Beispiel #1
0
int
_nrrdHestKernelSpecParse(void *ptr, char *str, char err[AIR_STRLEN_HUGE]) {
  NrrdKernelSpec **ksP;
  char me[]="_nrrdHestKernelSpecParse", *nerr;

  if (!(ptr && str)) {
    sprintf(err, "%s: got NULL pointer", me);
    return 1;
  }
  ksP = (NrrdKernelSpec **)ptr;
  *ksP = nrrdKernelSpecNew();
  if (nrrdKernelParse(&((*ksP)->kernel), (*ksP)->parm, str)) {
    nerr = biffGetDone(NRRD);
    airStrcpy(err, AIR_STRLEN_HUGE, nerr);
    free(nerr);
    return 1;
  }
  return 0;
}
Beispiel #2
0
int
main(int argc, char *argv[]) {
  char *me, *kS, *minS, *stepS, *maxS, *outS, *err, kstr[AIR_STRLEN_LARGE];
  const NrrdKernel *k;
  NrrdKernelSpec *ksp;
  double parm[NRRD_KERNEL_PARMS_NUM], min, step, max, integral,
    *dom_d, *ran_d;
  float *dom_f, *ran_f, v, r_f, r_d;
  FILE *fout;
  int i, len;
  airArray *mop;

  me = argv[0];
  if (6 != argc) {
    usage(me);
  }
  kS = argv[1];
  minS = argv[2];
  stepS = argv[3];
  maxS = argv[4];
  outS = argv[5];
  
  mop = airMopNew();
  if (nrrdKernelParse(&k, parm, kS)) {
    airMopAdd(mop, err=biffGetDone(NRRD), airFree, airMopAlways);
    fprintf(stderr, "%s: trouble:\n%s\n", me, err);
    airMopError(mop);
    exit(1);
  }
  ksp = nrrdKernelSpecNew();
  airMopAdd(mop, ksp, (airMopper)nrrdKernelSpecNix, airMopAlways);
  nrrdKernelSpecSet(ksp, k, parm);
  if (nrrdKernelSpecSprint(kstr, ksp)) {
    airMopAdd(mop, err=biffGetDone(NRRD), airFree, airMopAlways);
    fprintf(stderr, "%s: trouble:\n%s\n", me, err);
    airMopError(mop);
    exit(1);
  }
  printf("%s: printed kernel as \"%s\"\n", me, kstr);
  if (3 != (sscanf(minS, "%lf", &min) +
            sscanf(stepS, "%lf", &step) +
            sscanf(maxS, "%lf", &max))) {
    fprintf(stderr, "%s: couldn't parse \"%s\", \"%s\", \"%s\" as 3 doubles\n",
            me, minS, stepS, maxS);
    exit(1);
  }
  if (!( min <= -k->support(parm) && max >= k->support(parm) )) {
    fprintf(stderr, "%s: WARNING: support=%g => lower min (%g) or raise max (%g)\n",
            me, k->support(parm), min, max);
  }

  /* see how many values are in the interval */
  len = 0;
  for (v=min; v<=max; v+=step) {
    len++;
  }
  /* allocate domain and range for both float and double */
  if (!( (dom_d = (double *)calloc(len, sizeof(double))) &&
         (ran_d = (double *)calloc(len, sizeof(double))) &&
         (dom_f = (float *)calloc(len, sizeof(float))) &&
         (ran_f = (float *)calloc(len, sizeof(float))) )) {
    fprintf(stderr, "%s: PANIC: couldn't allocate buffers\n", me);
    exit(1);
  }
  airMopAdd(mop, dom_d, airFree, airMopAlways);
  airMopAdd(mop, ran_d, airFree, airMopAlways);
  airMopAdd(mop, dom_f, airFree, airMopAlways);
  airMopAdd(mop, ran_f, airFree, airMopAlways);
  /* set values in both domains */
  i=0;
  for (v=min; v<=max; v+=step) {
    /* note that the value stored in dom_d[i] is only a 
       single-precision float, so that it is really equal to dom_f[i] */
    dom_d[i] = v;
    dom_f[i] = v;
    i++;
  }
  /* do the vector evaluations */
  k->evalN_f(ran_f, dom_f, len, parm);
  k->evalN_d(ran_d, dom_d, len, parm);
  /* do the single evaluations, and make sure everything agrees */
  i = 0;
  integral = 0;
  for (v=min; v<=max; v+=step) {
    /* compare two single evaluations */
    r_f = k->eval1_f(v, parm);
    r_d = k->eval1_d(v, parm);
    if (!CLOSE(r_f,r_d)) {
      fprintf(stderr, "%s: (eval1_f(%g)== %f) != (eval1_d(%g)== %f)\n",
              me, v, r_f, v, r_d);
    }
    /* compare single float with vector float */
    if (!CLOSE(r_f,ran_f[i])) {
      fprintf(stderr, "%s: (eval1_f(%g)== %f) != (evalN_f[%d]== %f)\n",
              me, v, r_f, i, ran_f[i]);
    }
    /* compare single float with vector double */
    r_d = ran_d[i];
    if (!CLOSE(r_f,r_d)) {
      fprintf(stderr, "%s: (eval1_f(%g)== %f) != (evalN_d[%d]== %f)\n",
              me, v, r_f, i, r_d);
    }
    integral += step*ran_d[i];
    i++;
  }
  if (!KINDACLOSE(integral, k->integral(parm))) {
    fprintf(stderr, 
            "discrete integral %f != %f\n", integral, k->integral(parm));
    /* not a fatal error */
  }
  
  /* it all checks out; write the file */
  if (!(fout = fopen(outS, "w"))) {
    fprintf(stderr, "%s: couldn't open \"%s\" for writing\n", me, outS);
    exit(1);
  }
  for (i=0; i<=len-1; i++) {
    fprintf(fout, "%g %g\n", dom_f[i], ran_f[i]);
  }
  fclose(fout);

  fprintf(stderr, "(for matlab:)\n");
  fprintf(stderr, "x = dlmread(\'%s\', \' \'); plot(x(:,1), x(:,2));\n", outS);
  airMopOkay(mop);
  exit(0);
}
Beispiel #3
0
int
main(int argc, char *argv[]) {
  char *me, *kernS[2], *minS, *stepS, *maxS, *outS, *err, kstr[AIR_STRLEN_LARGE];
  const NrrdKernel *kern[2];
  NrrdKernelSpec *ksp[2];
  double parm[NRRD_KERNEL_PARMS_NUM], min, step, max, integral,
    *dom_d, *ran_d;
  float *dom_f, *ran_f, val, r_f, r_d;
  FILE *fout;
  int i, len;
  airArray *mop;
  unsigned int kii;

  me = argv[0];
  if (!( 6 == argc || 7 == argc )) {
    usage(me);
  }
  kernS[0] = argv[1];
  minS = argv[2];
  stepS = argv[3];
  maxS = argv[4];
  outS = argv[5];
  if (7 == argc) {
    kernS[1] = argv[6];
  } else {
    kernS[1] = NULL;
  }

  if (3 != (sscanf(minS, "%lf", &min) +
            sscanf(stepS, "%lf", &step) +
            sscanf(maxS, "%lf", &max))) {
    fprintf(stderr, "%s: couldn't parse \"%s\", \"%s\", \"%s\" as 3 doubles\n",
            me, minS, stepS, maxS);
    exit(1);
  }

  mop = airMopNew();
  for (kii=0; kii<=(kernS[1] ? 1 : 0); kii++) {
    if (nrrdKernelParse(&(kern[kii]), parm, kernS[kii])) {
      airMopAdd(mop, err=biffGetDone(NRRD), airFree, airMopAlways);
      fprintf(stderr, "%s: (kii %u) trouble:\n%s\n", me, kii, err);
      airMopError(mop);
      exit(1);
    }
    ksp[kii] = nrrdKernelSpecNew();
    airMopAdd(mop, ksp[kii], (airMopper)nrrdKernelSpecNix, airMopAlways);
    nrrdKernelSpecSet(ksp[kii], kern[kii], parm);
    if (nrrdKernelSpecSprint(kstr, ksp[kii])) {
      airMopAdd(mop, err=biffGetDone(NRRD), airFree, airMopAlways);
      fprintf(stderr, "%s: trouble:\n%s\n", me, err);
      airMopError(mop);
      exit(1);
    }
    fprintf(stderr, "%s: printed kernel as \"%s\"\n", me, kstr);
    if (!( min <= -kern[kii]->support(parm)
           && max >= kern[kii]->support(parm) )) {
      fprintf(stderr, "%s: WARNING: support=%g => lower min (%g) or raise max (%g)\n",
              me, kern[kii]->support(parm), min, max);
    }
    fprintf(stderr, "%s: support(%s) = %g\n", me, kstr, kern[kii]->support(parm));
  }

  /* see how many values are in the interval */
  len = 0;
  for (val=min; val<=max; val+=step) {
    len++;
  }
  /* allocate domain and range for both float and double */
  if (!( (dom_d = (double *)calloc(len, sizeof(double))) &&
         (ran_d = (double *)calloc(len, sizeof(double))) &&
         (dom_f = (float *)calloc(len, sizeof(float))) &&
         (ran_f = (float *)calloc(len, sizeof(float))) )) {
    fprintf(stderr, "%s: PANIC: couldn't allocate buffers\n", me);
    exit(1);
  }
  airMopAdd(mop, dom_d, airFree, airMopAlways);
  airMopAdd(mop, ran_d, airFree, airMopAlways);
  airMopAdd(mop, dom_f, airFree, airMopAlways);
  airMopAdd(mop, ran_f, airFree, airMopAlways);
  /* set values in both domains */
  i=0;
  for (val=min; val<=max; val+=step) {
    /* note that the value stored in dom_d[i] is only a
       single-precision float, so that it is really equal to dom_f[i] */
    dom_d[i] = val;
    dom_f[i] = val;
    i++;
  }
  /* do the vector evaluations */
  kern[0]->evalN_f(ran_f, dom_f, len, parm);
  kern[0]->evalN_d(ran_d, dom_d, len, parm);
  /* do the single evaluations, and make sure everything agrees */
  i = 0;
  integral = 0;
  for (val=min; val<=max; val+=step) {
    /* compare two single evaluations */
    r_f = kern[0]->eval1_f(val, parm);
    r_d = kern[0]->eval1_d(val, parm);
    if (!CLOSE(r_f,r_d, 0.00001)) {
      fprintf(stderr, "%s: (eval1_f(%g)== %f) != (eval1_d(%g)== %f)\n",
              me, val, r_f, val, r_d);
    }
    /* compare single float with vector float */
    if (!CLOSE(r_f,ran_f[i], 0.00001)) {
      fprintf(stderr, "%s: (eval1_f(%g)== %f) != (evalN_f[%d]== %f)\n",
              me, val, r_f, i, ran_f[i]);
    }
    /* compare single float with vector double */
    r_d = ran_d[i];
    if (!CLOSE(r_f,r_d, 0.00001)) {
      fprintf(stderr, "%s: (eval1_f(%g)== %f) != (evalN_d[%d]== %f)\n",
              me, val, r_f, i, r_d);
    }
    integral += step*ran_d[i];
    /* possibly check on given derivatives */
    if (kern[1]) {
      double numd;
      numd = (kern[0]->eval1_d(val+step/2, parm)
              - kern[0]->eval1_d(val-step/2, parm))/step;
      if (!CLOSE(numd, kern[1]->eval1_d(val+step, parm), 0.005)) {
        fprintf(stderr, "%s: |numerical f'(%g) %g - true %g| = %g > 0.005\n",
                me, val, numd, kern[1]->eval1_d(val+step, parm),
                fabs(numd - kern[1]->eval1_d(val+step, parm)));
        /* exit(1); */
      }
    }
    i++;
  }
  if (!CLOSE(integral, kern[0]->integral(parm), 0.0005)) {
    fprintf(stderr, "%s: HEY HEY HEY HEY HEY HEY!\n", me);
    fprintf(stderr,
            "%s: discrete integral %f != %f\n", me, integral, kern[0]->integral(parm));
    /* exit(1); */
  }

  /* it all checks out; write the file */
  if (!(fout = airFopen(outS, stdout, "w"))) {
    fprintf(stderr, "%s: couldn't open \"%s\" for writing\n", me, outS);
    exit(1);
  }
  for (i=0; i<=len-1; i++) {
    fprintf(fout, "%g %g\n", dom_f[i], ran_f[i]);
  }
  fclose(fout);

  airMopOkay(mop);
  exit(0);
}