/* $NetBSD: lexi.c,v 1.10 2002/03/22 22:30:02 kristerw Exp $ */ /* * Copyright (c) 1980, 1993 * The Regents of the University of California. All rights reserved. * Copyright (c) 1976 Board of Trustees of the University of Illinois. * Copyright (c) 1985 Sun Microsystems, Inc. * All rights reserved. * * Redistribution and use in source and binary forms, with or without * modification, are permitted provided that the following conditions * are met: * 1. Redistributions of source code must retain the above copyright * notice, this list of conditions and the following disclaimer. * 2. Redistributions in binary form must reproduce the above copyright * notice, this list of conditions and the following disclaimer in the * documentation and/or other materials provided with the distribution. * 3. All advertising materials mentioning features or use of this software * must display the following acknowledgement: * This product includes software developed by the University of * California, Berkeley and its contributors. * 4. Neither the name of the University nor the names of its contributors * may be used to endorse or promote products derived from this software * without specific prior written permission. * * THIS SOFTWARE IS PROVIDED BY THE REGENTS AND CONTRIBUTORS ``AS IS'' AND * ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE * IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE * ARE DISCLAIMED. IN NO EVENT SHALL THE REGENTS OR CONTRIBUTORS BE LIABLE * FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL * DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS * OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) * HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT * LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY * OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF * SUCH DAMAGE. */ #include #ifndef lint #if 0 static char sccsid[] = "@(#)lexi.c 8.1 (Berkeley) 6/6/93"; #else __RCSID("$NetBSD: lexi.c,v 1.10 2002/03/22 22:30:02 kristerw Exp $"); #endif #endif /* not lint */ /* * Here we have the token scanner for indent. It scans off one token and puts * it in the global variable "token". It returns a code, indicating the type * of token scanned. */ #include #include #include #include #include "indent_globs.h" #include "indent_codes.h" #define alphanum 1 #define opchar 3 struct templ { char *rwd; int rwcode; }; struct templ specials[1000] = { {"switch", 1}, {"case", 2}, {"break", 0}, {"struct", 3}, {"union", 3}, {"enum", 3}, {"default", 2}, {"int", 4}, {"char", 4}, {"float", 4}, {"double", 4}, {"long", 4}, {"short", 4}, {"typdef", 4}, {"unsigned", 4}, {"register", 4}, {"static", 4}, {"global", 4}, {"extern", 4}, {"void", 4}, {"goto", 0}, {"return", 0}, {"if", 5}, {"while", 5}, {"for", 5}, {"else", 6}, {"do", 6}, {"sizeof", 7}, {0, 0} }; char chartype[128] = { /* this is used to facilitate the decision of * what type (alphanumeric, operator) each * character is */ 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 3, 0, 0, 1, 3, 3, 0, 0, 0, 3, 3, 0, 3, 0, 3, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 3, 3, 3, 3, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 3, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 0, 3, 0, 3, 0 }; int lexi() { int unary_delim; /* this is set to 1 if the current token * * forces a following operator to be unary */ static int last_code; /* the last token type returned */ static int l_struct; /* set to 1 if the last token was 'struct' */ int code; /* internal code to be returned */ char qchar; /* the delimiter character for a string */ e_token = s_token; /* point to start of place to save token */ unary_delim = false; ps.col_1 = ps.last_nl; /* tell world that this token started in * column 1 iff the last thing scanned was nl */ ps.last_nl = false; while (*buf_ptr == ' ' || *buf_ptr == '\t') { /* get rid of blanks */ ps.col_1 = false; /* leading blanks imply token is not * in column 1 */ if (++buf_ptr >= buf_end) fill_buffer(); } /* Scan an alphanumeric token */ if (chartype[(int) *buf_ptr] == alphanum || (buf_ptr[0] == '.' && isdigit((unsigned char)buf_ptr[1]))) { /* * we have a character or number */ char *j; /* used for searching thru list of * * reserved words */ struct templ *p; if (isdigit((unsigned char)*buf_ptr) || (buf_ptr[0] == '.' && isdigit((unsigned char)buf_ptr[1]))) { int seendot = 0, seenexp = 0, seensfx = 0; if (*buf_ptr == '0' && (buf_ptr[1] == 'x' || buf_ptr[1] == 'X')) { *e_token++ = *buf_ptr++; *e_token++ = *buf_ptr++; while (isxdigit((unsigned char)*buf_ptr)) { CHECK_SIZE_TOKEN; *e_token++ = *buf_ptr++; } } else { while (1) { if (*buf_ptr == '.') { if (seendot) break; else seendot++; } CHECK_SIZE_TOKEN; *e_token++ = *buf_ptr++; if (!isdigit((unsigned char)*buf_ptr) && *buf_ptr != '.') { if ((*buf_ptr != 'E' && *buf_ptr != 'e') || seenexp) break; else { seenexp++; seendot++; CHECK_SIZE_TOKEN; *e_token++ = *buf_ptr++; if (*buf_ptr == '+' || *buf_ptr == '-') *e_token++ = *buf_ptr++; } } } } if (*buf_ptr == 'F' || *buf_ptr == 'f') { /* float constant */ *e_token++ = *buf_ptr++; } else { /* integer constant */ while (1) { if (!(seensfx & 1) && (*buf_ptr == 'U' || *buf_ptr == 'u')) { CHECK_SIZE_TOKEN; *e_token++ = *buf_ptr++; seensfx |= 1; continue; } if (!(seensfx & 2) && (*buf_ptr == 'L' || *buf_ptr == 'l')) { CHECK_SIZE_TOKEN; if (buf_ptr[1] == buf_ptr[0]) *e_token++ = *buf_ptr++; *e_token++ = *buf_ptr++; seensfx |= 2; continue; } break; } } } else while (chartype[(int) *buf_ptr] == alphanum) { /* copy it over */ CHECK_SIZE_TOKEN; *e_token++ = *buf_ptr++; if (buf_ptr >= buf_end) fill_buffer(); } *e_token++ = '\0'; while (*buf_ptr == ' ' || *buf_ptr == '\t') { /* get rid of blanks */ if (++buf_ptr >= buf_end) fill_buffer(); } ps.its_a_keyword = false; ps.sizeof_keyword = false; if (l_struct) { /* if last token was 'struct', then this token * should be treated as a declaration */ l_struct = false; last_code = ident; ps.last_u_d = true; return (decl); } ps.last_u_d = false; /* Operator after indentifier is * binary */ last_code = ident; /* Remember that this is the code we * will return */ /* * This loop will check if the token is a keyword. */ for (p = specials; (j = p->rwd) != 0; p++) { char *p = s_token; /* point at scanned token */ if (*j++ != *p++ || *j++ != *p++) continue; /* This test depends on the * fact that identifiers are * always at least 1 character * long (ie. the first two * bytes of the identifier are * always meaningful) */ if (p[-1] == 0) break; /* If its a one-character identifier */ while (*p++ == *j) if (*j++ == 0) goto found_keyword; /* I wish that C had a * multi-level break... */ } if (p->rwd) { /* we have a keyword */ found_keyword: ps.its_a_keyword = true; ps.last_u_d = true; switch (p->rwcode) { case 1:/* it is a switch */ return (swstmt); case 2:/* a case or default */ return (casestmt); case 3:/* a "struct" */ if (ps.p_l_follow) break; /* inside parens: cast */ l_struct = true; /* * Next time around, we will want to know that we have had a * 'struct' */ case 4:/* one of the declaration keywords */ if (ps.p_l_follow) { ps.cast_mask |= 1 << ps.p_l_follow; break; /* inside parens: cast */ } last_code = decl; return (decl); case 5:/* if, while, for */ return (sp_paren); case 6:/* do, else */ return (sp_nparen); case 7: ps.sizeof_keyword = true; default: /* all others are treated like any * other identifier */ return (ident); } /* end of switch */ } /* end of if (found_it) */ if (*buf_ptr == '(' && ps.tos <= 1 && ps.ind_level == 0) { char *tp = buf_ptr; while (tp < buf_end) if (*tp++ == ')' && (*tp == ';' || *tp == ',')) goto not_proc; strncpy(ps.procname, token, sizeof ps.procname - 1); ps.in_parameter_declaration = 1; rparen_count = 1; not_proc: ; } /* * The following hack attempts to guess whether or not the current * token is in fact a declaration keyword -- one that has been * typedefd */ if (((*buf_ptr == '*' && buf_ptr[1] != '=') || isalpha((unsigned char)*buf_ptr) || *buf_ptr == '_') && !ps.p_l_follow && !ps.block_init && (ps.last_token == rparen || ps.last_token == semicolon || ps.last_token == decl || ps.last_token == lbrace || ps.last_token == rbrace)) { ps.its_a_keyword = true; ps.last_u_d = true; last_code = decl; return decl; } if (last_code == decl) /* if this is a declared variable, * then following sign is unary */ ps.last_u_d = true; /* will make "int a -1" work */ last_code = ident; return (ident); /* the ident is not in the list */ } /* end of procesing for alpanum character */ /* Scan a non-alphanumeric token */ *e_token++ = *buf_ptr; /* if it is only a one-character token, it is * moved here */ *e_token = '\0'; if (++buf_ptr >= buf_end) fill_buffer(); switch (*token) { case '\n': unary_delim = ps.last_u_d; ps.last_nl = true; /* remember that we just had a newline */ code = (had_eof ? 0 : newline); /* * if data has been exausted, the newline is a dummy, and we should * return code to stop */ break; case '\'': /* start of quoted character */ case '"': /* start of string */ qchar = *token; if (troff) { e_token[-1] = '`'; if (qchar == '"') *e_token++ = '`'; e_token = chfont(&bodyf, &stringf, e_token); } do { /* copy the string */ while (1) { /* move one character or * [/] */ if (*buf_ptr == '\n') { printf("%d: Unterminated literal\n", line_no); goto stop_lit; } CHECK_SIZE_TOKEN; /* Only have to do this * once in this loop, * since CHECK_SIZE * guarantees that there * are at least 5 * entries left */ *e_token = *buf_ptr++; if (buf_ptr >= buf_end) fill_buffer(); if (*e_token == BACKSLASH) { /* if escape, copy extra * char */ if (*buf_ptr == '\n') /* check for escaped * newline */ ++line_no; if (troff) { *++e_token = BACKSLASH; if (*buf_ptr == BACKSLASH) *++e_token = BACKSLASH; } *++e_token = *buf_ptr++; ++e_token; /* we must increment * this again because we * copied two chars */ if (buf_ptr >= buf_end) fill_buffer(); } else break; /* we copied one character */ } /* end of while (1) */ } while (*e_token++ != qchar); if (troff) { e_token = chfont(&stringf, &bodyf, e_token - 1); if (qchar == '"') *e_token++ = '\''; } stop_lit: code = ident; break; case ('('): case ('['): unary_delim = true; code = lparen; break; case (')'): case (']'): code = rparen; break; case '#': unary_delim = ps.last_u_d; code = preesc; break; case '?': unary_delim = true; code = question; break; case (':'): code = colon; unary_delim = true; break; case (';'): unary_delim = true; code = semicolon; break; case ('{'): unary_delim = true; /* * if (ps.in_or_st) ps.block_init = 1; */ /* ? code = ps.block_init ? lparen : lbrace; */ code = lbrace; break; case ('}'): unary_delim = true; /* ? code = ps.block_init ? rparen : rbrace; */ code = rbrace; break; case 014: /* a form feed */ unary_delim = ps.last_u_d; ps.last_nl = true; /* remember this so we can set * 'ps.col_1' right */ code = form_feed; break; case (','): unary_delim = true; code = comma; break; case '.': unary_delim = false; code = period; break; case '-': case '+': /* check for -, +, --, ++ */ code = (ps.last_u_d ? unary_op : binary_op); unary_delim = true; if (*buf_ptr == token[0]) { /* check for doubled character */ *e_token++ = *buf_ptr++; /* buffer overflow will be checked at end of loop */ if (last_code == ident || last_code == rparen) { code = (ps.last_u_d ? unary_op : postop); /* check for following ++ or -- */ unary_delim = false; } } else if (*buf_ptr == '=') /* check for operator += */ *e_token++ = *buf_ptr++; else if (*buf_ptr == '>') { /* check for operator -> */ *e_token++ = *buf_ptr++; if (!pointer_as_binop) { unary_delim = false; code = unary_op; ps.want_blank = false; } } break; /* buffer overflow will be checked at end of * switch */ case '=': if (ps.in_or_st) ps.block_init = 1; #ifdef undef if (chartype[*buf_ptr] == opchar) { /* we have two char * assignment */ e_token[-1] = *buf_ptr++; if ((e_token[-1] == '<' || e_token[-1] == '>') && e_token[-1] == *buf_ptr) *e_token++ = *buf_ptr++; *e_token++ = '='; /* Flip =+ to += */ *e_token = 0; } #else if (*buf_ptr == '=') { /* == */ *e_token++ = '='; /* Flip =+ to += */ buf_ptr++; *e_token = 0; } #endif code = binary_op; unary_delim = true; break; /* can drop thru!!! */ case '>': case '<': case '!': /* ops like <, <<, <=, !=, etc */ if (*buf_ptr == '>' || *buf_ptr == '<' || *buf_ptr == '=') { *e_token++ = *buf_ptr; if (++buf_ptr >= buf_end) fill_buffer(); } if (*buf_ptr == '=') *e_token++ = *buf_ptr++; code = (ps.last_u_d ? unary_op : binary_op); unary_delim = true; break; default: if (token[0] == '/' && *buf_ptr == '*') { /* it is start of comment */ *e_token++ = '*'; if (++buf_ptr >= buf_end) fill_buffer(); code = comment; unary_delim = ps.last_u_d; break; } while (*(e_token - 1) == *buf_ptr || *buf_ptr == '=') { /* * handle ||, &&, etc, and also things as in int *****i */ *e_token++ = *buf_ptr; if (++buf_ptr >= buf_end) fill_buffer(); } code = (ps.last_u_d ? unary_op : binary_op); unary_delim = true; } /* end of switch */ if (code != newline) { l_struct = false; last_code = code; } if (buf_ptr >= buf_end) /* check for input buffer empty */ fill_buffer(); ps.last_u_d = unary_delim; *e_token = '\0'; /* null terminate the token */ return (code); } /* * Add the given keyword to the keyword table, using val as the keyword type */ void addkey(key, val) char *key; int val; { struct templ *p = specials; while (p->rwd) if (p->rwd[0] == key[0] && strcmp(p->rwd, key) == 0) return; else p++; if (p >= specials + sizeof specials / sizeof specials[0]) return; /* For now, table overflows are silently * ignored */ p->rwd = key; p->rwcode = val; p[1].rwd = 0; p[1].rwcode = 0; }