/*
* (c) copyright 1987 by the Vrije Universiteit, Amsterdam, The Netherlands.
* See the copyright notice in the ACK home directory, in the file "Copyright".
*
* Author: Ceriel J.H. Jacobs
*/
/* L E X I C A L A N A L Y S E R F O R M O D U L A - 2 */
/* $Id$ */
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#include "parameters.h"
#include "debug.h"
#include "alloc.h"
#include "em_arith.h"
#include "em_label.h"
#include "assert.h"
#include "LLlex.h"
#include "input.h"
#include "f_info.h"
#include "Lpars.h"
#include "class.h"
#include "idf.h"
#include "def.h"
#include "type.h"
#include "warning.h"
extern char *getwdir();
t_token dot,
aside;
t_type *toktype;
int idfsize = IDFSIZE;
int ForeignFlag;
#ifdef DEBUG
extern int cntlines;
#endif
int token_nmb = 0;
int tk_nmb_at_last_syn_err = -ERR_SHADOW;
extern char options[];
extern int flt_status;
STATIC
SkipComment()
{
/* Skip Modula-2 comments (* ... *).
Note that comments may be nested (par. 3.5).
*/
register int ch, c;
register int CommentLevel = 0;
LoadChar(ch);
if (ch == '$') {
LoadChar(ch);
switch(ch) {
case 'F':
/* Foreign; This definition module has an
implementation in another language.
In this case, don't generate prefixes in front
of the names. Also, don't generate call to
initialization routine.
*/
ForeignFlag = D_FOREIGN;
break;
case 'U':
inidf['_'] = 1;
break;
case 'A': /* Extra array bound checks, on or off */
case 'R': /* Range checks, on or off */
{
int on_on_minus = ch == 'R';
LoadChar(c);
if (c == '-') {
options[ch] = on_on_minus;
break;
}
if (c == '+') {
options[ch] = !on_on_minus;
break;
}
ch = c;
}
/* fall through */
default:
break;
}
}
for (;;) {
if (!(ch & 0200) && class(ch) == STNL) {
LineNumber++;
#ifdef DEBUG
cntlines++;
#endif
}
else if (ch == '(') {
LoadChar(ch);
if (ch == '*') CommentLevel++;
else continue;
}
else if (ch == '*') {
LoadChar(ch);
if (ch == ')') {
CommentLevel--;
if (CommentLevel < 0) break;
}
else continue;
}
else if (ch == EOI) {
lexerror("unterminated comment");
PushBack();
break;
}
LoadChar(ch);
}
}
STATIC struct string *
GetString(upto)
{
/* Read a Modula-2 string, delimited by the character "upto".
*/
register int ch;
register struct string *str = (struct string *)
Malloc((unsigned) sizeof(struct string));
register char *p;
register int len;
len = ISTRSIZE;
str->s_str = p = Malloc((unsigned int) ISTRSIZE);
while (LoadChar(ch), ch != upto) {
if (!(ch & 0200) && class(ch) == STNL) {
lexerror("newline in string");
LineNumber++;
#ifdef DEBUG
cntlines++;
#endif
break;
}
if (ch == EOI) {
lexerror("end-of-file in string");
break;
}
*p++ = ch;
if (p - str->s_str == len) {
str->s_str = Realloc(str->s_str,
(unsigned int) len + RSTRSIZE);
p = str->s_str + len;
len += RSTRSIZE;
}
}
str->s_length = p - str->s_str;
len = (str->s_length+(int)word_size) & ~((int)word_size-1);
while (p - str->s_str < len) {
*p++ = '\0';
}
str->s_str = Realloc(str->s_str, (unsigned) len);
if (str->s_length == 0) str->s_length = 1;
/* ??? string length at least 1 ??? */
return str;
}
static char *s_error = "illegal line directive";
STATIC int
getch()
{
register int ch;
while (LoadChar(ch), (ch & 0200) && ch != EOI) {
error("non-ascii '\\%03o' read", ch & 0377);
}
return ch;
}
void
CheckForLineDirective()
{
register int ch = getch();
register int i = 0;
char buf[IDFSIZE];
register char *c = buf;
for (;;) {
if (ch != '#') {
PushBack();
return;
}
do { /*
* Skip to next digit
* Do not skip newlines
*/
ch = getch();
if (class(ch) == STNL || class(ch) == STEOI) {
LineNumber++;
error(s_error);
return;
}
} while (class(ch) != STNUM);
while (class(ch) == STNUM) {
i = i*10 + (ch - '0');
ch = getch();
}
while (ch != '"' && class(ch) != STNL && class(ch) != STEOI)
ch = getch();
if (ch == '"') {
c = buf;
do {
ch = getch();
if (c < &buf[IDFSIZE]) *c++ = ch;
if (class(ch) == STNL || class(ch) == STEOI) {
LineNumber++;
error(s_error);
return;
}
} while (ch != '"');
*--c = '\0';
do {
ch = getch();
} while (class(ch) != STNL && class(ch) != STEOI);
/*
* Remember the file name
*/
if (class(ch) == STNL && strcmp(FileName,buf)) {
FileName = Salloc(buf,(unsigned) strlen(buf) + 1);
WorkingDir = getwdir(FileName);
}
}
if (class(ch) == STEOI) {
error(s_error);
return;
}
LineNumber = i;
}
}
STATIC
CheckForLet()
{
register int ch;
LoadChar(ch);
if (ch != EOI) {
if (class(ch) == STIDF) {
lexerror("token separator required between identifier and number");
}
PushBack();
}
}
int
LLlex()
{
/* LLlex() is the Lexical Analyzer.
The putting aside of tokens is taken into account.
*/
register t_token *tk = ˙
char buf[(IDFSIZE > NUMSIZE ? IDFSIZE : NUMSIZE) + 2];
register int ch, nch;
toktype = error_type;
if (ASIDE) { /* a token is put aside */
*tk = aside;
ASIDE = 0;
return tk->tk_symb;
}
token_nmb++;
again:
ch = getch();
tk->tk_lineno = LineNumber;
switch (class(ch)) {
case STNL:
LineNumber++;
#ifdef DEBUG
cntlines++;
#endif
CheckForLineDirective();
goto again;
case STSKIP:
goto again;
case STGARB:
if ((unsigned) ch - 040 < 0137) {
lexerror("garbage char %c", ch);
}
else lexerror("garbage char \\%03o", ch);
goto again;
case STSIMP:
if (ch == '(') {
LoadChar(nch);
if (nch == '*') {
SkipComment();
goto again;
}
PushBack();
}
if (ch == '&') return tk->tk_symb = AND;
if (ch == '~') return tk->tk_symb = NOT;
return tk->tk_symb = ch;
case STCOMP:
LoadChar(nch);
switch (ch) {
case '.':
if (nch == '.') {
return tk->tk_symb = UPTO;
}
break;
case ':':
if (nch == '=') {
return tk->tk_symb = BECOMES;
}
break;
case '<':
if (nch == '=') {
return tk->tk_symb = LESSEQUAL;
}
if (nch == '>') {
return tk->tk_symb = '#';
}
break;
case '>':
if (nch == '=') {
return tk->tk_symb = GREATEREQUAL;
}
break;
default :
crash("(LLlex, STCOMP)");
}
PushBack();
return tk->tk_symb = ch;
case STIDF:
{
register char *tag = &buf[0];
register t_idf *id;
do {
if (tag - buf < idfsize) *tag++ = ch;
LoadChar(ch);
if (ch == '_' && *(tag-1) == '_') {
lexerror("an identifier may not contain two consecutive underscores");
}
} while(in_idf(ch));
PushBack();
*tag = '\0';
if (*(tag - 1) == '_') {
lexerror("last character of an identifier may not be an underscore");
}
tk->TOK_IDF = id = str2idf(buf, 1);
return tk->tk_symb = id->id_reserved ? id->id_reserved : IDENT;
}
case STSTR: {
register struct string *str = GetString(ch);
if (str->s_length == 1) {
tk->TOK_INT = *(str->s_str) & 0377;
toktype = char_type;
free(str->s_str);
free((char *) str);
}
else {
tk->tk_data.tk_str = str;
if (! fit((arith)(str->s_length), (int) word_size)) {
lexerror("string too long");
}
toktype = standard_type(T_STRING, 1, (arith)(str->s_length));
}
return tk->tk_symb = STRING;
}
case STNUM:
{
/* The problem arising with the "parsing" of a number
is that we don't know the base in advance so we
have to read the number with the help of a rather
complex finite automaton.
*/
enum statetp {Oct,OptHex,Hex,Dec,OctEndOrHex,End,OptReal,Real};
register enum statetp state;
register int base = 8;
register char *np = &buf[0];
*np++ = ch;
state = is_oct(ch) ? Oct : Dec;
LoadChar(ch);
for (;;) {
switch(state) {
case Oct:
while (is_oct(ch)) {
if (np < &buf[NUMSIZE]) *np++ = ch;
LoadChar(ch);
}
if (ch == 'B' || ch == 'C') {
state = OctEndOrHex;
break;
}
/* Fall Through */
case Dec:
base = 10;
while (is_dig(ch)) {
if (np < &buf[NUMSIZE]) {
*np++ = ch;
}
LoadChar(ch);
}
if (ch == 'D') state = OptHex;
else if (is_hex(ch)) state = Hex;
else if (ch == '.') state = OptReal;
else {
state = End;
if (ch == 'H') base = 16;
else PushBack();
}
break;
case OptHex:
LoadChar(ch);
if (is_hex(ch)) {
if (np < &buf[NUMSIZE]) *np++ = 'D';
state = Hex;
}
else {
state = End;
ch = 'D';
PushBack();
}
break;
case Hex:
while (is_hex(ch)) {
if (np < &buf[NUMSIZE]) *np++ = ch;
LoadChar(ch);
}
base = 16;
state = End;
if (ch != 'H') {
lexerror("H expected after hex number");
PushBack();
}
break;
case OctEndOrHex:
if (np < &buf[NUMSIZE]) *np++ = ch;
LoadChar(ch);
if (ch == 'H') {
base = 16;
state = End;
break;
}
if (is_hex(ch)) {
state = Hex;
break;
}
PushBack();
ch = *--np;
*np++ = '\0';
/* Fall through */
case End: {
int ovfl = 0;
*np = '\0';
if (np >= &buf[NUMSIZE]) {
tk->TOK_INT = 1;
lexerror("constant too long");
}
else {
/* The upperbound will be the same as
when computed with something like
max(unsigned long) / base (when base
is even). The problem is that
unsigned long or unsigned arith is
not accepted by all compilers
*/
arith ubound = max_int[sizeof(arith)]
/ (base >> 1);
np = &buf[0];
while (*np == '0') np++;
tk->TOK_INT = 0;
while (*np) {
int c;
if (is_dig(*np)) {
c = *np++ - '0';
}
else {
assert(is_hex(*np));
c = *np++ - 'A' + 10;
}
if (tk->TOK_INT < 0 ||
tk->TOK_INT > ubound) {
ovfl++;
}
tk->TOK_INT = tk->TOK_INT*base;
if (tk->TOK_INT < 0 &&
tk->TOK_INT + c >= 0) {
ovfl++;
}
tk->TOK_INT += c;
}
}
toktype = card_type;
if (ch == 'C' && base == 8) {
toktype = char_type;
if (ovfl != 0 || tk->TOK_INT>255 ||
tk->TOK_INT < 0) {
lexwarning(W_ORDINARY, "character constant out of range");
}
CheckForLet();
return tk->tk_symb = INTEGER;
}
if (options['l']) {
if (base != 10) {
LoadChar(ch);
if (ch != 'D') {
PushBack();
}
}
}
if (ch == 'D' && (options['l'] || base == 10)) {
if (options['l']) {
/* Local extension: LONGCARD exists,
so internally also longintorcard_type
exists.
*/
toktype = longcard_type;
if (ovfl == 0 && tk->TOK_INT >= 0 &&
tk->TOK_INT<=max_int[(int)long_size]) {
toktype = longintorcard_type;
}
else if (! chk_bounds(tk->TOK_INT,
full_mask[(int)long_size],
T_CARDINAL)) {
ovfl = 1;
}
}
else {
if (ovfl != 0 ||
tk->TOK_INT > max_int[(int)long_size] ||
tk->TOK_INT < 0) {
ovfl = 1;
}
toktype = longint_type;
}
}
else if (ovfl == 0 && tk->TOK_INT >= 0 &&
tk->TOK_INT<=max_int[(int)int_size]) {
toktype = intorcard_type;
}
else if (! chk_bounds(tk->TOK_INT,
full_mask[(int)int_size],
T_CARDINAL)) {
ovfl = 1;
}
if (ovfl)
lexwarning(W_ORDINARY, "overflow in constant");
CheckForLet();
return tk->tk_symb = INTEGER;
}
case OptReal:
/* The '.' could be the first of the '..'
token. At this point, we need a
look-ahead of two characters.
*/
LoadChar(ch);
if (ch == '.') {
/* Indeed the '..' token
*/
PushBack();
PushBack();
state = End;
base = 10;
break;
}
state = Real;
break;
}
if (state == Real) break;
}
/* a real real constant */
if (np < &buf[NUMSIZE]) *np++ = '.';
toktype = real_type;
while (is_dig(ch)) {
/* Fractional part
*/
if (np < &buf[NUMSIZE]) *np++ = ch;
LoadChar(ch);
}
if (ch == 'D') {
toktype = longreal_type;
LoadChar(ch);
if (ch == '+' || ch == '-' || is_dig(ch)) {
ch = 'E';
PushBack();
}
}
if (ch == 'E') {
/* Scale factor
*/
if (np < &buf[NUMSIZE]) *np++ = ch;
LoadChar(ch);
if (ch == '+' || ch == '-') {
/* Signed scalefactor
*/
if (np < &buf[NUMSIZE]) *np++ = ch;
LoadChar(ch);
}
if (is_dig(ch)) {
do {
if (np < &buf[NUMSIZE]) *np++ = ch;
LoadChar(ch);
} while (is_dig(ch));
}
else {
lexerror("bad scale factor");
}
}
*np++ = '\0';
PushBack();
tk->tk_data.tk_real = new_real();
if (np >= &buf[NUMSIZE]) {
tk->TOK_RSTR = Salloc("0.0", 4);
lexerror("real constant too long");
}
else tk->TOK_RSTR = Salloc(buf, (unsigned) (np - buf));
CheckForLet();
flt_str2flt(tk->TOK_RSTR, &(tk->TOK_RVAL));
if (flt_status == FLT_OVFL) {
lexwarning(W_ORDINARY, "overflow in floating point constant");
}
return tk->tk_symb = REAL;
/*NOTREACHED*/
}
case STEOI:
return tk->tk_symb = -1;
case STCHAR:
default:
crash("(LLlex) Impossible character class");
/*NOTREACHED*/
}
/*NOTREACHED*/
}