/* $Header$ */ /* L E X I C A L A N A L Y Z E R */ #include "nofloat.h" #include "idfsize.h" #include "numsize.h" #include "debug.h" #include "strsize.h" #include "nopp.h" #include "input.h" #include "alloc.h" #include "arith.h" #include "def.h" #include "idf.h" #include "LLlex.h" #include "Lpars.h" #include "class.h" #include "assert.h" #include "sizes.h" /* Data about the token yielded */ struct token dot, ahead, aside; int ReplaceMacros = 1; /* replacing macros */ int EoiForNewline = 0; /* return EOI upon encountering newline */ int PreProcKeys = 0; /* return preprocessor key */ int AccFileSpecifier = 0; /* return filespecifier <...> */ int AccDefined = 0; /* accept "defined(...)" */ int UnknownIdIsZero = 0; /* interpret unknown id as integer 0 */ int SkipEscNewline = 0; /* how to interpret backslash-newline */ int Unstacked = 0; /* an unstack is done */ #define MAX_LL_DEPTH 2 static struct token LexStack[MAX_LL_DEPTH]; static LexSP = 0; /* In PushLex() the actions are taken in order to initialise or re-initialise the lexical scanner. E.g. at the invocation of a sub-parser that uses LLlex(), the state of the current parser should be saved. */ PushLex() { ASSERT(LexSP < 2); ASSERT(ASIDE == 0); /* ASIDE = 0; */ GetToken(&ahead); ahead.tk_line = LineNumber; ahead.tk_file = FileName; LexStack[LexSP++] = dot; } PopLex() { ASSERT(LexSP > 0); dot = LexStack[--LexSP]; } int LLlex() { /* LLlex() plays the role of Lexical Analyzer for the C parser. The look-ahead and putting aside of tokens are taken into account. */ if (ASIDE) { /* a token is put aside */ dot = aside; ASIDE = 0; } else { /* read ahead and return the old one */ dot = ahead; /* the following test is performed due to the dual task of LLlex(): it is also called for parsing the restricted constant expression following a #if or #elif. The newline character causes EOF to be returned in this case to stop the LLgen parsing task. */ if (DOT != EOI) GetToken(&ahead); else DOT = EOF; } /* keep track of the place of the token in the file */ ahead.tk_file = FileName; ahead.tk_line = LineNumber; return DOT; } char *string_token(); int GetToken(ptok) register struct token *ptok; { /* GetToken() is the actual token recognizer. It calls the control line interpreter if it encounters a "\n#" combination. Macro replacement is also performed if it is needed. */ char buf[(IDFSIZE > NUMSIZE ? IDFSIZE : NUMSIZE) + 1]; register int ch, nch; if (! LineNumber) goto firstline; again: /* rescan the input after an error or replacement */ #ifndef NOPP if (Unstacked) EnableMacros(); #endif LoadChar(ch); go_on: /* rescan, the following character has been read */ if ((ch & 0200) && ch != EOI) /* stop on non-ascii character */ fatal("non-ascii '\\%03o' read", ch & 0377); switch (class(ch)) { /* detect character class */ case STNL: /* newline, vertical space or formfeed */ firstline: LineNumber++; /* also at vs and ff */ if (EoiForNewline) /* called in control line */ /* a newline in a control line indicates the end-of-information of the line. */ return ptok->tk_symb = EOI; while (LoadChar(ch), ch == '#') { /* a control line follows */ domacro(); if (!LineNumber) goto firstline; } /* We have to loop here, because in `domacro' the nl, vt or ff is read. The character following it may again be a `#'. */ goto go_on; case STSKIP: /* just skip the skip characters */ goto again; case STGARB: /* garbage character */ #ifndef NOPP if (SkipEscNewline && (ch == '\\')) { /* a '\\' is allowed in #if/#elif expression */ LoadChar(ch); if (class(ch) == STNL) { /* vt , ff ? */ ++LineNumber; goto again; } PushBack(); ch = '\\'; } #endif NOPP if (040 < ch && ch < 0177) lexerror("garbage char %c", ch); else lexerror("garbage char \\%03o", ch); goto again; case STSIMP: /* a simple character, no part of compound token*/ if (ch == '/') { /* probably the start of comment */ LoadChar(ch); if (ch == '*') { /* start of comment */ skipcomment(); goto again; } else { PushBack(); ch = '/'; /* restore ch */ } } return ptok->tk_symb = ch; case STCOMP: /* maybe the start of a compound token */ LoadChar(nch); /* character lookahead */ switch (ch) { case '!': if (nch == '=') return ptok->tk_symb = NOTEQUAL; PushBack(); return ptok->tk_symb = ch; case '&': if (nch == '&') return ptok->tk_symb = AND; PushBack(); return ptok->tk_symb = ch; case '+': if (nch == '+') return ptok->tk_symb = PLUSPLUS; PushBack(); return ptok->tk_symb = ch; case '-': if (nch == '-') return ptok->tk_symb = MINMIN; if (nch == '>') return ptok->tk_symb = ARROW; PushBack(); return ptok->tk_symb = ch; case '<': if (AccFileSpecifier) { PushBack(); /* pushback nch */ ptok->tk_bts = string_token("file specifier", '>', &(ptok->tk_len)); return ptok->tk_symb = FILESPECIFIER; } if (nch == '<') return ptok->tk_symb = LEFT; if (nch == '=') return ptok->tk_symb = LESSEQ; PushBack(); return ptok->tk_symb = ch; case '=': if (nch == '=') return ptok->tk_symb = EQUAL; /* The following piece of code tries to recognise old-fashioned assignment operators `=op' */ switch (nch) { case '+': return ptok->tk_symb = PLUSAB; case '-': return ptok->tk_symb = MINAB; case '*': return ptok->tk_symb = TIMESAB; case '/': return ptok->tk_symb = DIVAB; case '%': return ptok->tk_symb = MODAB; case '>': case '<': LoadChar(ch); if (ch != nch) { PushBack(); lexerror("illegal combination '=%c'", nch); } return ptok->tk_symb = nch == '<' ? LEFTAB : RIGHTAB; case '&': return ptok->tk_symb = ANDAB; case '^': return ptok->tk_symb = XORAB; case '|': return ptok->tk_symb = ORAB; } PushBack(); return ptok->tk_symb = ch; case '>': if (nch == '=') return ptok->tk_symb = GREATEREQ; if (nch == '>') return ptok->tk_symb = RIGHT; PushBack(); return ptok->tk_symb = ch; case '|': if (nch == '|') return ptok->tk_symb = OR; PushBack(); return ptok->tk_symb = ch; } case STIDF: { register char *tg = &buf[0]; register int pos = -1; register int hash; register struct idf *idef; extern int idfsize; /* ??? */ hash = STARTHASH(); do { /* read the identifier */ if (++pos < idfsize) { #ifndef NOPP if (Unstacked) EnableMacros(); #endif *tg++ = ch; hash = ENHASH(hash, ch, pos); } LoadChar(ch); } while (in_idf(ch)); hash = STOPHASH(hash); if (ch != EOI) PushBack(); *tg++ = '\0'; /* mark the end of the identifier */ idef = ptok->tk_idf = idf_hashed(buf, tg - buf, hash); #ifndef NOPP if (idef->id_macro && ReplaceMacros && replace(idef)) /* macro replacement should be performed */ goto again; if (UnknownIdIsZero && idef->id_reserved != SIZEOF) { ptok->tk_ival = (arith)0; ptok->tk_fund = INT; return ptok->tk_symb = INTEGER; } #endif NOPP ptok->tk_symb = ( idef->id_reserved ? idef->id_reserved : idef->id_def && idef->id_def->df_sc == TYPEDEF ? TYPE_IDENTIFIER : IDENTIFIER ); return IDENTIFIER; } case STCHAR: /* character constant */ { register arith val = 0, size = 0; LoadChar(ch); if (ch == '\'') lexerror("character constant too short"); else while (ch != '\'') { if (ch == '\n') { lexerror("newline in character constant"); LineNumber++; break; } if (ch == '\\') { LoadChar(ch); if (ch == '\n') LineNumber++; ch = quoted(ch); } val = val*256 + ch; size++; LoadChar(ch); } if (size > int_size) lexerror("character constant too long"); ptok->tk_ival = val; ptok->tk_fund = INT; return ptok->tk_symb = INTEGER; } case STSTR: /* string */ ptok->tk_bts = string_token("string", '"', &(ptok->tk_len)); return ptok->tk_symb = STRING; case STNUM: /* a numeric constant */ { /* It should be noted that 099 means 81(decimal) and 099.5 means 99.5 . This severely limits the tricks we can use to scan a numeric value. */ register char *np = &buf[1]; register int base = 10; register int vch; register arith val = 0; if (ch == '.') { /* an embarrassing ambiguity */ #ifndef NOFLOAT LoadChar(vch); PushBack(); if (!is_dig(vch)) /* just a `.' */ return ptok->tk_symb = ch; *np++ = '0'; /* in the rest of the compiler, all floats have to start with a digit. */ #else NOFLOAT return ptok->tk_symb = ch; #endif NOFLOAT } if (ch == '0') { *np++ = ch; LoadChar(ch); if (ch == 'x' || ch == 'X') { base = 16; LoadChar(ch); } else base = 8; } while (vch = val_in_base(ch, base), vch >= 0) { val = val*base + vch; if (np < &buf[NUMSIZE]) *np++ = ch; LoadChar(ch); } if (ch == 'l' || ch == 'L') { ptok->tk_ival = val; ptok->tk_fund = LONG; return ptok->tk_symb = INTEGER; } #ifndef NOFLOAT if (base == 16 || !(ch == '.' || ch == 'e' || ch == 'E')) #endif NOFLOAT { PushBack(); ptok->tk_ival = val; /* The semantic analyser must know if the integral constant is given in octal/hexa- decimal form, in which case its type is UNSIGNED, or in decimal form, in which case its type is signed, indicated by the fund INTEGER. */ ptok->tk_fund = (base == 10 || (base == 8 && val == (arith)0)) ? INTEGER : UNSIGNED; return ptok->tk_symb = INTEGER; } /* where's the test for the length of the integral ??? */ #ifndef NOFLOAT if (ch == '.'){ if (np < &buf[NUMSIZE]) *np++ = ch; LoadChar(ch); } while (is_dig(ch)){ if (np < &buf[NUMSIZE]) *np++ = ch; LoadChar(ch); } if (ch == 'e' || ch == 'E') { if (np < &buf[NUMSIZE]) *np++ = ch; LoadChar(ch); if (ch == '+' || ch == '-') { if (np < &buf[NUMSIZE]) *np++ = ch; LoadChar(ch); } if (!is_dig(ch)) { lexerror("malformed floating constant"); if (np < &buf[NUMSIZE]) *np++ = ch; } while (is_dig(ch)) { if (np < &buf[NUMSIZE]) *np++ = ch; LoadChar(ch); } } PushBack(); *np++ = '\0'; buf[0] = '-'; /* good heavens... */ if (np == &buf[NUMSIZE+1]) { lexerror("floating constant too long"); ptok->tk_fval = Salloc("0.0", 5) + 1; } else ptok->tk_fval = Salloc(buf, np - buf) + 1; return ptok->tk_symb = FLOATING; #endif NOFLOAT } case STEOI: /* end of text on source file */ return ptok->tk_symb = EOI; default: /* this cannot happen */ crash("bad class for char 0%o", ch); } /*NOTREACHED*/ } skipcomment() { /* The last character read has been the '*' of '/_*'. The characters, except NL and EOI, between '/_*' and the first occurring '*_/' are not interpreted. NL only affects the LineNumber. EOI is not legal. Important note: it is not possible to stop skipping comment beyond the end-of-file of an included file. EOI is returned by LoadChar only on encountering EOF of the top-level file... */ register int c; NoUnstack++; LoadChar(c); do { while (c != '*') { if (class(c) == STNL) ++LineNumber; else if (c == EOI) { NoUnstack--; return; } LoadChar(c); } /* last Character seen was '*' */ LoadChar(c); } while (c != '/'); NoUnstack--; } char * string_token(nm, stop_char, plen) char *nm; int *plen; { register int ch; register int str_size; register char *str = Malloc(str_size = ISTRSIZE); register int pos = 0; LoadChar(ch); while (ch != stop_char) { if (ch == '\n') { lexerror("newline in %s", nm); LineNumber++; break; } if (ch == EOI) { lexerror("end-of-file inside %s", nm); break; } if (ch == '\\') { LoadChar(ch); if (ch == '\n') { LineNumber++; continue; } ch = quoted(ch); } str[pos++] = ch; if (pos == str_size) str = Srealloc(str, str_size += RSTRSIZE); LoadChar(ch); } str[pos++] = '\0'; /* for filenames etc. */ *plen = pos; return str; } int quoted(ch) register int ch; { /* quoted() replaces an escaped character sequence by the character meant. */ /* first char after backslash already in ch */ if (!is_oct(ch)) { /* a quoted char */ switch (ch) { case 'n': ch = '\n'; break; case 't': ch = '\t'; break; case 'b': ch = '\b'; break; case 'r': ch = '\r'; break; case 'f': ch = '\f'; break; } } else { /* a quoted octal */ register int oct = 0, cnt = 0; do { oct = oct*8 + (ch-'0'); LoadChar(ch); } while (is_oct(ch) && ++cnt < 3); PushBack(); ch = oct; } return ch&0377; } /* provisional */ int val_in_base(ch, base) register int ch; { return is_dig(ch) ? ch - '0' : base != 16 ? -1 : is_hex(ch) ? (ch - 'a' + 10) & 017 : -1; }