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cfortran.h
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cfortran.h
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/* cfortran.h 4.3 */
/* http://www-zeus.desy.de/~burow/cfortran/ */
/* Burkhard Burow [email protected] 1990 - 2001. */
#ifndef __CFORTRAN_LOADED
#define __CFORTRAN_LOADED
/*
THIS FILE IS PROPERTY OF BURKHARD BUROW. IF YOU ARE USING THIS FILE YOU
SHOULD ALSO HAVE ACCESS TO CFORTRAN.DOC WHICH PROVIDES TERMS FOR USING,
MODIFYING, COPYING AND DISTRIBUTING THE CFORTRAN.H PACKAGE.
*/
/*
Avoid symbols already used by compilers and system *.h:
__ - OSF1 zukal06 V3.0 347 alpha, cc -c -std1 cfortest.c
*/
/* First prepare for the C compiler. */
#ifndef ANSI_C_preprocessor /* i.e. user can override. */
#ifdef __CF__KnR
#define ANSI_C_preprocessor 0
#else
#ifdef __STDC__
#define ANSI_C_preprocessor 1
#else
#define _cfleft 1
#define _cfright
#define _cfleft_cfright 0
#define ANSI_C_preprocessor _cfleft/**/_cfright
#endif
#endif
#endif
#if ANSI_C_preprocessor
#define _0(A,B) A##B
#define _(A,B) _0(A,B) /* see cat,xcat of K&R ANSI C p. 231 */
#define _2(A,B) A##B /* K&R ANSI C p.230: .. identifier is not replaced */
#define _3(A,B,C) _(A,_(B,C))
#else /* if it turns up again during rescanning. */
#define _(A,B) A/**/B
#define _2(A,B) A/**/B
#define _3(A,B,C) A/**/B/**/C
#endif
#if (defined(vax)&&defined(unix)) || (defined(__vax__)&&defined(__unix__))
#define VAXUltrix
#endif
#include <stdio.h> /* NULL [in all machines stdio.h] */
#include <string.h> /* strlen, memset, memcpy, memchr. */
#if !( defined(VAXUltrix) || defined(sun) || (defined(apollo)&&!defined(__STDCPP__)) )
#include <stdlib.h> /* malloc,free */
#else
#include <malloc.h> /* Had to be removed for DomainOS h105 10.4 sys5.3 425t*/
#ifdef apollo
#define __CF__APOLLO67 /* __STDCPP__ is in Apollo 6.8 (i.e. ANSI) and onwards */
#endif
#endif
#if !defined(__GNUC__) && !defined(__sun) && (defined(sun)||defined(VAXUltrix)||defined(lynx))
#define __CF__KnR /* Sun, LynxOS and VAX Ultrix cc only supports K&R. */
/* Manually define __CF__KnR for HP if desired/required.*/
#endif /* i.e. We will generate Kernighan and Ritchie C. */
/* Note that you may define __CF__KnR before #include cfortran.h, in order to
generate K&R C instead of the default ANSI C. The differences are mainly in the
function prototypes and declarations. All machines, except the Apollo, work
with either style. The Apollo's argument promotion rules require ANSI or use of
the obsolete std_$call which we have not implemented here. Hence on the Apollo,
only C calling FORTRAN subroutines will work using K&R style.*/
/* Remainder of cfortran.h depends on the Fortran compiler. */
#if defined(CLIPPERFortran) || defined(pgiFortran)
#define f2cFortran
#endif
/* VAX/VMS does not let us \-split long #if lines. */
/* Split #if into 2 because some HP-UX can't handle long #if */
#if !(defined(NAGf90Fortran)||defined(f2cFortran)||defined(hpuxFortran)||defined(apolloFortran)||defined(sunFortran)||defined(IBMR2Fortran)||defined(CRAYFortran))
#if !(defined(mipsFortran)||defined(DECFortran)||defined(vmsFortran)||defined(CONVEXFortran)||defined(PowerStationFortran)||defined(AbsoftUNIXFortran)||defined(AbsoftProFortran)||defined(SXFortran))
/* If no Fortran compiler is given, we choose one for the machines we know. */
#if defined(lynx) || defined(VAXUltrix)
#define f2cFortran /* Lynx: Only support f2c at the moment.
VAXUltrix: f77 behaves like f2c.
Support f2c or f77 with gcc, vcc with f2c.
f77 with vcc works, missing link magic for f77 I/O.*/
#endif
#if defined(__hpux) /* 921107: Use __hpux instead of __hp9000s300 */
#define hpuxFortran /* Should also allow hp9000s7/800 use.*/
#endif
#if defined(apollo)
#define apolloFortran /* __CF__APOLLO67 also defines some behavior. */
#endif
#if defined(sun) || defined(__sun)
#define sunFortran
#endif
#if defined(_IBMR2)
#define IBMR2Fortran
#endif
#if defined(_CRAY)
#define CRAYFortran /* _CRAYT3E also defines some behavior. */
#endif
#if defined(_SX)
#define SXFortran
#endif
#if defined(mips) || defined(__mips)
#define mipsFortran
#endif
#if defined(vms) || defined(__vms)
#define vmsFortran
#endif
#if defined(__alpha) && defined(__unix__)
#define DECFortran
#endif
#if defined(__convex__)
#define CONVEXFortran
#endif
#if defined(VISUAL_CPLUSPLUS)
#define PowerStationFortran
#endif
#endif /* ...Fortran */
#endif /* ...Fortran */
/* Split #if into 2 because some HP-UX can't handle long #if */
#if !(defined(NAGf90Fortran)||defined(f2cFortran)||defined(hpuxFortran)||defined(apolloFortran)||defined(sunFortran)||defined(IBMR2Fortran)||defined(CRAYFortran))
#if !(defined(mipsFortran)||defined(DECFortran)||defined(vmsFortran)||defined(CONVEXFortran)||defined(PowerStationFortran)||defined(AbsoftUNIXFortran)||defined(AbsoftProFortran)||defined(SXFortran))
/* If your compiler barfs on ' #error', replace # with the trigraph for # */
#error "cfortran.h: Can't find your environment among:\
- MIPS cc and f77 2.0. (e.g. Silicon Graphics, DECstations, ...) \
- IBM AIX XL C and FORTRAN Compiler/6000 Version 01.01.0000.0000 \
- VAX VMS CC 3.1 and FORTRAN 5.4. \
- Alpha VMS DEC C 1.3 and DEC FORTRAN 6.0. \
- Alpha OSF DEC C and DEC Fortran for OSF/1 AXP Version 1.2 \
- Apollo DomainOS 10.2 (sys5.3) with f77 10.7 and cc 6.7. \
- CRAY \
- NEC SX-4 SUPER-UX \
- CONVEX \
- Sun \
- PowerStation Fortran with Visual C++ \
- HP9000s300/s700/s800 Latest test with: HP-UX A.08.07 A 9000/730 \
- LynxOS: cc or gcc with f2c. \
- VAXUltrix: vcc,cc or gcc with f2c. gcc or cc with f77. \
- f77 with vcc works; but missing link magic for f77 I/O. \
- NO fort. None of gcc, cc or vcc generate required names.\
- f2c : Use #define f2cFortran, or cc -Df2cFortran \
- NAG f90: Use #define NAGf90Fortran, or cc -DNAGf90Fortran \
- Absoft UNIX F77: Use #define AbsoftUNIXFortran or cc -DAbsoftUNIXFortran \
- Absoft Pro Fortran: Use #define AbsoftProFortran \
- Portland Group Fortran: Use #define pgiFortran"
/* Compiler must throw us out at this point! */
#endif
#endif
#if defined(VAXC) && !defined(__VAXC)
#define OLD_VAXC
#pragma nostandard /* Prevent %CC-I-PARAMNOTUSED. */
#endif
/* Throughout cfortran.h we use: UN = Uppercase Name. LN = Lowercase Name. */
#if defined(f2cFortran) || defined(NAGf90Fortran) || defined(DECFortran) || defined(mipsFortran) || defined(apolloFortran) || defined(sunFortran) || defined(CONVEXFortran) || defined(SXFortran) || defined(extname)
#define CFC_(UN,LN) _(LN,_) /* Lowercase FORTRAN symbols. */
#define orig_fcallsc(UN,LN) CFC_(UN,LN)
#else
#if defined(CRAYFortran) || defined(PowerStationFortran) || defined(AbsoftProFortran)
#ifdef _CRAY /* (UN), not UN, circumvents CRAY preprocessor bug. */
#define CFC_(UN,LN) (UN) /* Uppercase FORTRAN symbols. */
#else /* At least VISUAL_CPLUSPLUS barfs on (UN), so need UN. */
#define CFC_(UN,LN) UN /* Uppercase FORTRAN symbols. */
#endif
#define orig_fcallsc(UN,LN) CFC_(UN,LN) /* CRAY insists on arg.'s here. */
#else /* For following machines one may wish to change the fcallsc default. */
#define CF_SAME_NAMESPACE
#ifdef vmsFortran
#define CFC_(UN,LN) LN /* Either case FORTRAN symbols. */
/* BUT we usually use UN for C macro to FORTRAN routines, so use LN here,*/
/* because VAX/VMS doesn't do recursive macros. */
#define orig_fcallsc(UN,LN) UN
#else /* HP-UX without +ppu or IBMR2 without -qextname. NOT reccomended. */
#define CFC_(UN,LN) LN /* Lowercase FORTRAN symbols. */
#define orig_fcallsc(UN,LN) CFC_(UN,LN)
#endif /* vmsFortran */
#endif /* CRAYFortran PowerStationFortran */
#endif /* ....Fortran */
#define fcallsc(UN,LN) orig_fcallsc(UN,LN)
#define preface_fcallsc(P,p,UN,LN) CFC_(_(P,UN),_(p,LN))
#define append_fcallsc(P,p,UN,LN) CFC_(_(UN,P),_(LN,p))
#define C_FUNCTION(UN,LN) fcallsc(UN,LN)
#define FORTRAN_FUNCTION(UN,LN) CFC_(UN,LN)
#ifndef COMMON_BLOCK
#ifndef CONVEXFortran
#ifndef CLIPPERFortran
#if !(defined(AbsoftUNIXFortran)||defined(AbsoftProFortran))
#define COMMON_BLOCK(UN,LN) CFC_(UN,LN)
#else
#define COMMON_BLOCK(UN,LN) _(_C,LN)
#endif /* AbsoftUNIXFortran or AbsoftProFortran */
#else
#define COMMON_BLOCK(UN,LN) _(LN,__)
#endif /* CLIPPERFortran */
#else
#define COMMON_BLOCK(UN,LN) _3(_,LN,_)
#endif /* CONVEXFortran */
#endif /* COMMON_BLOCK */
#ifndef DOUBLE_PRECISION
#if defined(CRAYFortran) && !defined(_CRAYT3E)
#define DOUBLE_PRECISION long double
#else
#define DOUBLE_PRECISION double
#endif
#endif
#ifndef FORTRAN_REAL
#if defined(CRAYFortran) && defined(_CRAYT3E)
#define FORTRAN_REAL double
#else
#define FORTRAN_REAL float
#endif
#endif
#ifdef CRAYFortran
#ifdef _CRAY
#include <fortran.h>
#else
#include "fortran.h" /* i.e. if crosscompiling assume user has file. */
#endif
#define FLOATVVVVVVV_cfPP (FORTRAN_REAL *) /* Used for C calls FORTRAN. */
/* CRAY's double==float but CRAY says pointers to doubles and floats are diff.*/
#define VOIDP (void *) /* When FORTRAN calls C, we don't know if C routine
arg.'s have been declared float *, or double *. */
#else
#define FLOATVVVVVVV_cfPP
#define VOIDP
#endif
#ifdef vmsFortran
#if defined(vms) || defined(__vms)
#include <descrip.h>
#else
#include "descrip.h" /* i.e. if crosscompiling assume user has file. */
#endif
#endif
#ifdef sunFortran
#if defined(sun) || defined(__sun)
#include <math.h> /* Sun's FLOATFUNCTIONTYPE, ASSIGNFLOAT, RETURNFLOAT. */
#else
#include "math.h" /* i.e. if crosscompiling assume user has file. */
#endif
/* At least starting with the default C compiler SC3.0.1 of SunOS 5.3,
* FLOATFUNCTIONTYPE, ASSIGNFLOAT, RETURNFLOAT are not required and not in
* <math.h>, since sun C no longer promotes C float return values to doubles.
* Therefore, only use them if defined.
* Even if gcc is being used, assume that it exhibits the Sun C compiler
* behavior in order to be able to use *.o from the Sun C compiler.
* i.e. If FLOATFUNCTIONTYPE, etc. are in math.h, they required by gcc.
*/
#endif
#ifndef apolloFortran
#define COMMON_BLOCK_DEF(DEFINITION, NAME) extern DEFINITION NAME
#define CF_NULL_PROTO
#else /* HP doesn't understand #elif. */
/* Without ANSI prototyping, Apollo promotes float functions to double. */
/* Note that VAX/VMS, IBM, Mips choke on 'type function(...);' prototypes. */
#define CF_NULL_PROTO ...
#ifndef __CF__APOLLO67
#define COMMON_BLOCK_DEF(DEFINITION, NAME) \
DEFINITION NAME __attribute((__section(NAME)))
#else
#define COMMON_BLOCK_DEF(DEFINITION, NAME) \
DEFINITION NAME #attribute[section(NAME)]
#endif
#endif
#ifdef __cplusplus
#undef CF_NULL_PROTO
#define CF_NULL_PROTO ...
#endif
#ifndef USE_NEW_DELETE
#ifdef __cplusplus
#define USE_NEW_DELETE 1
#else
#define USE_NEW_DELETE 0
#endif
#endif
#if USE_NEW_DELETE
#define _cf_malloc(N) new char[N]
#define _cf_free(P) delete[] P
#else
#define _cf_malloc(N) (char *)malloc(N)
#define _cf_free(P) free(P)
#endif
#ifdef mipsFortran
#define CF_DECLARE_GETARG int f77argc; char **f77argv
#define CF_SET_GETARG(ARGC,ARGV) f77argc = ARGC; f77argv = ARGV
#else
#define CF_DECLARE_GETARG
#define CF_SET_GETARG(ARGC,ARGV)
#endif
#ifdef OLD_VAXC /* Allow %CC-I-PARAMNOTUSED. */
#pragma standard
#endif
#define AcfCOMMA ,
#define AcfCOLON ;
/*-------------------------------------------------------------------------*/
/* UTILITIES USED WITHIN CFORTRAN.H */
#define _cfMIN(A,B) (A<B?A:B)
/* 970211 - XIX.145:
firstindexlength - better name is all_but_last_index_lengths
secondindexlength - better name is last_index_length
*/
#define firstindexlength(A) (sizeof(A[0])==1 ? 1 : (sizeof(A) / sizeof(A[0])) )
#define secondindexlength(A) (sizeof(A[0])==1 ? sizeof(A) : sizeof(A[0]) )
/* Behavior of FORTRAN LOGICAL. All machines' LOGICAL is same size as C's int.
Conversion is automatic except for arrays which require F2CLOGICALV/C2FLOGICALV.
f2c, MIPS f77 [DECstation, SGI], VAX Ultrix f77,
HP-UX f77 : as in C.
VAX/VMS FORTRAN, VAX Ultrix fort,
Absoft Unix Fortran, IBM RS/6000 xlf : LS Bit = 0/1 = TRUE/FALSE.
Apollo : neg. = TRUE, else FALSE.
[Apollo accepts -1 as TRUE for function values, but NOT all other neg. values.]
[DECFortran for Ultrix RISC is also called f77 but is the same as VAX/VMS.]
[MIPS f77 treats .eqv./.neqv. as .eq./.ne. and hence requires LOGICAL_STRICT.]*/
#if defined(NAGf90Fortran) || defined(f2cFortran) || defined(mipsFortran) || defined(PowerStationFortran) || defined(hpuxFortran800) || defined(AbsoftUNIXFortran) || defined(AbsoftProFortran) || defined(SXFortran)
/* SX/PowerStationFortran have 0 and 1 defined, others are neither T nor F. */
/* hpuxFortran800 has 0 and 0x01000000 defined. Others are unknown. */
#define LOGICAL_STRICT /* Other Fortran have .eqv./.neqv. == .eq./.ne. */
#endif
#define C2FLOGICALV(A,I) \
do {int __i; for(__i=0;__i<I;__i++) A[__i]=C2FLOGICAL(A[__i]); } while (0)
#define F2CLOGICALV(A,I) \
do {int __i; for(__i=0;__i<I;__i++) A[__i]=F2CLOGICAL(A[__i]); } while (0)
#if defined(apolloFortran)
#define C2FLOGICAL(L) ((L)?-1:(L)&~((unsigned)1<<sizeof(int)*8-1))
#define F2CLOGICAL(L) ((L)<0?(L):0)
#else
#if defined(CRAYFortran)
#define C2FLOGICAL(L) _btol(L)
#define F2CLOGICAL(L) _ltob(&(L)) /* Strangely _ltob() expects a pointer. */
#else
#if defined(IBMR2Fortran) || defined(vmsFortran) || defined(DECFortran) || defined(AbsoftUNIXFortran)
/* How come no AbsoftProFortran ? */
#define C2FLOGICAL(L) ((L)?(L)|1:(L)&~(int)1)
#define F2CLOGICAL(L) ((L)&1?(L):0)
#else
#if defined(CONVEXFortran)
#define C2FLOGICAL(L) ((L) ? ~0 : 0 )
#define F2CLOGICAL(L) (L)
#else /* others evaluate LOGICALs as for C. */
#define C2FLOGICAL(L) (L)
#define F2CLOGICAL(L) (L)
#ifndef LOGICAL_STRICT
#undef C2FLOGICALV
#undef F2CLOGICALV
#define C2FLOGICALV(A,I)
#define F2CLOGICALV(A,I)
#endif /* LOGICAL_STRICT */
#endif /* CONVEXFortran || All Others */
#endif /* IBMR2Fortran vmsFortran DECFortran AbsoftUNIXFortran */
#endif /* CRAYFortran */
#endif /* apolloFortran */
/* 970514 - In addition to CRAY, there may be other machines
for which LOGICAL_STRICT makes no sense. */
#if defined(LOGICAL_STRICT) && !defined(CRAYFortran)
/* Force C2FLOGICAL to generate only the values for either .TRUE. or .FALSE.
SX/PowerStationFortran only have 0 and 1 defined.
Elsewhere, only needed if you want to do:
logical lvariable
if (lvariable .eq. .true.) then ! (1)
instead of
if (lvariable .eqv. .true.) then ! (2)
- (1) may not even be FORTRAN/77 and that Apollo's f77 and IBM's xlf
refuse to compile (1), so you are probably well advised to stay away from
(1) and from LOGICAL_STRICT.
- You pay a (slight) performance penalty for using LOGICAL_STRICT. */
#undef C2FLOGICAL
#ifdef hpuxFortran800
#define C2FLOGICAL(L) ((L)?0x01000000:0)
#else
#if defined(apolloFortran) || defined(vmsFortran) || defined(DECFortran)
#define C2FLOGICAL(L) ((L)?-1:0) /* These machines use -1/0 for .true./.false.*/
#else
#define C2FLOGICAL(L) ((L)? 1:0) /* All others use +1/0 for .true./.false.*/
#endif
#endif
#endif /* LOGICAL_STRICT */
/* Convert a vector of C strings into FORTRAN strings. */
#ifndef __CF__KnR
static char *c2fstrv(char* cstr, char *fstr, int elem_len, int sizeofcstr)
#else
static char *c2fstrv( cstr, fstr, elem_len, sizeofcstr)
char* cstr; char *fstr; int elem_len; int sizeofcstr;
#endif
{ int i,j;
/* elem_len includes \0 for C strings. Fortran strings don't have term. \0.
Useful size of string must be the same in both languages. */
for (i=0; i<sizeofcstr/elem_len; i++) {
for (j=1; j<elem_len && *cstr; j++) *fstr++ = *cstr++;
cstr += 1+elem_len-j;
for (; j<elem_len; j++) *fstr++ = ' ';
} /* 95109 - Seems to be returning the original fstr. */
return fstr-sizeofcstr+sizeofcstr/elem_len; }
/* Convert a vector of FORTRAN strings into C strings. */
#ifndef __CF__KnR
static char *f2cstrv(char *fstr, char* cstr, int elem_len, int sizeofcstr)
#else
static char *f2cstrv( fstr, cstr, elem_len, sizeofcstr)
char *fstr; char* cstr; int elem_len; int sizeofcstr;
#endif
{ int i,j;
/* elem_len includes \0 for C strings. Fortran strings don't have term. \0.
Useful size of string must be the same in both languages. */
cstr += sizeofcstr;
fstr += sizeofcstr - sizeofcstr/elem_len;
for (i=0; i<sizeofcstr/elem_len; i++) {
*--cstr = '\0';
for (j=1; j<elem_len; j++) *--cstr = *--fstr;
} return cstr; }
/* kill the trailing char t's in string s. */
#ifndef __CF__KnR
static char *kill_trailing(char *s, char t)
#else
static char *kill_trailing( s, t) char *s; char t;
#endif
{char *e;
e = s + strlen(s);
if (e>s) { /* Need this to handle NULL string.*/
while (e>s && *--e==t); /* Don't follow t's past beginning. */
e[*e==t?0:1] = '\0'; /* Handle s[0]=t correctly. */
} return s; }
/* kill_trailingn(s,t,e) will kill the trailing t's in string s. e normally
points to the terminating '\0' of s, but may actually point to anywhere in s.
s's new '\0' will be placed at e or earlier in order to remove any trailing t's.
If e<s string s is left unchanged. */
#ifndef __CF__KnR
static char *kill_trailingn(char *s, char t, char *e)
#else
static char *kill_trailingn( s, t, e) char *s; char t; char *e;
#endif
{
if (e==s) *e = '\0'; /* Kill the string makes sense here.*/
else if (e>s) { /* Watch out for neg. length string.*/
while (e>s && *--e==t); /* Don't follow t's past beginning. */
e[*e==t?0:1] = '\0'; /* Handle s[0]=t correctly. */
} return s; }
/* Note the following assumes that any element which has t's to be chopped off,
does indeed fill the entire element. */
#ifndef __CF__KnR
static char *vkill_trailing(char* cstr, int elem_len, int sizeofcstr, char t)
#else
static char *vkill_trailing( cstr, elem_len, sizeofcstr, t)
char* cstr; int elem_len; int sizeofcstr; char t;
#endif
{ int i;
for (i=0; i<sizeofcstr/elem_len; i++) /* elem_len includes \0 for C strings. */
kill_trailingn(cstr+elem_len*i,t,cstr+elem_len*(i+1)-1);
return cstr; }
#ifdef vmsFortran
typedef struct dsc$descriptor_s fstring;
#define DSC$DESCRIPTOR_A(DIMCT) \
struct { \
unsigned short dsc$w_length; unsigned char dsc$b_dtype; \
unsigned char dsc$b_class; char *dsc$a_pointer; \
char dsc$b_scale; unsigned char dsc$b_digits; \
struct { \
unsigned : 3; unsigned dsc$v_fl_binscale : 1; \
unsigned dsc$v_fl_redim : 1; unsigned dsc$v_fl_column : 1; \
unsigned dsc$v_fl_coeff : 1; unsigned dsc$v_fl_bounds : 1; \
} dsc$b_aflags; \
unsigned char dsc$b_dimct; unsigned long dsc$l_arsize; \
char *dsc$a_a0; long dsc$l_m [DIMCT]; \
struct { \
long dsc$l_l; long dsc$l_u; \
} dsc$bounds [DIMCT]; \
}
typedef DSC$DESCRIPTOR_A(1) fstringvector;
/*typedef DSC$DESCRIPTOR_A(2) fstringarrarr;
typedef DSC$DESCRIPTOR_A(3) fstringarrarrarr;*/
#define initfstr(F,C,ELEMNO,ELEMLEN) \
( (F).dsc$l_arsize= ( (F).dsc$w_length =(ELEMLEN) ) \
*( (F).dsc$l_m[0]=(F).dsc$bounds[0].dsc$l_u=(ELEMNO) ), \
(F).dsc$a_a0 = ( (F).dsc$a_pointer=(C) ) - (F).dsc$w_length ,(F))
#else
#define _NUM_ELEMS -1
#define _NUM_ELEM_ARG -2
#define NUM_ELEMS(A) A,_NUM_ELEMS
#define NUM_ELEM_ARG(B) *_2(A,B),_NUM_ELEM_ARG
#define TERM_CHARS(A,B) A,B
#ifndef __CF__KnR
static int num_elem(char *strv, unsigned elem_len, int term_char, int num_term)
#else
static int num_elem( strv, elem_len, term_char, num_term)
char *strv; unsigned elem_len; int term_char; int num_term;
#endif
/* elem_len is the number of characters in each element of strv, the FORTRAN
vector of strings. The last element of the vector must begin with at least
num_term term_char characters, so that this routine can determine how
many elements are in the vector. */
{
unsigned num,i;
if (num_term == _NUM_ELEMS || num_term == _NUM_ELEM_ARG)
return term_char;
if (num_term <=0) num_term = (int)elem_len;
for (num=0; ; num++) {
for (i=0; i<(unsigned)num_term && *strv==term_char; i++,strv++);
if (i==(unsigned)num_term) break;
else strv += elem_len-i;
}
return (int)num;
}
#endif
/*-------------------------------------------------------------------------*/
/* UTILITIES FOR C TO USE STRINGS IN FORTRAN COMMON BLOCKS */
/* C string TO Fortran Common Block STRing. */
/* DIM is the number of DIMensions of the array in terms of strings, not
characters. e.g. char a[12] has DIM = 0, char a[12][4] has DIM = 1, etc. */
#define C2FCBSTR(CSTR,FSTR,DIM) \
c2fstrv((char *)CSTR, (char *)FSTR, sizeof(FSTR)/cfelementsof(FSTR,DIM)+1, \
sizeof(FSTR)+cfelementsof(FSTR,DIM))
/* Fortran Common Block string TO C STRing. */
#define FCB2CSTR(FSTR,CSTR,DIM) \
vkill_trailing(f2cstrv((char *)FSTR, (char *)CSTR, \
sizeof(FSTR)/cfelementsof(FSTR,DIM)+1, \
sizeof(FSTR)+cfelementsof(FSTR,DIM)), \
sizeof(FSTR)/cfelementsof(FSTR,DIM)+1, \
sizeof(FSTR)+cfelementsof(FSTR,DIM), ' ')
#define cfDEREFERENCE0
#define cfDEREFERENCE1 *
#define cfDEREFERENCE2 **
#define cfDEREFERENCE3 ***
#define cfDEREFERENCE4 ****
#define cfDEREFERENCE5 *****
#define cfelementsof(A,D) (sizeof(A)/sizeof(_(cfDEREFERENCE,D)(A)))
/*-------------------------------------------------------------------------*/
/* UTILITIES FOR C TO CALL FORTRAN SUBROUTINES */
/* Define lookup tables for how to handle the various types of variables. */
#ifdef OLD_VAXC /* Prevent %CC-I-PARAMNOTUSED. */
#pragma nostandard
#endif
#define ZTRINGV_NUM(I) I
#define ZTRINGV_ARGFP(I) (*(_2(A,I))) /* Undocumented. For PINT, etc. */
#define ZTRINGV_ARGF(I) _2(A,I)
#ifdef CFSUBASFUN
#define ZTRINGV_ARGS(I) ZTRINGV_ARGF(I)
#else
#define ZTRINGV_ARGS(I) _2(B,I)
#endif
#define PBYTE_cfVP(A,B) PINT_cfVP(A,B)
#define PDOUBLE_cfVP(A,B)
#define PFLOAT_cfVP(A,B)
#ifdef ZTRINGV_ARGS_allows_Pvariables
/* This allows Pvariables for ARGS. ARGF machinery is above ARGFP.
* B is not needed because the variable may be changed by the Fortran routine,
* but because B is the only way to access an arbitrary macro argument. */
#define PINT_cfVP(A,B) int B = (int)A; /* For ZSTRINGV_ARGS */
#else
#define PINT_cfVP(A,B)
#endif
#define PLOGICAL_cfVP(A,B) int *B; /* Returning LOGICAL in FUNn and SUBn */
#define PLONG_cfVP(A,B) PINT_cfVP(A,B)
#define PSHORT_cfVP(A,B) PINT_cfVP(A,B)
#define VCF_INT_S(T,A,B) _(T,VVVVVVV_cfTYPE) B = A;
#define VCF_INT_F(T,A,B) _(T,_cfVCF)(A,B)
/* _cfVCF table is directly mapped to _cfCCC table. */
#define BYTE_cfVCF(A,B)
#define DOUBLE_cfVCF(A,B)
#if !defined(__CF__KnR)
#define FLOAT_cfVCF(A,B)
#else
#define FLOAT_cfVCF(A,B) FORTRAN_REAL B = A;
#endif
#define INT_cfVCF(A,B)
#define LOGICAL_cfVCF(A,B)
#define LONG_cfVCF(A,B)
#define SHORT_cfVCF(A,B)
/* 980416
Cast (void (*)(CF_NULL_PROTO)) causes SunOS CC 4.2 occasionally to barf,
while the following equivalent typedef is fine.
For consistency use the typedef on all machines.
*/
typedef void (*cfCAST_FUNCTION)(CF_NULL_PROTO);
#define VCF(TN,I) _Icf4(4,V,TN,_(A,I),_(B,I),F)
#define VVCF(TN,AI,BI) _Icf4(4,V,TN,AI,BI,S)
#define INT_cfV(T,A,B,F) _(VCF_INT_,F)(T,A,B)
#define INTV_cfV(T,A,B,F)
#define INTVV_cfV(T,A,B,F)
#define INTVVV_cfV(T,A,B,F)
#define INTVVVV_cfV(T,A,B,F)
#define INTVVVVV_cfV(T,A,B,F)
#define INTVVVVVV_cfV(T,A,B,F)
#define INTVVVVVVV_cfV(T,A,B,F)
#define PINT_cfV( T,A,B,F) _(T,_cfVP)(A,B)
#define PVOID_cfV( T,A,B,F)
#if defined(apolloFortran) || defined(hpuxFortran800) || defined(AbsoftUNIXFortran) || defined(AbsoftProFortran)
#define ROUTINE_cfV(T,A,B,F) void (*B)(CF_NULL_PROTO) = (cfCAST_FUNCTION)A;
#else
#define ROUTINE_cfV(T,A,B,F)
#endif
#define SIMPLE_cfV(T,A,B,F)
#ifdef vmsFortran
#define STRING_cfV(T,A,B,F) static struct {fstring f; unsigned clen;} B = \
{{0,DSC$K_DTYPE_T,DSC$K_CLASS_S,NULL},0};
#define PSTRING_cfV(T,A,B,F) static fstring B={0,DSC$K_DTYPE_T,DSC$K_CLASS_S,NULL};
#define STRINGV_cfV(T,A,B,F) static fstringvector B = \
{sizeof(A),DSC$K_DTYPE_T,DSC$K_CLASS_A,NULL,0,0,{0,0,1,1,1},1,0,NULL,0,{1,0}};
#define PSTRINGV_cfV(T,A,B,F) static fstringvector B = \
{0,DSC$K_DTYPE_T,DSC$K_CLASS_A,NULL,0,0,{0,0,1,1,1},1,0,NULL,0,{1,0}};
#else
#define STRING_cfV(T,A,B,F) struct {unsigned int clen, flen;} B;
#define STRINGV_cfV(T,A,B,F) struct {char *s, *fs; unsigned flen;} B;
#define PSTRING_cfV(T,A,B,F) int B;
#define PSTRINGV_cfV(T,A,B,F) struct{char *fs; unsigned int sizeofA,flen;}B;
#endif
#define ZTRINGV_cfV(T,A,B,F) STRINGV_cfV(T,A,B,F)
#define PZTRINGV_cfV(T,A,B,F) PSTRINGV_cfV(T,A,B,F)
/* Note that the actions of the A table were performed inside the AA table.
VAX Ultrix vcc, and HP-UX cc, didn't evaluate arguments to functions left to
right, so we had to split the original table into the current robust two. */
#define ACF(NAME,TN,AI,I) _(TN,_cfSTR)(4,A,NAME,I,AI,_(B,I),0)
#define DEFAULT_cfA(M,I,A,B)
#define LOGICAL_cfA(M,I,A,B) B=C2FLOGICAL(B);
#define PLOGICAL_cfA(M,I,A,B) A=C2FLOGICAL(A);
#define STRING_cfA(M,I,A,B) STRING_cfC(M,I,A,B,sizeof(A))
#define PSTRING_cfA(M,I,A,B) PSTRING_cfC(M,I,A,B,sizeof(A))
#ifdef vmsFortran
#define AATRINGV_cfA( A,B, sA,filA,silA) \
initfstr(B,_cf_malloc((sA)-(filA)),(filA),(silA)-1), \
c2fstrv(A,B.dsc$a_pointer,(silA),(sA));
#define APATRINGV_cfA( A,B, sA,filA,silA) \
initfstr(B,A,(filA),(silA)-1),c2fstrv(A,A,(silA),(sA));
#else
#define AATRINGV_cfA( A,B, sA,filA,silA) \
(B.s=_cf_malloc((sA)-(filA)),B.fs=c2fstrv(A,B.s,(B.flen=(silA)-1)+1,(sA)));
#define APATRINGV_cfA( A,B, sA,filA,silA) \
B.fs=c2fstrv(A,A,(B.flen=(silA)-1)+1,B.sizeofA=(sA));
#endif
#define STRINGV_cfA(M,I,A,B) \
AATRINGV_cfA((char *)A,B,sizeof(A),firstindexlength(A),secondindexlength(A))
#define PSTRINGV_cfA(M,I,A,B) \
APATRINGV_cfA((char *)A,B,sizeof(A),firstindexlength(A),secondindexlength(A))
#define ZTRINGV_cfA(M,I,A,B) AATRINGV_cfA( (char *)A,B, \
(_3(M,_ELEMS_,I))*(( _3(M,_ELEMLEN_,I))+1), \
(_3(M,_ELEMS_,I)),(_3(M,_ELEMLEN_,I))+1)
#define PZTRINGV_cfA(M,I,A,B) APATRINGV_cfA( (char *)A,B, \
(_3(M,_ELEMS_,I))*(( _3(M,_ELEMLEN_,I))+1), \
(_3(M,_ELEMS_,I)),(_3(M,_ELEMLEN_,I))+1)
#define PBYTE_cfAAP(A,B) &A
#define PDOUBLE_cfAAP(A,B) &A
#define PFLOAT_cfAAP(A,B) FLOATVVVVVVV_cfPP &A
#define PINT_cfAAP(A,B) &A
#define PLOGICAL_cfAAP(A,B) B= &A /* B used to keep a common W table. */
#define PLONG_cfAAP(A,B) &A
#define PSHORT_cfAAP(A,B) &A
#define AACF(TN,AI,I,C) _SEP_(TN,C,cfCOMMA) _Icf(3,AA,TN,AI,_(B,I))
#define INT_cfAA(T,A,B) &B
#define INTV_cfAA(T,A,B) _(T,VVVVVV_cfPP) A
#define INTVV_cfAA(T,A,B) _(T,VVVVV_cfPP) A[0]
#define INTVVV_cfAA(T,A,B) _(T,VVVV_cfPP) A[0][0]
#define INTVVVV_cfAA(T,A,B) _(T,VVV_cfPP) A[0][0][0]
#define INTVVVVV_cfAA(T,A,B) _(T,VV_cfPP) A[0][0][0][0]
#define INTVVVVVV_cfAA(T,A,B) _(T,V_cfPP) A[0][0][0][0][0]
#define INTVVVVVVV_cfAA(T,A,B) _(T,_cfPP) A[0][0][0][0][0][0]
#define PINT_cfAA(T,A,B) _(T,_cfAAP)(A,B)
#define PVOID_cfAA(T,A,B) (void *) A
#if defined(apolloFortran) || defined(hpuxFortran800) || defined(AbsoftUNIXFortran)
#define ROUTINE_cfAA(T,A,B) &B
#else
#define ROUTINE_cfAA(T,A,B) (cfCAST_FUNCTION)A
#endif
#define STRING_cfAA(T,A,B) STRING_cfCC(T,A,B)
#define PSTRING_cfAA(T,A,B) PSTRING_cfCC(T,A,B)
#ifdef vmsFortran
#define STRINGV_cfAA(T,A,B) &B
#else
#ifdef CRAYFortran
#define STRINGV_cfAA(T,A,B) _cptofcd(B.fs,B.flen)
#else
#define STRINGV_cfAA(T,A,B) B.fs
#endif
#endif
#define PSTRINGV_cfAA(T,A,B) STRINGV_cfAA(T,A,B)
#define ZTRINGV_cfAA(T,A,B) STRINGV_cfAA(T,A,B)
#define PZTRINGV_cfAA(T,A,B) STRINGV_cfAA(T,A,B)
#if defined(vmsFortran) || defined(CRAYFortran)
#define JCF(TN,I)
#define KCF(TN,I)
#else
#define JCF(TN,I) _(TN,_cfSTR)(1,J,_(B,I), 0,0,0,0)
#if defined(AbsoftUNIXFortran)
#define DEFAULT_cfJ(B) ,0
#else
#define DEFAULT_cfJ(B)
#endif
#define LOGICAL_cfJ(B) DEFAULT_cfJ(B)
#define PLOGICAL_cfJ(B) DEFAULT_cfJ(B)
#define STRING_cfJ(B) ,B.flen
#define PSTRING_cfJ(B) ,B
#define STRINGV_cfJ(B) STRING_cfJ(B)
#define PSTRINGV_cfJ(B) STRING_cfJ(B)
#define ZTRINGV_cfJ(B) STRING_cfJ(B)
#define PZTRINGV_cfJ(B) STRING_cfJ(B)
/* KCF is identical to DCF, except that KCF ZTRING is not empty. */
#define KCF(TN,I) _(TN,_cfSTR)(1,KK,_(B,I), 0,0,0,0)
#if defined(AbsoftUNIXFortran)
#define DEFAULT_cfKK(B) , unsigned B
#else
#define DEFAULT_cfKK(B)
#endif
#define LOGICAL_cfKK(B) DEFAULT_cfKK(B)
#define PLOGICAL_cfKK(B) DEFAULT_cfKK(B)
#define STRING_cfKK(B) , unsigned B
#define PSTRING_cfKK(B) STRING_cfKK(B)
#define STRINGV_cfKK(B) STRING_cfKK(B)
#define PSTRINGV_cfKK(B) STRING_cfKK(B)
#define ZTRINGV_cfKK(B) STRING_cfKK(B)
#define PZTRINGV_cfKK(B) STRING_cfKK(B)
#endif
#define WCF(TN,AN,I) _(TN,_cfSTR)(2,W,AN,_(B,I), 0,0,0)
#define DEFAULT_cfW(A,B)
#define LOGICAL_cfW(A,B)
#define PLOGICAL_cfW(A,B) *B=F2CLOGICAL(*B);
#define STRING_cfW(A,B) (A[B.clen]!='\0'?A[B.clen]='\0':0); /* A?="constnt"*/
#define PSTRING_cfW(A,B) kill_trailing(A,' ');
#ifdef vmsFortran
#define STRINGV_cfW(A,B) _cf_free(B.dsc$a_pointer);
#define PSTRINGV_cfW(A,B) \
vkill_trailing(f2cstrv((char*)A, (char*)A, \
B.dsc$w_length+1, B.dsc$l_arsize+B.dsc$l_m[0]), \
B.dsc$w_length+1, B.dsc$l_arsize+B.dsc$l_m[0], ' ');
#else
#define STRINGV_cfW(A,B) _cf_free(B.s);
#define PSTRINGV_cfW(A,B) vkill_trailing( \
f2cstrv((char*)A,(char*)A,B.flen+1,B.sizeofA), B.flen+1,B.sizeofA,' ');
#endif
#define ZTRINGV_cfW(A,B) STRINGV_cfW(A,B)
#define PZTRINGV_cfW(A,B) PSTRINGV_cfW(A,B)
#define NCF(TN,I,C) _SEP_(TN,C,cfCOMMA) _Icf(2,N,TN,_(A,I),0)
#define NNCF(TN,I,C) UUCF(TN,I,C)
#define NNNCF(TN,I,C) _SEP_(TN,C,cfCOLON) _Icf(2,N,TN,_(A,I),0)
#define INT_cfN(T,A) _(T,VVVVVVV_cfTYPE) * A
#define INTV_cfN(T,A) _(T,VVVVVV_cfTYPE) * A
#define INTVV_cfN(T,A) _(T,VVVVV_cfTYPE) * A
#define INTVVV_cfN(T,A) _(T,VVVV_cfTYPE) * A
#define INTVVVV_cfN(T,A) _(T,VVV_cfTYPE) * A
#define INTVVVVV_cfN(T,A) _(T,VV_cfTYPE) * A
#define INTVVVVVV_cfN(T,A) _(T,V_cfTYPE) * A
#define INTVVVVVVV_cfN(T,A) _(T,_cfTYPE) * A
#define PINT_cfN(T,A) _(T,_cfTYPE) * A
#define PVOID_cfN(T,A) void * A
#if defined(apolloFortran) || defined(hpuxFortran800) || defined(AbsoftUNIXFortran)
#define ROUTINE_cfN(T,A) void (**A)(CF_NULL_PROTO)
#else
#define ROUTINE_cfN(T,A) void ( *A)(CF_NULL_PROTO)
#endif
#ifdef vmsFortran
#define STRING_cfN(T,A) fstring * A
#define STRINGV_cfN(T,A) fstringvector * A
#else
#ifdef CRAYFortran
#define STRING_cfN(T,A) _fcd A
#define STRINGV_cfN(T,A) _fcd A
#else
#define STRING_cfN(T,A) char * A
#define STRINGV_cfN(T,A) char * A
#endif
#endif
#define PSTRING_cfN(T,A) STRING_cfN(T,A) /* CRAY insists on arg.'s here. */
#define PNSTRING_cfN(T,A) STRING_cfN(T,A) /* CRAY insists on arg.'s here. */
#define PPSTRING_cfN(T,A) STRING_cfN(T,A) /* CRAY insists on arg.'s here. */
#define PSTRINGV_cfN(T,A) STRINGV_cfN(T,A)
#define ZTRINGV_cfN(T,A) STRINGV_cfN(T,A)
#define PZTRINGV_cfN(T,A) PSTRINGV_cfN(T,A)
/* Apollo 6.7, CRAY, old Sun, VAX/Ultrix vcc/cc and new ultrix
can't hack more than 31 arg's.
e.g. ultrix >= 4.3 gives message:
zow35> cc -c -DDECFortran cfortest.c
cfe: Fatal: Out of memory: cfortest.c
zow35>
Old __hpux had the problem, but new 'HP-UX A.09.03 A 9000/735' is fine
if using -Aa, otherwise we have a problem.
*/
#ifndef MAX_PREPRO_ARGS
#if !defined(__GNUC__) && (defined(VAXUltrix) || defined(__CF__APOLLO67) || (defined(sun)&&!defined(__sun)) || defined(_CRAY) || defined(__ultrix__) || (defined(__hpux)&&defined(__CF__KnR)))
#define MAX_PREPRO_ARGS 31
#else
#define MAX_PREPRO_ARGS 99
#endif
#endif
#if defined(AbsoftUNIXFortran) || defined(AbsoftProFortran)
/* In addition to explicit Absoft stuff, only Absoft requires:
- DEFAULT coming from _cfSTR.
DEFAULT could have been called e.g. INT, but keep it for clarity.
- M term in CFARGT14 and CFARGT14FS.
*/
#define ABSOFT_cf1(T0) _(T0,_cfSTR)(0,ABSOFT1,0,0,0,0,0)
#define ABSOFT_cf2(T0) _(T0,_cfSTR)(0,ABSOFT2,0,0,0,0,0)
#define ABSOFT_cf3(T0) _(T0,_cfSTR)(0,ABSOFT3,0,0,0,0,0)
#define DEFAULT_cfABSOFT1
#define LOGICAL_cfABSOFT1
#define STRING_cfABSOFT1 ,MAX_LEN_FORTRAN_FUNCTION_STRING
#define DEFAULT_cfABSOFT2
#define LOGICAL_cfABSOFT2
#define STRING_cfABSOFT2 ,unsigned D0
#define DEFAULT_cfABSOFT3
#define LOGICAL_cfABSOFT3
#define STRING_cfABSOFT3 ,D0
#else
#define ABSOFT_cf1(T0)
#define ABSOFT_cf2(T0)
#define ABSOFT_cf3(T0)
#endif
/* _Z introduced to cicumvent IBM and HP silly preprocessor warning.
e.g. "Macro CFARGT14 invoked with a null argument."
*/
#define _Z
#define CFARGT14S(S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE) \
S(T1,1) S(T2,2) S(T3,3) S(T4,4) S(T5,5) S(T6,6) S(T7,7) \
S(T8,8) S(T9,9) S(TA,10) S(TB,11) S(TC,12) S(TD,13) S(TE,14)
#define CFARGT27S(S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,TL,TM,TN,TO,TP,TQ,TR) \
S(T1,1) S(T2,2) S(T3,3) S(T4,4) S(T5,5) S(T6,6) S(T7,7) \
S(T8,8) S(T9,9) S(TA,10) S(TB,11) S(TC,12) S(TD,13) S(TE,14) \
S(TF,15) S(TG,16) S(TH,17) S(TI,18) S(TJ,19) S(TK,20) S(TL,21) \
S(TM,22) S(TN,23) S(TO,24) S(TP,25) S(TQ,26) S(TR,27)
#define CFARGT14FS(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE) \
F(T1,1,0) F(T2,2,1) F(T3,3,1) F(T4,4,1) F(T5,5,1) F(T6,6,1) F(T7,7,1) \
F(T8,8,1) F(T9,9,1) F(TA,10,1) F(TB,11,1) F(TC,12,1) F(TD,13,1) F(TE,14,1) \
M CFARGT14S(S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE)
#define CFARGT27FS(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,TL,TM,TN,TO,TP,TQ,TR) \
F(T1,1,0) F(T2,2,1) F(T3,3,1) F(T4,4,1) F(T5,5,1) F(T6,6,1) F(T7,7,1) \
F(T8,8,1) F(T9,9,1) F(TA,10,1) F(TB,11,1) F(TC,12,1) F(TD,13,1) F(TE,14,1) \
F(TF,15,1) F(TG,16,1) F(TH,17,1) F(TI,18,1) F(TJ,19,1) F(TK,20,1) F(TL,21,1) \
F(TM,22,1) F(TN,23,1) F(TO,24,1) F(TP,25,1) F(TQ,26,1) F(TR,27,1) \
M CFARGT27S(S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,TL,TM,TN,TO,TP,TQ,TR)
#if !(defined(PowerStationFortran)||defined(hpuxFortran800))
/* Old CFARGT14 -> CFARGT14FS as seen below, for Absoft cross-compile yields:
SunOS> cc -c -Xa -DAbsoftUNIXFortran c.c
"c.c", line 406: warning: argument mismatch
Haven't checked if this is ANSI C or a SunOS bug. SunOS -Xs works ok.
Behavior is most clearly seen in example:
#define A 1 , 2
#define C(X,Y,Z) x=X. y=Y. z=Z.
#define D(X,Y,Z) C(X,Y,Z)
D(x,A,z)
Output from preprocessor is: x = x . y = 1 . z = 2 .
#define CFARGT14(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE) \
CFARGT14FS(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE)
*/
#define CFARGT14(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE) \
F(T1,1,0) F(T2,2,1) F(T3,3,1) F(T4,4,1) F(T5,5,1) F(T6,6,1) F(T7,7,1) \
F(T8,8,1) F(T9,9,1) F(TA,10,1) F(TB,11,1) F(TC,12,1) F(TD,13,1) F(TE,14,1) \
M CFARGT14S(S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE)
#define CFARGT27(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,TL,TM,TN,TO,TP,TQ,TR) \
F(T1,1,0) F(T2,2,1) F(T3,3,1) F(T4,4,1) F(T5,5,1) F(T6,6,1) F(T7,7,1) \
F(T8,8,1) F(T9,9,1) F(TA,10,1) F(TB,11,1) F(TC,12,1) F(TD,13,1) F(TE,14,1) \
F(TF,15,1) F(TG,16,1) F(TH,17,1) F(TI,18,1) F(TJ,19,1) F(TK,20,1) F(TL,21,1) \
F(TM,22,1) F(TN,23,1) F(TO,24,1) F(TP,25,1) F(TQ,26,1) F(TR,27,1) \
M CFARGT27S(S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,TL,TM,TN,TO,TP,TQ,TR)
#define CFARGT20(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK) \
F(T1,1,0) F(T2,2,1) F(T3,3,1) F(T4,4,1) F(T5,5,1) F(T6,6,1) F(T7,7,1) \
F(T8,8,1) F(T9,9,1) F(TA,10,1) F(TB,11,1) F(TC,12,1) F(TD,13,1) F(TE,14,1) \
F(TF,15,1) F(TG,16,1) F(TH,17,1) F(TI,18,1) F(TJ,19,1) F(TK,20,1) \
S(T1,1) S(T2,2) S(T3,3) S(T4,4) S(T5,5) S(T6,6) S(T7,7) \
S(T8,8) S(T9,9) S(TA,10) S(TB,11) S(TC,12) S(TD,13) S(TE,14) \
S(TF,15) S(TG,16) S(TH,17) S(TI,18) S(TJ,19) S(TK,20)
#define CFARGTA14(F,S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,A1,A2,A3,A4,A5,A6,A7,A8,A9,AA,AB,AC,AD,AE) \
F(T1,A1,1,0) F(T2,A2,2,1) F(T3,A3,3,1) F(T4,A4,4,1) F(T5,A5,5,1) F(T6,A6,6,1) \
F(T7,A7,7,1) F(T8,A8,8,1) F(T9,A9,9,1) F(TA,AA,10,1) F(TB,AB,11,1) F(TC,AC,12,1) \
F(TD,AD,13,1) F(TE,AE,14,1) S(T1,1) S(T2,2) S(T3,3) S(T4,4) \
S(T5,5) S(T6,6) S(T7,7) S(T8,8) S(T9,9) S(TA,10) \
S(TB,11) S(TC,12) S(TD,13) S(TE,14)
#if MAX_PREPRO_ARGS>31
#define CFARGTA20(F,S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,A1,A2,A3,A4,A5,A6,A7,A8,A9,AA,AB,AC,AD,AE,AF,AG,AH,AI,AJ,AK) \
F(T1,A1,1,0) F(T2,A2,2,1) F(T3,A3,3,1) F(T4,A4,4,1) F(T5,A5,5,1) F(T6,A6,6,1) \
F(T7,A7,7,1) F(T8,A8,8,1) F(T9,A9,9,1) F(TA,AA,10,1) F(TB,AB,11,1) F(TC,AC,12,1) \
F(TD,AD,13,1) F(TE,AE,14,1) F(TF,AF,15,1) F(TG,AG,16,1) F(TH,AH,17,1) F(TI,AI,18,1) \
F(TJ,AJ,19,1) F(TK,AK,20,1) S(T1,1) S(T2,2) S(T3,3) S(T4,4) \
S(T5,5) S(T6,6) S(T7,7) S(T8,8) S(T9,9) S(TA,10) \
S(TB,11) S(TC,12) S(TD,13) S(TE,14) S(TF,15) S(TG,16) \
S(TH,17) S(TI,18) S(TJ,19) S(TK,20)
#define CFARGTA27(F,S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,TL,TM,TN,TO,TP,TQ,TR,A1,A2,A3,A4,A5,A6,A7,A8,A9,AA,AB,AC,AD,AE,AF,AG,AH,AI,AJ,AK,AL,AM,AN,AO,AP,AQ,AR) \
F(T1,A1,1,0) F(T2,A2,2,1) F(T3,A3,3,1) F(T4,A4,4,1) F(T5,A5,5,1) F(T6,A6,6,1) \
F(T7,A7,7,1) F(T8,A8,8,1) F(T9,A9,9,1) F(TA,AA,10,1) F(TB,AB,11,1) F(TC,AC,12,1) \
F(TD,AD,13,1) F(TE,AE,14,1) F(TF,AF,15,1) F(TG,AG,16,1) F(TH,AH,17,1) F(TI,AI,18,1) \
F(TJ,AJ,19,1) F(TK,AK,20,1) F(TL,AL,21,1) F(TM,AM,22,1) F(TN,AN,23,1) F(TO,AO,24,1) \
F(TP,AP,25,1) F(TQ,AQ,26,1) F(TR,AR,27,1) S(T1,1) S(T2,2) S(T3,3) \
S(T4,4) S(T5,5) S(T6,6) S(T7,7) S(T8,8) S(T9,9) \
S(TA,10) S(TB,11) S(TC,12) S(TD,13) S(TE,14) S(TF,15) \
S(TG,16) S(TH,17) S(TI,18) S(TJ,19) S(TK,20) S(TL,21) \
S(TM,22) S(TN,23) S(TO,24) S(TP,25) S(TQ,26) S(TR,27)
#endif
#else
#define CFARGT14(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE) \
F(T1,1,0) S(T1,1) F(T2,2,1) S(T2,2) F(T3,3,1) S(T3,3) F(T4,4,1) S(T4,4) \
F(T5,5,1) S(T5,5) F(T6,6,1) S(T6,6) F(T7,7,1) S(T7,7) F(T8,8,1) S(T8,8) \
F(T9,9,1) S(T9,9) F(TA,10,1) S(TA,10) F(TB,11,1) S(TB,11) F(TC,12,1) S(TC,12) \
F(TD,13,1) S(TD,13) F(TE,14,1) S(TE,14)
#define CFARGT27(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,TL,TM,TN,TO,TP,TQ,TR) \
F(T1,1,0) S(T1,1) F(T2,2,1) S(T2,2) F(T3,3,1) S(T3,3) F(T4,4,1) S(T4,4) \
F(T5,5,1) S(T5,5) F(T6,6,1) S(T6,6) F(T7,7,1) S(T7,7) F(T8,8,1) S(T8,8) \
F(T9,9,1) S(T9,9) F(TA,10,1) S(TA,10) F(TB,11,1) S(TB,11) F(TC,12,1) S(TC,12) \
F(TD,13,1) S(TD,13) F(TE,14,1) S(TE,14) F(TF,15,1) S(TF,15) F(TG,16,1) S(TG,16) \
F(TH,17,1) S(TH,17) F(TI,18,1) S(TI,18) F(TJ,19,1) S(TJ,19) F(TK,20,1) S(TK,20) \
F(TL,21,1) S(TL,21) F(TM,22,1) S(TM,22) F(TN,23,1) S(TN,23) F(TO,24,1) S(TO,24) \
F(TP,25,1) S(TP,25) F(TQ,26,1) S(TQ,26) F(TR,27,1) S(TR,27)
#define CFARGT20(F,S,M,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK) \
F(T1,1,0) S(T1,1) F(T2,2,1) S(T2,2) F(T3,3,1) S(T3,3) F(T4,4,1) S(T4,4) \
F(T5,5,1) S(T5,5) F(T6,6,1) S(T6,6) F(T7,7,1) S(T7,7) F(T8,8,1) S(T8,8) \
F(T9,9,1) S(T9,9) F(TA,10,1) S(TA,10) F(TB,11,1) S(TB,11) F(TC,12,1) S(TC,12) \
F(TD,13,1) S(TD,13) F(TE,14,1) S(TE,14) F(TF,15,1) S(TF,15) F(TG,16,1) S(TG,16) \
F(TH,17,1) S(TH,17) F(TI,18,1) S(TI,18) F(TJ,19,1) S(TJ,19) F(TK,20,1) S(TK,20)
#define CFARGTA14(F,S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,A1,A2,A3,A4,A5,A6,A7,A8,A9,AA,AB,AC,AD,AE) \
F(T1,A1,1,0) S(T1,1) F(T2,A2,2,1) S(T2,2) F(T3,A3,3,1) S(T3,3) \
F(T4,A4,4,1) S(T4,4) F(T5,A5,5,1) S(T5,5) F(T6,A6,6,1) S(T6,6) \
F(T7,A7,7,1) S(T7,7) F(T8,A8,8,1) S(T8,8) F(T9,A9,9,1) S(T9,9) \
F(TA,AA,10,1) S(TA,10) F(TB,AB,11,1) S(TB,11) F(TC,AC,12,1) S(TC,12) \
F(TD,AD,13,1) S(TD,13) F(TE,AE,14,1) S(TE,14)
#if MAX_PREPRO_ARGS>31
#define CFARGTA20(F,S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,A1,A2,A3,A4,A5,A6,A7,A8,A9,AA,AB,AC,AD,AE,AF,AG,AH,AI,AJ,AK) \
F(T1,A1,1,0) S(T1,1) F(T2,A2,2,1) S(T2,2) F(T3,A3,3,1) S(T3,3) \
F(T4,A4,4,1) S(T4,4) F(T5,A5,5,1) S(T5,5) F(T6,A6,6,1) S(T6,6) \
F(T7,A7,7,1) S(T7,7) F(T8,A8,8,1) S(T8,8) F(T9,A9,9,1) S(T9,9) \
F(TA,AA,10,1) S(TA,10) F(TB,AB,11,1) S(TB,11) F(TC,AC,12,1) S(TC,12) \
F(TD,AD,13,1) S(TD,13) F(TE,AE,14,1) S(TE,14) F(TF,AF,15,1) S(TF,15) \
F(TG,AG,16,1) S(TG,16) F(TH,AH,17,1) S(TH,17) F(TI,AI,18,1) S(TI,18) \
F(TJ,AJ,19,1) S(TJ,19) F(TK,AK,20,1) S(TK,20)
#define CFARGTA27(F,S,T1,T2,T3,T4,T5,T6,T7,T8,T9,TA,TB,TC,TD,TE,TF,TG,TH,TI,TJ,TK,TL,TM,TN,TO,TP,TQ,TR,A1,A2,A3,A4,A5,A6,A7,A8,A9,AA,AB,AC,AD,AE,AF,AG,AH,AI,AJ,AK,AL,AM,AN,AO,AP,AQ,AR) \
F(T1,A1,1,0) S(T1,1) F(T2,A2,2,1) S(T2,2) F(T3,A3,3,1) S(T3,3) \
F(T4,A4,4,1) S(T4,4) F(T5,A5,5,1) S(T5,5) F(T6,A6,6,1) S(T6,6) \
F(T7,A7,7,1) S(T7,7) F(T8,A8,8,1) S(T8,8) F(T9,A9,9,1) S(T9,9) \
F(TA,AA,10,1) S(TA,10) F(TB,AB,11,1) S(TB,11) F(TC,AC,12,1) S(TC,12) \
F(TD,AD,13,1) S(TD,13) F(TE,AE,14,1) S(TE,14) F(TF,AF,15,1) S(TF,15) \
F(TG,AG,16,1) S(TG,16) F(TH,AH,17,1) S(TH,17) F(TI,AI,18,1) S(TI,18) \
F(TJ,AJ,19,1) S(TJ,19) F(TK,AK,20,1) S(TK,20) F(TL,AL,21,1) S(TL,21) \
F(TM,AM,22,1) S(TM,22) F(TN,AN,23,1) S(TN,23) F(TO,AO,24,1) S(TO,24) \
F(TP,AP,25,1) S(TP,25) F(TQ,AQ,26,1) S(TQ,26) F(TR,AR,27,1) S(TR,27)
#endif
#endif