/*------------------------------------------------------------------------*/
int sci_plot2d(char* fname, void *pvApiCtx)
{
SciErr sciErr;
int* piAddrl1 = NULL;
double* l1 = NULL;
int* piAddrl2 = NULL;
double* l2 = NULL;
double* lt = NULL;
int iTypel1 = 0;
int iTypel2 = 0;
int lw = 0;
int m1 = 0, n1 = 0, m2 = 0, n2 = 0;
int test = 0, i = 0, j = 0, iskip = 0;
int frame_def = 8;
int *frame = &frame_def;
int axes_def = 1;
int *axes = &axes_def;
/* F.Leray 18.05.04 : log. case test*/
int size_x = 0, size_y = 0;
char dataflag = 0;
char* logFlags = NULL;
int* style = NULL;
double* rect = NULL;
char* strf = NULL;
char* legend = NULL;
int* nax = NULL;
BOOL flagNax = FALSE;
char strfl[4];
BOOL freeStrf = FALSE;
rhs_opts opts[] =
{
{ -1, "axesflag", -1, 0, 0, NULL},
{ -1, "frameflag", -1, 0, 0, NULL},
{ -1, "leg", -1, 0, 0, NULL},
{ -1, "logflag", -1, 0, 0, NULL},
{ -1, "nax", -1, 0, 0, NULL},
{ -1, "rect", -1, 0, 0, NULL},
{ -1, "strf", -1, 0, 0, NULL},
{ -1, "style", -1, 0, 0, NULL},
{ -1, NULL, -1, 0, 0, NULL}
};
if (nbInputArgument(pvApiCtx) == 0)
{
sci_demo(fname, pvApiCtx);
return 0;
}
CheckInputArgument(pvApiCtx, 1, 9);
iskip = 0;
if (getOptionals(pvApiCtx, fname, opts) == 0)
{
ReturnArguments(pvApiCtx);
return 0;
}
if (checkInputArgumentType(pvApiCtx, 1, sci_strings))
{
/* logflags */
GetLogflags(pvApiCtx, fname, 1, opts, &logFlags);
iskip = 1;
}
if (FirstOpt(pvApiCtx) == 2 + iskip) /** plot2d([loglags,] y, <opt_args>); **/
{
sciErr = getVarAddressFromPosition(pvApiCtx, 1 + iskip, &piAddrl2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
sciErr = getVarType(pvApiCtx, piAddrl2, &iTypel2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// the argument can be a matrix of doubles or other
// If it is not a matrix of doubles, call overload
if (iTypel2 == sci_matrix)
{
// Retrieve a matrix of double at position 1 + iskip.
sciErr = getMatrixOfDouble(pvApiCtx, piAddrl2, &m2, &n2, &l2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 1 + iskip);
return 1;
}
}
else
{
OverLoad(1);
return 0;
}
if (m2 == 1 && n2 > 1)
{
m2 = n2;
n2 = 1;
}
m1 = m2;
n1 = n2;
sciErr = allocMatrixOfDouble(pvApiCtx, nbInputArgument(pvApiCtx) + 1, m1, n1, &l1);
if (sciErr.iErr)
{
printError(&sciErr, 0);
Scierror(999, _("%s: Memory allocation error.\n"), fname);
return 1;
}
for (i = 0; i < m2 ; ++i)
{
for (j = 0 ; j < n2 ; ++j)
{
*(l1 + i + m2 * j) = (double) i + 1;
}
}
}
else if (FirstOpt(pvApiCtx) >= 3 + iskip) /** plot2d([loglags,] x, y[, style [,...]]); **/
{
/* x */
sciErr = getVarAddressFromPosition(pvApiCtx, 1 + iskip, &piAddrl1);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
sciErr = getVarType(pvApiCtx, piAddrl1, &iTypel1);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// x can be a matrix of doubles or other
// If x is not a matrix of doubles, call overload
if (iTypel1 == sci_matrix)
{
// Retrieve a matrix of double at position 1 + iskip.
sciErr = getMatrixOfDouble(pvApiCtx, piAddrl1, &m1, &n1, &l1);
if (sciErr.iErr)
{
printError(&sciErr, 0);
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 1 + iskip);
return 1;
}
}
else
{
OverLoad(1);
return 0;
}
/* y */
sciErr = getVarAddressFromPosition(pvApiCtx, 2 + iskip, &piAddrl2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
sciErr = getVarType(pvApiCtx, piAddrl2, &iTypel2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// y can be a matrix of doubles or other
// If y is not a matrix of doubles, call overload
if (iTypel2 == sci_matrix)
{
// Retrieve a matrix of double at position 1 + iskip.
sciErr = getMatrixOfDouble(pvApiCtx, piAddrl2, &m2, &n2, &l2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 2 + iskip);
return 1;
}
}
else
{
OverLoad(2);
return 0;
}
test = (m1 * n1 == 0) ||
((m1 == 1 || n1 == 1) && (m2 == 1 || n2 == 1) && (m1 * n1 == m2 * n2)) ||
((m1 == m2) && (n1 == n2)) ||
((m1 == 1 && n1 == m2) || (n1 == 1 && m1 == m2));
//CheckDimProp
if (!test)
{
Scierror(999, _("%s: Wrong size for input arguments: Incompatible sizes.\n"), fname);
return 1;
}
if (m1 * n1 == 0)
{
/* default x=1:n */
sciErr = allocMatrixOfDouble(pvApiCtx, nbInputArgument(pvApiCtx) + 1, m2, n2, <);
if (sciErr.iErr)
{
printError(&sciErr, 0);
Scierror(999, _("%s: Memory allocation error.\n"), fname);
return 1;
}
if (m2 == 1 && n2 > 1)
{
m2 = n2;
n2 = 1;
}
for (i = 0; i < m2 ; ++i)
{
for (j = 0 ; j < n2 ; ++j)
{
*(lt + i + m2 * j) = (double) i + 1;
}
}
m1 = m2;
n1 = n2;
l1 = lt;
}
else if ((m1 == 1 || n1 == 1) && (m2 != 1 && n2 != 1))
{
/* a single x vector for mutiple columns for y */
sciErr = allocMatrixOfDouble(pvApiCtx, nbInputArgument(pvApiCtx) + 1, m2, n2, <);
if (sciErr.iErr)
{
printError(&sciErr, 0);
Scierror(999, _("%s: Memory allocation error.\n"), fname);
return 1;
}
for (i = 0; i < m2 ; ++i)
{
for (j = 0 ; j < n2 ; ++j)
{
*(lt + i + m2 * j) = *(l1 + i);
}
}
m1 = m2;
n1 = n2;
l1 = lt;
}
else if ((m1 == 1 && n1 == 1) && (n2 != 1))
{
/* a single y row vector for a single x */
sciErr = allocMatrixOfDouble(pvApiCtx, nbInputArgument(pvApiCtx) + 1, m1, n2, <);
if (sciErr.iErr)
{
printError(&sciErr, 0);
Scierror(999, _("%s: Memory allocation error.\n"), fname);
return 1;
}
for (j = 0 ; j < n2 ; ++j)
{
lt[j] = *l1;
}
n1 = n2;
l1 = lt;
}
else
{
if (m2 == 1 && n2 > 1)
{
m2 = n2;
n2 = 1;
}
if (m1 == 1 && n1 > 1)
{
m1 = n1;
n1 = 1;
}
}
}
else
{
Scierror(999, _("%s: Wrong number of mandatory input arguments. At least %d expected.\n"), fname, 1);
return 0;
}
if (n1 == -1 || n2 == -1 || m1 == -1 || m2 == -1)
{
Scierror(999, _("%s: Wrong size for input arguments #%d and #%d.\n"), fname, 1, 2); /* @TODO : detail error */
return 0;
}
sciGetStyle(pvApiCtx, fname, 3 + iskip, n1, opts, &style);
GetStrf(pvApiCtx, fname, 4 + iskip, opts, &strf);
GetLegend(pvApiCtx, fname, 5 + iskip, opts, &legend);
GetRect(pvApiCtx, fname, 6 + iskip, opts, &rect);
GetNax(pvApiCtx, 7 + iskip, opts, &nax, &flagNax);
if (iskip == 0)
{
GetLogflags(pvApiCtx, fname, 8, opts, &logFlags);
}
freeStrf = !isDefStrf(strf);
// Check strf [0-1][0-8][0-5]
if (!isDefStrf(strf) && (strlen(strf) != 3 || strf[0] < '0' || strf[0] > '1' || strf[1] < '0' || strf[1] > '8' || strf[2] < '0' || strf[2] > '5'))
{
Scierror(999, _("%s: Wrong value for strf option: %s.\n"), fname, strf);
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
return -1;
}
if (isDefStrf(strf))
{
strcpy(strfl, DEFSTRFN);
strf = strfl;
if (!isDefRect(rect))
{
strfl[1] = '7';
}
if (!isDefLegend(legend))
{
strfl[0] = '1';
}
GetOptionalIntArg(pvApiCtx, fname, 9, "frameflag", &frame, 1, opts);
if (frame != &frame_def)
{
if (*frame >= 0 && *frame <= 8)
{
strfl[1] = (char)(*frame + 48);
}
else
{
Scierror(999, _("%s: Wrong value for frameflag option.\n"), fname);
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
return -1;
}
}
GetOptionalIntArg(pvApiCtx, fname, 9, "axesflag", &axes, 1, opts);
if (axes != &axes_def)
{
if ((*axes >= 0 && *axes <= 5) || *axes == 9)
{
strfl[2] = (char)(*axes + 48);
}
else
{
Scierror(999, _("%s: Wrong value for axesflag option.\n"), fname);
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
return -1;
}
}
}
/* Make a test on log. mode : available or not depending on the bounds set by Rect arg. or xmin/xmax :
Rect case :
- if the min bound is strictly posivite, we can use log. mode
- if not, send error message
x/y min/max case:
- we find the first strictly positive min bound in Plo2dn.c ?? */
switch (strf[1])
{
case '0':
/* no computation, the plot use the previous (or default) scale */
break;
case '1' :
case '3' :
case '5' :
case '7':
/* based on Rect arg */
if (rect[0] > rect[2] || rect[1] > rect[3])
{
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
Scierror(999, _("%s: Impossible status min > max in x or y rect data.\n"), fname);
return -1;
}
if (rect[0] <= 0. && logFlags[1] == 'l') /* xmin */
{
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
Scierror(999, _("%s: Bounds on x axis must be strictly positive to use logarithmic mode.\n"), fname);
return -1;
}
if (rect[1] <= 0. && logFlags[2] == 'l') /* ymin */
{
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
Scierror(999, _("%s: Bounds on y axis must be strictly positive to use logarithmic mode.\n"), fname);
return -1;
}
break;
case '2' :
case '4' :
case '6' :
case '8':
case '9':
/* computed from the x/y min/max */
if ((int)strlen(logFlags) < 1)
{
dataflag = 'g';
}
else
{
dataflag = logFlags[0];
}
switch (dataflag)
{
case 'e' :
size_x = (m1 != 0) ? 2 : 0;
break;
case 'o' :
size_x = m1;
break;
case 'g' :
default :
size_x = (n1 * m1);
break;
}
if (size_x != 0)
{
if (logFlags[1] == 'l' && sciFindStPosMin((l1), size_x) <= 0.0)
{
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
Scierror(999, _("%s: At least one x data must be strictly positive to compute the bounds and use logarithmic mode.\n"), fname);
return -1;
}
}
size_y = (n1 * m1);
if (size_y != 0)
{
if (logFlags[2] == 'l' && sciFindStPosMin((l2), size_y) <= 0.0)
{
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
Scierror(999, _("%s: At least one y data must be strictly positive to compute the bounds and use logarithmic mode\n"), fname);
return -1;
}
}
break;
}
// open a figure if none already exists
getOrCreateDefaultSubwin();
Objplot2d (1, logFlags, (l1), (l2), &n1, &m1, style, strf, legend, rect, nax, flagNax);
// Allocated by sciGetStyle (get_style_arg function in GetCommandArg.c)
FREE(style);
if (freeStrf)
{
freeAllocatedSingleString(strf);
}
AssignOutputVariable(pvApiCtx, 1) = 0;
ReturnArguments(pvApiCtx);
return 0;
}
/*--------------------------------------------------------------------------*/
int sci_param3d1(char *fname, void *pvApiCtx)
{
SciErr sciErr;
int izcol = 0, isfac = 0;
double *zcol = NULL;
static double ebox_def [6] = { 0, 1, 0, 1, 0, 1};
double *ebox = ebox_def;
static int iflag_def[3] = {1, 2, 4};
int iflag[3] , *ifl = NULL;
double alpha_def = 35.0 , theta_def = 45.0;
double *alpha = &alpha_def, *theta = &theta_def;
int m1 = 0, n1 = 0, m2 = 0, n2 = 0, m3 = 0, n3 = 0;
int m3n = 0, n3n = 0, m3l = 0;
static rhs_opts opts[] =
{
{ -1, "alpha", -1, 0, 0, NULL},
{ -1, "ebox", -1, 0, 0, NULL},
{ -1, "flag", -1, 0, 0, NULL},
{ -1, "leg", -1, 0, 0, NULL},
{ -1, "theta", -1, 0, 0, NULL},
{ -1, NULL, -1, 0, 0, NULL}
};
char * labels = NULL;
int* piAddr1 = NULL;
int* piAddr2 = NULL;
int* piAddr3 = NULL;
int* piAddr31 = NULL;
int* piAddr32 = NULL;
double* l1 = NULL;
double* l2 = NULL;
double* l3 = NULL;
double* l3n = NULL;
if (nbInputArgument(pvApiCtx) <= 0)
{
sci_demo(fname, pvApiCtx);
return 0;
}
CheckInputArgument(pvApiCtx, 3, 8);
if (getOptionals(pvApiCtx, fname, opts) == 0)
{
ReturnArguments(pvApiCtx);
return 0;
}
if (FirstOpt(pvApiCtx) < 4)
{
Scierror(999, _("%s: Misplaced optional argument: #%d must be at position %d.\n"), fname, 1, 4);
return (0);
}
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 1, &piAddr1);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// Retrieve a matrix of double at position 1.
sciErr = getMatrixOfDouble(pvApiCtx, piAddr1, &m1, &n1, &l1); /* x */
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 1);
printError(&sciErr, 0);
return 1;
}
if (m1 == 1 && n1 > 1)
{
m1 = n1;
n1 = 1;
}
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 2, &piAddr2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// Retrieve a matrix of double at position 2.
sciErr = getMatrixOfDouble(pvApiCtx, piAddr2, &m2, &n2, &l2); /* y */
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 2);
printError(&sciErr, 0);
return 1;
}
if (m2 == 1 && n2 > 1)
{
m2 = n2;
n2 = 1;
}
if (m1 * n1 == 0)
{
AssignOutputVariable(pvApiCtx, 1) = 0;
ReturnArguments(pvApiCtx);
return 0;
}
//CheckSameDims
if (m1 != m2 || n1 != n2)
{
Scierror(999, _("%s: Wrong size for input argument #%d: %d-by-%d matrix expected.\n"), fname, 1, m1, n1);
return 1;
}
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 3, &piAddr3);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
switch (getInputArgumentType(pvApiCtx, 3))
{
case 1 :
izcol = 0;
// Retrieve a matrix of double at position 3.
// YOU MUST REMOVE YOUR VARIABLE DECLARATION "int l3".
sciErr = getMatrixOfDouble(pvApiCtx, piAddr3, &m3, &n3, &l3); /* z */
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
break;
case 15 :
izcol = 1;
/* z = list(z,colors) */
sciErr = getListItemNumber(pvApiCtx, piAddr3, &m3l);
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
if (m3l != 2)
{
Scierror(999, _("%s: Wrong size for input argument #%d: List of size %d expected.\n"),
fname, 2, m3l, 2);
return 0;
}
sciErr = getListItemAddress(pvApiCtx, piAddr3, 1, &piAddr31);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
sciErr = getMatrixOfDouble(pvApiCtx, piAddr31, &m3, &n3, &l3); /* z */
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
sciErr = getListItemAddress(pvApiCtx, piAddr3, 2, &piAddr32);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
sciErr = getMatrixOfDouble(pvApiCtx, piAddr32, &m3n, &n3n, &l3n); /* z */
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
zcol = (l3n);
if (m3n * n3n != n3)
{
Scierror(999, _("%s: Wrong size for input argument #%d: %d expected.\n"), fname, 3, n3);
return 0;
}
break;
default :
OverLoad(3);
return 0;
}
if (m3 == 1 && n3 > 1)
{
m3 = n3;
n3 = 1;
}
//CheckSameDims
if (m1 != m3 || n1 != n3)
{
Scierror(999, _("%s: Wrong size for input argument #%d: %d-by-%d matrix expected.\n"), fname, 1, m1, n1);
return 1;
}
GetOptionalDoubleArg(pvApiCtx, fname, 4, "theta", &theta, 1, opts);
GetOptionalDoubleArg(pvApiCtx, fname, 5, "alpha", &alpha, 1, opts);
GetLabels(pvApiCtx, fname, 6, opts, &labels);
iflag_def[1] = 8;
ifl = &(iflag_def[1]);
GetOptionalIntArg(pvApiCtx, fname, 7, "flag", &ifl, 2, opts);
iflag[0] = iflag_def[0];
iflag[1] = ifl[0];
iflag[2] = ifl[1];
GetOptionalDoubleArg(pvApiCtx, fname, 8, "ebox", &ebox, 6, opts);
if (m1 == 1 && n1 > 1)
{
m1 = n1;
n1 = 1;
}
getOrCreateDefaultSubwin();
/* NG beg */
isfac = -1;
Objplot3d (fname, &isfac, &izcol, (l1), (l2), (l3), zcol, &m1, &n1, theta, alpha, labels, iflag, ebox, &m1, &n1, &m2, &n2, &m3, &n3, &m3n, &n3n); /*Adding F.Leray 12.03.04*/
AssignOutputVariable(pvApiCtx, 1) = 0;
ReturnArguments(pvApiCtx);
return 0;
}
/*------------------------------------------------------------------------*/
int sci_param3d(char * fname, void *pvApiCtx)
{
SciErr sciErr;
int izcol = 0, isfac = 0;
static double ebox_def[6] = { 0, 1, 0, 1, 0, 1};
double *ebox = ebox_def;
static int iflag_def[3] = {1, 2, 4};
int iflag[3], *ifl = NULL, ix1 = 0, one = 1;
double alpha_def = 35.0 , theta_def = 45.0;
double *alpha = &alpha_def, *theta = &theta_def;
int m1 = 0, n1 = 0, m2 = 0, n2 = 0, m3 = 0, n3 = 0;
int m3n = 0, n3n = 0; /* F.Leray 19.03.04*/
static rhs_opts opts[] =
{
{ -1, "alpha", -1, 0, 0, NULL},
{ -1, "ebox", -1, 0, 0, NULL},
{ -1, "flag", -1, 0, 0, NULL},
{ -1, "leg", -1, 0, 0, NULL},
{ -1, "theta", -1, 0, 0, NULL},
{ -1, NULL, -1, 0, 0, NULL}
};
char * labels = NULL;
int* piAddr1 = NULL;
int* piAddr2 = NULL;
int* piAddr3 = NULL;
double* l1 = NULL;
double* l2 = NULL;
double* l3 = NULL;
if (nbInputArgument(pvApiCtx) <= 0)
{
sci_demo(fname, pvApiCtx);
return 0;
}
CheckInputArgument(pvApiCtx, 3, 8);
if (getOptionals(pvApiCtx, fname, opts) == 0)
{
ReturnArguments(pvApiCtx);
return 0;
}
if (FirstOpt(pvApiCtx) < 4)
{
Scierror(999, _("%s: Misplaced optional argument: #%d must be at position %d.\n"), fname, 1, 4);
return(0);
}
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 1, &piAddr1);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// Retrieve a matrix of double at position 1.
sciErr = getMatrixOfDouble(pvApiCtx, piAddr1, &m1, &n1, &l1);
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 1);
printError(&sciErr, 0);
return 1;
}
if (m1 * n1 == 0)
{
AssignOutputVariable(pvApiCtx, 1) = 0;
ReturnArguments(pvApiCtx);
return 0;
}
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 2, &piAddr2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// Retrieve a matrix of double at position 2.
sciErr = getMatrixOfDouble(pvApiCtx, piAddr2, &m2, &n2, &l2);
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 2);
printError(&sciErr, 0);
return 1;
}
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 3, &piAddr3);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// Retrieve a matrix of double at position 3.
sciErr = getMatrixOfDouble(pvApiCtx, piAddr3, &m3, &n3, &l3);
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument #%d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
//CheckSameDims
if (m1 != m2 || n1 != n2)
{
Scierror(999, _("%s: Wrong size for input argument #%d: %d-by-%d matrix expected.\n"), fname, 1, m1, n1);
return 1;
}
//CheckSameDims
if (m2 != m3 || n2 != n3)
{
Scierror(999, _("%s: Wrong size for input argument #%d: %d-by-%d matrix expected.\n"), fname, 2, m2, n2);
return 1;
}
GetOptionalDoubleArg(pvApiCtx, fname, 4, "theta", &theta, 1, opts);
GetOptionalDoubleArg(pvApiCtx, fname, 5, "alpha", &alpha, 1, opts);
GetLabels(pvApiCtx, fname, 6, opts, &labels);
iflag_def[1] = 8;
ifl = &(iflag_def[1]);
GetOptionalIntArg(pvApiCtx, fname, 7, "flag", &ifl, 2, opts);
iflag[0] = iflag_def[0];
iflag[1] = ifl[0];
iflag[2] = ifl[1];
GetOptionalDoubleArg(pvApiCtx, fname, 8, "ebox", &ebox, 6, opts);
getOrCreateDefaultSubwin();
ix1 = m1 * n1;
/* NG beg */
isfac = -1;
izcol = 0;
Objplot3d (fname, &isfac, &izcol, (l1), (l2), (l3), (double *) NULL, &ix1, &one, theta, alpha, labels, iflag, ebox, &m1, &n1, &m2, &n2, &m3, &n3, &m3n, &n3n); /*Adding F.Leray 12.03.04 */
/* NG end */
AssignOutputVariable(pvApiCtx, 1) = 0;
ReturnArguments(pvApiCtx);
return 0;
}
/*--------------------------------------------------------------------------*/
int sci_plot3d(char * fname, unsigned long fname_len)
{
SciErr sciErr;
static double ebox_def [6] = { 0, 1, 0, 1, 0, 1};
double *ebox = ebox_def;
static int iflag_def[3] = {2, 2, 4};
int *iflag = iflag_def;
double alpha_def = 35.0 , theta_def = 45.0;
double *alpha = &alpha_def, *theta = &theta_def;
int m1 = 0, n1 = 0, m2 = 0, n2 = 0, m3 = 0, n3 = 0;
int m3n = 0, n3n = 0, m3l = 0;
int izcol = 0, isfac = 0;
double *zcol = NULL;
static rhs_opts opts[] =
{
{ -1, "alpha", -1, 0, 0, NULL},
{ -1, "ebox", -1, 0, 0, NULL},
{ -1, "flag", -1, 0, 0, NULL},
{ -1, "leg", -1, 0, 0, NULL},
{ -1, "theta", -1, 0, 0, NULL},
{ -1, NULL, -1, 0, 0, NULL}
};
char * legend = NULL;
int* piAddr1 = NULL;
int* piAddr2 = NULL;
int* piAddr3 = NULL;
int* piAddr31 = NULL;
int* piAddr32 = NULL;
double* l1 = NULL;
double* l2 = NULL;
double* l3 = NULL;
double* l3n = NULL;
/*
** This overload the function to call demo script
** the demo script is called %_<fname>
*/
if (nbInputArgument(pvApiCtx) <= 0)
{
sci_demo(fname, fname_len);
return 0;
}
CheckInputArgument(pvApiCtx, 3, 8);
if (getOptionals(pvApiCtx, fname, opts) == 0)
{
ReturnArguments(pvApiCtx);
return 0;
}
if (FirstOpt() < 4)
{
Scierror(999, _("%s: Misplaced optional argument: #%d must be at position %d.\n"), fname, 1, 4);
return -1;
}
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 1, &piAddr1);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// Retrieve a matrix of double at position 1.
sciErr = getMatrixOfDouble(pvApiCtx, piAddr1, &m1, &n1, &l1);
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument %d: A real expected.\n"), fname, 1);
printError(&sciErr, 0);
return 1;
}
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 2, &piAddr2);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// Retrieve a matrix of double at position 2.
sciErr = getMatrixOfDouble(pvApiCtx, piAddr2, &m2, &n2, &l2);
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument %d: A real expected.\n"), fname, 2);
printError(&sciErr, 0);
return 1;
}
if (m1 * n1 == 0)
{
AssignOutputVariable(pvApiCtx, 1) = 0;
ReturnArguments(pvApiCtx);
return 0;
}
if (nbInputArgument(pvApiCtx) >= 3)
{
/* third argument can be a matrix z or a list list(z,zcol) */
sciErr = getVarAddressFromPosition(pvApiCtx, 3, &piAddr3);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
switch (getInputArgumentType(pvApiCtx, 3))
{
case sci_matrix :
//get variable address
sciErr = getVarAddressFromPosition(pvApiCtx, 3, &piAddr3);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
// Retrieve a matrix of double at position 3.
sciErr = getMatrixOfDouble(pvApiCtx, piAddr3, &m3, &n3, &l3);
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument %d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
izcol = 0;
break;
case sci_list :
izcol = 1;
/* z = list(z,colors) */
sciErr = getListItemNumber(pvApiCtx, piAddr3, &m3l);
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument %d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
if (m3l != 2)
{
Scierror(999, _("%s: Wrong size for input argument #%d: List of size %d expected.\n"),
fname, 2, m3l, 2);
return 1;
}
sciErr = getListItemAddress(pvApiCtx, piAddr3, 1, &piAddr31);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
sciErr = getMatrixOfDouble(pvApiCtx, piAddr31, &m3, &n3, &l3); /* z */
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument %d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
sciErr = getListItemAddress(pvApiCtx, piAddr3, 2, &piAddr32);
if (sciErr.iErr)
{
printError(&sciErr, 0);
return 1;
}
sciErr = getMatrixOfDouble(pvApiCtx, piAddr32, &m3n, &n3n, &l3n); /* z */
if (sciErr.iErr)
{
Scierror(202, _("%s: Wrong type for argument %d: A real expected.\n"), fname, 3);
printError(&sciErr, 0);
return 1;
}
zcol = (l3n);
if (m3n * n3n != n3 && m3n * n3n != m3 * n3)
{
Scierror(999, _("%s: Wrong size for input argument #%d: %d or %d expected.\n"), fname, 3, n3, m3 * n3);
return 1;
}
/*
* Added by E Segre 4/5/2000. In the case where zcol is a
* matrix of the same size as z, we set izcol to 2. This
* value is later transmitted to the C2F(fac3dg) routine,
* which has been modified to do the interpolated shading
* (see the file SCI/modules/graphics/src/c/Plo3d.c
*/
if (m3n * n3n == m3 * n3)
{
izcol = 2 ;
}
break;
default :
OverLoad(3);
return 0;
}
}
iflag_def[1] = 8;
GetOptionalDoubleArg(pvApiCtx, fname, 4, "theta", &theta, 1, opts);
GetOptionalDoubleArg(pvApiCtx, fname, 5, "alpha", &alpha, 1, opts);
GetLabels(pvApiCtx, fname, 6, opts, &legend);
GetOptionalIntArg(pvApiCtx, fname, 7, "flag", &iflag, 3, opts);
GetOptionalDoubleArg(pvApiCtx, fname, 8, "ebox", &ebox, 6, opts);
if (m1 * n1 == m3 * n3 && m1 * n1 == m2 * n2 && m1 * n1 != 1)
{
if (! (m1 == m2 && m2 == m3 && n1 == n2 && n2 == n3))
{
Scierror(999, _("%s: Wrong value for input arguments #%d, #%d and #%d: Incompatible length.\n"), fname, 1, 2, 3);
return 1;
}
}
else
{
if (m2 * n2 != n3)
{
Scierror(999, _("%s: Wrong value for input arguments #%d and #%d: Incompatible length.\n"), fname, 2, 3);
return 1;
}
if (m1 * n1 != m3)
{
Scierror(999, _("%s: Wrong value for input arguments #%d and #%d: Incompatible length.\n"), fname, 1, 3);
return 1;
}
if (m1 * n1 <= 1 || m2 * n2 <= 1)
{
Scierror(999, _("%s: Wrong size for input arguments #%d and #%d: %s expected.\n"), fname, 2, 3, ">= 2");
return 1;
}
}
if (m1 * n1 == 0 || m2 * n2 == 0 || m3 * n3 == 0)
{
AssignOutputVariable(pvApiCtx, 1) = 0;
ReturnArguments(pvApiCtx);
return 0;
}
getOrCreateDefaultSubwin();
/******************** 24/05/2002 ********************/
if (m1 * n1 == m3 * n3 && m1 * n1 == m2 * n2 && m1 * n1 != 1) /* NG beg */
{
isfac = 1;
}
else
{
isfac = 0;
}
Objplot3d (fname, &isfac, &izcol, (l1), (l2), (l3), zcol, &m3, &n3, theta, alpha, legend, iflag, ebox, &m1, &n1, &m2, &n2, &m3, &n3, &m3n, &n3n); /*Adding F.Leray 12.03.04 and 19.03.04*/
AssignOutputVariable(pvApiCtx, 1) = 0;
ReturnArguments(pvApiCtx);
return 0;
}
/*------------------------------------------------------------------------*/
int sci_plot2d( char * fname, unsigned long fname_len )
{
int m1 = 0, n1 = 0, l1 = 0, m2 = 0, n2 = 0, l2 = 0, lt = 0;
int test = 0, i = 0, j = 0, iskip = 0;
int frame_def = 8;
int *frame = &frame_def;
int axes_def = 1;
int *axes = &axes_def;
/* F.Leray 18.05.04 : log. case test*/
int size_x = 0, size_y = 0;
double xd[2];
char dataflag = 0;
char * logFlags = NULL ;
int * style = NULL ;
double * rect = NULL ;
char * strf = NULL ;
char * legend = NULL ;
int * nax = NULL ;
BOOL flagNax = FALSE ;
char strfl[4];
static rhs_opts opts[] = { { -1, "axesflag", "?", 0, 0, 0},
{ -1, "frameflag", "?", 0, 0, 0},
{ -1, "leg", "?", 0, 0, 0},
{ -1, "logflag", "?", 0, 0, 0},
{ -1, "nax", "?", 0, 0, 0},
{ -1, "rect", "?", 0, 0, 0},
{ -1, "strf", "?", 0, 0, 0},
{ -1, "style", "?", 0, 0, 0},
{ -1, NULL, NULL, 0, 0, 0}
};
if (Rhs == 0)
{
sci_demo(fname, fname_len);
return 0;
}
CheckRhs(1, 9);
iskip = 0;
if ( get_optionals(fname, opts) == 0)
{
PutLhsVar();
return 0 ;
}
if (GetType(1) == sci_strings)
{
/* logflags */
GetLogflags( fname, 1, opts, &logFlags ) ;
iskip = 1;
}
if (FirstOpt() == 2 + iskip) /** plot2d([loglags,] y, <opt_args>); **/
{
GetRhsVar(1 + iskip, MATRIX_OF_DOUBLE_DATATYPE, &m2, &n2, &l2);
if (m2 == 1 && n2 > 1)
{
m2 = n2;
n2 = 1;
}
m1 = m2;
n1 = n2;
CreateVar(Rhs + 1, MATRIX_OF_DOUBLE_DATATYPE, &m1, &n1, &l1);
for (i = 0; i < m2 ; ++i)
{
for (j = 0 ; j < n2 ; ++j)
{
*stk( l1 + i + m2 * j) = (double) i + 1;
}
}
}
else if (FirstOpt() >= 3 + iskip) /** plot2d([loglags,] x, y[, style [,...]]); **/
{
/* x */
GetRhsVar(1 + iskip, MATRIX_OF_DOUBLE_DATATYPE, &m1, &n1, &l1);
/* y */
GetRhsVar(2 + iskip, MATRIX_OF_DOUBLE_DATATYPE, &m2, &n2, &l2);
test = (m1 * n1 == 0) ||
((m1 == 1 || n1 == 1) && (m2 == 1 || n2 == 1) && (m1 * n1 == m2 * n2)) ||
((m1 == m2) && (n1 == n2)) ||
((m1 == 1 && n1 == m2) || (n1 == 1 && m1 == m2));
CheckDimProp(1 + iskip, 2 + iskip, !test);
if (m1 * n1 == 0)
{
/* default x=1:n */
CreateVar(Rhs + 1, MATRIX_OF_DOUBLE_DATATYPE, &m2, &n2, <);
if (m2 == 1 && n2 > 1)
{
m2 = n2;
n2 = 1;
}
for (i = 0; i < m2 ; ++i)
{
for (j = 0 ; j < n2 ; ++j)
{
*stk( lt + i + m2 * j) = (double) i + 1;
}
}
m1 = m2;
n1 = n2;
l1 = lt;
}
else if ((m1 == 1 || n1 == 1) && (m2 != 1 && n2 != 1) )
{
/* a single x vector for mutiple columns for y */
CreateVar(Rhs + 1, MATRIX_OF_DOUBLE_DATATYPE, &m2, &n2, <);
for (i = 0; i < m2 ; ++i)
{
for (j = 0 ; j < n2 ; ++j)
{
*stk( lt + i + m2 * j) = *stk(l1 + i);
}
}
m1 = m2;
n1 = n2;
l1 = lt;
}
else if ((m1 == 1 && n1 == 1) && (n2 != 1) )
{
/* a single y row vector for a single x */
CreateVar(Rhs + 1, MATRIX_OF_DOUBLE_DATATYPE, &m1, &n2, <);
for (j = 0 ; j < n2 ; ++j)
{
*stk( lt + j ) = *stk(l1);
}
n1 = n2;
l1 = lt;
}
else
{
if (m2 == 1 && n2 > 1)
{
m2 = n2;
n2 = 1;
}
if (m1 == 1 && n1 > 1)
{
m1 = n1;
n1 = 1;
}
}
}
else
{
Scierror(999, _("%s: Wrong number of mandatory input arguments. At least %d expected.\n"), fname, 1);
return 0;
}
if (n1 == -1 || n2 == -1 || m1 == -1 || m2 == -1)
{
Scierror(999, _("%s: Wrong size for input arguments #%d and #%d.\n"), fname, 1, 2); /* @TODO : detail error */
return 0;
}
sciGetStyle( fname, 3 + iskip, n1, opts, &style ) ;
GetStrf( fname, 4 + iskip, opts, &strf ) ;
GetLegend( fname, 5 + iskip, opts, &legend );
GetRect( fname, 6 + iskip, opts, &rect );
GetNax( 7 + iskip, opts, &nax, &flagNax ) ;
if (iskip == 0)
{
GetLogflags( fname, 8, opts, &logFlags ) ;
}
if ( isDefStrf( strf ) )
{
strcpy(strfl, DEFSTRFN);
strf = strfl;
if ( !isDefRect( rect ) )
{
strfl[1] = '7';
}
if ( !isDefLegend( legend ) )
{
strfl[0] = '1';
}
GetOptionalIntArg(fname, 9, "frameflag", &frame, 1, opts);
if ( frame != &frame_def )
{
strfl[1] = (char)(*frame + 48);
}
GetOptionalIntArg(fname, 9, "axesflag", &axes, 1, opts);
if (axes != &axes_def)
{
strfl[2] = (char)(*axes + 48);
}
}
/* Make a test on log. mode : available or not depending on the bounds set by Rect arg. or xmin/xmax :
Rect case :
- if the min bound is strictly posivite, we can use log. mode
- if not, send error message
x/y min/max case:
- we find the first strictly positive min bound in Plo2dn.c ?? */
switch (strf[1])
{
case '0':
/* no computation, the plot use the previous (or default) scale */
break;
case '1' :
case '3' :
case '5' :
case '7':
/* based on Rect arg */
if ( rect[0] > rect[2] || rect[1] > rect[3])
{
Scierror(999, _("%s: Impossible status min > max in x or y rect data.\n"), fname);
return -1;
}
if ( rect[0] <= 0. && logFlags[1] == 'l') /* xmin */
{
Scierror(999, _("%s: Bounds on x axis must be strictly positive to use logarithmic mode.\n"), fname);
return -1 ;
}
if ( rect[1] <= 0. && logFlags[2] == 'l') /* ymin */
{
Scierror(999, _("%s: Bounds on y axis must be strictly positive to use logarithmic mode.\n"), fname);
return -1 ;
}
break;
case '2' :
case '4' :
case '6' :
case '8':
case '9':
/* computed from the x/y min/max */
if ( (int)strlen(logFlags) < 1)
{
dataflag = 'g' ;
}
else
{
dataflag = logFlags[0];
}
switch ( dataflag )
{
case 'e' :
xd[0] = 1.0;
xd[1] = (double)m1;
size_x = (m1 != 0) ? 2 : 0 ;
break;
case 'o' :
size_x = m1;
break;
case 'g' :
default :
size_x = (n1 * m1) ;
break;
}
if (size_x != 0)
{
if (logFlags[1] == 'l' && sciFindStPosMin(stk(l1), size_x) <= 0.0 )
{
Scierror(999, _("%s: At least one x data must be strictly positive to compute the bounds and use logarithmic mode.\n"), fname);
return -1 ;
}
}
size_y = (n1 * m1) ;
if (size_y != 0)
{
if ( logFlags[2] == 'l' && sciFindStPosMin(stk(l2), size_y) <= 0.0 )
{
Scierror(999, _("%s: At least one y data must be strictly positive to compute the bounds and use logarithmic mode\n"), fname);
return -1 ;
}
}
break;
}
// open a figure if none already exists
getOrCreateDefaultSubwin();
Objplot2d (1, logFlags, stk(l1), stk(l2), &n1, &m1, style, strf, legend, rect, nax, flagNax);
LhsVar(1) = 0;
PutLhsVar();
return 0;
}
