/* $NetBSD: lexi.c,v 1.16 2019/04/04 15:22:13 kamil Exp $ */ /*- * SPDX-License-Identifier: BSD-4-Clause * * Copyright (c) 1985 Sun Microsystems, Inc. * Copyright (c) 1980, 1993 * The Regents of the University of California. All rights reserved. * 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. */ #if 0 #ifndef lint static char sccsid[] = "@(#)lexi.c 8.1 (Berkeley) 6/6/93"; #endif /* not lint */ #endif #include #ifndef lint #if defined(__NetBSD__) __RCSID("$NetBSD: lexi.c,v 1.16 2019/04/04 15:22:13 kamil Exp $"); #elif defined(__FreeBSD__) __FBSDID("$FreeBSD: head/usr.bin/indent/lexi.c 337862 2018-08-15 18:19:45Z pstef $"); #endif #endif /* * 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 #include #include "indent_globs.h" #include "indent_codes.h" #include "indent.h" struct templ { const char *rwd; int rwcode; }; /* * This table has to be sorted alphabetically, because it'll be used in binary * search. For the same reason, string must be the first thing in struct templ. */ struct templ specials[] = { {"_Bool", 4}, {"_Complex", 4}, {"_Imaginary", 4}, {"auto", 10}, {"bool", 4}, {"break", 9}, {"case", 8}, {"char", 4}, {"complex", 4}, {"const", 4}, {"continue", 12}, {"default", 8}, {"do", 6}, {"double", 4}, {"else", 6}, {"enum", 3}, {"extern", 10}, {"float", 4}, {"for", 5}, {"global", 4}, {"goto", 9}, {"if", 5}, {"imaginary", 4}, {"inline", 12}, {"int", 4}, {"long", 4}, {"offsetof", 1}, {"register", 10}, {"restrict", 12}, {"return", 9}, {"short", 4}, {"signed", 4}, {"sizeof", 2}, {"static", 10}, {"struct", 3}, {"switch", 7}, {"typedef", 11}, {"union", 3}, {"unsigned", 4}, {"void", 4}, {"volatile", 4}, {"while", 5} }; const char **typenames; int typename_count; int typename_top = -1; /* * The transition table below was rewritten by hand from lx's output, given * the following definitions. lx is Katherine Flavel's lexer generator. * * O = /[0-7]/; D = /[0-9]/; NZ = /[1-9]/; * H = /[a-f0-9]/i; B = /[0-1]/; HP = /0x/i; * BP = /0b/i; E = /e[+\-]?/i D+; P = /p[+\-]?/i D+; * FS = /[fl]/i; IS = /u/i /(l|L|ll|LL)/? | /(l|L|ll|LL)/ /u/i?; * * D+ E FS? -> $float; * D* "." D+ E? FS? -> $float; * D+ "." E? FS? -> $float; HP H+ IS? -> $int; * HP H+ P FS? -> $float; NZ D* IS? -> $int; * HP H* "." H+ P FS? -> $float; "0" O* IS? -> $int; * HP H+ "." P FS -> $float; BP B+ IS? -> $int; */ static char const *table[] = { /* examples: 00 s 0xx t 00xaa a 11 101100xxa.. r 11ee0001101lbuuxx.a.pp t.01.e+008bLuxll0Ll.aa.p+0 states: ABCDEFGHIJKLMNOPQRSTUVWXYZ */ ['0'] = "CEIDEHHHIJQ U Q VUVVZZZ", ['1'] = "DEIDEHHHIJQ U Q VUVVZZZ", ['7'] = "DEIDEHHHIJ U VUVVZZZ", ['9'] = "DEJDEHHHJJ U VUVVZZZ", ['a'] = " U VUVV ", ['b'] = " K U VUVV ", ['e'] = " FFF FF U VUVV ", ['f'] = " f f U VUVV f", ['u'] = " MM M i iiM M ", ['x'] = " N ", ['p'] = " FFX ", ['L'] = " LLf fL PR Li L f", ['l'] = " OOf fO S P O i O f", ['+'] = " G Y ", ['.'] = "B EE EE T W ", /* ABCDEFGHIJKLMNOPQRSTUVWXYZ */ [0] = "uuiifuufiuuiiuiiiiiuiuuuuu", }; static int strcmp_type(const void *e1, const void *e2) { return (strcmp(e1, *(const char * const *)e2)); } int lexi(struct parser_state *state) { int unary_delim; /* this is set to 1 if the current token * forces a following operator to be unary */ int code; /* internal code to be returned */ char qchar; /* the delimiter character for a string */ e_token = s_token; /* point to start of place to save token */ unary_delim = false; state->col_1 = state->last_nl; /* tell world that this token started * in column 1 iff the last thing * scanned was a newline */ state->last_nl = false; while (*buf_ptr == ' ' || *buf_ptr == '\t') { /* get rid of blanks */ state->col_1 = false; /* leading blanks imply token is not in column * 1 */ if (++buf_ptr >= buf_end) fill_buffer(); } /* Scan an alphanumeric token */ if (isalnum((unsigned char)*buf_ptr) || *buf_ptr == '_' || *buf_ptr == '$' || (buf_ptr[0] == '.' && isdigit((unsigned char)buf_ptr[1]))) { /* * we have a character or number */ struct templ *p; if (isdigit((unsigned char)*buf_ptr) || (buf_ptr[0] == '.' && isdigit((unsigned char)buf_ptr[1]))) { char s; unsigned char i; for (s = 'A'; s != 'f' && s != 'i' && s != 'u'; ) { i = (unsigned char)*buf_ptr; if (i >= nitems(table) || table[i] == NULL || table[i][s - 'A'] == ' ') { s = table[0][s - 'A']; break; } s = table[i][s - 'A']; CHECK_SIZE_TOKEN(1); *e_token++ = *buf_ptr++; if (buf_ptr >= buf_end) fill_buffer(); } /* s now indicates the type: f(loating), i(integer), u(nknown) */ } else while (isalnum((unsigned char)*buf_ptr) || *buf_ptr == BACKSLASH || *buf_ptr == '_' || *buf_ptr == '$') { /* fill_buffer() terminates buffer with newline */ if (*buf_ptr == BACKSLASH) { if (*(buf_ptr + 1) == '\n') { buf_ptr += 2; if (buf_ptr >= buf_end) fill_buffer(); } else break; } CHECK_SIZE_TOKEN(1); /* copy it over */ *e_token++ = *buf_ptr++; if (buf_ptr >= buf_end) fill_buffer(); } *e_token = '\0'; if (s_token[0] == 'L' && s_token[1] == '\0' && (*buf_ptr == '"' || *buf_ptr == '\'')) return (strpfx); while (*buf_ptr == ' ' || *buf_ptr == '\t') { /* get rid of blanks */ if (++buf_ptr >= buf_end) fill_buffer(); } state->keyword = 0; if (state->last_token == structure && !state->p_l_follow) { /* if last token was 'struct' and we're not * in parentheses, then this token * should be treated as a declaration */ state->last_u_d = true; return (decl); } /* * Operator after identifier is binary unless last token was 'struct' */ state->last_u_d = (state->last_token == structure); p = bsearch(s_token, specials, sizeof(specials) / sizeof(specials[0]), sizeof(specials[0]), strcmp_type); if (p == NULL) { /* not a special keyword... */ char *u; /* ... so maybe a type_t or a typedef */ if ((opt.auto_typedefs && ((u = strrchr(s_token, '_')) != NULL) && strcmp(u, "_t") == 0) || (typename_top >= 0 && bsearch(s_token, typenames, typename_top + 1, sizeof(typenames[0]), strcmp_type))) { state->keyword = 4; /* a type name */ state->last_u_d = true; goto found_typename; } } else { /* we have a keyword */ state->keyword = p->rwcode; state->last_u_d = true; switch (p->rwcode) { case 7: /* it is a switch */ return (swstmt); case 8: /* a case or default */ return (casestmt); case 3: /* a "struct" */ /* FALLTHROUGH */ case 4: /* one of the declaration keywords */ found_typename: if (state->p_l_follow) { /* inside parens: cast, param list, offsetof or sizeof */ state->cast_mask |= (1 << state->p_l_follow) & ~state->not_cast_mask; } if (state->last_token == period || state->last_token == unary_op) { state->keyword = 0; break; } if (p != NULL && p->rwcode == 3) return (structure); if (state->p_l_follow) break; return (decl); case 5: /* if, while, for */ return (sp_paren); case 6: /* do, else */ return (sp_nparen); case 10: /* storage class specifier */ return (storage); case 11: /* typedef */ return (type_def); default: /* all others are treated like any other * identifier */ return (ident); } /* end of switch */ } /* end of if (found_it) */ if (*buf_ptr == '(' && state->tos <= 1 && state->ind_level == 0 && state->in_parameter_declaration == 0 && state->block_init == 0) { char *tp = buf_ptr; while (tp < buf_end) if (*tp++ == ')' && (*tp == ';' || *tp == ',')) goto not_proc; strncpy(state->procname, token, sizeof state->procname - 1); if (state->in_decl) state->in_parameter_declaration = 1; return (funcname); 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 */ else if (!state->p_l_follow && !state->block_init && !state->in_stmt && ((*buf_ptr == '*' && buf_ptr[1] != '=') || isalpha((unsigned char)*buf_ptr)) && (state->last_token == semicolon || state->last_token == lbrace || state->last_token == rbrace)) { state->keyword = 4; /* a type name */ state->last_u_d = true; return decl; } if (state->last_token == decl) /* if this is a declared variable, * then following sign is unary */ state->last_u_d = true; /* will make "int a -1" work */ return (ident); /* the ident is not in the list */ } /* end of procesing for alpanum character */ /* Scan a non-alphanumeric token */ CHECK_SIZE_TOKEN(3); /* things like "<<=" */ *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 = state->last_u_d; state->last_nl = true; /* remember that we just had a newline */ code = (had_eof ? 0 : newline); /* * if data has been exhausted, the newline is a dummy, and we should * return code to stop */ break; case '\'': /* start of quoted character */ case '"': /* start of string */ qchar = *token; do { /* copy the string */ while (1) { /* move one character or [/] */ if (*buf_ptr == '\n') { diag2(1, "Unterminated literal"); goto stop_lit; } CHECK_SIZE_TOKEN(2); *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; *++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); stop_lit: code = ident; break; case ('('): case ('['): unary_delim = true; code = lparen; break; case (')'): case (']'): code = rparen; break; case '#': unary_delim = state->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 (state->in_or_st) state->block_init = 1; */ /* ? code = state->block_init ? lparen : lbrace; */ code = lbrace; break; case ('}'): unary_delim = true; /* ? code = state->block_init ? rparen : rbrace; */ code = rbrace; break; case 014: /* a form feed */ unary_delim = state->last_u_d; state->last_nl = true; /* remember this so we can set 'state->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 = (state->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 (state->last_token == ident || state->last_token == rparen) { code = (state->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++; unary_delim = false; code = unary_op; state->want_blank = false; } break; /* buffer overflow will be checked at end of * switch */ case '=': if (state->in_or_st) state->block_init = 1; if (*buf_ptr == '=') {/* == */ *e_token++ = '='; /* Flip =+ to += */ buf_ptr++; *e_token = 0; } 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 = (state->last_u_d ? unary_op : binary_op); unary_delim = true; break; case '*': unary_delim = true; if (!state->last_u_d) { if (*buf_ptr == '=') *e_token++ = *buf_ptr++; code = binary_op; break; } while (*buf_ptr == '*' || isspace((unsigned char)*buf_ptr)) { if (*buf_ptr == '*') { CHECK_SIZE_TOKEN(1); *e_token++ = *buf_ptr; } if (++buf_ptr >= buf_end) fill_buffer(); } if (ps.in_decl) { char *tp = buf_ptr; while (isalpha((unsigned char)*tp) || isspace((unsigned char)*tp)) { if (++tp >= buf_end) fill_buffer(); } if (*tp == '(') ps.procname[0] = ' '; } code = unary_op; 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 = state->last_u_d; break; } while (*(e_token - 1) == *buf_ptr || *buf_ptr == '=') { /* * handle ||, &&, etc, and also things as in int *****i */ CHECK_SIZE_TOKEN(1); *e_token++ = *buf_ptr; if (++buf_ptr >= buf_end) fill_buffer(); } code = (state->last_u_d ? unary_op : binary_op); unary_delim = true; } /* end of switch */ if (buf_ptr >= buf_end) /* check for input buffer empty */ fill_buffer(); state->last_u_d = unary_delim; CHECK_SIZE_TOKEN(1); *e_token = '\0'; /* null terminate the token */ return (code); } /* Initialize constant transition table */ void init_constant_tt(void) { table['-'] = table['+']; table['8'] = table['9']; table['2'] = table['3'] = table['4'] = table['5'] = table['6'] = table['7']; table['A'] = table['C'] = table['D'] = table['c'] = table['d'] = table['a']; table['B'] = table['b']; table['E'] = table['e']; table['U'] = table['u']; table['X'] = table['x']; table['P'] = table['p']; table['F'] = table['f']; } void alloc_typenames(void) { typenames = (const char **)malloc(sizeof(typenames[0]) * (typename_count = 16)); if (typenames == NULL) err(1, NULL); } void add_typename(const char *key) { int comparison; const char *copy; if (typename_top + 1 >= typename_count) { typenames = realloc((void *)typenames, sizeof(typenames[0]) * (typename_count *= 2)); if (typenames == NULL) err(1, NULL); } if (typename_top == -1) typenames[++typename_top] = copy = strdup(key); else if ((comparison = strcmp(key, typenames[typename_top])) >= 0) { /* take advantage of sorted input */ if (comparison == 0) /* remove duplicates */ return; typenames[++typename_top] = copy = strdup(key); } else { int p; for (p = 0; (comparison = strcmp(key, typenames[p])) > 0; p++) /* find place for the new key */; if (comparison == 0) /* remove duplicates */ return; memmove(&typenames[p + 1], &typenames[p], sizeof(typenames[0]) * (++typename_top - p)); typenames[p] = copy = strdup(key); } if (copy == NULL) err(1, NULL); }