if (!(p < 0.0)) {
              b_p = bb;
            } else {
              b_p = -bb;
            }

            temp = Tr->data[m + Tr->size[0] * m] + (p + b_p);
            b = Tr->data[(m + Tr->size[0] * m) - 1] - Tr->data[m + Tr->size[0] *
              (m - 1)];
            c = 0.0;
          } else {
            scale = Tr->data[(m + Tr->size[0] * m) - 1] + Tr->data[m + Tr->size
              [0] * (m - 1)];
            bcmax = muDoubleScalarHypot(scale, temp);
            emlrtPushRtStackR2012b(&hg_emlrtRSI, emlrtRootTLSGlobal);
            bb = 0.5 * (1.0 + muDoubleScalarAbs(scale) / bcmax);
            if (bb < 0.0) {
              emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
              eml_error();
              emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
            }

            cs = muDoubleScalarSqrt(bb);
            emlrtPopRtStackR2012b(&hg_emlrtRSI, emlrtRootTLSGlobal);
            if (!(scale < 0.0)) {
              b_scale = 1;
            } else {
              b_scale = -1;
            }

            bcmax = -(p / (bcmax * cs)) * (real_T)b_scale;
            scale = Tr->data[(m + Tr->size[0] * (m - 1)) - 1] * cs + Tr->data[(m
              + Tr->size[0] * m) - 1] * bcmax;
            bb = -Tr->data[(m + Tr->size[0] * (m - 1)) - 1] * bcmax + Tr->data
              [(m + Tr->size[0] * m) - 1] * cs;
            p = Tr->data[m + Tr->size[0] * (m - 1)] * cs + Tr->data[m + Tr->
              size[0] * m] * bcmax;
            temp = -Tr->data[m + Tr->size[0] * (m - 1)] * bcmax + Tr->data[m +
              Tr->size[0] * m] * cs;
            b = bb * cs + temp * bcmax;
            c = -scale * bcmax + p * cs;
            temp = 0.5 * ((scale * cs + p * bcmax) + (-bb * bcmax + temp * cs));
            if (c != 0.0) {
              if (b != 0.0) {
                if ((b < 0.0) == (c < 0.0)) {
                  emlrtPushRtStackR2012b(&ig_emlrtRSI, emlrtRootTLSGlobal);
                  emlrtPopRtStackR2012b(&ig_emlrtRSI, emlrtRootTLSGlobal);
                  emlrtPushRtStackR2012b(&jg_emlrtRSI, emlrtRootTLSGlobal);
                  emlrtPopRtStackR2012b(&jg_emlrtRSI, emlrtRootTLSGlobal);
                  bb = muDoubleScalarSqrt(muDoubleScalarAbs(b)) *
                    muDoubleScalarSqrt(muDoubleScalarAbs(c));
                  emlrtPushRtStackR2012b(&kg_emlrtRSI, emlrtRootTLSGlobal);
                  emlrtPopRtStackR2012b(&kg_emlrtRSI, emlrtRootTLSGlobal);
                  if (!(c < 0.0)) {
                    b_c = bb;
                  } else {
                    b_c = -bb;
                  }

                  temp += b_c;
                  b -= c;
                  c = 0.0;
                }
              } else {
                b = -c;
                c = 0.0;
              }
            }
          }
        }

        if (c == 0.0) {
          bcmax = 0.0;
        } else {
          emlrtPushRtStackR2012b(&lg_emlrtRSI, emlrtRootTLSGlobal);
          bcmax = muDoubleScalarSqrt(muDoubleScalarAbs(b)) * muDoubleScalarSqrt
            (muDoubleScalarAbs(c));
          emlrtPopRtStackR2012b(&lg_emlrtRSI, emlrtRootTLSGlobal);
        }

        emlrtPopRtStackR2012b(&ch_emlrtRSI, emlrtRootTLSGlobal);
        mu1_re = temp - Tr->data[m + Tr->size[0] * m];
        scale = muDoubleScalarHypot(muDoubleScalarHypot(mu1_re, bcmax), Tr->
          data[m + Tr->size[0] * (m - 1)]);
        if (bcmax == 0.0) {
          mu1_re /= scale;
          cs = 0.0;
        } else if (mu1_re == 0.0) {
          mu1_re = 0.0;
          cs = bcmax / scale;
        } else {
          mu1_re /= scale;
          cs = bcmax / scale;
        }

        c = Tr->data[m + Tr->size[0] * (m - 1)] / scale;
        emlrtPushRtStackR2012b(&dh_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&dh_emlrtRSI, emlrtRootTLSGlobal);
        for (loop_ub = m - 1; loop_ub + 1 <= mtmp; loop_ub++) {
          b = T->data[(m + T->size[0] * loop_ub) - 1].re;
          temp = T->data[(m + T->size[0] * loop_ub) - 1].im;
          bb = T->data[(m + T->size[0] * loop_ub) - 1].re;
          p = T->data[(m + T->size[0] * loop_ub) - 1].im;
          bcmax = T->data[(m + T->size[0] * loop_ub) - 1].im;
          scale = T->data[(m + T->size[0] * loop_ub) - 1].re;
          T->data[(m + T->size[0] * loop_ub) - 1].re = (mu1_re * bb + cs * p) +
            c * T->data[m + T->size[0] * loop_ub].re;
          T->data[(m + T->size[0] * loop_ub) - 1].im = (mu1_re * bcmax - cs *
            scale) + c * T->data[m + T->size[0] * loop_ub].im;
          bcmax = mu1_re * T->data[m + T->size[0] * loop_ub].re - cs * T->data[m
            + T->size[0] * loop_ub].im;
          scale = mu1_re * T->data[m + T->size[0] * loop_ub].im + cs * T->data[m
            + T->size[0] * loop_ub].re;
          T->data[m + T->size[0] * loop_ub].re = bcmax - c * b;
          T->data[m + T->size[0] * loop_ub].im = scale - c * temp;
        }

        emlrtPushRtStackR2012b(&eh_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&eh_emlrtRSI, emlrtRootTLSGlobal);
        for (loop_ub = 0; loop_ub + 1 <= m + 1; loop_ub++) {
          b = T->data[loop_ub + T->size[0] * (m - 1)].re;
          temp = T->data[loop_ub + T->size[0] * (m - 1)].im;
          bcmax = mu1_re * T->data[loop_ub + T->size[0] * (m - 1)].re - cs *
            T->data[loop_ub + T->size[0] * (m - 1)].im;
          scale = mu1_re * T->data[loop_ub + T->size[0] * (m - 1)].im + cs *
            T->data[loop_ub + T->size[0] * (m - 1)].re;
          bb = T->data[loop_ub + T->size[0] * m].re;
          p = T->data[loop_ub + T->size[0] * m].im;
          T->data[loop_ub + T->size[0] * (m - 1)].re = bcmax + c * bb;
          T->data[loop_ub + T->size[0] * (m - 1)].im = scale + c * p;
          bb = T->data[loop_ub + T->size[0] * m].re;
          p = T->data[loop_ub + T->size[0] * m].im;
          bcmax = T->data[loop_ub + T->size[0] * m].im;
          scale = T->data[loop_ub + T->size[0] * m].re;
          T->data[loop_ub + T->size[0] * m].re = (mu1_re * bb + cs * p) - c * b;
          T->data[loop_ub + T->size[0] * m].im = (mu1_re * bcmax - cs * scale) -
            c * temp;
        }

        emlrtPushRtStackR2012b(&fh_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&fh_emlrtRSI, emlrtRootTLSGlobal);
        for (loop_ub = 0; loop_ub + 1 <= mtmp; loop_ub++) {
          b = U->data[loop_ub + U->size[0] * (m - 1)].re;
          temp = U->data[loop_ub + U->size[0] * (m - 1)].im;
          bcmax = mu1_re * U->data[loop_ub + U->size[0] * (m - 1)].re - cs *
            U->data[loop_ub + U->size[0] * (m - 1)].im;
          scale = mu1_re * U->data[loop_ub + U->size[0] * (m - 1)].im + cs *
            U->data[loop_ub + U->size[0] * (m - 1)].re;
          bb = U->data[loop_ub + U->size[0] * m].re;
          p = U->data[loop_ub + U->size[0] * m].im;
          U->data[loop_ub + U->size[0] * (m - 1)].re = bcmax + c * bb;
          U->data[loop_ub + U->size[0] * (m - 1)].im = scale + c * p;
          bb = U->data[loop_ub + U->size[0] * m].re;
          p = U->data[loop_ub + U->size[0] * m].im;
          bcmax = U->data[loop_ub + U->size[0] * m].im;
          scale = U->data[loop_ub + U->size[0] * m].re;
          U->data[loop_ub + U->size[0] * m].re = (mu1_re * bb + cs * p) - c * b;
          U->data[loop_ub + U->size[0] * m].im = (mu1_re * bcmax - cs * scale) -
            c * temp;
        }

        T->data[m + T->size[0] * (m - 1)].re = 0.0;
        T->data[m + T->size[0] * (m - 1)].im = 0.0;
      }
    }
  }

  emlrtPopRtStackR2012b(&bh_emlrtRSI, emlrtRootTLSGlobal);
}
Exemplo n.º 21
0
static void sf_c3_controller1(SFc3_controller1InstanceStruct *chartInstance)
{
  int32_T c3_previousEvent;
  real_T c3_hoistedGlobal;
  real_T c3_u;
  uint32_T c3_debug_family_var_map[5];
  real_T c3_T;
  real_T c3_nargin = 1.0;
  real_T c3_nargout = 1.0;
  real_T c3_y;
  real_T c3_x;
  real_T c3_b_x;
  real_T c3_b_y;
  real_T c3_c_x;
  real_T c3_d_x;
  real_T c3_c_y;
  real_T c3_b;
  real_T c3_d_y;
  real_T c3_A;
  real_T c3_B;
  real_T c3_e_x;
  real_T c3_e_y;
  real_T c3_f_x;
  real_T c3_f_y;
  real_T c3_g_x;
  real_T c3_g_y;
  real_T *c3_b_u;
  real_T *c3_h_y;
  c3_h_y = (real_T *)ssGetOutputPortSignal(chartInstance->S, 1);
  c3_b_u = (real_T *)ssGetInputPortSignal(chartInstance->S, 0);
  _sfTime_ = (real_T)ssGetT(chartInstance->S);
  _SFD_CC_CALL(CHART_ENTER_SFUNCTION_TAG, 2);
  _SFD_DATA_RANGE_CHECK(*c3_b_u, 0U);
  _SFD_DATA_RANGE_CHECK(*c3_h_y, 1U);
  c3_previousEvent = _sfEvent_;
  _sfEvent_ = CALL_EVENT;
  _SFD_CC_CALL(CHART_ENTER_DURING_FUNCTION_TAG, 2);
  c3_hoistedGlobal = *c3_b_u;
  c3_u = c3_hoistedGlobal;
  sf_debug_symbol_scope_push_eml(0U, 5U, 5U, c3_debug_family_names,
    c3_debug_family_var_map);
  sf_debug_symbol_scope_add_eml(&c3_T, c3_sf_marshall, 0U);
  sf_debug_symbol_scope_add_eml(&c3_nargin, c3_sf_marshall, 1U);
  sf_debug_symbol_scope_add_eml(&c3_nargout, c3_sf_marshall, 2U);
  sf_debug_symbol_scope_add_eml(&c3_u, c3_sf_marshall, 3U);
  sf_debug_symbol_scope_add_eml(&c3_y, c3_sf_marshall, 4U);
  CV_EML_FCN(0, 0);

  /*  hard limit cutoff function. */
  _SFD_EML_CALL(0, 4);
  c3_T = 100.0;
  _SFD_EML_CALL(0, 5);
  c3_x = c3_u;
  c3_b_x = c3_x;
  c3_b_y = muDoubleScalarAbs(c3_b_x);
  if (CV_EML_IF(0, 0, c3_b_y > c3_T)) {
    _SFD_EML_CALL(0, 6);
    c3_c_x = c3_u;
    c3_d_x = c3_c_x;
    c3_c_y = muDoubleScalarAbs(c3_d_x);
    c3_b = c3_c_y;
    c3_d_y = 100.0 * c3_b;
    c3_A = c3_d_y;
    c3_B = c3_u;
    c3_e_x = c3_A;
    c3_e_y = c3_B;
    c3_f_x = c3_e_x;
    c3_f_y = c3_e_y;
    c3_g_x = c3_f_x;
    c3_g_y = c3_f_y;
    c3_u = c3_g_x / c3_g_y;
  }

  _SFD_EML_CALL(0, 8);
  c3_y = c3_u;
  _SFD_EML_CALL(0, -8);
  sf_debug_symbol_scope_pop();
  *c3_h_y = c3_y;
  _SFD_CC_CALL(EXIT_OUT_OF_FUNCTION_TAG, 2);
  _sfEvent_ = c3_previousEvent;
  sf_debug_check_for_state_inconsistency(_controller1MachineNumber_,
    chartInstance->chartNumber, chartInstance->instanceNumber);
}
Exemplo n.º 22
0
void sammon(sammonStackData *SD, const real_T x[1000000], real_T y[2000], real_T
            *E)
{
  real_T B;
  int32_T i;
  real_T dv0[1000];
  int32_T b_i;
  boolean_T exitg1;
  real_T alpha1;
  real_T beta1;
  char_T TRANSB;
  char_T TRANSA;
  ptrdiff_t m_t;
  ptrdiff_t n_t;
  ptrdiff_t k_t;
  ptrdiff_t lda_t;
  ptrdiff_t ldb_t;
  ptrdiff_t ldc_t;
  double * alpha1_t;
  double * Aia0_t;
  double * Bib0_t;
  double * beta1_t;
  double * Cic0_t;
  real_T g[2000];
  real_T y2[2000];
  real_T b_y[2000];
  real_T c_y[2000];
  real_T d_y[2000];
  real_T e_y[2000];
  real_T b_g[2000];
  int32_T j;
  int32_T b_j;
  boolean_T exitg2;
  real_T dv1[1000];
  real_T E_new;

  /* #codgen */
  /*  */
  /*  SAMMON - apply Sammon's nonlinear mapping  */
  /*  */
  /*     Y = SAMMON(X) applies Sammon's nonlinear mapping procedure on */
  /*     multivariate data X, where each row represents a pattern and each column */
  /*     represents a feature.  On completion, Y contains the corresponding */
  /*     co-ordinates of each point on the map.  By default, a two-dimensional */
  /*     map is created.  Note if X contains any duplicated rows, SAMMON will */
  /*     fail (ungracefully).  */
  /*  */
  /*     [Y,E] = SAMMON(X) also returns the value of the cost function in E (i.e. */
  /*     the stress of the mapping). */
  /*  */
  /*     An N-dimensional output map is generated by Y = SAMMON(X,N) . */
  /*  */
  /*     A set of optimisation options can also be specified using a third */
  /*     argument, Y = SAMMON(X,N,OPTS) , where OPTS is a structure with fields: */
  /*  */
  /*        MaxIter        - maximum number of iterations */
  /*        TolFun         - relative tolerance on objective function */
  /*        MaxHalves      - maximum number of step halvings */
  /*        Input          - {'raw','distance'} if set to 'distance', X is  */
  /*                         interpreted as a matrix of pairwise distances. */
  /*        Display        - {'off', 'on', 'iter'} */
  /*        Initialisation - {'pca', 'random'} */
  /*  */
  /*     The default options structure can be retrieved by calling SAMMON with */
  /*     no parameters. */
  /*  */
  /*     References : */
  /*  */
  /*        [1] Sammon, John W. Jr., "A Nonlinear Mapping for Data Structure */
  /*            Analysis", IEEE Transactions on Computers, vol. C-18, no. 5, */
  /*            pp 401-409, May 1969. */
  /*  */
  /*     See also : SAMMON_TEST */
  /*  */
  /*  File        : sammon.m */
  /*  */
  /*  Date        : Monday 12th November 2007. */
  /*  */
  /*  Author      : Gavin C. Cawley and Nicola L. C. Talbot */
  /*  */
  /*  Description : Simple vectorised MATLAB implementation of Sammon's non-linear */
  /*                mapping algorithm [1]. */
  /*  */
  /*  References  : [1] Sammon, John W. Jr., "A Nonlinear Mapping for Data */
  /*                    Structure Analysis", IEEE Transactions on Computers, */
  /*                    vol. C-18, no. 5, pp 401-409, May 1969. */
  /*  */
  /*  History     : 10/08/2004 - v1.00 */
  /*                11/08/2004 - v1.10 Hessian made positive semidefinite */
  /*                13/08/2004 - v1.11 minor optimisation */
  /*                12/11/2007 - v1.20 initialisation using the first n principal */
  /*                                   components. */
  /*  */
  /*  Thanks      : Dr Nick Hamilton ([email protected]) for supplying the */
  /*                code for implementing initialisation using the first n */
  /*                principal components (introduced in v1.20). */
  /*  */
  /*  To do       : The current version does not take advantage of the symmetry */
  /*                of the distance matrix in order to allow for easy */
  /*                vectorisation.  This may not be a good choice for very large */
  /*                datasets, so perhaps one day I'll get around to doing a MEX */
  /*                version using the BLAS library etc. for very large datasets. */
  /*  */
  /*  Copyright   : (c) Dr Gavin C. Cawley, November 2007. */
  /*  */
  /*     This program is free software; you can redistribute it and/or modify */
  /*     it under the terms of the GNU General Public License as published by */
  /*     the Free Software Foundation; either version 2 of the License, or */
  /*     (at your option) any later version. */
  /*  */
  /*     This program is distributed in the hope that it will be useful, */
  /*     but WITHOUT ANY WARRANTY; without even the implied warranty of */
  /*     MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the */
  /*     GNU General Public License for more details. */
  /*  */
  /*     You should have received a copy of the GNU General Public License */
  /*     along with this program; if not, write to the Free Software */
  /*     Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */
  /*  */
  /*  use the default options structure */
  /*  create distance matrix unless given by parameters */
  emlrtPushRtStackR2012b(&emlrtRSI, emlrtRootTLSGlobal);
  euclid(SD, x, x, SD->f2.D);
  emlrtPopRtStackR2012b(&emlrtRSI, emlrtRootTLSGlobal);

  /*  remaining initialisation */
  B = b_sum(SD->f2.D);
  eye(SD->f2.delta);
  for (i = 0; i < 1000000; i++) {
    SD->f2.D[i] += SD->f2.delta[i];
  }

  rdivide(1.0, SD->f2.D, SD->f2.Dinv);
  emlrtPushRtStackR2012b(&b_emlrtRSI, emlrtRootTLSGlobal);
  randn(y);
  emlrtPopRtStackR2012b(&b_emlrtRSI, emlrtRootTLSGlobal);
  emlrtPushRtStackR2012b(&c_emlrtRSI, emlrtRootTLSGlobal);
  b_euclid(SD, y, y, SD->f2.d);
  eye(SD->f2.delta);
  for (i = 0; i < 1000000; i++) {
    SD->f2.d[i] += SD->f2.delta[i];
  }

  emlrtPopRtStackR2012b(&c_emlrtRSI, emlrtRootTLSGlobal);
  rdivide(1.0, SD->f2.d, SD->f2.dinv);
  for (i = 0; i < 1000000; i++) {
    SD->f2.b_D[i] = SD->f2.D[i] - SD->f2.d[i];
  }

  power(SD->f2.b_D, SD->f2.delta);
  for (i = 0; i < 1000000; i++) {
    SD->f2.d[i] = SD->f2.delta[i] * SD->f2.Dinv[i];
  }

  d_sum(SD->f2.d, dv0);
  *E = e_sum(dv0);

  /*  get on with it */
  b_i = 0;
  exitg1 = FALSE;
  while ((exitg1 == FALSE) && (b_i < 500)) {
    /*  compute gradient, Hessian and search direction (note it is actually */
    /*  1/4 of the gradient and Hessian, but the step size is just the ratio */
    /*  of the gradient and the diagonal of the Hessian so it doesn't matter). */
    for (i = 0; i < 1000000; i++) {
      SD->f2.delta[i] = SD->f2.dinv[i] - SD->f2.Dinv[i];
    }

    emlrtPushRtStackR2012b(&d_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    alpha1 = 1.0;
    beta1 = 0.0;
    TRANSB = 'N';
    TRANSA = 'N';
    for (i = 0; i < 2000; i++) {
      SD->f2.y_old[i] = 1.0;
      SD->f2.deltaone[i] = 0.0;
    }

    emlrtPushRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    m_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    n_t = (ptrdiff_t)(2);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    k_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    lda_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldb_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldc_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    alpha1_t = (double *)(&alpha1);
    emlrtPopRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    Aia0_t = (double *)(&SD->f2.delta[0]);
    emlrtPopRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    Bib0_t = (double *)(&SD->f2.y_old[0]);
    emlrtPopRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    beta1_t = (double *)(&beta1);
    emlrtPopRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    Cic0_t = (double *)(&SD->f2.deltaone[0]);
    emlrtPopRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    dgemm(&TRANSA, &TRANSB, &m_t, &n_t, &k_t, alpha1_t, Aia0_t, &lda_t, Bib0_t,
          &ldb_t, beta1_t, Cic0_t, &ldc_t);
    emlrtPopRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&d_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&e_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    alpha1 = 1.0;
    beta1 = 0.0;
    TRANSB = 'N';
    TRANSA = 'N';
    memset(&g[0], 0, 2000U * sizeof(real_T));
    emlrtPushRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    m_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    n_t = (ptrdiff_t)(2);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    k_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    lda_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldb_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldc_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    alpha1_t = (double *)(&alpha1);
    emlrtPopRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    Aia0_t = (double *)(&SD->f2.delta[0]);
    emlrtPopRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    Bib0_t = (double *)(&y[0]);
    emlrtPopRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    beta1_t = (double *)(&beta1);
    emlrtPopRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    Cic0_t = (double *)(&g[0]);
    emlrtPopRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    dgemm(&TRANSA, &TRANSB, &m_t, &n_t, &k_t, alpha1_t, Aia0_t, &lda_t, Bib0_t,
          &ldb_t, beta1_t, Cic0_t, &ldc_t);
    emlrtPopRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    for (i = 0; i < 2000; i++) {
      g[i] -= y[i] * SD->f2.deltaone[i];
    }

    emlrtPopRtStackR2012b(&e_emlrtRSI, emlrtRootTLSGlobal);
    c_power(SD->f2.dinv, SD->f2.delta);
    b_power(y, y2);
    emlrtPushRtStackR2012b(&f_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    alpha1 = 1.0;
    beta1 = 0.0;
    TRANSB = 'N';
    TRANSA = 'N';
    memset(&b_y[0], 0, 2000U * sizeof(real_T));
    emlrtPushRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    m_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    n_t = (ptrdiff_t)(2);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    k_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    lda_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldb_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldc_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    alpha1_t = (double *)(&alpha1);
    emlrtPopRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    Aia0_t = (double *)(&SD->f2.delta[0]);
    emlrtPopRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    Bib0_t = (double *)(&y2[0]);
    emlrtPopRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    beta1_t = (double *)(&beta1);
    emlrtPopRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    Cic0_t = (double *)(&b_y[0]);
    emlrtPopRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    dgemm(&TRANSA, &TRANSB, &m_t, &n_t, &k_t, alpha1_t, Aia0_t, &lda_t, Bib0_t,
          &ldb_t, beta1_t, Cic0_t, &ldc_t);
    emlrtPopRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    for (i = 0; i < 2000; i++) {
      c_y[i] = 2.0 * y[i];
    }

    emlrtPushRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    alpha1 = 1.0;
    beta1 = 0.0;
    TRANSB = 'N';
    TRANSA = 'N';
    memset(&d_y[0], 0, 2000U * sizeof(real_T));
    emlrtPushRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    m_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    n_t = (ptrdiff_t)(2);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    k_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    lda_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldb_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldc_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    alpha1_t = (double *)(&alpha1);
    emlrtPopRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    Aia0_t = (double *)(&SD->f2.delta[0]);
    emlrtPopRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    Bib0_t = (double *)(&y[0]);
    emlrtPopRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    beta1_t = (double *)(&beta1);
    emlrtPopRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    Cic0_t = (double *)(&d_y[0]);
    emlrtPopRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    dgemm(&TRANSA, &TRANSB, &m_t, &n_t, &k_t, alpha1_t, Aia0_t, &lda_t, Bib0_t,
          &ldb_t, beta1_t, Cic0_t, &ldc_t);
    emlrtPopRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    alpha1 = 1.0;
    beta1 = 0.0;
    TRANSB = 'N';
    TRANSA = 'N';
    for (i = 0; i < 2000; i++) {
      SD->f2.y_old[i] = 1.0;
      e_y[i] = 0.0;
    }

    emlrtPushRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    m_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    n_t = (ptrdiff_t)(2);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    k_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    lda_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldb_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    ldc_t = (ptrdiff_t)(1000);
    emlrtPopRtStackR2012b(&x_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&q_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    alpha1_t = (double *)(&alpha1);
    emlrtPopRtStackR2012b(&r_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    Aia0_t = (double *)(&SD->f2.delta[0]);
    emlrtPopRtStackR2012b(&s_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    Bib0_t = (double *)(&SD->f2.y_old[0]);
    emlrtPopRtStackR2012b(&t_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    beta1_t = (double *)(&beta1);
    emlrtPopRtStackR2012b(&u_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    Cic0_t = (double *)(&e_y[0]);
    emlrtPopRtStackR2012b(&v_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPushRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    dgemm(&TRANSA, &TRANSB, &m_t, &n_t, &k_t, alpha1_t, Aia0_t, &lda_t, Bib0_t,
          &ldb_t, beta1_t, Cic0_t, &ldc_t);
    emlrtPopRtStackR2012b(&w_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&k_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&j_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&i_emlrtRSI, emlrtRootTLSGlobal);
    emlrtPopRtStackR2012b(&f_emlrtRSI, emlrtRootTLSGlobal);
    for (i = 0; i < 2000; i++) {
      SD->f2.y_old[i] = ((b_y[i] - SD->f2.deltaone[i]) - c_y[i] * d_y[i]) + y2[i]
        * e_y[i];
      b_g[i] = -g[i];
    }

    b_abs(SD->f2.y_old, y2);
    for (i = 0; i < 2000; i++) {
      SD->f2.deltaone[i] = y2[i];
      SD->f2.y_old[i] = y[i];
    }

    b_rdivide(b_g, SD->f2.deltaone, y2);

    /*  use step-halving procedure to ensure progress is made */
    j = 1;
    b_j = 0;
    exitg2 = FALSE;
    while ((exitg2 == FALSE) && (b_j < 20)) {
      j = b_j + 1;
      for (i = 0; i < 2000; i++) {
        y[i] = SD->f2.y_old[i] + y2[i];
      }

      emlrtPushRtStackR2012b(&g_emlrtRSI, emlrtRootTLSGlobal);
      b_euclid(SD, y, y, SD->f2.d);
      eye(SD->f2.delta);
      for (i = 0; i < 1000000; i++) {
        SD->f2.d[i] += SD->f2.delta[i];
      }

      emlrtPopRtStackR2012b(&g_emlrtRSI, emlrtRootTLSGlobal);
      rdivide(1.0, SD->f2.d, SD->f2.dinv);
      for (i = 0; i < 1000000; i++) {
        SD->f2.b_D[i] = SD->f2.D[i] - SD->f2.d[i];
      }

      power(SD->f2.b_D, SD->f2.delta);
      for (i = 0; i < 1000000; i++) {
        SD->f2.d[i] = SD->f2.delta[i] * SD->f2.Dinv[i];
      }

      d_sum(SD->f2.d, dv1);
      E_new = e_sum(dv1);
      if (E_new < *E) {
        exitg2 = TRUE;
      } else {
        for (i = 0; i < 2000; i++) {
          y2[i] *= 0.5;
        }

        b_j++;
        emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar,
          emlrtRootTLSGlobal);
      }
    }

    /*  bomb out if too many halving steps are required */
    if ((j == 20) || (muDoubleScalarAbs((*E - E_new) / *E) < 1.0E-9)) {
      exitg1 = TRUE;
    } else {
      /*  evaluate termination criterion */
      /*  report progress */
      *E = E_new;
      b_i++;
      emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, emlrtRootTLSGlobal);
    }
  }

  /*  fiddle stress to match the original Sammon paper */
  *E *= 0.5 / B;
}
Exemplo n.º 23
0
/* Function Definitions */
void linearODESSEP2X4(const emxArray_real_T *T, const emxArray_real_T *I)
{
  int32_T i;
  real_T hoistedGlobal[9];
  int32_T j;
  int32_T b_i;
  real_T normA;
  real_T y[81];
  real_T F[81];
  boolean_T exitg2;
  real_T s;
  boolean_T exitg1;
  static const real_T theta[5] = { 0.01495585217958292, 0.253939833006323,
    0.95041789961629319, 2.097847961257068, 5.3719203511481517 };

  static const int8_T iv2[5] = { 3, 5, 7, 9, 13 };

  int32_T eint;
  real_T b_y[81];
  real_T beta1;
  char_T TRANSB;
  char_T TRANSA;
  ptrdiff_t m_t;
  ptrdiff_t n_t;
  ptrdiff_t k_t;
  ptrdiff_t lda_t;
  ptrdiff_t ldb_t;
  ptrdiff_t ldc_t;
  double * alpha1_t;
  double * Aia0_t;
  double * Bib0_t;
  double * beta1_t;
  double * Cic0_t;
  emlrtPushRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);

  /* global k1 k2 k3 k4 k5 k6 k7 k8 k9 k10 k11 k12 L1 L2 L3 L4 H1 H2 H3 H4 g1 g2 E1 E2 alpha A J Q; */
  /* Right */
  /* [C1,C2,C3,Q1,Q2,Q3,D1,D2,Z] */
  Q[0] = -k2 * A - L2 * J;
  Q[9] = L2 * J;
  Q[18] = 0.0;
  Q[27] = k2 * A;
  Q[36] = 0.0;
  Q[45] = 0.0;
  Q[54] = 0.0;
  Q[63] = 0.0;
  Q[72] = 0.0;
  Q[1] = L1;
  Q[10] = (-k4 * A - L1) - L4 * J;
  Q[19] = L4 * J;
  Q[28] = 0.0;
  Q[37] = k4 * A;
  Q[46] = 0.0;
  Q[55] = 0.0;
  Q[64] = 0.0;
  Q[73] = 0.0;
  Q[2] = 0.0;
  Q[11] = L3;
  Q[20] = -k6 * A - L3;
  Q[29] = 0.0;
  Q[38] = 0.0;
  Q[47] = k6 * A;
  Q[56] = 0.0;
  Q[65] = 0.0;
  Q[74] = 0.0;
  Q[3] = k1;
  Q[12] = 0.0;
  Q[21] = 0.0;
  Q[30] = (-k1 - L2 * J) - H2;
  Q[39] = L2 * J;
  Q[48] = 0.0;
  Q[57] = 0.0;
  Q[66] = H2;
  Q[75] = 0.0;
  Q[4] = 0.0;
  Q[13] = k3;
  Q[22] = 0.0;
  Q[31] = L1;
  Q[40] = (-k3 - L1) - L4 * J;
  Q[49] = L4 * J;
  Q[58] = 0.0;
  Q[67] = 0.0;
  Q[76] = 0.0;
  Q[5] = 0.0;
  Q[14] = 0.0;
  Q[23] = k5;
  Q[32] = 0.0;
  Q[41] = L3;
  Q[50] = -k5 - L3;
  Q[59] = 0.0;
  Q[68] = 0.0;
  Q[77] = 0.0;
  Q[6] = H1;
  Q[15] = 0.0;
  Q[24] = 0.0;
  Q[33] = 0.0;
  Q[42] = 0.0;
  Q[51] = 0.0;
  Q[60] = -k2 * A - H1;
  Q[69] = k2 * A;
  Q[78] = 0.0;
  Q[7] = 0.0;
  Q[16] = 0.0;
  Q[25] = 0.0;
  Q[34] = 0.0;
  Q[43] = 0.0;
  Q[52] = 0.0;
  Q[61] = k1;
  Q[70] = -k1 - H3;
  Q[79] = H3;
  Q[8] = H4;
  Q[17] = 0.0;
  Q[26] = 0.0;
  Q[35] = 0.0;
  Q[44] = 0.0;
  Q[53] = 0.0;
  Q[62] = 0.0;
  Q[71] = 0.0;
  Q[80] = -H4;
  Q_dirty |= 1U;
  emlrtPopRtStackR2012b(&l_emlrtRSI, emlrtRootTLSGlobal);
  i = 0;
  while (i <= T->size[0] - 1) {
    emlrtPushRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    memcpy(&hoistedGlobal[0], &p0[0], 9U * sizeof(real_T));
    j = T->size[0];
    b_i = (int32_T)(1.0 + (real_T)i);
    emlrtDynamicBoundsCheckFastR2012b(b_i, 1, j, &t_emlrtBCI, emlrtRootTLSGlobal);
    normA = T->data[i];
    for (j = 0; j < 81; j++) {
      y[j] = Q[j] * normA;
    }

    normA = 0.0;
    j = 0;
    exitg2 = FALSE;
    while ((exitg2 == FALSE) && (j < 9)) {
      s = 0.0;
      for (b_i = 0; b_i < 9; b_i++) {
        s += muDoubleScalarAbs(y[b_i + 9 * j]);
      }

      if (muDoubleScalarIsNaN(s)) {
        normA = rtNaN;
        exitg2 = TRUE;
      } else {
        if (s > normA) {
          normA = s;
        }

        j++;
      }
    }

    if (normA <= 5.3719203511481517) {
      b_i = 0;
      exitg1 = FALSE;
      while ((exitg1 == FALSE) && (b_i < 5)) {
        if (normA <= theta[b_i]) {
          emlrtPushRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
          PadeApproximantOfDegree(y, iv2[b_i], F);
          emlrtPopRtStackR2012b(&n_emlrtRSI, emlrtRootTLSGlobal);
          exitg1 = TRUE;
        } else {
          b_i++;
        }
      }
    } else {
      normA /= 5.3719203511481517;
      if ((!muDoubleScalarIsInf(normA)) && (!muDoubleScalarIsNaN(normA))) {
        normA = frexp(normA, &eint);
        j = eint;
      } else {
        j = 0;
      }

      s = j;
      if (normA == 0.5) {
        s = (real_T)j - 1.0;
      }

      normA = muDoubleScalarPower(2.0, s);
      emlrtPushRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
      for (j = 0; j < 81; j++) {
        b_y[j] = y[j] / normA;
      }

      PadeApproximantOfDegree(b_y, 13.0, F);
      emlrtPopRtStackR2012b(&o_emlrtRSI, emlrtRootTLSGlobal);
      emlrtForLoopVectorCheckR2012b(1.0, 1.0, s, mxDOUBLE_CLASS, (int32_T)s,
        &g_emlrtRTEI, emlrtRootTLSGlobal);
      for (j = 0; j < (int32_T)s; j++) {
        emlrtPushRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&cb_emlrtRSI, emlrtRootTLSGlobal);
        memcpy(&y[0], &F[0], 81U * sizeof(real_T));
        emlrtPushRtStackR2012b(&db_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&eb_emlrtRSI, emlrtRootTLSGlobal);
        normA = 1.0;
        beta1 = 0.0;
        TRANSB = 'N';
        TRANSA = 'N';
        memset(&F[0], 0, 81U * sizeof(real_T));
        emlrtPushRtStackR2012b(&fb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        m_t = (ptrdiff_t)(9);
        emlrtPopRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&fb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&gb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        n_t = (ptrdiff_t)(9);
        emlrtPopRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&gb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&hb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        k_t = (ptrdiff_t)(9);
        emlrtPopRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&hb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&ib_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        lda_t = (ptrdiff_t)(9);
        emlrtPopRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&ib_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&jb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        ldb_t = (ptrdiff_t)(9);
        emlrtPopRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&jb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&kb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        ldc_t = (ptrdiff_t)(9);
        emlrtPopRtStackR2012b(&rb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&kb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&lb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        alpha1_t = (double *)(&normA);
        emlrtPopRtStackR2012b(&lb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&mb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        Aia0_t = (double *)(&y[0]);
        emlrtPopRtStackR2012b(&mb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&nb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        Bib0_t = (double *)(&y[0]);
        emlrtPopRtStackR2012b(&nb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        beta1_t = (double *)(&beta1);
        emlrtPopRtStackR2012b(&ob_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&pb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        Cic0_t = (double *)(&F[0]);
        emlrtPopRtStackR2012b(&pb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPushRtStackR2012b(&qb_emlrtRSI, emlrtRootTLSGlobal);
        emlrt_checkEscapedGlobals();
        dgemm(&TRANSA, &TRANSB, &m_t, &n_t, &k_t, alpha1_t, Aia0_t, &lda_t,
              Bib0_t, &ldb_t, beta1_t, Cic0_t, &ldc_t);
        emlrtPopRtStackR2012b(&qb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&eb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&db_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&cb_emlrtRSI, emlrtRootTLSGlobal);
        emlrtPopRtStackR2012b(&p_emlrtRSI, emlrtRootTLSGlobal);
      }
    }

    for (j = 0; j < 9; j++) {
      p0[j] = 0.0;
      for (b_i = 0; b_i < 9; b_i++) {
        p0[j] += hoistedGlobal[b_i] * F[b_i + 9 * j];
      }
    }

    p0_dirty |= 1U;
    emlrtPopRtStackR2012b(&m_emlrtRSI, emlrtRootTLSGlobal);
    j = I->size[0];
    b_i = 1 + i;
    normA = Acell * 1.0E+12 * (g1 * p0[3] * (V - E1) + g2 * (p0[4] + p0[5]) * (V
      - E2)) - I->data[emlrtDynamicBoundsCheckFastR2012b(b_i, 1, j, &u_emlrtBCI,
      emlrtRootTLSGlobal) - 1];
    normA = muDoubleScalarAbs(normA);
    err += normA * normA;
    err_dirty |= 1U;
    i++;
    emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, emlrtRootTLSGlobal);
  }
}
Exemplo n.º 24
0
/* Function Definitions */
void generateOFDMSignal(const emlrtStack *sp, OFDMDemodulator_1 *iobj_0,
  OFDMDemodulator_1 *iobj_1, OFDMDemodulator_1 **hPreambleDemod,
  OFDMDemodulator_1 **hDataDemod, creal_T r[25600], d_struct_T *tx)
{
  OFDMModulator_1 hDataMod;
  OFDMModulator hPreambleMod;
  creal_T shortPreambleOFDM[64];
  int32_T i;
  creal_T completeShortPreambleOFDM[160];
  creal_T longPreambleOFDM[64];
  creal_T completeLongPreambleOFDM[160];
  real_T originalData[560];
  real_T x[560];
  int32_T ib;
  real_T b_originalData[560];
  commcodegen_CRCGenerator_6 hGen;
  real_T dataWithCRC[563];
  commcodegen_BPSKModulator_1 hMod;
  creal_T modData[563];
  real_T varargin_1[13];
  int32_T k;
  commcodegen_BPSKModulator_1 *obj;
  const mxArray *y;
  static const int32_T iv54[2] = { 1, 45 };

  const mxArray *m10;
  char_T cv58[45];
  static const char_T cv59[45] = { 'M', 'A', 'T', 'L', 'A', 'B', ':', 's', 'y',
    's', 't', 'e', 'm', ':', 'm', 'e', 't', 'h', 'o', 'd', 'C', 'a', 'l', 'l',
    'e', 'd', 'W', 'h', 'e', 'n', 'R', 'e', 'l', 'e', 'a', 's', 'e', 'd', 'C',
    'o', 'd', 'e', 'g', 'e', 'n' };

  const mxArray *b_y;
  static const int32_T iv55[2] = { 1, 4 };

  char_T cv60[4];
  static const char_T cv61[4] = { 's', 't', 'e', 'p' };

  const mxArray *c_y;
  static const int32_T iv56[2] = { 1, 51 };

  char_T cv62[51];
  static const char_T cv63[51] = { 'M', 'A', 'T', 'L', 'A', 'B', ':', 's', 'y',
    's', 't', 'e', 'm', ':', 'm', 'e', 't', 'h', 'o', 'd', 'C', 'a', 'l', 'l',
    'e', 'd', 'W', 'h', 'e', 'n', 'L', 'o', 'c', 'k', 'e', 'd', 'R', 'e', 'l',
    'e', 'a', 's', 'e', 'd', 'C', 'o', 'd', 'e', 'g', 'e', 'n' };

  const mxArray *d_y;
  static const int32_T iv57[2] = { 1, 5 };

  char_T cv64[5];
  static const char_T cv65[5] = { 's', 'e', 't', 'u', 'p' };

  static const int8_T value[8] = { 13, 1, 1, 1, 1, 1, 1, 1 };

  boolean_T anyInputSizeChanged;
  boolean_T exitg2;
  static const int8_T iv58[8] = { 13, 1, 1, 1, 1, 1, 1, 1 };

  creal_T varargout_1[13];
  creal_T b_modData[576];
  creal_T ofdmData[576];
  comm_PNSequence_5 hPN;
  comm_PNSequence_5 *b_obj;
  static const int8_T iv59[8] = { 1, 0, 0, 0, 1, 0, 0, 1 };

  static const int8_T iv60[7] = { 0, 0, 0, 0, 0, 0, 1 };

  int8_T pilot[12];
  uint8_T tmp;
  uint8_T tmp2;
  int8_T pilots[48];
  int32_T ia;
  real_T b_pilots[48];
  creal_T b_r[960];
  creal_T preambles[320];
  creal_T c_r[1280];
  OFDMDemodulator_1 *object;
  int8_T b_data[4];
  int32_T exitg1;
  int32_T exponent;
  boolean_T b2;
  int32_T i12;
  const mxArray *e_y;
  static const int32_T iv61[2] = { 1, 13 };

  char_T cv66[13];
  static const char_T cv67[13] = { 'c', 'o', 'm', 'm', ':', 'O', 'F', 'D', 'M',
    ':', 'x', 'x', 'x' };

  static const creal_T dcv3[53] = { { 0.0, 0.0 }, { 0.0, 0.0 }, { 1.0, 1.0 }, {
      0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { -1.0, -1.0 }, { 0.0, 0.0 }, {
      0.0, 0.0 }, { 0.0, 0.0 }, { 1.0, 1.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0,
      0.0 }, { -1.0, -1.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { -1.0,
      -1.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 1.0, 1.0 }, { 0.0, 0.0
    }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, {
      0.0, 0.0 }, { -1.0, -1.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { -
      1.0, -1.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 1.0, 1.0 }, { 0.0,
      0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 1.0, 1.0 }, { 0.0, 0.0 }, { 0.0, 0.0
    }, { 0.0, 0.0 }, { 1.0, 1.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, { 0.0, 0.0 }, {
      1.0, 1.0 }, { 0.0, 0.0 }, { 0.0, 0.0 } };

  static const int8_T iv62[53] = { 1, 1, -1, -1, 1, 1, -1, 1, -1, 1, 1, 1, 1, 1,
    1, -1, -1, 1, 1, -1, 1, -1, 1, 1, 1, 1, 0, 1, -1, -1, 1, 1, -1, 1, -1, 1, -1,
    -1, -1, -1, -1, 1, 1, -1, -1, 1, -1, 1, -1, 1, 1, 1, 1 };

  static const int8_T iv63[48] = { 1, 2, 3, 4, 5, 7, 8, 9, 10, 11, 12, 13, 14,
    15, 16, 17, 18, 19, 21, 22, 23, 24, 25, 26, 28, 29, 30, 31, 32, 33, 35, 36,
    37, 38, 39, 40, 41, 42, 43, 44, 45, 46, 47, 49, 50, 51, 52, 53 };

  emlrtStack st;
  emlrtStack b_st;
  emlrtStack c_st;
  emlrtStack d_st;
  emlrtStack e_st;
  emlrtStack f_st;
  emlrtStack g_st;
  st.prev = sp;
  st.tls = sp->tls;
  b_st.prev = &st;
  b_st.tls = st.tls;
  c_st.prev = &b_st;
  c_st.tls = b_st.tls;
  d_st.prev = &c_st;
  d_st.tls = c_st.tls;
  e_st.prev = &d_st;
  e_st.tls = d_st.tls;
  f_st.prev = &e_st;
  f_st.tls = e_st.tls;
  g_st.prev = &f_st;
  g_st.tls = f_st.tls;
  emlrtHeapReferenceStackEnterFcnR2012b(sp);
  emxInitStruct_OFDMModulator_1(sp, &hDataMod, &s_emlrtRTEI, TRUE);
  emxInitStruct_OFDMModulator(sp, &hPreambleMod, &t_emlrtRTEI, TRUE);

  /*  generateOFDMSignal: Generate OFDM signal based on the 802.11a standard. */
  /*  This function returns the time domain signal and a structure containing */
  /*  details about the signal itself.  This information is required by the */
  /*  receiver to operate correctly. */
  /* % System Parameters */
  /*  OFDM modulator FFT size */
  /*  Enable moving averages for estimates */
  /* 1e3 */
  /*  Message to transmit */
  /*  String holder */
  /* coder.varsize('payloadMessage', [1, 80], [0 1]); */
  /* payloadMessage = ''; */
  /* % Create Short Preamble */
  /*  % [-27:-17] */
  /*  % [-16:-1] */
  /*  % [0:15] */
  /*  [16:27] */
  /*  % Create modulator */
  /*  hPreambleMod = OFDMModulator(... */
  /*      'NumGuardBandCarriers', [6; 5],... */
  /*      'CyclicPrefixLength',   0,... */
  /*      'FFTLength' ,           FFTLength,... */
  /*      'NumSymbols',           1);     */
  /*  Create modulator */
  st.site = &lk_emlrtRSI;
  OFDMModulator_OFDMModulator(&hPreambleMod);

  /*  Modulate and scale */
  st.site = &mk_emlrtRSI;
  SystemCore_step(&st, &hPreambleMod, shortPreambleOFDM);
  st.site = &mk_emlrtRSI;
  for (i = 0; i < 64; i++) {
    shortPreambleOFDM[i].re *= 1.4719601443879744;
    shortPreambleOFDM[i].im *= 1.4719601443879744;
  }

  /*  Form 10 Short Preambles */
  memcpy(&completeShortPreambleOFDM[0], &shortPreambleOFDM[0], sizeof(creal_T) <<
         6);
  memcpy(&completeShortPreambleOFDM[64], &shortPreambleOFDM[0], sizeof(creal_T) <<
         6);
  memcpy(&completeShortPreambleOFDM[128], &shortPreambleOFDM[0], sizeof(creal_T)
         << 5);

  /* % Create Long Preamble */
  /*  Modulate */
  st.site = &nk_emlrtRSI;
  b_SystemCore_step(&st, &hPreambleMod, longPreambleOFDM);

  /*  Form 2 Long Preambles */
  memcpy(&completeLongPreambleOFDM[0], &longPreambleOFDM[32], sizeof(creal_T) <<
         5);
  memcpy(&completeLongPreambleOFDM[32], &longPreambleOFDM[0], sizeof(creal_T) <<
         6);
  memcpy(&completeLongPreambleOFDM[96], &longPreambleOFDM[0], sizeof(creal_T) <<
         6);

  /* % Generate Data */
  /*  Use string as message */
  st.site = &ok_emlrtRSI;
  b_OFDMletters2bits(&st, originalData);
  st.site = &pk_emlrtRSI;
  for (i = 0; i < 80; i++) {
    for (ib = 0; ib < 7; ib++) {
      x[ib + 7 * i] = originalData[i + 80 * ib];
    }
  }

  memcpy(&b_originalData[0], &x[0], 560U * sizeof(real_T));

  /*  Generate CRC */
  st.site = &qk_emlrtRSI;
  b_CRCGenerator_CRCGenerator(&hGen);
  st.site = &rk_emlrtRSI;
  e_SystemCore_step(&st, &hGen, b_originalData, dataWithCRC);

  /*  Add CRC */
  /*  Construct modulator for each subcarrier */
  st.site = &sk_emlrtRSI;
  BPSKModulator_BPSKModulator(&hMod);

  /*  BPSK */
  /*  Apply modulator for each subcarrier */
  st.site = &tk_emlrtRSI;
  f_SystemCore_step(&st, &hMod, dataWithCRC, modData);

  /*  Pad IFFT */
  st.site = &uk_emlrtRSI;
  b_st.site = &u_emlrtRSI;
  emlrtRandu(varargin_1, 13);
  for (k = 0; k < 13; k++) {
    b_st.site = &v_emlrtRSI;
    b_st.site = &v_emlrtRSI;
    c_st.site = &p_emlrtRSI;
    varargin_1[k] = muDoubleScalarFloor(varargin_1[k] * 2.0);
  }

  st.site = &uk_emlrtRSI;
  obj = &hMod;
  if (!obj->isReleased) {
  } else {
    y = NULL;
    m10 = mxCreateCharArray(2, iv54);
    for (i = 0; i < 45; i++) {
      cv58[i] = cv59[i];
    }

    emlrtInitCharArrayR2013a(&st, 45, m10, cv58);
    emlrtAssign(&y, m10);
    b_y = NULL;
    m10 = mxCreateCharArray(2, iv55);
    for (i = 0; i < 4; i++) {
      cv60[i] = cv61[i];
    }

    emlrtInitCharArrayR2013a(&st, 4, m10, cv60);
    emlrtAssign(&b_y, m10);
    b_st.site = &cb_emlrtRSI;
    c_error(&b_st, message(&b_st, y, b_y, &emlrtMCI), &emlrtMCI);
  }

  if (!obj->isInitialized) {
    b_st.site = &cb_emlrtRSI;
    if (!obj->isInitialized) {
    } else {
      c_y = NULL;
      m10 = mxCreateCharArray(2, iv56);
      for (i = 0; i < 51; i++) {
        cv62[i] = cv63[i];
      }

      emlrtInitCharArrayR2013a(&b_st, 51, m10, cv62);
      emlrtAssign(&c_y, m10);
      d_y = NULL;
      m10 = mxCreateCharArray(2, iv57);
      for (i = 0; i < 5; i++) {
        cv64[i] = cv65[i];
      }

      emlrtInitCharArrayR2013a(&b_st, 5, m10, cv64);
      emlrtAssign(&d_y, m10);
      c_st.site = &cb_emlrtRSI;
      c_error(&c_st, message(&c_st, c_y, d_y, &emlrtMCI), &emlrtMCI);
    }

    c_st.site = &cb_emlrtRSI;
    obj->isInitialized = TRUE;
    d_st.site = &db_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    e_st.site = &db_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    e_st.site = &db_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    e_st.site = &db_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    for (i = 0; i < 8; i++) {
      obj->inputVarSize1[i] = (uint32_T)value[i];
    }

    e_st.site = &db_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    e_st.site = &cb_emlrtRSI;
    e_st.site = &cb_emlrtRSI;
    f_st.site = &gg_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    d_st.site = &cb_emlrtRSI;
    e_st.site = &gg_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    d_st.site = &gg_emlrtRSI;
    d_st.site = &gg_emlrtRSI;
    e_st.site = &db_emlrtRSI;
    c_st.site = &cb_emlrtRSI;
    d_st.site = &gg_emlrtRSI;
    e_st.site = NULL;
  }

  b_st.site = &cb_emlrtRSI;
  b_st.site = &cb_emlrtRSI;
  b_st.site = &cb_emlrtRSI;
  c_st.site = &cb_emlrtRSI;
  c_st.site = &cb_emlrtRSI;
  d_st.site = &gg_emlrtRSI;
  b_st.site = &cb_emlrtRSI;
  b_st.site = &cb_emlrtRSI;
  anyInputSizeChanged = FALSE;
  k = 0;
  exitg2 = FALSE;
  while ((exitg2 == FALSE) && (k < 8)) {
    if (obj->inputVarSize1[k] != (uint32_T)iv58[k]) {
      anyInputSizeChanged = TRUE;
      c_st.site = &cb_emlrtRSI;
      for (i = 0; i < 8; i++) {
        obj->inputVarSize1[i] = (uint32_T)value[i];
      }

      d_st.site = &db_emlrtRSI;
      exitg2 = TRUE;
    } else {
      k++;
    }
  }

  if (anyInputSizeChanged) {
    b_st.site = &cb_emlrtRSI;
    b_st.site = &cb_emlrtRSI;
  }

  b_st.site = &cb_emlrtRSI;
  c_st.site = &cb_emlrtRSI;
  c_st.site = &cb_emlrtRSI;
  d_st.site = &gg_emlrtRSI;
  b_st.site = &cb_emlrtRSI;
  b_st.site = &cb_emlrtRSI;
  b_st.site = &cb_emlrtRSI;
  d_Nondirect_stepImpl(obj, varargin_1, varargout_1);
  memcpy(&b_modData[0], &modData[0], 563U * sizeof(creal_T));
  memcpy(&b_modData[563], &varargout_1[0], 13U * sizeof(creal_T));

  /*  Calculate required data sizes for correct receiver operation */
  /*  Save desired message size */
  /*  Save number of transmitted frames */
  /*  Convert data into subcarrier streams */
  st.site = &vk_emlrtRSI;
  memcpy(&ofdmData[0], &b_modData[0], 576U * sizeof(creal_T));

  /*  Create Pilots */
  st.site = &wk_emlrtRSI;
  b_obj = &hPN;

  /* System object Constructor function: comm.PNSequence */
  b_obj->S0_isInitialized = FALSE;
  b_obj->S1_isReleased = FALSE;
  for (i = 0; i < 8; i++) {
    b_obj->P0_Polynomial[i] = (uint8_T)iv59[i];
  }

  for (i = 0; i < 7; i++) {
    b_obj->P1_IniState[i] = 1;
    b_obj->P2_Mask[i] = (uint8_T)iv60[i];
  }

  st.site = &xk_emlrtRSI;
  b_obj = &hPN;
  if (!b_obj->S0_isInitialized) {
    b_obj->S0_isInitialized = TRUE;
    if (b_obj->S1_isReleased) {
      emlrtErrorWithMessageIdR2012b(&st, &bc_emlrtRTEI,
        "MATLAB:system:runtimeMethodCalledWhenReleasedCodegen", 0);
    }

    b_st.site = NULL;
    b_st.site = NULL;

    /* System object Initialization function: comm.PNSequence */
    for (ib = 0; ib < 7; ib++) {
      b_obj->W0_shiftReg[ib] = b_obj->P1_IniState[ib];
      emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, &b_st);
    }
  }

  b_st.site = NULL;

  /* System object Outputs function: comm.PNSequence */
  for (ib = 0; ib < 12; ib++) {
    tmp = 0;
    for (i = 0; i < 7; i++) {
      tmp = (uint8_T)((uint32_T)tmp + (uint8_T)((uint32_T)b_obj->P0_Polynomial[i
        + 1] * b_obj->W0_shiftReg[i]));
    }

    tmp &= 1;
    tmp2 = 0;
    for (i = 0; i < 7; i++) {
      tmp2 = (uint8_T)((uint32_T)tmp2 + (uint8_T)((uint32_T)b_obj->W0_shiftReg[i]
        * b_obj->P2_Mask[i]));
    }

    pilot[ib] = (int8_T)(tmp2 & 1);
    for (i = 5; i > -1; i += -1) {
      b_obj->W0_shiftReg[i + 1] = b_obj->W0_shiftReg[i];
    }

    b_obj->W0_shiftReg[0U] = tmp;
  }

  /*  Create pilot */
  st.site = &yk_emlrtRSI;
  ib = 0;
  for (i = 0; i < 4; i++) {
    ia = 0;
    for (k = 0; k < 12; k++) {
      pilots[ib] = pilot[ia];
      b_st.site = &ng_emlrtRSI;
      ia++;
      b_st.site = &og_emlrtRSI;
      ib++;
    }
  }

  /*  Expand to all pilot tones */
  st.site = &al_emlrtRSI;
  for (i = 0; i < 12; i++) {
    for (ib = 0; ib < 4; ib++) {
      b_pilots[ib + (i << 2)] = 2.0 * (real_T)(pilots[i + 12 * ib] < 1) - 1.0;
    }
  }

  /*  Bipolar to unipolar */
  st.site = &bl_emlrtRSI;
  for (i = 0; i < 12; i++) {
    b_pilots[3 + (i << 2)] = -b_pilots[3 + (i << 2)];
  }

  /*  Invert last pilot */
  /*  Construct Modulator */
  st.site = &cl_emlrtRSI;
  b_OFDMModulator_OFDMModulator(&st, &hDataMod);

  /*  Modulate */
  st.site = &dl_emlrtRSI;
  d_SystemCore_step(&st, &hDataMod, ofdmData, b_pilots, b_r);

  /*  Add preambles to data */
  memcpy(&preambles[0], &completeShortPreambleOFDM[0], 160U * sizeof(creal_T));
  memcpy(&preambles[160], &completeLongPreambleOFDM[0], 160U * sizeof(creal_T));
  memcpy(&c_r[0], &preambles[0], 320U * sizeof(creal_T));
  memcpy(&c_r[320], &b_r[0], 960U * sizeof(creal_T));

  /*  Repeat frame */
  st.site = &el_emlrtRSI;
  ib = 0;
  for (i = 0; i < 20; i++) {
    ia = 0;
    for (k = 0; k < 1280; k++) {
      r[ib] = c_r[ia];
      b_st.site = &ng_emlrtRSI;
      ia++;
      b_st.site = &og_emlrtRSI;
      ib++;
    }
  }

  /*  Save Demodulator object data for receiver */
  /* hDataDemod = get(OFDMDemodulator(hDataMod)); */
  /* hPreambleDemod = get(OFDMDemodulator(hPreambleMod)); */
  st.site = &fl_emlrtRSI;
  object = iobj_0;
  *hDataDemod = object;
  b_st.site = &jj_emlrtRSI;
  object = *hDataDemod;
  c_st.site = &y_emlrtRSI;
  d_st.site = &bb_emlrtRSI;
  d_st.site = &bb_emlrtRSI;
  object->isInitialized = FALSE;
  object->isReleased = FALSE;
  e_st.site = &cb_emlrtRSI;
  f_st.site = &db_emlrtRSI;
  e_st.site = &cb_emlrtRSI;
  f_st.site = &db_emlrtRSI;
  c_st.site = &y_emlrtRSI;
  c_st.site = &ab_emlrtRSI;
  b_st.site = &kj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &lj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &mj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &nj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &oj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &pj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &qj_emlrtRSI;
  c_st.site = &db_emlrtRSI;

  /* OFDMBase Base object for OFDMModulator and OFDMDemodulator System objects */
  /*  Copyright 2013 The MathWorks, Inc. */
  /* FFTLength FFT length */
  /*  Specify the IFFT length. This property can be set to an integer */
  /*  scalar. The value must be a power of two. The default value of */
  /*  this property is 64. */
  /* CyclicPrefixLength Cyclic prefix length */
  /*  Specify the cyclic prefix length. This property can be set to a */
  /*  non-negative interher scalar. The default value of this property is 16. */
  /* NumGuardBandCarriers Number of guard bands */
  /*  Specify the lower and upper guard bands in frequency domain.This */
  /*  property can be set to a non-nagative two-element vector.  */
  /*  The default setting of this property is [6 5]. */
  /* NumSymbols Number of OFDM symbols */
  /*  Specify the number of OFDM symbols at the output. The default value  */
  /*  of this property is 1. */
  /* PilotCarrierIndices Pilot subcarrier indices */
  /*  Specify the locations where pilots are to be inserted. You can */
  /*  set this property to a numeric scalar, column vector, matrix, or */
  /*  3-D array. The defalut value of the property is [-21; -7; 7; 21]. */
  /*  Nontunable ideally */
  /*  Constructor */
  /*      validateattributes(fftLen, {'numeric'}, ... */
  /*          {'real','scalar','integer','finite','>=',8}, ... */
  /*          [class(obj) '.' propName], propName);   */
  /*      validateattributes(CPLen, {'numeric'}, ... */
  /*          {'real','row','integer','nonnegative','finite'}, ... */
  /*          [class(obj) '.' propName], propName);   */
  /*      validateattributes(guardBands, {'numeric'}, ... */
  /*          {'real','integer','nonnegative','finite','size', [2, 1]}, ... */
  /*          [class(obj) '.' propName], propName);   */
  /*      validateattributes(numSym, {'numeric'}, ... */
  /*          {'real','scalar','integer','positive','finite'}, ... */
  /*          [class(obj) '.' propName], propName);   */
  /*      validateattributes(pilotIdx, {'numeric'}, ... */
  /*          {'real','integer','positive','finite','3d'}, ... */
  /*          [class(obj) '.' propName], propName);   */
  /*  Check the 3rd dimension for numTx */
  d_st.site = &uh_emlrtRSI;
  e_st.site = &vh_emlrtRSI;
  for (k = 0; k < 4; k++) {
    b_data[k] = (int8_T)(12 + 14 * k);
  }

  f_st.site = &mi_emlrtRSI;
  i = 0;
  f_st.site = &ki_emlrtRSI;
  f_st.site = &ji_emlrtRSI;
  k = 1;
  while (k <= 4) {
    ib = b_data[k - 1];
    do {
      exitg1 = 0;
      f_st.site = &ii_emlrtRSI;
      k++;
      if (k > 4) {
        exitg1 = 1;
      } else {
        f_st.site = &hi_emlrtRSI;
        frexp((real_T)ib / 2.0, &exponent);
        if (muDoubleScalarAbs(ib - b_data[k - 1]) < ldexp(1.0, exponent - 53)) {
          anyInputSizeChanged = TRUE;
        } else {
          anyInputSizeChanged = FALSE;
        }

        if (!anyInputSizeChanged) {
          exitg1 = 1;
        }
      }
    } while (exitg1 == 0);

    f_st.site = &gi_emlrtRSI;
    i++;
    b_data[i - 1] = (int8_T)ib;
    f_st.site = &fi_emlrtRSI;
    f_st.site = &fi_emlrtRSI;
  }

  f_st.site = &bi_emlrtRSI;
  f_st.site = &ai_emlrtRSI;
  f_st.site = &wh_emlrtRSI;
  if (1 > i) {
    b2 = FALSE;
  } else {
    b2 = (i > 2147483646);
  }

  if (b2) {
    g_st.site = &bg_emlrtRSI;
    check_forloop_overflow_error(&g_st);
  }

  d_st.site = &uh_emlrtRSI;
  d_st.site = &uh_emlrtRSI;
  if (1 > i) {
    i12 = 0;
  } else {
    i12 = i;
  }

  if (!(4 != i12)) {
  } else {
    e_y = NULL;
    m10 = mxCreateCharArray(2, iv61);
    for (i = 0; i < 13; i++) {
      cv66[i] = cv67[i];
    }

    emlrtInitCharArrayR2013a(&d_st, 13, m10, cv66);
    emlrtAssign(&e_y, m10);
    e_st.site = &mv_emlrtRSI;
    c_error(&e_st, b_message(&e_st, e_y, &g_emlrtMCI), &g_emlrtMCI);
  }

  /*  Error message:  */
  /*  If pilot index is 2-D, the indices per symbol must be unique; */
  /*  If pilot index is 3-D, the indices across transmit antennas per symbol must be unique. */
  c_st.site = &db_emlrtRSI;
  st.site = &gl_emlrtRSI;
  object = iobj_1;
  *hPreambleDemod = object;
  b_st.site = &jj_emlrtRSI;
  object = *hPreambleDemod;
  c_st.site = &y_emlrtRSI;
  d_st.site = &bb_emlrtRSI;
  d_st.site = &bb_emlrtRSI;
  object->isInitialized = FALSE;
  object->isReleased = FALSE;
  e_st.site = &cb_emlrtRSI;
  f_st.site = &db_emlrtRSI;
  e_st.site = &cb_emlrtRSI;
  f_st.site = &db_emlrtRSI;
  c_st.site = &y_emlrtRSI;
  c_st.site = &ab_emlrtRSI;
  b_st.site = &kj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &lj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &mj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &nj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &oj_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  c_st.site = &db_emlrtRSI;
  b_st.site = &pj_emlrtRSI;
  c_st.site = &db_emlrtRSI;

  /*  Calcuate OFDM frequency bin size */
  /*  Calculate locations of pilots without guardbands */
  /*  Calculate locations of subcarrier datastreams without guardbands */
  /* Remove guardband offsets */
  /* Remove index offsets for pilots and guardbands */
  /* dataSubcarrierIndexies([pilotLocationsWithoutGuardbands;DCNullLocation]) = [];%Remove pilot and DCNull locations */
  /*  Create return structure */
  for (i = 0; i < 560; i++) {
    tx->originalData[i] = b_originalData[i];
  }

  for (i = 0; i < 64; i++) {
    tx->shortPreambleOFDM[i] = shortPreambleOFDM[i];
  }

  for (i = 0; i < 160; i++) {
    tx->completeShortPreambleOFDM[i] = completeShortPreambleOFDM[i];
  }

  for (i = 0; i < 53; i++) {
    tx->shortPreamble[i] = dcv3[i];
  }

  for (i = 0; i < 53; i++) {
    tx->longPreamble[i] = iv62[i];
  }

  for (i = 0; i < 64; i++) {
    tx->longPreambleOFDM[i] = longPreambleOFDM[i];
  }

  for (i = 0; i < 160; i++) {
    tx->completeLongPreambleOFDM[i] = completeLongPreambleOFDM[i];
  }

  for (i = 0; i < 48; i++) {
    tx->pilots[i] = b_pilots[i];
  }

  for (i = 0; i < 320; i++) {
    tx->preambles[i] = preambles[i];
  }

  for (i = 0; i < 4; i++) {
    tx->pilotLocationsWithoutGuardbands[i] = 6.0 + 14.0 * (real_T)i;
  }

  tx->dataSubcarrierIndexies.size[0] = 1;
  tx->dataSubcarrierIndexies.size[1] = 48;
  for (i = 0; i < 48; i++) {
    tx->dataSubcarrierIndexies.data[i] = iv63[i];
  }

  tx->samplingFreq = 5.0E+6;
  tx->FFTLength = 64.0;
  tx->enableMA = TRUE;
  tx->numCarriers = 48.0;
  tx->padBits = 13.0;
  tx->numSamples = 576.0;
  tx->messageCharacters = 80.0;
  tx->numFrames = 20.0;
  tx->frameLength = 1280.0;
  tx->freqBin = 78125.0;
  tx->DecimationFactor = 0.0;
  tx->receiveBufferLength = 0.0;

  /*                              padBits: 13 */
  /*                           numSamples: 576 */
  /*                    messageCharacters: 80 */
  /*                            numFrames: 1000 */
  /*                          frameLength: 1280 */
  /*                              freqBin: 312500 */
  /*                           hDataDemod: [1x1 struct] */
  /*                       hPreambleDemod: [1x1 struct] */
  st.site = NULL;
  b_Destructor(&hPN);
  emxFreeStruct_OFDMModulator(&hPreambleMod);
  emxFreeStruct_OFDMModulator_1(&hDataMod);
  emlrtHeapReferenceStackLeaveFcnR2012b(sp);
}
Exemplo n.º 25
0
static void sf_c2_controller1(SFc2_controller1InstanceStruct *chartInstance)
{
  int32_T c2_previousEvent;
  real_T c2_hoistedGlobal;
  real_T c2_u;
  uint32_T c2_debug_family_var_map[4];
  real_T c2_nargin = 1.0;
  real_T c2_nargout = 1.0;
  real_T c2_y;
  real_T c2_x;
  real_T c2_b_x;
  real_T c2_b_y;
  real_T c2_c_x;
  real_T c2_xk;
  real_T c2_d_x;
  real_T c2_e_x;
  real_T c2_f_x;
  real_T *c2_b_u;
  real_T *c2_c_y;
  c2_c_y = (real_T *)ssGetOutputPortSignal(chartInstance->S, 1);
  c2_b_u = (real_T *)ssGetInputPortSignal(chartInstance->S, 0);
  _sfTime_ = (real_T)ssGetT(chartInstance->S);
  _SFD_CC_CALL(CHART_ENTER_SFUNCTION_TAG, 1);
  _SFD_DATA_RANGE_CHECK(*c2_b_u, 0U);
  _SFD_DATA_RANGE_CHECK(*c2_c_y, 1U);
  c2_previousEvent = _sfEvent_;
  _sfEvent_ = CALL_EVENT;
  _SFD_CC_CALL(CHART_ENTER_DURING_FUNCTION_TAG, 1);
  c2_hoistedGlobal = *c2_b_u;
  c2_u = c2_hoistedGlobal;
  sf_debug_symbol_scope_push_eml(0U, 4U, 4U, c2_debug_family_names,
    c2_debug_family_var_map);
  sf_debug_symbol_scope_add_eml(&c2_nargin, c2_sf_marshall, 0U);
  sf_debug_symbol_scope_add_eml(&c2_nargout, c2_sf_marshall, 1U);
  sf_debug_symbol_scope_add_eml(&c2_u, c2_sf_marshall, 2U);
  sf_debug_symbol_scope_add_eml(&c2_y, c2_sf_marshall, 3U);
  CV_EML_FCN(0, 0);
  _SFD_EML_CALL(0, 2);
  c2_x = c2_u;
  c2_b_x = c2_x;
  c2_b_y = muDoubleScalarAbs(c2_b_x);
  if (CV_EML_IF(0, 0, c2_b_y > 90.0)) {
    _SFD_EML_CALL(0, 3);
    c2_c_x = c2_u;
    c2_eml_scalar_eg(chartInstance);
    c2_xk = c2_c_x;
    c2_d_x = c2_xk;
    c2_eml_scalar_eg(chartInstance);
    c2_e_x = c2_d_x / 90.0;
    c2_f_x = c2_e_x;
    c2_f_x = muDoubleScalarFloor(c2_f_x);
    c2_u = c2_d_x - c2_f_x * 90.0;
  }

  _SFD_EML_CALL(0, 5);
  c2_y = c2_u;
  _SFD_EML_CALL(0, -5);
  sf_debug_symbol_scope_pop();
  *c2_c_y = c2_y;
  _SFD_CC_CALL(EXIT_OUT_OF_FUNCTION_TAG, 1);
  _sfEvent_ = c2_previousEvent;
  sf_debug_check_for_state_inconsistency(_controller1MachineNumber_,
    chartInstance->chartNumber, chartInstance->instanceNumber);
}
void drr_151213_XRayInParam(const emlrtStack *sp, const emxArray_boolean_T
  *voxel_data, const real_T voxel_size_mm[3], const real_T detector_dimensions[2],
  const real_T XRayIntrinsicParam[12], const real_T voxel_corner_min[3], const
  real_T T_carm[16], emxArray_real_T *projection)
{
  const mxArray *y;
  static const int32_T iv0[2] = { 1, 32 };

  const mxArray *m0;
  char_T cv0[32];
  int32_T i;
  static const char_T cv1[32] = { 'v', 'o', 'x', 'e', 'l', '_', 'd', 'a', 't',
    'a', ' ', 'm', 'u', 's', 't', ' ', 'b', 'e', ' ', '3', '-', 'd', 'i', 'm',
    'e', 'n', 's', 'i', 'o', 'n', 'a', 'l' };

  int32_T i0;
  real_T pixel_size_mm_h;
  real_T pixel_size_mm_w;
  uint32_T voxDim[3];
  real_T voxPlanes__max[3];
  real_T source[3];
  real_T pixel_size_mmel_wn[3];
  real_T pixel_size_mmel_hn[3];
  real_T corner[3];
  int32_T ih;
  int32_T iw;
  real_T tstep[3];
  real_T tnext[3];
  real_T pixel_point_mm[3];
  real_T ray_source2pixel[3];
  real_T b_voxPlanes__max[3];
  real_T b_ray_source2pixel[3];
  real_T t_plane_min[3];
  real_T t_plane_max[3];
  real_T tmax;
  int32_T pixel_size_mmIntensity;
  boolean_T exitg8;
  boolean_T exitg7;
  boolean_T exitg6;
  real_T t_larger[4];
  real_T temp;
  boolean_T exitg5;
  boolean_T exitg4;
  boolean_T exitg3;
  real_T t_smaller[4];
  int32_T itmp;
  boolean_T exitg2;
  boolean_T exitg1;
  real_T iz;
  real_T tx;
  real_T ty;
  real_T tz;
  int32_T i1;
  int32_T i2;
  int32_T i3;
  emlrtStack st;
  emlrtStack b_st;
  st.prev = sp;
  st.tls = sp->tls;
  b_st.prev = &st;
  b_st.tls = st.tls;

  /* % Modificiation Notes */
  /*  15.12.04 */
  /*           - Release 기존의 파일을 참고로 하여 고성영이 수정하였음.  */
  /*           - DRR을 완벽하게 하지 않고, voxel에 한점이라도 만나면 on으로 계산함 */
  /*           - 계산속도가 향상되었음 */
  /*           - 젬스에 있는 X-ray와 테스트하여 검증하였음 */
  /*  15 12 13 : The function input has been changed to utilize the x-ray */
  /*             intrinsic parameter provided by GEMSS  % 151213 kosy */
  /* %function [projection] = drr (voxel_data, voxel_size_mm, detector_dimensions, pixel_size_mm, isocenter_mm, cbct_angles_deg) */
  /* Creates a 2D projection at each cbct_angle of voxel_data. the projection */
  /* axis is defined by the isocenter to which the source and center of */
  /* the detector are aligned. This simulation assumes standard Cone Beam CT */
  /* geometry (source to isocenter distance is 100 cm and source to detector */
  /* distance is 150cm). */
  /*  */
  /* voxel_data: must be a 3 dimensional matrix (typically of CT data) */
  /* voxel_size_mm: a 3 element vector listing the size (in mm) of the voxels */
  /*                along each dimension */
  /* detector_dimension: a 2 element vector listing the dimensions (number of */
  /*                     pixels) in each dimension (u,v) */
  /* pixel_size_mm: a number defining the height and width of each pixel */
  /*                (assumes square pixel) */
  /* isocenter_mm: a 3 element vector pointing from the origin (corner) of the */
  /*               matrix element(1,1,1) to the isocenter */
  /* cbct_angles_deg: a list of angles to generate projections */
  /*  */
  /* Retrun Variable */
  /* projection: a 3D matrix with the 3rd dimension representing the angle of */
  /* roatation */
  /*  */
  /* { */
  /*  Author: Michael M. Folkerts [email protected] */
  /*  Institution: UCSD Physics, UTSW Radiation Oncology */
  /*  Updated: 2014-July. */
  /*  Notes: Siddon's Incremental algorithm | modified to read in 3D matlab matrix | Simplified Input | No guarantees!! */
  /*  */
  /*  References:  */
  /*  R.L. Siddon, */
  /*  "Fast calculation of the exact radiological path for a three-dimensional CT */
  /*  array," Medical Physics 12, 252-255 (1985). */
  /*  */
  /*  F. Jacobs, E. Sundermann, B. De Sutter, M. Christiaens and I. Lemahieu, */
  /*  "A fast algorithm to calculate the exact radiological path through a pixel_size_mmel or voxel space," */
  /*  Journal of Computing and Information Technology 6, 89-94 (1998). */
  /*   */
  /*  G. Han, Z. Liang and J. You, */
  /*  "A fast ray tracing technique for TCT and ECT studies," */
  /*  IEEE Medical Imaging Conference 1999. */
  /* } */
  /* function [projection] = drr_good_151204 (voxel_data, voxel_size_mm, detector_dimensions, pixel_size_mm, voxel_corner_min, T_carm)  */
  /*  if(0) */
  /*      voxel_data = OUTPUTgrid; */
  /*      voxel_size_mm = voxel_size; */
  /*      detector_dimensions = detector_dimension; */
  /*      pixel_size_mm = pixel_size; */
  /*      isocenter_mm = isocenter; */
  /*      T_carm: Transformation matrix of C-arm (that is set at the middle of */
  /*              detector & source) with respect to Voxel coordinates */
  /* tic; */
  /* this will verify the size: */
  if (eml_ndims_varsized(*(int32_T (*)[3])voxel_data->size) != 3) {
    st.site = &emlrtRSI;
    y = NULL;
    m0 = emlrtCreateCharArray(2, iv0);
    for (i = 0; i < 32; i++) {
      cv0[i] = cv1[i];
    }

    emlrtInitCharArrayR2013a(&st, 32, m0, cv0);
    emlrtAssign(&y, m0);
    b_st.site = &b_emlrtRSI;
    error(&b_st, y, &emlrtMCI);
  }

  /* constants: */
  /* .0001; */
  /* .0001; */
  /* sounce to imager(detector) distance */
  /* source to axis distance %% RRI set the coordinate at the middle between source and the detector */
  /* initialize memory for speed: */
  i0 = projection->size[0] * projection->size[1];
  pixel_size_mm_h = emlrtNonNegativeCheckFastR2012b(detector_dimensions[0],
    &b_emlrtDCI, sp);
  projection->size[0] = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_h,
    &emlrtDCI, sp);
  pixel_size_mm_h = emlrtNonNegativeCheckFastR2012b(detector_dimensions[1],
    &d_emlrtDCI, sp);
  projection->size[1] = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_h,
    &c_emlrtDCI, sp);
  emxEnsureCapacity(sp, (emxArray__common *)projection, i0, (int32_T)sizeof
                    (real_T), &emlrtRTEI);
  pixel_size_mm_h = emlrtNonNegativeCheckFastR2012b(detector_dimensions[0],
    &b_emlrtDCI, sp);
  pixel_size_mm_w = emlrtNonNegativeCheckFastR2012b(detector_dimensions[1],
    &d_emlrtDCI, sp);
  i = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_h, &emlrtDCI, sp) *
    (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_w, &c_emlrtDCI, sp);
  for (i0 = 0; i0 < i; i0++) {
    projection->data[i0] = 0.0;
  }

  for (i0 = 0; i0 < 3; i0++) {
    voxDim[i0] = (uint32_T)voxel_data->size[i0];
  }

  /* [size(voxel_data,1), size(voxel_data,2), size(voxel_data,3)]; */
  /* voxDim_x = voxDim(1); */
  /* voxDim_y = voxDim(2); */
  /* voxDim_z = voxDim(3); */
  /* difine voxel boundaries: */
  /* vector from origin to source */
  /* vector from origin to CENTER of detector */
  /* extract the key information from the intrinsic parameters   % 151213 kosy modi */
  pixel_size_mm_h = 1105.0 / XRayIntrinsicParam[0];
  pixel_size_mm_w = 1105.0 / XRayIntrinsicParam[4];

  /* vector pointing left, parallel to detector */
  /* define incremental vectors: */
  /* define upper lefthand corner of detector: */
  /* corner = detector + ( center_pixel_w*pixel_size_mmel.wn + center_pixel_h*pixel_size_mmel.hn ); */
  for (i = 0; i < 3; i++) {
    voxPlanes__max[i] = voxel_corner_min[i] + voxel_size_mm[i] * (real_T)
      voxDim[i];

    /* define up: */
    /* up = [0,0,1]; */
    /*  width of projection image */
    /*  height of projection image */
    /*  direction from the detector to the source */
    /* end initialization timer: */
    /* init_time = toc */
    /* start tracing timer: */
    /* tic; */
    source[i] = 552.5 * T_carm[4 + i] + T_carm[12 + i];

    /* define pixel_size_mmel vectors: */
    /*  length of pixel_size_mmel */
    pixel_size_mmel_wn[i] = -pixel_size_mm_w * T_carm[i];
    pixel_size_mmel_hn[i] = -pixel_size_mm_h * T_carm[8 + i];
    corner[i] = (-552.5 * T_carm[4 + i] + T_carm[12 + i]) +
      (detector_dimensions[0] * (pixel_size_mm_w * T_carm[i]) +
       detector_dimensions[1] * (pixel_size_mm_h * T_carm[8 + i])) / 2.0;
  }

  emlrtForLoopVectorCheckR2012b(1.0, 1.0, detector_dimensions[0], mxDOUBLE_CLASS,
                                (int32_T)detector_dimensions[0], &d_emlrtRTEI,
    sp);
  ih = 1;
  while (ih - 1 <= (int32_T)detector_dimensions[0] - 1) {
    /* if(mod(ih,100)==0),fprintf('height:\t%i...\n',ih);end */
    emlrtForLoopVectorCheckR2012b(1.0, 1.0, detector_dimensions[1],
      mxDOUBLE_CLASS, (int32_T)detector_dimensions[1], &c_emlrtRTEI, sp);
    iw = 1;
    while (iw - 1 <= (int32_T)detector_dimensions[1] - 1) {
      /* pixel_point_mm = corner + (ih-1)*pixel_size_mmel.hp + (iw-1)*pixel_size_mmel.wp; %ray end point */
      /* ray to be traced */
      /*  find parametrized (t) voxel plane (min or max) intersections: */
      /*  PLANE = P1 + t(P2-P1) */
      /*  SK added */
      /*  t_x = (i-x1) / (x2-x1), t_y = (j-y1) / (y2-y1), t_z = (k-z1) / (z2-z1) */
      for (i = 0; i < 3; i++) {
        pixel_size_mm_h = (corner[i] + ((1.0 + (real_T)(ih - 1)) - 1.0) *
                           pixel_size_mmel_hn[i]) + ((1.0 + (real_T)(iw - 1)) -
          1.0) * pixel_size_mmel_wn[i];

        /* ray end point */
        pixel_size_mm_w = pixel_size_mm_h - source[i];
        tstep[i] = voxel_corner_min[i] - source[i];
        tnext[i] = pixel_size_mm_w + 2.2250738585072014E-308;
        b_voxPlanes__max[i] = voxPlanes__max[i] - source[i];
        b_ray_source2pixel[i] = pixel_size_mm_w + 2.2250738585072014E-308;
        pixel_point_mm[i] = pixel_size_mm_h;
        ray_source2pixel[i] = pixel_size_mm_w;
      }

      rdivide(tstep, tnext, t_plane_min);
      rdivide(b_voxPlanes__max, b_ray_source2pixel, t_plane_max);

      /*  compute (parametric) intersection values */
      /*  tmin = max { min{tx(0), tx(Nx)}, min{ty(0), ty(Ny)], min{tz(0), tz(Nz)}, 0.0 } */
      /*  tmax = min { max{tx(0), tx(Nx)}, max{ty(0), ty(Ny)], max{tz(0), tz(Nz)}, 1.0 } */
      /* t_larger = [ max([t_plane_min(1), t_plane_max(1)]), max([t_plane_min(2), t_plane_max(2)]), max([t_plane_min(3), t_plane_max(3)]), 1.0 ]; */
      /* t_smaller = [ min([t_plane_min(1), t_plane_max(1)]), min([t_plane_min(2), t_plane_max(2)]), min([t_plane_min(3), t_plane_max(3)]), 0.0 ]; */
      i = 1;
      tmax = t_plane_min[0];
      if (muDoubleScalarIsNaN(t_plane_min[0])) {
        pixel_size_mmIntensity = 2;
        exitg8 = false;
        while ((!exitg8) && (pixel_size_mmIntensity < 3)) {
          i = 2;
          if (!muDoubleScalarIsNaN(t_plane_max[0])) {
            tmax = t_plane_max[0];
            exitg8 = true;
          } else {
            pixel_size_mmIntensity = 3;
          }
        }
      }

      if ((i < 2) && (t_plane_max[0] > tmax)) {
        tmax = t_plane_max[0];
      }

      i = 1;
      pixel_size_mm_h = t_plane_min[1];
      if (muDoubleScalarIsNaN(t_plane_min[1])) {
        pixel_size_mmIntensity = 2;
        exitg7 = false;
        while ((!exitg7) && (pixel_size_mmIntensity < 3)) {
          i = 2;
          if (!muDoubleScalarIsNaN(t_plane_max[1])) {
            pixel_size_mm_h = t_plane_max[1];
            exitg7 = true;
          } else {
            pixel_size_mmIntensity = 3;
          }
        }
      }

      if ((i < 2) && (t_plane_max[1] > pixel_size_mm_h)) {
        pixel_size_mm_h = t_plane_max[1];
      }

      i = 1;
      pixel_size_mm_w = t_plane_min[2];
      if (muDoubleScalarIsNaN(t_plane_min[2])) {
        pixel_size_mmIntensity = 2;
        exitg6 = false;
        while ((!exitg6) && (pixel_size_mmIntensity < 3)) {
          i = 2;
          if (!muDoubleScalarIsNaN(t_plane_max[2])) {
            pixel_size_mm_w = t_plane_max[2];
            exitg6 = true;
          } else {
            pixel_size_mmIntensity = 3;
          }
        }
      }

      if ((i < 2) && (t_plane_max[2] > pixel_size_mm_w)) {
        pixel_size_mm_w = t_plane_max[2];
      }

      t_larger[0] = tmax;
      t_larger[1] = pixel_size_mm_h;
      t_larger[2] = pixel_size_mm_w;
      t_larger[3] = 1.0;
      i = 1;
      temp = t_plane_min[0];
      if (muDoubleScalarIsNaN(t_plane_min[0])) {
        pixel_size_mmIntensity = 2;
        exitg5 = false;
        while ((!exitg5) && (pixel_size_mmIntensity < 3)) {
          i = 2;
          if (!muDoubleScalarIsNaN(t_plane_max[0])) {
            temp = t_plane_max[0];
            exitg5 = true;
          } else {
            pixel_size_mmIntensity = 3;
          }
        }
      }

      if ((i < 2) && (t_plane_max[0] < temp)) {
        temp = t_plane_max[0];
      }

      i = 1;
      pixel_size_mm_h = t_plane_min[1];
      if (muDoubleScalarIsNaN(t_plane_min[1])) {
        pixel_size_mmIntensity = 2;
        exitg4 = false;
        while ((!exitg4) && (pixel_size_mmIntensity < 3)) {
          i = 2;
          if (!muDoubleScalarIsNaN(t_plane_max[1])) {
            pixel_size_mm_h = t_plane_max[1];
            exitg4 = true;
          } else {
            pixel_size_mmIntensity = 3;
          }
        }
      }

      if ((i < 2) && (t_plane_max[1] < pixel_size_mm_h)) {
        pixel_size_mm_h = t_plane_max[1];
      }

      i = 1;
      pixel_size_mm_w = t_plane_min[2];
      if (muDoubleScalarIsNaN(t_plane_min[2])) {
        pixel_size_mmIntensity = 2;
        exitg3 = false;
        while ((!exitg3) && (pixel_size_mmIntensity < 3)) {
          i = 2;
          if (!muDoubleScalarIsNaN(t_plane_max[2])) {
            pixel_size_mm_w = t_plane_max[2];
            exitg3 = true;
          } else {
            pixel_size_mmIntensity = 3;
          }
        }
      }

      if ((i < 2) && (t_plane_max[2] < pixel_size_mm_w)) {
        pixel_size_mm_w = t_plane_max[2];
      }

      t_smaller[0] = temp;
      t_smaller[1] = pixel_size_mm_h;
      t_smaller[2] = pixel_size_mm_w;
      t_smaller[3] = 0.0;
      i = 1;
      itmp = 0;
      if (muDoubleScalarIsNaN(temp)) {
        pixel_size_mmIntensity = 1;
        exitg2 = false;
        while ((!exitg2) && (pixel_size_mmIntensity + 1 < 5)) {
          i = pixel_size_mmIntensity + 1;
          if (!muDoubleScalarIsNaN(t_smaller[pixel_size_mmIntensity])) {
            temp = t_smaller[pixel_size_mmIntensity];
            itmp = pixel_size_mmIntensity;
            exitg2 = true;
          } else {
            pixel_size_mmIntensity++;
          }
        }
      }

      if (i < 4) {
        while (i + 1 < 5) {
          if (t_smaller[i] > temp) {
            temp = t_smaller[i];
            itmp = i;
          }

          i++;
        }
      }

      i = 1;
      if (muDoubleScalarIsNaN(tmax)) {
        pixel_size_mmIntensity = 2;
        exitg1 = false;
        while ((!exitg1) && (pixel_size_mmIntensity < 5)) {
          i = pixel_size_mmIntensity;
          if (!muDoubleScalarIsNaN(t_larger[pixel_size_mmIntensity - 1])) {
            tmax = t_larger[pixel_size_mmIntensity - 1];
            exitg1 = true;
          } else {
            pixel_size_mmIntensity++;
          }
        }
      }

      if (i < 4) {
        while (i + 1 < 5) {
          if (t_larger[i] < tmax) {
            tmax = t_larger[i];
          }

          i++;
        }
      }

      for (i0 = 0; i0 < 3; i0++) {
        pixel_point_mm[i0] = (real_T)(pixel_point_mm[i0] < source[i0]) * -2.0 +
          1.0;
      }

      if (temp < tmax) {
        /*  if ray intersects volume */
        /* find index for each dimension: */
        for (i = 0; i < 3; i++) {
          pixel_size_mm_h = muDoubleScalarFloor((((ray_source2pixel[i] * temp +
            source[i]) - voxel_corner_min[i]) + 2.2250738585072014E-308) /
            voxel_size_mm[i]);

          /* (parametric) intersection values... */
          /* makes 0 or 1 */
          tnext[i] = (voxel_corner_min[i] + ((pixel_size_mm_h +
            (pixel_point_mm[i] + 1.0) / 2.0) * voxel_size_mm[i] - source[i])) /
            (ray_source2pixel[i] + 2.2250738585072014E-308);

          /*  parametric value for next plane intersection */
          tstep[i] = muDoubleScalarAbs(voxel_size_mm[i] / (ray_source2pixel[i] +
            2.2250738585072014E-308));
          t_plane_min[i] = pixel_size_mm_h;
        }

        /*  parametric step size */
        /* address special cases... */
        if (temp == t_plane_max[emlrtDynamicBoundsCheckFastR2012b(itmp + 1, 1, 3,
             &c_emlrtBCI, sp) - 1]) {
          /* if intersection is a "max" plane */
          t_plane_min[itmp] = (real_T)voxDim[itmp] - 1.0;
          tnext[itmp] = temp + tstep[itmp];

          /* next plane crossing */
        } else {
          t_plane_min[itmp] = 0.0;
          tnext[itmp] = temp + tstep[itmp];

          /* next plane crossing */
        }

        /*  voxel index values(add one for matlab): */
        pixel_size_mm_h = t_plane_min[0] + 1.0;
        pixel_size_mm_w = t_plane_min[1] + 1.0;
        iz = t_plane_min[2] + 1.0;
        tx = tnext[0];
        ty = tnext[1];
        tz = tnext[2];
        pixel_size_mmIntensity = 0;

        /* uncomment to generate P-matrix: */
        /* pixel_size_mmNum = 1; */
        /* len = norm(ray_source2pixel); % ray length */
        while ((temp + 0.0001 < tmax) && (!(pixel_size_mm_h * pixel_size_mm_w *
                 iz == 0.0))) {
          if ((tx < ty) && (tx < tz)) {
            /*  실제 DRR을 그리지 않고, 한점이라도 지나면 해당 점에 포함시킴 */
            i0 = voxel_data->size[0];
            i = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_h,
              &k_emlrtDCI, sp);
            itmp = voxel_data->size[1];
            i1 = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_w,
              &l_emlrtDCI, sp);
            i2 = voxel_data->size[2];
            i3 = (int32_T)emlrtIntegerCheckFastR2012b(iz, &m_emlrtDCI, sp);
            if (voxel_data->data[((emlrtDynamicBoundsCheckFastR2012b(i, 1, i0,
                   &j_emlrtBCI, sp) + voxel_data->size[0] *
                                   (emlrtDynamicBoundsCheckFastR2012b(i1, 1,
                    itmp, &k_emlrtBCI, sp) - 1)) + voxel_data->size[0] *
                                  voxel_data->size[1] *
                                  (emlrtDynamicBoundsCheckFastR2012b(i3, 1, i2,
                   &l_emlrtBCI, sp) - 1)) - 1]) {
              pixel_size_mmIntensity = 255;
              tmax = rtMinusInf;
            }

            temp = tx;
            tx += tstep[0];
            pixel_size_mm_h += pixel_point_mm[0];
          } else if (ty < tz) {
            /*  실제 DRR을 그리지 않고, 한점이라도 지나면 해당 점에 포함시킴 */
            i0 = voxel_data->size[0];
            i = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_h,
              &h_emlrtDCI, sp);
            itmp = voxel_data->size[1];
            i1 = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_w,
              &i_emlrtDCI, sp);
            i2 = voxel_data->size[2];
            i3 = (int32_T)emlrtIntegerCheckFastR2012b(iz, &j_emlrtDCI, sp);
            if (voxel_data->data[((emlrtDynamicBoundsCheckFastR2012b(i, 1, i0,
                   &g_emlrtBCI, sp) + voxel_data->size[0] *
                                   (emlrtDynamicBoundsCheckFastR2012b(i1, 1,
                    itmp, &h_emlrtBCI, sp) - 1)) + voxel_data->size[0] *
                                  voxel_data->size[1] *
                                  (emlrtDynamicBoundsCheckFastR2012b(i3, 1, i2,
                   &i_emlrtBCI, sp) - 1)) - 1]) {
              pixel_size_mmIntensity = 255;
              tmax = rtMinusInf;
            }

            temp = ty;
            ty += tstep[1];
            pixel_size_mm_w += pixel_point_mm[1];
          } else {
            /*  실제 DRR을 그리지 않고, 한점이라도 지나면 해당 점에 포함시킴 */
            i0 = voxel_data->size[0];
            i = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_h,
              &e_emlrtDCI, sp);
            itmp = voxel_data->size[1];
            i1 = (int32_T)emlrtIntegerCheckFastR2012b(pixel_size_mm_w,
              &f_emlrtDCI, sp);
            i2 = voxel_data->size[2];
            i3 = (int32_T)emlrtIntegerCheckFastR2012b(iz, &g_emlrtDCI, sp);
            if (voxel_data->data[((emlrtDynamicBoundsCheckFastR2012b(i, 1, i0,
                   &d_emlrtBCI, sp) + voxel_data->size[0] *
                                   (emlrtDynamicBoundsCheckFastR2012b(i1, 1,
                    itmp, &e_emlrtBCI, sp) - 1)) + voxel_data->size[0] *
                                  voxel_data->size[1] *
                                  (emlrtDynamicBoundsCheckFastR2012b(i3, 1, i2,
                   &f_emlrtBCI, sp) - 1)) - 1]) {
              pixel_size_mmIntensity = 255;
              tmax = rtMinusInf;
            }

            temp = tz;
            tz += tstep[2];
            iz += pixel_point_mm[2];
          }

          emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, sp);
        }

        /* end while */
        i0 = projection->size[0];
        i = projection->size[1];
        projection->data[(emlrtDynamicBoundsCheckFastR2012b(ih, 1, i0,
          &m_emlrtBCI, sp) + projection->size[0] *
                          (emlrtDynamicBoundsCheckFastR2012b(iw, 1, i,
          &n_emlrtBCI, sp) - 1)) - 1] = pixel_size_mmIntensity;
      } else {
        /* if no intersections */
        i0 = projection->size[0];
        i = projection->size[1];
        projection->data[(emlrtDynamicBoundsCheckFastR2012b(ih, 1, i0, &emlrtBCI,
          sp) + projection->size[0] * (emlrtDynamicBoundsCheckFastR2012b(iw, 1,
          i, &b_emlrtBCI, sp) - 1)) - 1] = 0.0;
      }

      /* if intersections */
      /* uncomment to generate P-matrix: */
      /* rayCount = rayCount + 1; */
      iw++;
      emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, sp);
    }

    /* width */
    /* fprintf('\n'); */
    ih++;
    emlrtBreakCheckFastR2012b(emlrtBreakCheckR2012bFlagVar, sp);
  }

  /* height */
  /* uncomment to generate P-matrix: */
  /* matrix = matrix(1:mtxCount-1,:); */
  /* stop trace timer: */
  /* trace_time = toc */
  /* fprintf('\n') */
  /* function */
  /* } */
}
Exemplo n.º 27
0
static void sf_gateway_c2_Demo_AU_VA1(SFc2_Demo_AU_VA1InstanceStruct
  *chartInstance)
{
  real_T c2_hoistedGlobal;
  real_T c2_randv;
  uint32_T c2_debug_family_var_map[6];
  real_T c2_randTrigger;
  real_T c2_nargin = 1.0;
  real_T c2_nargout = 2.0;
  real_T c2_v_trigW;
  real_T c2_v_trig;
  real_T c2_x;
  real_T c2_b_x;
  real_T c2_c_x;
  real_T c2_d_x;
  real_T *c2_b_randv;
  real_T *c2_b_v_trigW;
  real_T *c2_b_v_trig;
  boolean_T guard1 = false;
  boolean_T guard2 = false;
  c2_b_v_trig = (real_T *)ssGetOutputPortSignal(chartInstance->S, 2);
  c2_b_v_trigW = (real_T *)ssGetOutputPortSignal(chartInstance->S, 1);
  c2_b_randv = (real_T *)ssGetInputPortSignal(chartInstance->S, 0);
  _SFD_SYMBOL_SCOPE_PUSH(0U, 0U);
  _sfTime_ = sf_get_time(chartInstance->S);
  _SFD_CC_CALL(CHART_ENTER_SFUNCTION_TAG, 1U, chartInstance->c2_sfEvent);
  _SFD_DATA_RANGE_CHECK(*c2_b_randv, 0U);
  chartInstance->c2_sfEvent = CALL_EVENT;
  _SFD_CC_CALL(CHART_ENTER_DURING_FUNCTION_TAG, 1U, chartInstance->c2_sfEvent);
  c2_hoistedGlobal = *c2_b_randv;
  c2_randv = c2_hoistedGlobal;
  _SFD_SYMBOL_SCOPE_PUSH_EML(0U, 6U, 6U, c2_debug_family_names,
    c2_debug_family_var_map);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c2_randTrigger, 0U, c2_sf_marshallOut,
    c2_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c2_nargin, 1U, c2_sf_marshallOut,
    c2_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c2_nargout, 2U, c2_sf_marshallOut,
    c2_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML(&c2_randv, 3U, c2_sf_marshallOut);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c2_v_trigW, 4U, c2_sf_marshallOut,
    c2_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c2_v_trig, 5U, c2_sf_marshallOut,
    c2_sf_marshallIn);
  CV_EML_FCN(0, 0);
  _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 3);
  c2_v_trigW = 0.0;
  _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 5);
  c2_x = c2_randv;
  c2_randTrigger = c2_x;
  c2_b_x = c2_randTrigger;
  c2_randTrigger = c2_b_x;
  c2_randTrigger = muDoubleScalarFloor(c2_randTrigger);
  _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 7);
  guard2 = false;
  if (CV_EML_COND(0, 1, 0, 0.0 < c2_randTrigger)) {
    if (CV_EML_COND(0, 1, 1, c2_randTrigger < 30.0)) {
      CV_EML_MCDC(0, 1, 0, true);
      CV_EML_IF(0, 1, 0, true);
      _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 8);
      c2_v_trigW += 0.1;
    } else {
      guard2 = true;
    }
  } else {
    guard2 = true;
  }

  if (guard2 == true) {
    CV_EML_MCDC(0, 1, 0, false);
    CV_EML_IF(0, 1, 0, false);
  }

  _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 10);
  guard1 = false;
  if (CV_EML_COND(0, 1, 2, 30.0 < c2_randTrigger)) {
    if (CV_EML_COND(0, 1, 3, c2_randTrigger < 60.0)) {
      CV_EML_MCDC(0, 1, 1, true);
      CV_EML_IF(0, 1, 1, true);
      _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 11);
      c2_v_trigW -= 0.1;
    } else {
      guard1 = true;
    }
  } else {
    guard1 = true;
  }

  if (guard1 == true) {
    CV_EML_MCDC(0, 1, 1, false);
    CV_EML_IF(0, 1, 1, false);
  }

  _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 14);
  if (CV_EML_IF(0, 1, 2, c2_v_trigW > 0.0)) {
    _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 15);
    c2_v_trig = 1.0;
  } else {
    _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 16);
    if (CV_EML_IF(0, 1, 3, c2_v_trigW < 0.0)) {
      _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 17);
      c2_v_trig = -1.0;
      _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 18);
      c2_c_x = c2_v_trigW;
      c2_d_x = c2_c_x;
      c2_v_trigW = muDoubleScalarAbs(c2_d_x);
    } else {
      _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 20);
      c2_v_trig = 0.0;
      _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, 20);
      c2_v_trigW = 0.0;
    }
  }

  _SFD_EML_CALL(0U, chartInstance->c2_sfEvent, -20);
  _SFD_SYMBOL_SCOPE_POP();
  *c2_b_v_trigW = c2_v_trigW;
  *c2_b_v_trig = c2_v_trig;
  _SFD_CC_CALL(EXIT_OUT_OF_FUNCTION_TAG, 1U, chartInstance->c2_sfEvent);
  _SFD_SYMBOL_SCOPE_POP();
  _SFD_CHECK_FOR_STATE_INCONSISTENCY(_Demo_AU_VA1MachineNumber_,
    chartInstance->chartNumber, chartInstance->instanceNumber);
  _SFD_DATA_RANGE_CHECK(*c2_b_v_trigW, 1U);
  _SFD_DATA_RANGE_CHECK(*c2_b_v_trig, 2U);
}
static void sf_c1_Model_justmodel2(SFc1_Model_justmodel2InstanceStruct
  *chartInstance)
{
  int32_T c1_i2;
  real_T c1_hoistedGlobal;
  real_T c1_time;
  uint32_T c1_debug_family_var_map[5];
  real_T c1_surge;
  real_T c1_nargin = 1.0;
  real_T c1_nargout = 1.0;
  real_T c1_Force[3];
  int32_T c1_i3;
  real_T c1_b;
  real_T c1_y;
  real_T c1_b_b;
  real_T c1_b_y;
  real_T c1_x;
  real_T c1_b_x;
  real_T c1_c_b;
  real_T c1_c_y;
  real_T c1_d_b;
  real_T c1_d_y;
  real_T c1_c_x;
  real_T c1_d_x;
  real_T c1_e_b;
  real_T c1_e_y;
  real_T c1_e_x;
  real_T c1_f_x;
  real_T c1_f_y;
  real_T c1_varargin_1;
  real_T c1_varargin_2;
  real_T c1_g_x;
  real_T c1_h_x;
  real_T c1_xk;
  real_T c1_i_x;
  int32_T c1_i4;
  real_T *c1_b_time;
  real_T (*c1_b_Force)[3];
  c1_b_Force = (real_T (*)[3])ssGetOutputPortSignal(chartInstance->S, 1);
  c1_b_time = (real_T *)ssGetInputPortSignal(chartInstance->S, 0);
  _sfTime_ = (real_T)ssGetT(chartInstance->S);
  _SFD_CC_CALL(CHART_ENTER_SFUNCTION_TAG, 0U, chartInstance->c1_sfEvent);
  _SFD_DATA_RANGE_CHECK(*c1_b_time, 0U);
  for (c1_i2 = 0; c1_i2 < 3; c1_i2++) {
    _SFD_DATA_RANGE_CHECK((*c1_b_Force)[c1_i2], 1U);
  }

  chartInstance->c1_sfEvent = CALL_EVENT;
  _SFD_CC_CALL(CHART_ENTER_DURING_FUNCTION_TAG, 0U, chartInstance->c1_sfEvent);
  c1_hoistedGlobal = *c1_b_time;
  c1_time = c1_hoistedGlobal;
  _SFD_SYMBOL_SCOPE_PUSH_EML(0U, 5U, 5U, c1_debug_family_names,
    c1_debug_family_var_map);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c1_surge, 0U, c1_b_sf_marshallOut,
    c1_b_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c1_nargin, 1U, c1_b_sf_marshallOut,
    c1_b_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c1_nargout, 2U, c1_b_sf_marshallOut,
    c1_b_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML(&c1_time, 3U, c1_b_sf_marshallOut);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(c1_Force, 4U, c1_sf_marshallOut,
    c1_sf_marshallIn);
  CV_EML_FCN(0, 0);
  _SFD_EML_CALL(0U, chartInstance->c1_sfEvent, 3);
  for (c1_i3 = 0; c1_i3 < 3; c1_i3++) {
    c1_Force[c1_i3] = 0.0;
  }

  _SFD_EML_CALL(0U, chartInstance->c1_sfEvent, 5);
  c1_b = c1_time;
  c1_y = 0.066666666666666666 * c1_b;
  c1_b_b = c1_time;
  c1_b_y = 0.5 * c1_b_b;
  c1_x = c1_b_y;
  c1_b_x = c1_x;
  c1_b_x = muDoubleScalarCos(c1_b_x);
  c1_c_b = c1_b_x;
  c1_c_y = 10.0 * c1_c_b;
  c1_d_b = c1_time;
  c1_d_y = 0.3 * c1_d_b;
  c1_c_x = c1_d_y + 0.32;
  c1_d_x = c1_c_x;
  c1_d_x = muDoubleScalarSin(c1_d_x);
  c1_e_b = c1_d_x;
  c1_e_y = 14.0 * c1_e_b;
  c1_e_x = c1_c_y + c1_e_y;
  c1_f_x = c1_e_x;
  c1_f_y = muDoubleScalarAbs(c1_f_x);
  c1_varargin_1 = c1_y + c1_f_y;
  c1_varargin_2 = c1_varargin_1;
  c1_g_x = c1_varargin_2;
  c1_h_x = c1_g_x;
  c1_eml_scalar_eg(chartInstance);
  c1_xk = c1_h_x;
  c1_i_x = c1_xk;
  c1_eml_scalar_eg(chartInstance);
  c1_surge = muDoubleScalarMin(c1_i_x, 40.0);
  _SFD_EML_CALL(0U, chartInstance->c1_sfEvent, 7);
  c1_Force[0] = c1_surge;
  _SFD_EML_CALL(0U, chartInstance->c1_sfEvent, -7);
  _SFD_SYMBOL_SCOPE_POP();
  for (c1_i4 = 0; c1_i4 < 3; c1_i4++) {
    (*c1_b_Force)[c1_i4] = c1_Force[c1_i4];
  }

  _SFD_CC_CALL(EXIT_OUT_OF_FUNCTION_TAG, 0U, chartInstance->c1_sfEvent);
  _SFD_CHECK_FOR_STATE_INCONSISTENCY(_Model_justmodel2MachineNumber_,
    chartInstance->chartNumber, chartInstance->instanceNumber);
}
static void sf_c17_HIL_model_error(SFc17_HIL_model_errorInstanceStruct
  *chartInstance)
{
  real_T c17_hoistedGlobal;
  real_T c17_b_hoistedGlobal;
  real_T c17_alpha_pi;
  real_T c17_accumulation;
  uint32_T c17_debug_family_var_map[6];
  real_T c17_sgn;
  real_T c17_nargin = 2.0;
  real_T c17_nargout = 1.0;
  real_T c17_alpha_inf;
  real_T c17_x;
  real_T c17_b_x;
  real_T c17_y;
  real_T c17_c_x;
  real_T c17_d_x;
  real_T c17_a;
  real_T c17_b_y;
  real_T c17_b_a;
  real_T c17_c_y;
  real_T *c17_b_alpha_pi;
  real_T *c17_b_alpha_inf;
  real_T *c17_b_accumulation;
  int32_T exitg1;
  c17_b_accumulation = (real_T *)ssGetInputPortSignal(chartInstance->S, 1);
  c17_b_alpha_inf = (real_T *)ssGetOutputPortSignal(chartInstance->S, 1);
  c17_b_alpha_pi = (real_T *)ssGetInputPortSignal(chartInstance->S, 0);
  _sfTime_ = (real_T)ssGetT(chartInstance->S);
  _SFD_CC_CALL(CHART_ENTER_SFUNCTION_TAG, 16U, chartInstance->c17_sfEvent);
  _SFD_DATA_RANGE_CHECK(*c17_b_alpha_pi, 0U);
  _SFD_DATA_RANGE_CHECK(*c17_b_alpha_inf, 1U);
  _SFD_DATA_RANGE_CHECK(*c17_b_accumulation, 2U);
  chartInstance->c17_sfEvent = CALL_EVENT;
  _SFD_CC_CALL(CHART_ENTER_DURING_FUNCTION_TAG, 16U, chartInstance->c17_sfEvent);
  c17_hoistedGlobal = *c17_b_alpha_pi;
  c17_b_hoistedGlobal = *c17_b_accumulation;
  c17_alpha_pi = c17_hoistedGlobal;
  c17_accumulation = c17_b_hoistedGlobal;
  _SFD_SYMBOL_SCOPE_PUSH_EML(0U, 6U, 6U, c17_debug_family_names,
    c17_debug_family_var_map);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c17_sgn, 0U, c17_sf_marshallOut,
    c17_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c17_nargin, 1U, c17_sf_marshallOut,
    c17_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c17_nargout, 2U, c17_sf_marshallOut,
    c17_sf_marshallIn);
  _SFD_SYMBOL_SCOPE_ADD_EML(&c17_alpha_pi, 3U, c17_sf_marshallOut);
  _SFD_SYMBOL_SCOPE_ADD_EML(&c17_accumulation, 4U, c17_sf_marshallOut);
  _SFD_SYMBOL_SCOPE_ADD_EML_IMPORTABLE(&c17_alpha_inf, 5U, c17_sf_marshallOut,
    c17_sf_marshallIn);
  CV_EML_FCN(0, 0);
  _SFD_EML_CALL(0U, chartInstance->c17_sfEvent, 4);
  c17_alpha_inf = c17_alpha_pi;
  _SFD_EML_CALL(0U, chartInstance->c17_sfEvent, 5);
  do {
    exitg1 = 0;
    c17_x = c17_accumulation - c17_alpha_inf;
    c17_b_x = c17_x;
    c17_y = muDoubleScalarAbs(c17_b_x);
    if (CV_EML_WHILE(0, 1, 0, c17_y > 3.1415926535897931)) {
      _SFD_EML_CALL(0U, chartInstance->c17_sfEvent, 7);
      c17_c_x = c17_accumulation - c17_alpha_inf;
      c17_sgn = c17_c_x;
      c17_d_x = c17_sgn;
      c17_sgn = c17_d_x;
      c17_sgn = muDoubleScalarSign(c17_sgn);
      _SFD_EML_CALL(0U, chartInstance->c17_sfEvent, 8);
      c17_a = c17_sgn;
      c17_b_y = c17_a * 2.0;
      c17_b_a = c17_b_y;
      c17_c_y = c17_b_a * 3.1415926535897931;
      c17_alpha_inf += c17_c_y;
      _SFD_EML_CALL(0U, chartInstance->c17_sfEvent, 5);
      _SF_MEX_LISTEN_FOR_CTRL_C(chartInstance->S);
    } else {
      exitg1 = 1;
    }
  } while (exitg1 == 0);

  _SFD_EML_CALL(0U, chartInstance->c17_sfEvent, -8);
  _SFD_SYMBOL_SCOPE_POP();
  *c17_b_alpha_inf = c17_alpha_inf;
  _SFD_CC_CALL(EXIT_OUT_OF_FUNCTION_TAG, 16U, chartInstance->c17_sfEvent);
  _SFD_CHECK_FOR_STATE_INCONSISTENCY(_HIL_model_errorMachineNumber_,
    chartInstance->chartNumber, chartInstance->instanceNumber);
}
Exemplo n.º 30
0
static void c_eml_qrsolve(const emlrtStack *sp, const emxArray_real_T *A,
  emxArray_real_T *B, emxArray_real_T *Y)
{
  emxArray_real_T *b_A;
  emxArray_real_T *work;
  int32_T mn;
  int32_T i51;
  int32_T ix;
  emxArray_real_T *tau;
  emxArray_int32_T *jpvt;
  int32_T m;
  int32_T n;
  int32_T b_mn;
  emxArray_real_T *vn1;
  emxArray_real_T *vn2;
  int32_T k;
  boolean_T overflow;
  boolean_T b12;
  int32_T i;
  int32_T i_i;
  int32_T nmi;
  int32_T mmi;
  int32_T pvt;
  int32_T iy;
  boolean_T b13;
  real_T xnorm;
  int32_T i52;
  real_T atmp;
  real_T d16;
  boolean_T b14;
  boolean_T b_i;
  ptrdiff_t n_t;
  ptrdiff_t incx_t;
  double * xix0_t;
  boolean_T exitg1;
  const mxArray *y;
  static const int32_T iv78[2] = { 1, 8 };

  const mxArray *m14;
  char_T cv76[8];
  static const char_T cv77[8] = { '%', '%', '%', 'd', '.', '%', 'd', 'e' };

  char_T cv78[14];
  uint32_T unnamed_idx_0;
  emlrtStack st;
  emlrtStack b_st;
  emlrtStack c_st;
  emlrtStack d_st;
  emlrtStack e_st;
  emlrtStack f_st;
  emlrtStack g_st;
  emlrtStack h_st;
  st.prev = sp;
  st.tls = sp->tls;
  b_st.prev = &st;
  b_st.tls = st.tls;
  c_st.prev = &b_st;
  c_st.tls = b_st.tls;
  d_st.prev = &c_st;
  d_st.tls = c_st.tls;
  e_st.prev = &d_st;
  e_st.tls = d_st.tls;
  f_st.prev = &e_st;
  f_st.tls = e_st.tls;
  g_st.prev = &f_st;
  g_st.tls = f_st.tls;
  h_st.prev = &g_st;
  h_st.tls = g_st.tls;
  emlrtHeapReferenceStackEnterFcnR2012b(sp);
  emxInit_real_T(sp, &b_A, 2, &m_emlrtRTEI, true);
  b_emxInit_real_T(sp, &work, 1, &rb_emlrtRTEI, true);
  mn = (int32_T)muDoubleScalarMin(A->size[0], A->size[1]);
  st.site = &mc_emlrtRSI;
  b_st.site = &nc_emlrtRSI;
  c_st.site = &oc_emlrtRSI;
  i51 = b_A->size[0] * b_A->size[1];
  b_A->size[0] = A->size[0];
  b_A->size[1] = A->size[1];
  emxEnsureCapacity(&c_st, (emxArray__common *)b_A, i51, (int32_T)sizeof(real_T),
                    &m_emlrtRTEI);
  ix = A->size[0] * A->size[1];
  for (i51 = 0; i51 < ix; i51++) {
    b_A->data[i51] = A->data[i51];
  }

  b_emxInit_real_T(&c_st, &tau, 1, &m_emlrtRTEI, true);
  b_emxInit_int32_T(&c_st, &jpvt, 2, &m_emlrtRTEI, true);
  m = b_A->size[0];
  n = b_A->size[1];
  b_mn = muIntScalarMin_sint32(b_A->size[0], b_A->size[1]);
  i51 = tau->size[0];
  tau->size[0] = b_mn;
  emxEnsureCapacity(&c_st, (emxArray__common *)tau, i51, (int32_T)sizeof(real_T),
                    &n_emlrtRTEI);
  d_st.site = &mf_emlrtRSI;
  e_st.site = &rb_emlrtRSI;
  f_st.site = &sb_emlrtRSI;
  g_st.site = &tb_emlrtRSI;
  eml_signed_integer_colon(&g_st, b_A->size[1], jpvt);
  if ((b_A->size[0] == 0) || (b_A->size[1] == 0)) {
  } else {
    ix = b_A->size[1];
    i51 = work->size[0];
    work->size[0] = ix;
    emxEnsureCapacity(&c_st, (emxArray__common *)work, i51, (int32_T)sizeof
                      (real_T), &m_emlrtRTEI);
    for (i51 = 0; i51 < ix; i51++) {
      work->data[i51] = 0.0;
    }

    b_emxInit_real_T(&c_st, &vn1, 1, &pb_emlrtRTEI, true);
    b_emxInit_real_T(&c_st, &vn2, 1, &qb_emlrtRTEI, true);
    d_st.site = &tc_emlrtRSI;
    ix = b_A->size[1];
    i51 = vn1->size[0];
    vn1->size[0] = ix;
    emxEnsureCapacity(&c_st, (emxArray__common *)vn1, i51, (int32_T)sizeof
                      (real_T), &pb_emlrtRTEI);
    i51 = vn2->size[0];
    vn2->size[0] = ix;
    emxEnsureCapacity(&c_st, (emxArray__common *)vn2, i51, (int32_T)sizeof
                      (real_T), &qb_emlrtRTEI);
    k = 1;
    d_st.site = &nf_emlrtRSI;
    overflow = (b_A->size[1] > 2147483646);
    if (overflow) {
      e_st.site = &db_emlrtRSI;
      check_forloop_overflow_error(&e_st);
    }

    for (ix = 0; ix + 1 <= b_A->size[1]; ix++) {
      d_st.site = &sc_emlrtRSI;
      vn1->data[ix] = b_eml_xnrm2(&d_st, b_A->size[0], b_A, k);
      vn2->data[ix] = vn1->data[ix];
      k += b_A->size[0];
    }

    d_st.site = &rc_emlrtRSI;
    if (1 > b_mn) {
      b12 = false;
    } else {
      b12 = (b_mn > 2147483646);
    }

    if (b12) {
      e_st.site = &db_emlrtRSI;
      check_forloop_overflow_error(&e_st);
    }

    for (i = 1; i <= b_mn; i++) {
      i_i = (i + (i - 1) * m) - 1;
      nmi = n - i;
      mmi = m - i;
      d_st.site = &of_emlrtRSI;
      ix = eml_ixamax(&d_st, 1 + nmi, vn1, i);
      pvt = (i + ix) - 2;
      if (pvt + 1 != i) {
        d_st.site = &pf_emlrtRSI;
        e_st.site = &bc_emlrtRSI;
        f_st.site = &cc_emlrtRSI;
        ix = 1 + m * pvt;
        iy = 1 + m * (i - 1);
        g_st.site = &dc_emlrtRSI;
        if (1 > m) {
          b13 = false;
        } else {
          b13 = (m > 2147483646);
        }

        if (b13) {
          h_st.site = &db_emlrtRSI;
          check_forloop_overflow_error(&h_st);
        }

        for (k = 1; k <= m; k++) {
          i51 = b_A->size[0] * b_A->size[1];
          xnorm = b_A->data[emlrtDynamicBoundsCheckFastR2012b(ix, 1, i51,
            &le_emlrtBCI, &f_st) - 1];
          i51 = b_A->size[0] * b_A->size[1];
          i52 = b_A->size[0] * b_A->size[1];
          b_A->data[emlrtDynamicBoundsCheckFastR2012b(ix, 1, i51, &le_emlrtBCI,
            &f_st) - 1] = b_A->data[emlrtDynamicBoundsCheckFastR2012b(iy, 1, i52,
            &le_emlrtBCI, &f_st) - 1];
          i51 = b_A->size[0] * b_A->size[1];
          b_A->data[emlrtDynamicBoundsCheckFastR2012b(iy, 1, i51, &le_emlrtBCI,
            &f_st) - 1] = xnorm;
          ix++;
          iy++;
        }

        ix = jpvt->data[pvt];
        jpvt->data[pvt] = jpvt->data[i - 1];
        jpvt->data[i - 1] = ix;
        vn1->data[pvt] = vn1->data[i - 1];
        vn2->data[pvt] = vn2->data[i - 1];
      }

      if (i < m) {
        d_st.site = &qc_emlrtRSI;
        atmp = b_A->data[i_i];
        d16 = 0.0;
        if (1 + mmi <= 0) {
        } else {
          e_st.site = &wc_emlrtRSI;
          xnorm = b_eml_xnrm2(&e_st, mmi, b_A, i_i + 2);
          if (xnorm != 0.0) {
            xnorm = muDoubleScalarHypot(b_A->data[i_i], xnorm);
            if (b_A->data[i_i] >= 0.0) {
              xnorm = -xnorm;
            }

            if (muDoubleScalarAbs(xnorm) < 1.0020841800044864E-292) {
              ix = 0;
              do {
                ix++;
                e_st.site = &xc_emlrtRSI;
                b_eml_xscal(&e_st, mmi, 9.9792015476736E+291, b_A, i_i + 2);
                xnorm *= 9.9792015476736E+291;
                atmp *= 9.9792015476736E+291;
              } while (!(muDoubleScalarAbs(xnorm) >= 1.0020841800044864E-292));

              e_st.site = &yc_emlrtRSI;
              xnorm = b_eml_xnrm2(&e_st, mmi, b_A, i_i + 2);
              xnorm = muDoubleScalarHypot(atmp, xnorm);
              if (atmp >= 0.0) {
                xnorm = -xnorm;
              }

              d16 = (xnorm - atmp) / xnorm;
              e_st.site = &ad_emlrtRSI;
              b_eml_xscal(&e_st, mmi, 1.0 / (atmp - xnorm), b_A, i_i + 2);
              e_st.site = &bd_emlrtRSI;
              if (1 > ix) {
                b14 = false;
              } else {
                b14 = (ix > 2147483646);
              }

              if (b14) {
                f_st.site = &db_emlrtRSI;
                check_forloop_overflow_error(&f_st);
              }

              for (k = 1; k <= ix; k++) {
                xnorm *= 1.0020841800044864E-292;
              }

              atmp = xnorm;
            } else {
              d16 = (xnorm - b_A->data[i_i]) / xnorm;
              atmp = 1.0 / (b_A->data[i_i] - xnorm);
              e_st.site = &cd_emlrtRSI;
              b_eml_xscal(&e_st, mmi, atmp, b_A, i_i + 2);
              atmp = xnorm;
            }
          }
        }

        tau->data[i - 1] = d16;
      } else {
        atmp = b_A->data[i_i];
        d_st.site = &pc_emlrtRSI;
        tau->data[i - 1] = eml_matlab_zlarfg();
      }

      b_A->data[i_i] = atmp;
      if (i < n) {
        atmp = b_A->data[i_i];
        b_A->data[i_i] = 1.0;
        d_st.site = &qf_emlrtRSI;
        eml_matlab_zlarf(&d_st, mmi + 1, nmi, i_i + 1, tau->data[i - 1], b_A, i
                         + i * m, m, work);
        b_A->data[i_i] = atmp;
      }

      d_st.site = &rf_emlrtRSI;
      if (i + 1 > n) {
        b_i = false;
      } else {
        b_i = (n > 2147483646);
      }

      if (b_i) {
        e_st.site = &db_emlrtRSI;
        check_forloop_overflow_error(&e_st);
      }

      for (ix = i; ix + 1 <= n; ix++) {
        if (vn1->data[ix] != 0.0) {
          xnorm = muDoubleScalarAbs(b_A->data[(i + b_A->size[0] * ix) - 1]) /
            vn1->data[ix];
          xnorm = 1.0 - xnorm * xnorm;
          if (xnorm < 0.0) {
            xnorm = 0.0;
          }

          atmp = vn1->data[ix] / vn2->data[ix];
          atmp = xnorm * (atmp * atmp);
          if (atmp <= 1.4901161193847656E-8) {
            if (i < m) {
              d_st.site = &sf_emlrtRSI;
              e_st.site = &uc_emlrtRSI;
              if (mmi < 1) {
                xnorm = 0.0;
              } else {
                f_st.site = &vc_emlrtRSI;
                g_st.site = &vc_emlrtRSI;
                n_t = (ptrdiff_t)(mmi);
                g_st.site = &vc_emlrtRSI;
                incx_t = (ptrdiff_t)(1);
                i51 = b_A->size[0] * b_A->size[1];
                i52 = (i + m * ix) + 1;
                xix0_t = (double *)(&b_A->data[emlrtDynamicBoundsCheckFastR2012b
                                    (i52, 1, i51, &vb_emlrtBCI, &f_st) - 1]);
                xnorm = dnrm2(&n_t, xix0_t, &incx_t);
              }

              vn1->data[ix] = xnorm;
              vn2->data[ix] = vn1->data[ix];
            } else {
              vn1->data[ix] = 0.0;
              vn2->data[ix] = 0.0;
            }
          } else {
            d_st.site = &tf_emlrtRSI;
            vn1->data[ix] *= muDoubleScalarSqrt(xnorm);
          }
        }
      }
    }

    emxFree_real_T(&vn2);
    emxFree_real_T(&vn1);
  }

  atmp = 0.0;
  if (mn > 0) {
    xnorm = muDoubleScalarMax(A->size[0], A->size[1]) * muDoubleScalarAbs
      (b_A->data[0]) * 2.2204460492503131E-16;
    k = 0;
    exitg1 = false;
    while ((!exitg1) && (k <= mn - 1)) {
      if (muDoubleScalarAbs(b_A->data[k + b_A->size[0] * k]) <= xnorm) {
        st.site = &lc_emlrtRSI;
        y = NULL;
        m14 = emlrtCreateCharArray(2, iv78);
        for (i = 0; i < 8; i++) {
          cv76[i] = cv77[i];
        }

        emlrtInitCharArrayR2013a(&st, 8, m14, cv76);
        emlrtAssign(&y, m14);
        b_st.site = &tg_emlrtRSI;
        emlrt_marshallIn(&b_st, c_sprintf(&b_st, b_sprintf(&b_st, y,
          emlrt_marshallOut(14.0), emlrt_marshallOut(6.0), &o_emlrtMCI),
          emlrt_marshallOut(xnorm), &p_emlrtMCI), "sprintf", cv78);
        st.site = &kc_emlrtRSI;
        b_eml_warning(&st, atmp, cv78);
        exitg1 = true;
      } else {
        atmp++;
        k++;
      }
    }
  }

  unnamed_idx_0 = (uint32_T)A->size[1];
  i51 = Y->size[0];
  Y->size[0] = (int32_T)unnamed_idx_0;
  emxEnsureCapacity(sp, (emxArray__common *)Y, i51, (int32_T)sizeof(real_T),
                    &m_emlrtRTEI);
  ix = (int32_T)unnamed_idx_0;
  for (i51 = 0; i51 < ix; i51++) {
    Y->data[i51] = 0.0;
  }

  for (ix = 0; ix < mn; ix++) {
    if (tau->data[ix] != 0.0) {
      xnorm = B->data[ix];
      i51 = A->size[0] + (int32_T)(1.0 - ((1.0 + (real_T)ix) + 1.0));
      emlrtForLoopVectorCheckR2012b((1.0 + (real_T)ix) + 1.0, 1.0, A->size[0],
        mxDOUBLE_CLASS, i51, &ac_emlrtRTEI, sp);
      for (i = 0; i < i51; i++) {
        unnamed_idx_0 = ((uint32_T)ix + i) + 2U;
        xnorm += b_A->data[((int32_T)unnamed_idx_0 + b_A->size[0] * ix) - 1] *
          B->data[(int32_T)unnamed_idx_0 - 1];
      }

      xnorm *= tau->data[ix];
      if (xnorm != 0.0) {
        B->data[ix] -= xnorm;
        i51 = A->size[0] + (int32_T)(1.0 - ((1.0 + (real_T)ix) + 1.0));
        emlrtForLoopVectorCheckR2012b((1.0 + (real_T)ix) + 1.0, 1.0, A->size[0],
          mxDOUBLE_CLASS, i51, &yb_emlrtRTEI, sp);
        for (i = 0; i < i51; i++) {
          unnamed_idx_0 = ((uint32_T)ix + i) + 2U;
          B->data[(int32_T)unnamed_idx_0 - 1] -= b_A->data[((int32_T)
            unnamed_idx_0 + b_A->size[0] * ix) - 1] * xnorm;
        }
      }
    }
  }

  emxFree_real_T(&tau);
  emlrtForLoopVectorCheckR2012b(1.0, 1.0, atmp, mxDOUBLE_CLASS, (int32_T)atmp,
    &xb_emlrtRTEI, sp);
  for (i = 0; i < (int32_T)atmp; i++) {
    Y->data[jpvt->data[i] - 1] = B->data[i];
  }

  emlrtForLoopVectorCheckR2012b(atmp, -1.0, 1.0, mxDOUBLE_CLASS, (int32_T)-(1.0
    + (-1.0 - atmp)), &wb_emlrtRTEI, sp);
  for (ix = 0; ix < (int32_T)-(1.0 + (-1.0 - atmp)); ix++) {
    xnorm = atmp + -(real_T)ix;
    Y->data[jpvt->data[(int32_T)xnorm - 1] - 1] = eml_div(Y->data[jpvt->data
      [(int32_T)xnorm - 1] - 1], b_A->data[((int32_T)xnorm + b_A->size[0] *
      ((int32_T)xnorm - 1)) - 1]);
    for (i = 0; i < (int32_T)(xnorm - 1.0); i++) {
      Y->data[jpvt->data[i] - 1] -= Y->data[jpvt->data[(int32_T)xnorm - 1] - 1] *
        b_A->data[i + b_A->size[0] * ((int32_T)xnorm - 1)];
    }
  }

  emxFree_int32_T(&jpvt);
  emxFree_real_T(&work);
  emxFree_real_T(&b_A);
  emlrtHeapReferenceStackLeaveFcnR2012b(sp);
}