/********** Copyright 1990 Regents of the University of California. All rights reserved. Author: 1985 Wayne A. Christopher, U. C. Berkeley CAD Group Modified: 2000 AlansFixes **********/ /*------------------------------------------------------------------------------ * encapsulated string assembly in translate() and finishLine() * this string facility (bxx_buffer) mainly abstracts away buffer allocation. * this fixes a buffer overflow in finishLine, caused by lengthy descriptions * of the kind: * B1 1 2 I=v(1)+v(2)+v(3)+... * Larice, 22nd Aug 2009 *----------------------------------------------------------------------------*/ /*------------------------------------------------------------------------------ * Added changes supplied by by H.Tanaka with some tidy up of comments, debug * statements, and variables. This fixes a problem with nested .subsck elements * that accessed .model lines. Code not ideal, but it seems to work okay. * Also took opportunity to tidy a few other items (unused variables etc.), plus * fix a few spelling errors in the comments, and a memory leak. * SJB 25th March 2005 *----------------------------------------------------------------------------*/ /*------------------------------------------------------------------------------ * re-written by SDB during 4.2003 to enable SPICE2 POLY statements to be processed * properly. This is particularly important for dependent sources, whose argument * list changes when POLY is used. * Major changes include: * -- Added lots of comments which (hopefully) elucidate the steps taken * by the program during its processing. * -- Re-wrote translate, which does the processing of each card. * Please direct comments/questions/complaints to Stuart Brorson: * mailto:sdb@cloud9.net *-----------------------------------------------------------------------------*/ /* * Expand subcircuits. This is very spice-dependent. Bug fixes by Norbert * Jeske on 10/5/85. */ /*======================================================================* * Expand all subcircuits in the deck. This handles imbedded .subckt * definitions. The variables substart, subend, and subinvoke can be used * to redefine the controls used. The syntax is invariant though. * NOTE: the deck must be passed without the title line. * What we do is as follows: first make one pass through the circuit * and collect all of the subcircuits. Then, whenever a line that starts * with 'x' is found, copy the subcircuit associated with that name and * splice it in. A few of the problems: the nodes in the spliced-in * stuff must be unique, so when we copy it, append "subcktname:" to * each node. If we are in a nested subcircuit, use foo:bar:...:node. * Then we have to systematically change all references to the renamed * nodes. On top of that, we have to know how many args BJT's have, * so we have to keep track of model names. *======================================================================*/ /*#define TRACE*/ #include "ngspice/ngspice.h" #include "ngspice/cpdefs.h" #include "ngspice/ftedefs.h" #include "ngspice/fteinp.h" #include #ifdef XSPICE /* gtri - add - wbk - 11/9/90 - include MIF function prototypes */ #include "ngspice/mifproto.h" /* gtri - end - wbk - 11/9/90 */ #endif #include "subckt.h" #include "variable.h" #include "numparam/numpaif.h" extern void line_free_x(struct line * deck, bool recurse); #define line_free(line,flag) { line_free_x(line,flag); line = NULL; } /* ----- static declarations ----- */ static struct line * doit(struct line *deck); static int translate(struct line *deck, char *formal, char *actual, char *scname, char *subname); struct bxx_buffer; static void finishLine(struct bxx_buffer *dst, char *src, char *scname); static int settrans(char *formal, char *actual, char *subname); static char * gettrans(const char *name, const char *name_end); static int numnodes(char *name); static int numdevs(char *s); static bool modtranslate(struct line *deck, char *subname); static void devmodtranslate(struct line *deck, char *subname); static int inp_numnodes(char c); /*--------------------------------------------------------------------- * table is used in settrans and gettrans -- it holds the netnames used * in the .subckt definition (t_old), and in the subcircuit invocation * (t_new) *--------------------------------------------------------------------*/ static struct tab { char *t_old; char *t_new; } table[512]; /* That had better be enough. */ /*--------------------------------------------------------------------- * subs is the linked list which holds the .subckt definitions * found during processing. *--------------------------------------------------------------------*/ struct subs { char *su_name; /* The .subckt name. */ char *su_args; /* The .subckt arguments, space separated. */ int su_numargs; struct line *su_def; /* Pointer to the .subckt definition. */ struct subs *su_next; } ; /* submod is the list of original model names, modnames is the * list of translated names (i.e. after subckt expansion) */ static wordlist *modnames, *submod; static struct subs *subs = NULL; static bool nobjthack = FALSE; /* flag indicating use of the experimental numparams library */ static bool use_numparams = FALSE; static char start[32], sbend[32], invoke[32], model[32]; static char node[128][128]; static int numgnode; /*------------------------------------------------------------------- inp_subcktexpand is the top level function which translates .subckts into mainlined code. Note that there are several things we need to do: 1. Find all .subckt definitions & stick them into a list. 2. Find all subcircuit invocations (refdes X) and replace them with the .subckt definition stored earlier. 3. Do parameter substitution. The algorithm is as follows: 1. Define some aliases for .subckt, .ends, etc. 2. First numparam pass: substitute paramterized tokens by intermediate values 1000000001 etc. 3. Make a list node[] of global nodes 4. Clean up parens around netnames 5. Call doit, which does the actual translation. 6. Second numparam pass: Do final substitution 7. Check the results & return. inp_subcktexpand takes as argument a pointer to deck, and it returns a pointer to the same deck after the new subcircuits are spliced in. -------------------------------------------------------------------*/ struct line * inp_subcktexpand(struct line *deck) { struct line *ll, *c; char *s; int ok = 0; char *t; int i; wordlist *wl; modnames = NULL; if(!cp_getvar("substart", CP_STRING, start)) (void) strcpy(start, ".subckt"); if(!cp_getvar("subend", CP_STRING, sbend)) (void) strcpy(sbend, ".ends"); if(!cp_getvar("subinvoke", CP_STRING, invoke)) (void) strcpy(invoke, "x"); if(!cp_getvar("modelcard", CP_STRING, model)) (void) strcpy(model, ".model"); if(!cp_getvar("modelline", CP_STRING, model)) (void) strcpy(model, ".model"); nobjthack = cp_getvar("nobjthack", CP_BOOL, NULL); use_numparams = cp_getvar("numparams", CP_BOOL, NULL); use_numparams = TRUE; /* deck has .control sections already removed, but not comments */ if ( use_numparams ) { #ifdef TRACE fprintf(stderr,"Numparams is processing this deck:\n"); c=deck; while( c!=NULL) { fprintf(stderr,"%3d:%s\n",c->li_linenum, c->li_line); c= c->li_next; } #endif /* TRACE */ ok = nupa_signal( NUPADECKCOPY, NULL); /* get the subckt/model names from the deck */ c=deck; while ( c != NULL) { /* first Numparam pass */ if ( ciprefix( ".subckt", c->li_line ) ) nupa_scan(c->li_line, c->li_linenum, TRUE); if ( ciprefix( ".model", c->li_line ) ) nupa_scan(c->li_line, c->li_linenum, FALSE); c= c->li_next; } c=deck; while ( c != NULL) { /* first Numparam pass */ c->li_line = nupa_copy(c->li_line, c->li_linenum); c= c->li_next; } /* now copy instances */ #ifdef TRACE fprintf(stderr,"Numparams transformed deck:\n"); c=deck; while( c!=NULL) { fprintf(stderr,"%3d:%s\n",c->li_linenum, c->li_line); c= c->li_next; } #endif /* TRACE */ } /* Get all the model names so we can deal with BJTs, etc. * Stick all the model names into the doubly-linked wordlist modnames. */ for (c = deck; c; c = c->li_next) if (ciprefix(model, c->li_line)) { s = c->li_line; txfree(gettok(&s)); /* discard the model keyword */ wl = alloc(struct wordlist); wl->wl_next = modnames; if (modnames) modnames->wl_prev = wl; modnames = wl; wl->wl_word = gettok(&s); /* wl->wl_word now holds name of model */ }/*model name finding routine*/ #ifdef TRACE { wordlist * w; printf("Models found:\n"); for(w = modnames; w; w = w->wl_next) printf("%s\n",w->wl_word); } #endif /* TRACE */ /* Added by H.Tanaka to find global nodes */ for(i=0;i<128;i++) strcpy(node[i],"");/* Clear global node holder */ for (c = deck; c; c = c->li_next) { if (ciprefix(".global", c->li_line)) { s = c->li_line; txfree(gettok(&s)); numgnode=0; while(*s) { i=0; t=s; for (/*s*/; *s && !isspace(*s); s++) i++; strncpy(node[numgnode], t, (size_t) i); if(i>0 && t[i-1] != '\0') node[numgnode][i] = '\0'; while (isspace(*s)) s++; numgnode++; } /* node[] holds name of global node */ #ifdef TRACE printf("***Global node option has been found.***\n"); for(i=0;ili_line[0] = '*'; /* comment it out */ }/* if(ciprefix.. */ } /* for(c=deck.. */ /* Let's do a few cleanup things... Get rid of ( ) around node lists... */ for (c = deck; c; c = c->li_next) { /* iterate on lines in deck */ char *s = c->li_line; if(*s == '*') /* skip comment */ continue; if (ciprefix(start, s)) { /* if we find .subckt . . . */ #ifdef TRACE /* SDB debug statement */ printf("In inp_subcktexpand, found a .subckt: %s\n", s); #endif while (*s && *s != '(') /* search opening paren */ s++; if (*s == '(') { int level = 0; do { /* strip outer parens '(' ')', just the first pair */ if(*s == '(' && level++ == 0) { *s = ' '; } if(*s == ')' && --level == 0) { *s = ' '; break; } } while(*s++); } } else if (*s=='.') { continue; /* skip .commands */ } else { /* any other line . . . */ while (*s && !isspace(*s)) /* skip first token */ s++; while (*s && isspace(*s)) /* skip whitespace */ s++; if (*s == '(') { int level = 0; do { /* strip outer parens '(' ')', just the first pair, why ? */ if(*s == '(' && level++ == 0) { *s = ' '; } if(*s == ')' && --level == 0) { *s = ' '; break; } } while(*s++); } /* if (*s == '(' . . . */ } /* any other line */ } /* for (c = deck . . . */ /* doit does the actual splicing in of the .subckt . . . */ #ifdef TRACE /* SDB debug statement */ printf("In inp_subcktexpand, about to call doit.\n"); #endif /* TRACE */ ll = doit(deck); /* SJB: free up the modnames linked list now we are done with it */ if(modnames != NULL) { wl_free(modnames); modnames = NULL; } /* Count numbers of line in deck after expansion */ if (ll!=NULL) { dynMaxckt = 0; /* number of lines in deck after expansion */ for (c = ll; c; c = c->li_next) dynMaxckt++; } /* Now check to see if there are still subckt instances undefined... */ if (ll!=NULL) { for (c = ll; c; c = c->li_next) { if (ciprefix(invoke, c->li_line)) { fprintf(cp_err, "Error: unknown subckt: %s\n", c->li_line); if ( use_numparams ) { ok = ok && nupa_signal(NUPAEVALDONE, NULL); } return NULL; } } } if ( use_numparams ) { /* the NUMPARAM final line translation pass */ ok= ok && nupa_signal(NUPASUBDONE, NULL); c= ll; while (c != NULL) { /* 'param' .meas statements can have dependencies on measurement values */ /* need to skip evaluating here and evaluate after other .meas statements */ if ( ciprefix( ".meas", c->li_line ) ) { if ( !strstr( c->li_line, "param" ) ) nupa_eval( c->li_line, c->li_linenum, c->li_linenum_orig); } else { nupa_eval( c->li_line, c->li_linenum, c->li_linenum_orig); } c= c->li_next; } #ifdef TRACE fprintf(stderr,"Numparams converted deck:\n"); c=ll; while( c!=NULL) { fprintf(stderr,"%3d:%s\n",c->li_linenum, c->li_line); c= c->li_next; } #endif /* TRACE */ /*nupa_list_params(stdout);*/ nupa_copy_inst_dico(); ok= ok && nupa_signal(NUPAEVALDONE, NULL); } return (ll); /* return the spliced deck. */ } #define MAXNEST 21 /*-------------------------------------------------------------------*/ /* doit does the actual substitution of .subckts. */ /* It takes two passes: the first extracts .subckts */ /* and sticks pointer to them into the linked list sss. It does */ /* the extraction recursively. Then, it look for subcircuit */ /* invocations and substitutes the stored .subckt into */ /* the main circuit file. */ /* It takes as argument a pointer to the deck, and returns a */ /* pointer to the deck after the subcircuit has been spliced in. */ /*-------------------------------------------------------------------*/ static struct line * doit(struct line *deck) { struct line *c, *last, *lc, *lcc; struct line *savenext; struct subs *sssfree = NULL, *sss = NULL, *ks; /* *sss and *ks temporarily hold decks to substitute */ char *s, *t, *scname, *subname; int nest, numpasses = MAXNEST, i; bool gotone; wordlist *tmodnames = modnames; wordlist *tsubmod = submod; struct subs *ts = subs; int error; /* Save all the old stuff... */ subs = NULL; submod = NULL; #ifdef TRACE /* SDB debug statement */ printf("In doit, about to start first pass through deck.\n"); for(c=deck;c; c=c->li_next) printf(" %s\n",c->li_line); #endif /* First pass: xtract all the .subckts and stick pointers to them into sss. */ for (last = deck, lc = NULL; last; ) { if (ciprefix(sbend, last->li_line)) { /* if line == .ends */ fprintf(cp_err, "Error: misplaced %s line: %s\n", sbend, last->li_line); return (NULL); } else if (ciprefix(start, last->li_line)) { /* if line == .subckt */ if (last->li_next == NULL) { /* first check that next line is non null */ fprintf(cp_err, "Error: no %s line.\n", sbend); return (NULL); } lcc = NULL; wl_free(submod); submod = NULL; gotone = FALSE; /* Here we loop through the deck looking for .subckt and .ends cards. * At the end of this section, last will point to the location of the * .subckt card, and lcc will point to the location of the .ends card. */ for (nest = 0, c = last->li_next; c; c = c->li_next) { if (ciprefix(sbend, c->li_line)) { /* found a .ends */ if (!nest) break; /* nest = 0 means we have balanced .subckt and .ends */ else { nest--; /* decrement nesting, and assign lcc to the current card */ lcc = c; /* (lcc points to the position of the .ends) */ continue; /* then continue looping */ } } else if (ciprefix(start, c->li_line)) /* if .subckt, increment nesting */ nest++; lcc = c; /* lcc points to current pos of c */ } /* for (nest = 0 . . . */ /* Check to see if we have looped through remainder of deck without finding .ends */ if (!c) { fprintf(cp_err, "Error: no %s line.\n", sbend); return (NULL); } sssfree = sss = alloc(struct subs); if (!lcc) /* if lcc is null, then no .ends was found. */ lcc = last; if ( use_numparams==FALSE ) lcc->li_next = NULL; /* shouldn't we free some memory here????? */ /* At this point, last points to the .subckt card, and lcc points to the .ends card */ /* what does this do!??!?! */ if (lc) lc->li_next = c->li_next; else deck = c->li_next; /* Now put the .subckt definition found into sss */ sss->su_def = last->li_next; s = last->li_line; txfree(gettok(&s)); sss->su_name = gettok(&s); sss->su_args = copy(s); /* count the number of args in the .subckt line */ for (sss->su_numargs = 0, i = 0; s[i]; ) { while (isspace(s[i])) i++; if (s[i]) { sss->su_numargs++; while (s[i] && !isspace(s[i])) i++; } } sss->su_next = subs; subs = sss; /* Now that sss is built, assign it to subs */ last = c->li_next; lcc = subs->su_def; /*gp */ c->li_next = NULL; /* Numparam needs line c */ c->li_line[0] = '*'; /* comment it out */ } else { /* line is neither .ends nor .subckt. */ /* make lc point to this card, and advance last to next card. */ lc = last; last = last->li_next; } } /* for (last = deck . . . . */ /* At this point, sss holds the .subckt definition found, subs holds * all .subckt defs found, including this one, * last points to the NULL at the end of the deck, * lc points to the last non-.subckt or .ends card, * and lcc points to the .ends card */ if (!sss) /* if sss == FALSE, we have found no subckts. Just return. */ return (deck); /* Otherwise, expand sub-subcircuits recursively. */ for (ks = sss = subs; sss; sss = sss->su_next) /* iterate through the list of subcircuits */ if ((sss->su_def = doit(sss->su_def)) == NULL) return (NULL); subs = ks; /* ks has held pointer to start of subcircuits list. */ #ifdef TRACE /* SDB debug statement */ printf("In doit, about to start second pass through deck.\n"); for(c=deck;c; c=c->li_next) printf(" %s\n",c->li_line); #endif error = 0; /* Second pass: do the replacements. */ do { /* while (!error && numpasses-- && gotone) */ gotone = FALSE; for (c = deck, lc = NULL; c; ) { if (ciprefix(invoke, c->li_line)) { /* found reference to .subckt (i.e. component with refdes X) */ char *tofree, *tofree2; gotone = TRUE; t = tofree = s = copy(c->li_line); /* s & t hold copy of component line */ /* make scname point to first non-whitepace chars after refdes invocation * e.g. if invocation is Xreference, *scname = reference */ tofree2 = scname = gettok(&s); /*scname += strlen(invoke); */ while ((*scname == ' ') || (*scname == '\t') || (*scname == ':')) scname++; /* Now set s to point to last non-space chars in line (i.e. * the name of the model invoked */ while(*s) s++; s--; while ((*s == ' ') || (*s == '\t')) *s-- = '\0'; while ((*s != ' ') && (*s != '\t')) s--; s++; /* iterate through .subckt list and look for .subckt name invoked */ for (sss = subs; sss; sss = sss->su_next) if (eq(sss->su_name, s)) break; /* At this point, sss points to the .subckt invoked, * and scname points to the netnames * involved. */ /* If no .subckt is found, don't complain -- this might be an * instance of a subckt that is defined above at higher level. */ if (!sss) { lc = c; c = c->li_next; continue; } /* Now we have to replace this line with the * macro definition. */ subname = copy(sss->su_name); /* make lcc point to a copy of the .subckt definition */ lcc = inp_deckcopy(sss->su_def); /* Change the names of .models found in .subckts . . . */ if (modtranslate(lcc, scname)) /* this translates the model name in the .model line */ devmodtranslate(lcc, scname); /* This translates the model name on all components in the deck */ s = sss->su_args; txfree(gettok(&t)); /* Throw out the subcircuit refdes */ /* now invoke translate, which handles the remainder of the * translation. */ if (!translate(lcc, s, t, scname, subname)) error = 1; tfree(subname); /* Now splice the decks together. */ savenext = c->li_next; if ( use_numparams==FALSE ) { /* old style: c will drop a dangling pointer: memory leak */ if (lc) lc->li_next = lcc; else deck = lcc; } else { /* ifdef NUMPARAMS, keep the invoke line as a comment */ c->li_next = lcc; c->li_line[0] = '*'; /* comment it out */ } while (lcc->li_next != NULL) lcc = lcc->li_next; lcc->li_next = c->li_next; lcc->li_next = savenext; c = lcc->li_next; lc = lcc; tfree(tofree); tfree(tofree2); } /* if (ciprefix(invoke, c->li_line)) . . . */ else { lc = c; c = c->li_next; } } } while (!error && numpasses-- && gotone); if (!numpasses) { fprintf(cp_err, "Error: infinite subckt recursion\n"); return (NULL); } #ifdef TRACE /* Added by H.Tanaka to display converted deck */ printf("Converted deck\n"); for (c = deck; c; c = c->li_next){ printf( "%s\n",c->li_line); } { wordlist * w; printf("Models:\n"); for(w = modnames; w; w = w->wl_next) printf("%s\n",w->wl_word); } #endif if (error) return NULL; /* error message already reported; should free( ) */ subs = ts; modnames = tmodnames; submod = tsubmod; /* struct subs { char *su_name; char *su_args; int su_numargs; struct line *su_def; struct subs *su_next; } ; */ while(sssfree) { struct subs *sss2 = sssfree; sssfree = sssfree->su_next; tfree(sss2->su_name); tfree(sss2->su_args); line_free(sss2->su_def, TRUE); tfree(sss2); } return (deck); } /*-------------------------------------------------------------------*/ /* Copy a deck, including the actual lines. */ /*-------------------------------------------------------------------*/ struct line * inp_deckcopy(struct line *deck) { struct line *d = NULL, *nd = NULL; while (deck) { if (nd) { d->li_next = alloc(struct line); d = d->li_next; } else nd = d = alloc(struct line); d->li_linenum = deck->li_linenum; d->li_line = copy(deck->li_line); if (deck->li_error) d->li_error = copy(deck->li_error); d->li_actual = inp_deckcopy(deck->li_actual); deck = deck->li_next; } return (nd); } /*------------------------------------------------------------------- * struct bxx_buffer, * a string assembly facility. * * usage: * * struct bxx_buffer thing; * bxx_init(&thing); * ... * while(...) { * bxx_rewind(&thing); * ... * bxx_putc(&thing, ...) * bxx_printf(&thing, ...) * bxx_put_cstring(&thing, ...) * bxx_put_substring(&thing, ...) * ... * strcpy(bxx_buffer(&thing) * } * .. * bxx_free(&thing) * * main aspect: * reallocates/extends its buffer itself. * * note: * during asssembly the internal buffer is * not necessarily '\0' terminated. * but will be when bxx_buffer() is invoked */ struct bxx_buffer { char *dst; char *limit; char *buffer; }; /* must be a power of 2 */ static const int bxx_chunksize = 1024; static void bxx_init(struct bxx_buffer *t) { /* assert(0 == (bxx_chunksize & (bxx_chunksize - 1))); */ t->buffer = TMALLOC(char, bxx_chunksize); t->dst = t->buffer; t->limit = t->buffer + bxx_chunksize; } static void bxx_free(struct bxx_buffer *t) { tfree(t->buffer); } static void bxx_rewind(struct bxx_buffer *t) { t->dst = t->buffer; } static void bxx_extend(struct bxx_buffer *t, int howmuch) { int pos = (int)(t->dst - t->buffer); int len = (int)(t->limit - t->buffer); /* round up */ howmuch += (bxx_chunksize - 1); howmuch &= ~(bxx_chunksize - 1); len += howmuch; t->buffer = TREALLOC(char, t->buffer, len); t->dst = t->buffer + pos; t->limit = t->buffer + len; } static void bxx_printf(struct bxx_buffer *t, const char *fmt, ...) { va_list ap; for (;;) { int ret; int size = (int)(t->limit - t->dst); va_start(ap, fmt); ret = vsnprintf(t->dst, (size_t) size, fmt, ap); va_end(ap); if(ret == -1) { bxx_extend(t, bxx_chunksize); } else if(ret >= size) { bxx_extend(t, ret - size + 1); } else { t->dst += ret; break; } } va_end(ap); } static inline char bxx_putc(struct bxx_buffer *t, char c) { if(t->dst >= t->limit) bxx_extend(t, 1); return *(t->dst)++ = c; } static void bxx_put_cstring(struct bxx_buffer *t, const char *cstring) { while(*cstring) bxx_putc(t, *cstring++); } static void bxx_put_substring(struct bxx_buffer *t, const char *str, const char *end) { while(str < end) bxx_putc(t, *str++); } static char * bxx_buffer(struct bxx_buffer *t) { if((t->dst == t->buffer) || (t->dst[-1] != '\0')) bxx_putc(t, '\0'); return t->buffer; } /*------------------------------------------------------------------------------------------* * Translate all of the device names and node names in the .subckt deck. They are * pre-pended with subname:, unless they are in the formal list, in which case * they are replaced with the corresponding entry in the actual list. * The one special case is node 0 -- this is always ground and we don't * touch it. * * Variable name meanings: * *deck = pointer to subcircuit definition (lcc) (struct line) * formal = copy of the .subckt definition line (e.g. ".subckt subcircuitname 1 2 3") (string) * actual = copy of the .subcircuit invocation line (e.g. "Xexample 4 5 6 subcircuitname") (string) * scname = refdes (- first letter) used at invocation (e.g. "example") (string) * subname = copy of the subcircuit name *-------------------------------------------------------------------------------------------*/ static int translate(struct line *deck, char *formal, char *actual, char *scname, char *subname) { struct line *c; struct bxx_buffer buffer; char *next_name, dev_type, *name, *s, *t, ch, *nametofree, *paren_ptr, *new_str; int nnodes, i, dim; int rtn=0; bxx_init(&buffer); /* settrans builds the table holding the translated netnames. */ i = settrans(formal, actual, subname); if (i < 0) { fprintf(stderr, "Too few parameters for subcircuit type \"%s\" (instance: x%s)\n", subname, scname); goto quit; } else if (i > 0) { fprintf(stderr, "Too many parameters for subcircuit type \"%s\" (instance: x%s)\n", subname, scname); goto quit; } /* now iterate through the .subckt deck and translate the cards. */ for (c = deck; c; c = c->li_next) { dev_type = *(c->li_line); #ifdef TRACE /* SDB debug statement */ printf("\nIn translate, examining line (dev_type: %c, subname: %s, instance: %s) %s \n", dev_type, subname, scname, c->li_line ); #endif if ( ciprefix( ".ic", c->li_line ) || ciprefix( ".nodeset", c->li_line ) ) { paren_ptr = s = c->li_line; while ( ( paren_ptr = strstr( paren_ptr, "(" ) ) != NULL) { *paren_ptr = '\0'; paren_ptr++; name = paren_ptr; if ( ( paren_ptr = strstr( paren_ptr, ")" ) ) == NULL) { *(name-1) = '('; fprintf(cp_err, "Error: missing closing ')' for .ic|.nodeset statement %s\n", c->li_line); goto quit; } *paren_ptr = '\0'; t = gettrans(name, NULL); if (t) { new_str = TMALLOC(char, strlen(s) + strlen(t) + strlen(paren_ptr + 1) + 3); sprintf( new_str, "%s(%s)%s", s, t, paren_ptr+1 ); } else { new_str = TMALLOC(char, strlen(s) + strlen(scname) + strlen(name) + strlen(paren_ptr + 1) + 4); sprintf( new_str, "%s(%s.%s)%s", s, scname, name, paren_ptr+1 ); } paren_ptr = new_str + strlen(s) + 1; tfree(s); s = new_str; } c->li_line = s; continue; } /* Rename the device. */ switch (dev_type) { case '\0': case '*': case '$': case '.': /* Just a pointer to the line into s and then break */ bxx_rewind(&buffer); s = c->li_line; break; #ifdef XSPICE /*=================== case A ====================*/ /* gtri - add - wbk - 10/23/90 - process A devices specially */ /* since they have a more involved and variable length node syntax */ case 'a': case 'A': /* translate the instance name according to normal rules */ s = c->li_line; name = MIFgettok(&s); bxx_rewind(&buffer); bxx_printf(&buffer, "a.%s.%s ", scname, name ); /* Now translate the nodes, looking ahead one token to recognize */ /* when we reach the model name which should not be translated */ /* here. */ next_name = MIFgettok(&s); for (;;) { /* rotate the tokens and get the the next one */ name = next_name; next_name = MIFgettok(&s); /* if next token is NULL, name holds the model name, so exit */ if(next_name == NULL) break; /* Process the token in name. If it is special, then don't */ /* translate it. */ switch(*name) { case '[': case ']': case '~': bxx_printf(&buffer, "%s ", name); break; case '%': bxx_printf(&buffer, "%%"); /* don't translate the port type identifier */ name = next_name; next_name = MIFgettok(&s); bxx_printf(&buffer, "%s ", name); break; default: /* must be a node name at this point, so translate it */ t = gettrans(name, NULL); if (t) { bxx_printf(&buffer, "%s ", t); } else { if(name[0]=='v' || name[0]=='V') { bxx_printf(&buffer, "v.%s.%s ", scname, name); } else { bxx_printf(&buffer, "%s.%s ", scname, name); } } break; } /* switch */ } /* while */ /* copy in the last token, which is the model name */ if(name) { bxx_printf(&buffer, "%s ", name); } /* Set s to null string for compatibility with code */ /* after switch statement */ s = ""; break; /* case 'a' */ /* gtri - end - wbk - 10/23/90 */ #endif /*================ case E, F, G, H ================*/ /* This section handles controlled sources and allows for SPICE2 POLY attributes. * This is a new section, added by SDB to handle POLYs in sources. Significant * changes were made in here. * 4.21.2003 -- SDB. mailto:sdb@cloud9.net */ case 'E': case 'e': case 'F': case 'f': case 'G': case 'g': case 'H': case 'h': s = c->li_line; /* s now holds the SPICE line */ t = name = gettok(&s); /* name points to the refdes */ if (!name) continue; if (!*name) { tfree(name); continue; } /* Here's where we translate the refdes to e.g. F:subcircuitname:57 * and stick the translated name into buffer. */ ch = *name; /* ch identifies the type of component */ bxx_rewind(&buffer); bxx_printf(&buffer, "%c.%s.%s ", ch, scname, name); tfree(t); /* Next iterate over all nodes (netnames) found and translate them. */ nnodes = numnodes(c->li_line); while (nnodes-- > 0) { name = gettok_node(&s); if (name == NULL) { fprintf(cp_err, "Error: too few nodes: %s\n", c->li_line); goto quit; } /* call gettrans and see if netname was used in the invocation */ t = gettrans(name, NULL); if (t) { /* the netname was used during the invocation; print it into the buffer */ bxx_printf(&buffer, "%s ", t); } else { /* net netname was not used during the invocation; place a * translated name into the buffer.*/ bxx_printf(&buffer, "%s.%s ", scname, name); } tfree(name); } /* while (nnodes-- . . . . */ /* Next we handle the POLY (if any) */ /* get next token */ t = s; next_name = (char *)gettok_noparens(&t); if ( (strcmp(next_name, "POLY") == 0) || (strcmp(next_name, "poly") == 0)) { /* found POLY . . . . */ #ifdef TRACE /* SDB debug statement */ printf("In translate, looking at e, f, g, h found poly\n"); #endif /* move pointer ahead of ( */ if( get_l_paren(&s) == 1 ) { fprintf(cp_err, "Error: no left paren after POLY %s\n", c->li_line); tfree(next_name); goto quit; } nametofree = gettok_noparens(&s); dim = atoi(nametofree); /* convert returned string to int */ tfree(nametofree); /* move pointer ahead of ) */ if( get_r_paren(&s) == 1 ) { fprintf(cp_err, "Error: no right paren after POLY %s\n", c->li_line); tfree(next_name); goto quit; } /* Write POLY(dim) into buffer */ bxx_printf(&buffer, "POLY( %d ) ", dim); } /* if ( (strcmp(next_name, "POLY") == 0) . . . */ else dim = 1; /* only one controlling source . . . */ tfree(next_name); /* Now translate the controlling source/nodes */ nnodes = dim * numdevs(c->li_line); while (nnodes-- > 0) { nametofree = name = gettok_node(&s); /* name points to the returned token */ if (name == NULL) { fprintf(cp_err, "Error: too few devs: %s\n", c->li_line); goto quit; } if ( (dev_type == 'f') || (dev_type == 'F') || (dev_type == 'h') || (dev_type == 'H') ) { /* Handle voltage source name */ #ifdef TRACE /* SDB debug statement */ printf("In translate, found type f or h\n"); #endif ch = *name; /* ch is the first char of the token. */ bxx_printf(&buffer, "%c.%s.%s ", ch, scname, name); /* From Vsense and Urefdes creates V.Urefdes.sense */ } else { /* Handle netname */ #ifdef TRACE /* SDB debug statement */ printf("In translate, found type e or g\n"); #endif /* call gettrans and see if netname was used in the invocation */ t = gettrans(name, NULL); if (t) { /* the netname was used during the invocation; print it into the buffer */ bxx_printf(&buffer, "%s ", t); } else { /* net netname was not used during the invocation; place a * translated name into the buffer. */ bxx_printf(&buffer, "%s.%s ", scname, name); /* From netname and Urefdes creates Urefdes:netname */ } } tfree(nametofree); } /* while (nnodes--. . . . */ /* Now write out remainder of line (polynomial coeffs) */ finishLine(&buffer, s, scname); s = ""; break; /*================= Default case ===================*/ default: /* this section handles ordinary components */ s = c->li_line; nametofree = name = gettok_node(&s); /* changed to gettok_node to handle netlists with ( , ) */ if (!name) continue; if (!*name) { tfree(name); continue; } /* Here's where we translate the refdes to e.g. R:subcircuitname:57 * and stick the translated name into buffer. */ ch = *name; bxx_rewind(&buffer); if ( ch != 'x' ) { bxx_printf(&buffer, "%c.%s.%s ", ch, scname, name); } else { bxx_printf(&buffer, "%s.%s ", scname, name); } tfree(nametofree); /* Next iterate over all nodes (netnames) found and translate them. */ nnodes = numnodes(c->li_line); while (nnodes-- > 0) { name = gettok_node(&s); if (name == NULL ) { fprintf(cp_err, "Error: too few nodes: %s\n", c->li_line); goto quit; } /* call gettrans and see if netname was used in the invocation */ t = gettrans(name, NULL); if (t) { /* the netname was used during the invocation; print it into the buffer */ bxx_printf(&buffer, "%s ", t); } else { /* net netname was not used during the invocation; place a * translated name into the buffer. */ bxx_printf(&buffer, "%s.%s ", scname, name); } tfree(name); } /* while (nnodes-- . . . . */ /* Now translate any devices (i.e. controlling sources). * This may be superfluous because we handle dependent * source devices above . . . . */ nnodes = numdevs(c->li_line); while (nnodes-- > 0) { t = name = gettok_node(&s); if (name == NULL) { fprintf(cp_err, "Error: too few devs: %s\n", c->li_line); goto quit; } ch = *name; if ( ch != 'x' ) { bxx_printf(&buffer, "%c.%s.%s ", ch, scname, name); } else { bxx_printf(&buffer, "%s ", scname); } tfree(t); } /* while (nnodes--. . . . */ /* Now we finish off the line. For most components (R, C, etc), * this involves adding the component value to the buffer. * We also scan through the line for v(something) and * i(something)... */ finishLine(&buffer, s, scname); s = ""; } /* switch(c->li_line . . . . */ bxx_printf(&buffer, "%s", s); tfree(c->li_line); c->li_line = copy(bxx_buffer(&buffer)); #ifdef TRACE /* SDB debug statement */ printf("In translate, translated line = %s \n", c->li_line); #endif } /* for (c = deck . . . . */ rtn = 1; quit: for (i = 0; ; i++) { if(!table[i].t_old && !table[i].t_new) break; FREE(table[i].t_old); FREE(table[i].t_new); } bxx_free(&buffer); return rtn; } /*-------------------------------------------------------------------* * finishLine now doesn't handle current or voltage sources. * Therefore, it just writes out the final netnames, if required. * Changes made by SDB on 4.29.2003. *-------------------------------------------------------------------*/ static void finishLine(struct bxx_buffer *t, char *src, char *scname) { char *buf, *buf_end, which; char *s; int lastwasalpha; lastwasalpha = 0; while (*src) { /* Find the next instance of "[vi](" in * this string. */ if (((*src != 'v') && (*src != 'V') && (*src != 'i') && (*src != 'I')) || lastwasalpha) { lastwasalpha = isalpha(*src); bxx_putc(t, *src++); continue; } for (s = src + 1; *s && isspace(*s); s++) ; if (!*s || (*s != '(')) { lastwasalpha = isalpha(*src); bxx_putc(t, *src++); continue; } lastwasalpha = 0; bxx_putc(t, which = *src); src = s; bxx_putc(t, *src++); while (isspace(*src)) src++; for (buf = src; *src && !isspace(*src) && *src != ',' && (*src != ')'); ) { src++; } buf_end = src; if ((which == 'v') || (which == 'V')) s = gettrans(buf, buf_end); else s = NULL; if (s) { bxx_put_cstring(t, s); } else { /* just a normal netname . . . . */ /* i(vname) -> i(v.subckt.vname) i(ename) -> i(e.subckt.ename) i(hname) -> i(h.subckt.hname) i(bname) -> i(b.subckt.hname) */ if ((which == 'i' || which == 'I') && (buf[0] == 'v' || buf[0] == 'V' || buf[0] == 'e' || buf[0] == 'h' || buf[0] == 'b' || buf[0] == 'B')) { bxx_putc(t, buf[0]); bxx_putc(t, '.'); /*i = 1; */ } /* else { i = 0; } */ bxx_put_cstring(t, scname); bxx_putc(t, '.'); bxx_put_substring(t, buf, buf_end); } /* translate the reference node, as in the "2" in "v(4,2)" */ if ((which == 'v') || (which == 'V')) { while (*src && (isspace(*src) || *src == ',')) { src++; } if (*src && *src != ')') { for (buf = src; *src && !isspace(*src) && (*src != ')'); ) src++; s = gettrans(buf, buf_end = src); bxx_putc(t, ','); if (s) { bxx_put_cstring(t, s); } else { bxx_put_cstring(t, scname); bxx_putc(t, '.'); bxx_put_substring(t, buf, buf_end); } } } } } /*------------------------------------------------------------------------------* * settrans builds the table which holds the old and new netnames. * it also compares the number of nets present in the .subckt definition against * the number of nets present in the subcircuit invocation. It returns 0 if they * match, otherwise, it returns an error. * * Variable definitions: * formal = copy of the .subckt definition line (e.g. ".subckt subcircuitname 1 2 3") (string) * actual = copy of the .subcircuit invocation line (e.g. "Xexample 4 5 6 subcircuitname") (string) * subname = copy of the subcircuit name *------------------------------------------------------------------------------*/ static int settrans(char *formal, char *actual, char *subname) { int i; bzero(table,sizeof(*table)); for (i = 0; ; i++) { table[i].t_old = gettok(&formal); table[i].t_new = gettok(&actual); if (table[i].t_new == NULL) { return -1; /* Too few actual / too many formal */ } else if (table[i].t_old == NULL) { if (eq(table[i].t_new, subname)) break; else return 1; /* Too many actual / too few formal */ } } return 0; } /* compare a substring, with a '\0' terminated string * the substring itself is required to be free of a '\0' */ static int eq_substr(const char* str, const char *end, const char *cstring) { while(str < end) if(*str++ != *cstring++) return 0; return (*cstring == '\0'); } /*------------------------------------------------------------------------------* * gettrans returns the name of the top level net if it is in the list, * otherwise it returns NULL. *------------------------------------------------------------------------------*/ static char * gettrans(const char *name, const char *name_end) { int i; if(!name_end) name_end = strchr(name, '\0'); #ifdef XSPICE /* gtri - wbk - 2/27/91 - don't translate the reserved word 'null' */ if (eq_substr(name, name_end, "null")) return ("null"); /* gtri - end */ #endif /* Added by H.Tanaka to translate global nodes */ for(i=0;i.[0-9]+ */ static bool model_bin_match( char* token, char* model_name ) { char* dot_char; bool flag = FALSE; /* continue evaluation if toeken is part of model_name */ if ( strncmp( model_name, token, strlen(token) ) == 0 ) { /* find last dot in model_name */ if ( (dot_char = strrchr( model_name, '.' )) != NULL ) { flag = TRUE; dot_char++; while( *dot_char != '\0' ) { if ( !isdigit( *dot_char ) ) { flag = FALSE; break; } dot_char++; } } } return flag; } /*-------------------------------------------------------------------*/ /*-------------------------------------------------------------------*/ static int numnodes(char *name) { /* gtri - comment - wbk - 10/23/90 - Do not modify this routine for */ /* 'A' type devices since the callers will not know how to find the */ /* nodes even if they know how many there are. Modify the callers */ /* instead. */ /* gtri - end - wbk - 10/23/90 */ char c; struct subs *sss; char *s, *t, buf[4 * BSIZE_SP]; wordlist *wl; int n, i, gotit; while (*name && isspace(*name)) name++; c = *name; if(isupper(c)) c = (char) tolower(c); (void) strncpy(buf, name, sizeof(buf)); s = buf; if (c == 'x') { /* Handle this ourselves. */ while(*s) s++; s--; while ((*s == ' ') || (*s == '\t')) *s-- = '\0'; while ((*s != ' ') && (*s != '\t')) s--; s++; for (sss = subs; sss; sss = sss->su_next) if (eq(sss->su_name, s)) break; if (!sss) { fprintf(cp_err, "Error: no such subcircuit: %s\n", s); return (0); } return (sss->su_numargs); } n = inp_numnodes(c); /* Added this code for variable number of nodes on BSIM3SOI/CPL devices */ /* The consequence of this code is that the value returned by the */ /* inp_numnodes(c) call must be regarded as "maximum number of nodes */ /* for a given device type. */ /* Paolo Nenzi Jan-2001 */ /* I hope that works, this code is very very untested */ if ((c=='m') || (c=='p')) { /* IF this is a mos or cpl */ i = 0; s = buf; gotit = 0; txfree(gettok(&s)); /* Skip component name */ while ((i < n) && (*s) && !gotit) { t = gettok_node(&s); /* get nodenames . . . */ for (wl = modnames; wl; wl = wl->wl_next) { /* also need to check if binnable device mos model */ if (eq(t, wl->wl_word) || model_bin_match( t, wl->wl_word ) ) gotit = 1; } i++; tfree(t); } /* while . . . . */ /* Note: node checks must be done on #_of_node-1 because the */ /* "while" cycle increments the counter even when a model is */ /* recognized. This code may be better! */ if (i < 5) { fprintf(cp_err, "Error: too few nodes for MOS or CPL: %s\n", name); return(0); } return(i-1); /* compensate the unnecessary increment in the while cycle */ } /* if (c=='m' . . . */ if (nobjthack || (c != 'q')) return (n); for (s = buf, i = 0; *s && (i < 4); i++) txfree(gettok(&s)); if (i == 3) return (3); else if (i < 4) { fprintf(cp_err, "Error: too few nodes for BJT: %s\n", name); return (0); } /* Now, is this a model? */ t = gettok(&s); for (wl = modnames; wl; wl = wl->wl_next) if (eq(t, wl->wl_word)) { tfree(t); return (3); } tfree(t); return (4); } /*-------------------------------------------------------------------* * This function returns the number of controlling voltage sources * (for F, H) or controlling nodes (for G, E) attached to a dependent * source. *-------------------------------------------------------------------*/ static int numdevs(char *s) { while (*s && isspace(*s)) s++; switch (*s) { case 'K': case 'k': return (2); /* two nodes per voltage controlled source */ case 'G': case 'g': case 'E': case 'e': return(2); /* one source per current controlled source */ case 'F': case 'f': case 'H': case 'h': /* 2 lines here added to fix w bug, NCF 1/31/95 */ case 'W': case 'w': return (1); default: return (0); } } /*----------------------------------------------------------------------* * modtranslate -- translates .model lines found in subckt definitions. * Calling arguments are: * *deck = pointer to the .subckt definition (linked list) * *subname = pointer to the subcircuit name used at the subcircuit invocation (string) * Modtranslate returns TRUE if it translated a model name, FALSE * otherwise. *----------------------------------------------------------------------*/ static bool modtranslate(struct line *deck, char *subname) { struct line *c; char *buffer, *name, *t, model[4 * BSIZE_SP]; wordlist *wl, *wlsub; bool gotone; (void) strcpy(model, ".model"); gotone = FALSE; for (c = deck; c; c = c->li_next) { /* iterate through model def . . . */ if (ciprefix(model, c->li_line)) { gotone = TRUE; t = c->li_line; #ifdef TRACE /* SDB debug statement */ printf("In modtranslate, translating line %s\n", t); #endif name = gettok(&t); /* at this point, name = .model */ buffer = TMALLOC(char, strlen(name) + strlen(t) + strlen(subname) + 4); (void) sprintf(buffer, "%s ",name); /* at this point, buffer = ".model " */ tfree(name); name = gettok(&t); /* name now holds model name */ wlsub = alloc(struct wordlist); wlsub->wl_next = submod; if (submod) submod->wl_prev = wlsub; /* here's where we insert the model name into the model name list */ submod = wlsub; wlsub->wl_word = name; #ifdef TRACE /* SDB debug statement */ printf("In modtranslate, sticking model name %s into submod\n", wlsub->wl_word); #endif /* now stick the new model name into the model line. */ (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); /* buffer = "model subname:modelname " */ (void) strcat(buffer, t); tfree(c->li_line); c->li_line = buffer; #ifdef TRACE /* SDB debug statement */ printf("In modtranslate, translated line= %s\n", c->li_line); #endif /* this looks like it tries to stick the translated model name into the list of model names */ t = c->li_line; txfree(gettok(&t)); wl = alloc(struct wordlist); wl->wl_next = modnames; if (modnames) modnames->wl_prev = wl; modnames = wl; wl->wl_word = gettok(&t); #ifdef TRACE /* SDB debug statement */ printf("In modtranslate, sticking model name %s into modnames\n", wl->wl_word); #endif } } return(gotone); } /*-------------------------------------------------------------------* * Devmodtranslate scans through the deck, and translates the * name of the model in a line held in a .subckt. For example: * before: .subckt U1 . . . . * Q1 c b e 2N3904 * after: Q1 c b e U1:2N3904 *-------------------------------------------------------------------*/ static void devmodtranslate(struct line *deck, char *subname) { struct line *s; char *buffer, *name, *t, c; wordlist *wlsub; bool found; char* dot_char; int i, j; char *next_name; for (s = deck; s; s = s->li_next) { t = s->li_line; #ifdef TRACE /* SDB debug stuff */ printf("In devmodtranslate, examining line %s.\n", t); #endif while (*t && isspace(*t)) t++; c = *t; /* set c to first char in line. . . . */ if(isupper(c)) c = (char) tolower(c); found = FALSE; buffer = TMALLOC(char, strlen(t) + strlen(subname) + 4); switch (c) { #ifdef XSPICE case 'a': /* Code for codemodels (dev prefix "A") added by SDB on 6.10.2004. * The algorithm is simple. We don't know how many nodes or sources are attached, * but the name of the model is always last. Therefore, just iterate through all * tokens until the last one is reached. Then translate it. */ #ifdef TRACE /* SDB debug statement */ printf("In devmodtranslate, found codemodel, line= %s\n", t); #endif /* first do refdes. */ name = gettok(&t); /* get refdes */ (void) sprintf(buffer,"%s ",name); tfree(name); /* now do remainder of line. */ next_name = gettok(&t); for (;;) { name = next_name; next_name = gettok(&t); if(next_name == NULL) { /* if next_name is NULL, we are at the line end. * name holds the model name. Therefore, break */ break; } else { /* next_name holds something. Write name into the buffer and continue. */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); } } /* while */ /* Now, is name a subcircuit model? * Note that we compare against submod = untranslated names of models. */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { #ifdef TRACE /* SDB debug statement */ printf("In devmodtranslate, comparing model name against submod list item %s\n", wlsub->wl_word ); #endif if (eq(name, wlsub->wl_word)) { (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } if (!found) (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); #ifdef TRACE /* SDB debug statement */ printf("In devmodtranslate, translated codemodel line= %s\n", buffer); #endif (void) strcat(buffer, t); tfree(s->li_line); s->li_line = buffer; break; #endif /* XSPICE */ case 'r': case 'c': name = gettok(&t); /* get refdes */ (void) sprintf(buffer,"%s ",name); tfree(name); name = gettok_node(&t); /* get first netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* get second netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); if (*t) { /* if there is a model, process it. . . . */ name = gettok(&t); /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } if (!found) (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); } found = FALSE; if (*t) { name = gettok(&t); /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } if (!found) (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); } (void) strcat(buffer, t); tfree(s->li_line); s->li_line = buffer; break; case 'd': name = gettok(&t); /* get refdes */ (void) sprintf(buffer,"%s ",name); tfree(name); name = gettok_node(&t); /* get first attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* get second attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok(&t); /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } if (!found) (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); (void) strcat(buffer, t); tfree(s->li_line); s->li_line = buffer; break; #if ADMS >= 3 case 'u': /* urc transmissionline */ /* hijacked for adms */ name = gettok_node(&t); /* this can be either a model name or a node name. */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { /* a three terminal bjt */ (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } while (!found) { (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* this can be either a model name or a node name. */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { /* a three terminal bjt */ (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } } found = FALSE; (void) strcat(buffer, t); tfree(s->li_line); s->li_line = buffer; break; #else case 'u': /* urc transmissionline */ #endif /* 3 terminal devices */ case 'w': /* current controlled switch */ case 'j': /* jfet */ case 'z': /* hfet, mesa */ name = gettok(&t); (void) sprintf(buffer,"%s ",name); name = gettok(&t); (void) sprintf(buffer + strlen(buffer), "%s ", name); name = gettok(&t); (void) sprintf(buffer + strlen(buffer), "%s ", name); name = gettok(&t); (void) sprintf(buffer + strlen(buffer), "%s ", name); name = gettok(&t); /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } if (!found) (void) sprintf(buffer + strlen(buffer), "%s ", name); (void) strcat(buffer, t); tfree(s->li_line); s->li_line = buffer; break; /* 4 terminal devices */ case 'm': case 'o': /* ltra */ case 's': /* vc switch */ case 'y': /* txl */ /* Changed gettok() to gettok_node() on 12.2.2003 by SDB to enable parsing lines like "S1 10 11 (80,51) SLATCH1" which occur in real Analog Devices SPICE models. */ name = gettok(&t); /* get refdes */ (void) sprintf(buffer,"%s ",name); tfree(name); name = gettok_node(&t); /* get first attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* get second attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* get third attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* get fourth attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok(&t); /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { i = (int) strlen(wlsub->wl_word); j = 0; /* Now, have we a binned model? */ if ( (dot_char = strstr( wlsub->wl_word, "." )) != NULL) { dot_char++; j++; while( *dot_char != '\0' ) { if ( !isdigit( *dot_char ) ) { break; } dot_char++; j++; } } if ( strncmp( name, wlsub->wl_word, (size_t) (i - j) ) == 0 ) { (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } if (!found) (void) sprintf(buffer + strlen(buffer), "%s ", name); (void) strcat(buffer, t); tfree(s->li_line); s->li_line = buffer; tfree(name); break; /* 3-5 terminal devices */ case 'q': name = gettok(&t); /* get refdes */ (void) sprintf(buffer,"%s ",name); tfree(name); name = gettok_node(&t); /* get first attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* get second attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* get third attached netname */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok_node(&t); /* this can be either a model name or a node name. */ /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { /* a three terminal bjt */ (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } if (!found) { if (*t) { /* There is another token - perhaps a model */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok(&t); /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { /* a four terminal bjt */ (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } } } #ifdef ADMS if (!found) { if (*t) { /* There is another token - perhaps a model */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); name = gettok(&t); /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { /* a five terminal bjt */ (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } } } #endif if (!found) /* Fallback w/o subckt name before */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); found = FALSE; (void) strcat(buffer, t); tfree(s->li_line); s->li_line = buffer; break; /* 4-18 terminal devices */ case 'p': /* cpl */ name = gettok(&t); /* get refdes */ (void) sprintf(buffer,"%s ",name); tfree(name); /* now do remainder of line. */ next_name = gettok(&t); for (;;) { name = next_name; next_name = gettok(&t); if((next_name == NULL) || (strstr(next_name, "len") != NULL)) { /* if next_name is NULL or len or length, we are at the line end. * name holds the model name. Therefore, break */ break; } else { /* next_name holds something. Write name into the buffer and continue. */ (void) sprintf(buffer + strlen(buffer), "%s ", name); tfree(name); } } /* while */ /* Now, is this a subcircuit model? */ for (wlsub = submod; wlsub; wlsub = wlsub->wl_next) { if (eq(name, wlsub->wl_word)) { (void) sprintf(buffer + strlen(buffer), "%s:%s ", subname, name); found = TRUE; break; } } if (!found) (void) sprintf(buffer + strlen(buffer), "%s ", name); (void) strcat(buffer, t); tfree(s->li_line); s->li_line = buffer; break; default: tfree(buffer); break; } } return; } /*----------------------------------------------------------------------* * inp_numnodes returns the number of nodes (netnames) attached to the * component. * This is a spice-dependent thing. It should probably go somewhere * else, but... Note that we pretend that dependent sources and mutual * inductors have more nodes than they really do... *----------------------------------------------------------------------*/ static int inp_numnodes(char c) { if (isupper(c)) c = (char) tolower(c); switch (c) { case ' ': case '\t': case '.': case 'x': case '*': case '$': return (0); case 'b': return (2); case 'c': return (2); case 'd': return (2); case 'e': return (2); /* changed from 4 to 2 by SDB on 4.22.2003 to enable POLY */ case 'f': return (2); case 'g': return (2); /* changed from 4 to 2 by SDB on 4.22.2003 to enable POLY */ case 'h': return (2); case 'i': return (2); case 'j': return (3); case 'k': return (0); case 'l': return (2); case 'm': return (7); /* This means that 7 is the maximun number of nodes */ case 'o': return (4); case 'p': return (18);/* 16 lines + 2 gnd is the maximum number of nodes for CPL */ case 'q': return (5); case 'r': return (2); case 's': return (4); case 't': return (4); case 'u': return (3); case 'v': return (2); case 'w': return (2); /* change 3 to 2 here to fix w bug, NCF 1/31/95 */ case 'y': return (4); case 'z': return (3); default: fprintf(cp_err, "Warning: unknown device type: %c\n", c); return (2); } }