#include "EXTERN.h"
#define PERL_IN_TOKE_C
#include "perl.h"
-#include "dquote_static.c"
+#include "dquote_inline.h"
#define new_constant(a,b,c,d,e,f,g) \
S_new_constant(aTHX_ a,b,STR_WITH_LEN(c),d,e,f, g)
* FUN1 : not used, except for not, which isn't a UNIOP
* BOop : bitwise or or xor
* BAop : bitwise and
+ * BCop : bitwise complement
* SHop : shift operator
* PWop : power operator
* PMop : pattern-matching operator
#define FUN1(f) return (pl_yylval.ival=f, PL_expect=XOPERATOR, PL_bufptr=s, REPORT((int)FUNC1))
#define BOop(f) return ao((pl_yylval.ival=f, PL_expect=XTERM, PL_bufptr=s, (int)BITOROP))
#define BAop(f) return ao((pl_yylval.ival=f, PL_expect=XTERM, PL_bufptr=s, (int)BITANDOP))
+#define BCop(f) return pl_yylval.ival=f, PL_expect=XTERM, PL_bufptr = s, \
+ REPORT('~')
#define SHop(f) return ao((pl_yylval.ival=f, PL_expect=XTERM, PL_bufptr=s, (int)SHIFTOP))
#define PWop(f) return ao((pl_yylval.ival=f, PL_expect=XTERM, PL_bufptr=s, (int)POWOP))
#define PMop(f) return(pl_yylval.ival=f, PL_expect=XTERM, PL_bufptr=s, REPORT((int)MATCHOP))
* It prints "Missing operator before end of line" if there's nothing
* after the missing operator, or "... before <...>" if there is something
* after the missing operator.
+ *
+ * PL_bufptr is expected to point to the start of the thing that was found,
+ * and s after the next token or partial token.
*/
STATIC void
will be destroyed and the former value of L</PL_parser> will be restored.
Nothing else need be done to clean up the parsing context.
-The code to be parsed comes from I<line> and I<rsfp>. I<line>, if
+The code to be parsed comes from C<line> and C<rsfp>. C<line>, if
non-null, provides a string (in SV form) containing code to be parsed.
-A copy of the string is made, so subsequent modification of I<line>
-does not affect parsing. I<rsfp>, if non-null, provides an input stream
+A copy of the string is made, so subsequent modification of C<line>
+does not affect parsing. C<rsfp>, if non-null, provides an input stream
from which code will be read to be parsed. If both are non-null, the
-code in I<line> comes first and must consist of complete lines of input,
-and I<rsfp> supplies the remainder of the source.
+code in C<line> comes first and must consist of complete lines of input,
+and C<rsfp> supplies the remainder of the source.
-The I<flags> parameter is reserved for future use. Currently it is only
+The C<flags> parameter is reserved for future use. Currently it is only
used by perl internally, so extensions should always pass zero.
=cut
if (PL_parser->lex_flags & LEX_DONT_CLOSE_RSFP)
PerlIO_clearerr(parser->rsfp);
- else if (parser->rsfp && (!parser->old_parser ||
- (parser->old_parser && parser->rsfp != parser->old_parser->rsfp)))
+ else if (parser->rsfp && (!parser->old_parser
+ || (parser->old_parser && parser->rsfp != parser->old_parser->rsfp)))
PerlIO_close(parser->rsfp);
SvREFCNT_dec(parser->rsfp_filters);
SvREFCNT_dec(parser->lex_stuff);
=for apidoc Amx|char *|lex_grow_linestr|STRLEN len
Reallocates the lexer buffer (L</PL_parser-E<gt>linestr>) to accommodate
-at least I<len> octets (including terminating C<NUL>). Returns a
+at least C<len> octets (including terminating C<NUL>). Returns a
pointer to the reallocated buffer. This is necessary before making
any direct modification of the buffer that would increase its length.
L</lex_stuff_pvn> provides a more convenient way to insert text into
uses of this facility run the risk of the inserted characters being
interpreted in an unintended manner.
-The string to be inserted is represented by I<len> octets starting
-at I<pv>. These octets are interpreted as either UTF-8 or Latin-1,
-according to whether the C<LEX_STUFF_UTF8> flag is set in I<flags>.
+The string to be inserted is represented by C<len> octets starting
+at C<pv>. These octets are interpreted as either UTF-8 or Latin-1,
+according to whether the C<LEX_STUFF_UTF8> flag is set in C<flags>.
The characters are recoded for the lexer buffer, according to how the
buffer is currently being interpreted (L</lex_bufutf8>). If a string
to be inserted is available as a Perl scalar, the L</lex_stuff_sv>
uses of this facility run the risk of the inserted characters being
interpreted in an unintended manner.
-The string to be inserted is represented by octets starting at I<pv>
+The string to be inserted is represented by octets starting at C<pv>
and continuing to the first nul. These octets are interpreted as either
UTF-8 or Latin-1, according to whether the C<LEX_STUFF_UTF8> flag is set
-in I<flags>. The characters are recoded for the lexer buffer, according
+in C<flags>. The characters are recoded for the lexer buffer, according
to how the buffer is currently being interpreted (L</lex_bufutf8>).
If it is not convenient to nul-terminate a string to be inserted, the
L</lex_stuff_pvn> function is more appropriate.
uses of this facility run the risk of the inserted characters being
interpreted in an unintended manner.
-The string to be inserted is the string value of I<sv>. The characters
+The string to be inserted is the string value of C<sv>. The characters
are recoded for the lexer buffer, according to how the buffer is currently
being interpreted (L</lex_bufutf8>). If a string to be inserted is
not already a Perl scalar, the L</lex_stuff_pvn> function avoids the
=for apidoc Amx|void|lex_unstuff|char *ptr
Discards text about to be lexed, from L</PL_parser-E<gt>bufptr> up to
-I<ptr>. Text following I<ptr> will be moved, and the buffer shortened.
+C<ptr>. Text following C<ptr> will be moved, and the buffer shortened.
This hides the discarded text from any lexing code that runs later,
as if the text had never appeared.
=for apidoc Amx|void|lex_read_to|char *ptr
Consume text in the lexer buffer, from L</PL_parser-E<gt>bufptr> up
-to I<ptr>. This advances L</PL_parser-E<gt>bufptr> to match I<ptr>,
+to C<ptr>. This advances L</PL_parser-E<gt>bufptr> to match C<ptr>,
performing the correct bookkeeping whenever a newline character is passed.
This is the normal way to consume lexed text.
=for apidoc Amx|void|lex_discard_to|char *ptr
Discards the first part of the L</PL_parser-E<gt>linestr> buffer,
-up to I<ptr>. The remaining content of the buffer will be moved, and
-all pointers into the buffer updated appropriately. I<ptr> must not
+up to C<ptr>. The remaining content of the buffer will be moved, and
+all pointers into the buffer updated appropriately. C<ptr> must not
be later in the buffer than the position of L</PL_parser-E<gt>bufptr>:
it is not permitted to discard text that has yet to be lexed.
If L</PL_parser-E<gt>bufptr> is pointing to the very end of the current
chunk (i.e., the current chunk has been entirely consumed), normally the
current chunk will be discarded at the same time that the new chunk is
-read in. If I<flags> includes C<LEX_KEEP_PREVIOUS>, the current chunk
+read in. If C<flags> includes C<LEX_KEEP_PREVIOUS>, the current chunk
will not be discarded. If the current chunk has not been entirely
consumed, then it will not be discarded regardless of the flag.
*/
#define LEX_FAKE_EOF 0x80000000
-#define LEX_NO_TERM 0x40000000
+#define LEX_NO_TERM 0x40000000 /* here-doc */
bool
Perl_lex_next_chunk(pTHX_ U32 flags)
bool got_some;
if (flags & ~(LEX_KEEP_PREVIOUS|LEX_FAKE_EOF|LEX_NO_TERM))
Perl_croak(aTHX_ "Lexing code internal error (%s)", "lex_next_chunk");
+ if (!(flags & LEX_NO_TERM) && PL_lex_inwhat)
+ return FALSE;
linestr = PL_parser->linestr;
buf = SvPVX(linestr);
- if (!(flags & LEX_KEEP_PREVIOUS) &&
- PL_parser->bufptr == PL_parser->bufend) {
+ if (!(flags & LEX_KEEP_PREVIOUS)
+ && PL_parser->bufptr == PL_parser->bufend)
+ {
old_bufend_pos = bufptr_pos = oldbufptr_pos = oldoldbufptr_pos = 0;
linestart_pos = 0;
if (PL_parser->last_uni != PL_parser->bufend)
CopLINE_set(PL_curcop, PL_parser->preambling + 1);
PL_parser->preambling = NOLINE;
}
- if (got_some_for_debugger && (PERLDB_LINE || PERLDB_SAVESRC) &&
- PL_curstash != PL_debstash) {
+ if ( got_some_for_debugger
+ && PERLDB_LINE_OR_SAVESRC
+ && PL_curstash != PL_debstash)
+ {
/* debugger active and we're not compiling the debugger code,
* so store the line into the debugger's array of lines
*/
If the next character is in (or extends into) the next chunk of input
text, the next chunk will be read in. Normally the current chunk will be
-discarded at the same time, but if I<flags> includes C<LEX_KEEP_PREVIOUS>
+discarded at the same time, but if C<flags> includes C<LEX_KEEP_PREVIOUS>
then the current chunk will not be discarded.
If the input is being interpreted as UTF-8 and a UTF-8 encoding error
If the next character is in (or extends into) the next chunk of input
text, the next chunk will be read in. Normally the current chunk will be
-discarded at the same time, but if I<flags> includes C<LEX_KEEP_PREVIOUS>
+discarded at the same time, but if C<flags> includes C<LEX_KEEP_PREVIOUS>
then the current chunk will not be discarded.
If the input is being interpreted as UTF-8 and a UTF-8 encoding error
If spaces extend into the next chunk of input text, the next chunk will
be read in. Normally the current chunk will be discarded at the same
-time, but if I<flags> includes C<LEX_KEEP_PREVIOUS> then the current
+time, but if C<flags> includes C<LEX_KEEP_PREVIOUS> then the current
chunk will not be discarded.
=cut
incline(s);
need_incline = 0;
}
+ } else if (!c) {
+ s++;
} else {
break;
}
in_brackets = TRUE;
else if (*p == ']')
in_brackets = FALSE;
- else if ((*p == '@' || *p == '%') &&
- !after_slash &&
- !in_brackets ) {
+ else if ((*p == '@' || *p == '%')
+ && !after_slash
+ && !in_brackets )
+ {
must_be_last = TRUE;
greedy_proto = *p;
}
const char *n;
const char *e;
line_t line_num;
+ UV uv;
PERL_ARGS_ASSERT_INCLINE;
if (*e != '\n' && *e != '\0')
return; /* false alarm */
- line_num = grok_atou(n, &e) - 1;
+ if (!grok_atoUV(n, &uv, &e))
+ return;
+ line_num = ((line_t)uv) - 1;
if (t - s > 0) {
const STRLEN len = t - s;
{
PERL_ARGS_ASSERT_SKIPSPACE_FLAGS;
if (PL_lex_formbrack && PL_lex_brackets <= PL_lex_formbrack) {
- while (s < PL_bufend && SPACE_OR_TAB(*s))
+ while (s < PL_bufend && (SPACE_OR_TAB(*s) || !*s))
s++;
} else {
STRLEN bufptr_pos = PL_bufptr - SvPVX(PL_linestr);
PL_bufptr = s;
lex_read_space(flags | LEX_KEEP_PREVIOUS |
- (PL_sublex_info.sub_inwhat || PL_lex_state == LEX_FORMLINE ?
+ (PL_lex_inwhat || PL_lex_state == LEX_FORMLINE ?
LEX_NO_NEXT_CHUNK : 0));
s = PL_bufptr;
PL_bufptr = SvPVX(PL_linestr) + bufptr_pos;
PL_last_uni++;
s = PL_last_uni;
while (isWORDCHAR_lazy_if(s,UTF) || *s == '-')
- s++;
+ s += UTF ? UTF8SKIP(s) : 1;
if ((t = strchr(s, '(')) && t < PL_bufptr)
return;
Perl_ck_warner_d(aTHX_ packWARN(WARN_AMBIGUOUS),
- "Warning: Use of \"%.*s\" without parentheses is ambiguous",
- (int)(s - PL_last_uni), PL_last_uni);
+ "Warning: Use of \"%"UTF8f"\" without parentheses is ambiguous",
+ UTF8fARG(UTF, (int)(s - PL_last_uni), PL_last_uni));
}
/*
tokereport(type, &NEXTVAL_NEXTTOKE);
}
#endif
+ assert(PL_nexttoke < C_ARRAY_LENGTH(PL_nexttype));
PL_nexttype[PL_nexttoke] = type;
PL_nexttoke++;
if (PL_lex_state != LEX_KNOWNEXT) {
start = skipspace(start);
s = start;
- if (isIDFIRST_lazy_if(s,UTF) ||
- (allow_pack && *s == ':') )
+ if (isIDFIRST_lazy_if(s,UTF)
+ || (allow_pack && *s == ':') )
{
s = scan_word(s, PL_tokenbuf, sizeof PL_tokenbuf, allow_pack, &len);
if (check_keyword) {
s = (char *)scan_version(s, ver, 0);
version = newSVOP(OP_CONST, 0, ver);
}
- else if ( (*s != ';' && *s != '{' && *s != '}' ) &&
- (s = skipspace(s), (*s != ';' && *s != '{' && *s != '}' )))
+ else if ((*s != ';' && *s != '{' && *s != '}' )
+ && (s = skipspace(s), (*s != ';' && *s != '{' && *s != '}' )))
{
PL_bufptr = s;
if (errstr)
return THING;
}
if (op_type == OP_CONST) {
- SV *sv = tokeq(PL_lex_stuff);
+ SV *sv = PL_lex_stuff;
+ PL_lex_stuff = NULL;
+ sv = tokeq(sv);
if (SvTYPE(sv) == SVt_PVIV) {
/* Overloaded constants, nothing fancy: Convert to SVt_PV: */
sv = nsv;
}
pl_yylval.opval = (OP*)newSVOP(op_type, 0, sv);
- PL_lex_stuff = NULL;
return THING;
}
SAVEI32(PL_lex_casemods);
SAVEI32(PL_lex_starts);
SAVEI8(PL_lex_state);
+ SAVEI8(PL_lex_defer);
SAVESPTR(PL_lex_repl);
SAVEVPTR(PL_lex_inpat);
SAVEI16(PL_lex_inwhat);
PL_lex_stuff = NULL;
PL_sublex_info.repl = NULL;
+ /* Arrange for PL_lex_stuff to be freed on scope exit, in case it gets
+ set for an inner quote-like operator and then an error causes scope-
+ popping. We must not have a PL_lex_stuff value left dangling, as
+ that breaks assumptions elsewhere. See bug #123617. */
+ SAVEGENERICSV(PL_lex_stuff);
+ SAVEGENERICSV(PL_sublex_info.repl);
+
PL_bufend = PL_bufptr = PL_oldbufptr = PL_oldoldbufptr = PL_linestart
= SvPVX(PL_linestr);
PL_bufend += SvCUR(PL_linestr);
PL_bufend = SvPVX(PL_linestr);
PL_bufend += SvCUR(PL_linestr);
PL_expect = XOPERATOR;
- PL_sublex_info.sub_inwhat = 0;
return ')';
}
}
/* We deliberately don't try to print the malformed character, which
* might not print very well; it also may be just the first of many
* malformations, so don't print what comes after it */
- yyerror(Perl_form(aTHX_
+ yyerror_pv(Perl_form(aTHX_
"Malformed UTF-8 character immediately after '%.*s'",
- (int) (first_bad_char_loc - (U8 *) backslash_ptr), backslash_ptr));
+ (int) (first_bad_char_loc - (U8 *) backslash_ptr), backslash_ptr),
+ SVf_UTF8);
return NULL;
}
\l \L \u \U \Q \E
(?{ or (??{
-
In transliterations:
characters are VERY literal, except for - not at the start or end
of the string, which indicates a range. If the range is in bytes,
#ifdef EBCDIC
/* Because of the discontinuities in EBCDIC A-Z and a-z, expand
* any subsets of these ranges into individual characters */
- if (literal_endpoint == 2 &&
- ((isLOWER_A(min) && isLOWER_A(max)) ||
- (isUPPER_A(min) && isUPPER_A(max))))
+ if (literal_endpoint == 2
+ && ((isLOWER_A(min) && isLOWER_A(max))
+ || (isUPPER_A(min) && isUPPER_A(max))))
{
for (i = min; i <= max; i++) {
if (isALPHA_A(i))
}
}
- /* if we get here, we're not doing a transliteration */
+ /* if we get to any of these else's, we're not doing a
+ * transliteration. */
else if (*s == '[' && PL_lex_inpat && !in_charclass) {
char *s1 = s-1;
while (s+1 < send && *s != ')')
*d++ = *s++;
}
- else if (!PL_lex_casemods &&
- ( s[2] == '{' /* This should match regcomp.c */
- || (s[2] == '?' && s[3] == '{')))
+ else if (!PL_lex_casemods
+ && ( s[2] == '{' /* This should match regcomp.c */
+ || (s[2] == '?' && s[3] == '{')))
{
break;
}
}
/* likewise skip #-initiated comments in //x patterns */
- else if (*s == '#' && PL_lex_inpat && !in_charclass &&
- ((PMOP*)PL_lex_inpat)->op_pmflags & RXf_PMf_EXTENDED) {
+ else if (*s == '#'
+ && PL_lex_inpat
+ && !in_charclass
+ && ((PMOP*)PL_lex_inpat)->op_pmflags & RXf_PMf_EXTENDED)
+ {
while (s+1 < send && *s != '\n')
*d++ = *s++;
}
(@foo, @::foo, @'foo, @{foo}, @$foo, @+, @-)
*/
else if (*s == '@' && s[1]) {
- if (isWORDCHAR_lazy_if(s+1,UTF))
+ if (UTF ? isIDFIRST_utf8((U8*)s+1) : isWORDCHAR_A(s[1]))
break;
if (strchr(":'{$", s[1]))
break;
/* warn on \1 - \9 in substitution replacements, but note that \11
* is an octal; and \19 is \1 followed by '9' */
- if (PL_lex_inwhat == OP_SUBST && !PL_lex_inpat &&
- isDIGIT(*s) && *s != '0' && !isDIGIT(s[1]))
+ if (PL_lex_inwhat == OP_SUBST
+ && !PL_lex_inpat
+ && isDIGIT(*s)
+ && *s != '0'
+ && !isDIGIT(s[1]))
{
/* diag_listed_as: \%d better written as $%d */
Perl_ck_warner(aTHX_ packWARN(WARN_SYNTAX), "\\%c better written as $%c", *s, *s);
if (has_utf8) {
d = (char*)uvchr_to_utf8((U8*)d, uv);
- if (PL_lex_inwhat == OP_TRANS &&
- PL_sublex_info.sub_op) {
+ if (PL_lex_inwhat == OP_TRANS
+ && PL_sublex_info.sub_op)
+ {
PL_sublex_info.sub_op->op_private |=
(PL_lex_repl ? OPpTRANS_FROM_UTF
: OPpTRANS_TO_UTF);
* Otherwise must be some \N{NAME}: convert to \N{U+c1.c2...}
* if a pattern; otherwise convert to utf8
*
- * If the regex compiler should ever need to differentiate
- * between the \N{U+...} and \N{name} forms, that could easily
- * be done here by stripping any leading zeros from the
- * \N{U+...} case, and adding them to the other one. */
-
- /* Here, 's' points to the 'N'; the test below is guaranteed to
+ * Here, 's' points to the 'N'; the test below is guaranteed to
* succeed if we are being called on a pattern, as we already
* know from a test above that the next character is a '{'. A
* non-pattern \N must mean 'named character', which requires
/* Here it looks like a named character */
if (*s == 'U' && s[1] == '+') { /* \N{U+...} */
- I32 flags = PERL_SCAN_ALLOW_UNDERSCORES
- | PERL_SCAN_SILENT_ILLDIGIT
- | PERL_SCAN_DISALLOW_PREFIX;
- STRLEN len;
-
s += 2; /* Skip to next char after the 'U+' */
- len = e - s;
- uv = grok_hex(s, &len, &flags, NULL);
- if (len == 0
- || ( len != (STRLEN)(e - s) && s[len] != '.'
- && PL_lex_inpat))
- {
- bad_NU:
- yyerror("Invalid hexadecimal number in \\N{U+...}");
- s = e + 1;
- continue;
- }
-
if (PL_lex_inpat) {
-#ifdef EBCDIC
- s -= 5; /* Include the '\N{U+' */
- /* On EBCDIC platforms, in \N{U+...}, the '...' is a
- * Unicode value, so convert to native so downstream
- * code can continue to assume it's native */
- /* XXX This should be in the regexp parser,
- because doing it here makes /\N{U+41}/ and
- =~ '\N{U+41}' do different things. */
- d += my_snprintf(d, e - s + 1 + 1, /* includes the '}'
- and the \0 */
- "\\N{U+%X",
- (unsigned int) UNI_TO_NATIVE(uv));
- s += 5 + len;
- while (*s == '.') {
- s++;
- len = e - s;
- uv = grok_hex(s, &len, &flags, NULL);
- if (!len
- || (len != (STRLEN)(e - s) && s[len] != '.'))
- goto bad_NU;
- s--;
- d += my_snprintf(
- d, e - s + 1 + 1, ".%X",
- (unsigned int)UNI_TO_NATIVE(uv)
- );
- s += len + 1;
+
+ /* In patterns, we can have \N{U+xxxx.yyyy.zzzz...} */
+ /* Check the syntax. */
+ const char *orig_s;
+ orig_s = s - 5;
+ if (!isXDIGIT(*s)) {
+ bad_NU:
+ yyerror(
+ "Invalid hexadecimal number in \\N{U+...}"
+ );
+ s = e + 1;
+ continue;
}
- *(d++) = '}';
-#else
- /* On non-EBCDIC platforms, pass it through unchanged.
- * The reason we evaluate the numbers is to make
- * sure there wasn't a syntax error. */
- const char * const orig_s = s - 5;
- while (*s == '.') {
- s++;
- len = e - s;
- uv = grok_hex(s, &len, &flags, NULL);
- if (!len
- || (len != (STRLEN)(e - s) && s[len] != '.'))
- goto bad_NU;
+ while (++s < e) {
+ if (isXDIGIT(*s))
+ continue;
+ else if ((*s == '.' || *s == '_')
+ && isXDIGIT(s[1]))
+ continue;
+ goto bad_NU;
}
- /* +1 is for the '}' */
+
+ /* Pass everything through unchanged.
+ * +1 is for the '}' */
Copy(orig_s, d, e - orig_s + 1, char);
d += e - orig_s + 1;
-#endif
}
else { /* Not a pattern: convert the hex to string */
+ I32 flags = PERL_SCAN_ALLOW_UNDERSCORES
+ | PERL_SCAN_SILENT_ILLDIGIT
+ | PERL_SCAN_DISALLOW_PREFIX;
+ STRLEN len = e - s;
+ uv = grok_hex(s, &len, &flags, NULL);
+ if (len == 0 || (len != (STRLEN)(e - s)))
+ goto bad_NU;
/* If the destination is not in utf8, unconditionally
* recode it to be so. This is because \N{} implies
char hex_string[4];
int len =
my_snprintf(hex_string,
- sizeof(hex_string),
- "%02X.", (U8) *str);
- PERL_MY_SNPRINTF_POST_GUARD(len, sizeof(hex_string));
+ sizeof(hex_string),
+ "%02X.",
+
+ /* The regex compiler is
+ * expecting Unicode, not
+ * native */
+ (U8) NATIVE_TO_LATIN1(*str));
+ PERL_MY_SNPRINTF_POST_GUARD(len,
+ sizeof(hex_string));
Copy(hex_string, d, 3, char);
d += 3;
str++;
len,
&char_length,
UTF8_ALLOW_ANYUV);
- /* Convert first code point to hex, including
- * the boiler plate before it. */
+ /* Convert first code point to Unicode hex,
+ * including the boiler plate before it. */
output_length =
my_snprintf(hex_string, sizeof(hex_string),
- "\\N{U+%X",
- (unsigned int) uv);
+ "\\N{U+%X",
+ (unsigned int) NATIVE_TO_UNI(uv));
/* Make sure there is enough space to hold it */
d = off + SvGROW(sv, off
d += output_length;
/* For each subsequent character, append dot and
- * its ordinal in hex */
+ * its Unicode code point in hex */
while ((str += char_length) < str_end) {
const STRLEN off = d - SvPVX_const(sv);
U32 uv = utf8n_to_uvchr((U8 *) str,
UTF8_ALLOW_ANYUV);
output_length =
my_snprintf(hex_string,
- sizeof(hex_string),
- ".%X",
- (unsigned int) uv);
+ sizeof(hex_string),
+ ".%X",
+ (unsigned int) NATIVE_TO_UNI(uv));
d = off + SvGROW(sv, off
+ output_length
else
weight -= 10;
}
- else if (*s == '$' && s[1] &&
- strchr("[#!%*<>()-=",s[1])) {
+ else if (*s == '$'
+ && s[1]
+ && strchr("[#!%*<>()-=",s[1]))
+ {
if (/*{*/ strchr("])} =",s[2]))
weight -= 10;
else
&& !(last_un_char == '$' || last_un_char == '@'
|| last_un_char == '&')
&& isALPHA(*s) && s[1] && isALPHA(s[1])) {
- char *d = tmpbuf;
+ char *d = s;
while (isALPHA(*s))
- *d++ = *s++;
- *d = '\0';
- if (keyword(tmpbuf, d - tmpbuf, 0))
+ s++;
+ if (keyword(d, s - d, 0))
weight -= 150;
}
if (un_char == last_un_char + 1)
}
if (*start == '$') {
- if (cv || PL_last_lop_op == OP_PRINT || PL_last_lop_op == OP_SAY ||
- isUPPER(*PL_tokenbuf))
+ if (cv || PL_last_lop_op == OP_PRINT || PL_last_lop_op == OP_SAY
+ || isUPPER(*PL_tokenbuf))
return 0;
s = skipspace(s);
PL_bufptr = start;
if (len == 11 && *pkgname == '_' && strEQ(pkgname, "__PACKAGE__"))
return PL_curstash;
- if (len > 2 &&
- (pkgname[len - 2] == ':' && pkgname[len - 1] == ':') &&
- (gv = gv_fetchpvn_flags(pkgname, len, ( UTF ? SVf_UTF8 : 0 ), SVt_PVHV)))
+ if (len > 2
+ && (pkgname[len - 2] == ':' && pkgname[len - 1] == ':')
+ && (gv = gv_fetchpvn_flags(pkgname,
+ len,
+ ( UTF ? SVf_UTF8 : 0 ), SVt_PVHV)))
{
return GvHV(gv); /* Foo:: */
}
STATIC bool
S_word_takes_any_delimeter(char *p, STRLEN len)
{
- return (len == 1 && strchr("msyq", p[0])) ||
- (len == 2 && (
- (p[0] == 't' && p[1] == 'r') ||
- (p[0] == 'q' && strchr("qwxr", p[1]))));
+ return (len == 1 && strchr("msyq", p[0]))
+ || (len == 2
+ && ((p[0] == 't' && p[1] == 'r')
+ || (p[0] == 'q' && strchr("qwxr", p[1]))));
}
static void
SvREFCNT_dec(tmp);
} );
- switch (PL_lex_state) {
- case LEX_NORMAL:
- case LEX_INTERPNORMAL:
- break;
-
/* when we've already built the next token, just pull it out of the queue */
- case LEX_KNOWNEXT:
+ if (PL_nexttoke) {
PL_nexttoke--;
pl_yylval = PL_nextval[PL_nexttoke];
if (!PL_nexttoke) {
}
return REPORT(next_type == 'p' ? pending_ident() : next_type);
}
+ }
+
+ switch (PL_lex_state) {
+ case LEX_NORMAL:
+ case LEX_INTERPNORMAL:
+ break;
/* interpolated case modifiers like \L \U, including \Q and \E.
when we get here, PL_bufptr is at the \
I32 tmp;
if (strnEQ(s, "L\\u", 3) || strnEQ(s, "U\\l", 3))
tmp = *s, *s = s[2], s[2] = (char)tmp; /* misordered... */
- if ((*s == 'L' || *s == 'U' || *s == 'F') &&
- (strchr(PL_lex_casestack, 'L')
+ if ((*s == 'L' || *s == 'U' || *s == 'F')
+ && (strchr(PL_lex_casestack, 'L')
|| strchr(PL_lex_casestack, 'U')
- || strchr(PL_lex_casestack, 'F'))) {
+ || strchr(PL_lex_casestack, 'F')))
+ {
PL_lex_casestack[--PL_lex_casemods] = '\0';
PL_lex_allbrackets--;
return REPORT(')');
/* FALLTHROUGH */
case LEX_INTERPEND:
+ /* Treat state as LEX_NORMAL if we have no inner lexing scope.
+ XXX This hack can be removed if we stop setting PL_lex_state to
+ LEX_KNOWNEXT, as can the hack under LEX_INTREPCONCAT below. */
+ if (UNLIKELY(!PL_lex_inwhat)) {
+ PL_lex_state = LEX_NORMAL;
+ break;
+ }
+
if (PL_lex_dojoin) {
const U8 dojoin_was = PL_lex_dojoin;
PL_lex_dojoin = FALSE;
Perl_croak(aTHX_ "panic: INTERPCONCAT, lex_brackets=%ld",
(long) PL_lex_brackets);
#endif
+ /* Treat state as LEX_NORMAL when not in an inner lexing scope.
+ XXX This hack can be removed if we stop setting PL_lex_state to
+ LEX_KNOWNEXT. */
+ if (UNLIKELY(!PL_lex_inwhat)) {
+ PL_lex_state = LEX_NORMAL;
+ break;
+ }
+
if (PL_bufptr == PL_bufend)
return REPORT(sublex_done());
case 26:
goto fake_eof; /* emulate EOF on ^D or ^Z */
case 0:
- if (!PL_rsfp && (!PL_parser->filtered || s+1 < PL_bufend)) {
+ if ((!PL_rsfp || PL_lex_inwhat)
+ && (!PL_parser->filtered || s+1 < PL_bufend)) {
PL_last_uni = 0;
PL_last_lop = 0;
- if (PL_lex_brackets &&
- PL_lex_brackstack[PL_lex_brackets-1] != XFAKEEOF) {
+ if (PL_lex_brackets
+ && PL_lex_brackstack[PL_lex_brackets-1] != XFAKEEOF)
+ {
yyerror((const char *)
(PL_lex_formbrack
? "Format not terminated"
PL_oldoldbufptr = PL_oldbufptr = s = PL_linestart = SvPVX(PL_linestr);
PL_bufend = SvPVX(PL_linestr) + SvCUR(PL_linestr);
PL_last_lop = PL_last_uni = NULL;
- if ((PERLDB_LINE || PERLDB_SAVESRC) && PL_curstash != PL_debstash)
+ if (PERLDB_LINE_OR_SAVESRC && PL_curstash != PL_debstash)
update_debugger_info(PL_linestr, NULL, 0);
goto retry;
}
s = PL_bufptr;
/* If it looks like the start of a BOM or raw UTF-16,
* check if it in fact is. */
- if (bof && PL_rsfp &&
- (*s == 0 ||
- *(U8*)s == BOM_UTF8_FIRST_BYTE ||
- *(U8*)s >= 0xFE ||
- s[1] == 0)) {
+ if (bof && PL_rsfp
+ && (*s == 0
+ || *(U8*)s == BOM_UTF8_FIRST_BYTE
+ || *(U8*)s >= 0xFE
+ || s[1] == 0))
+ {
Off_t offset = (IV)PerlIO_tell(PL_rsfp);
bof = (offset == (Off_t)SvCUR(PL_linestr));
#if defined(PERLIO_USING_CRLF) && defined(PERL_TEXTMODE_SCRIPTS)
d = instr(s,"perl -");
if (!d) {
d = instr(s,"perl");
+ if (d && d[4] == '6')
+ d = NULL;
#if defined(DOSISH)
/* avoid getting into infinite loops when shebang
* line contains "Perl" rather than "perl" */
*s = '#'; /* Don't try to parse shebang line */
}
#endif /* ALTERNATE_SHEBANG */
- if (!d &&
- *s == '#' &&
- ipathend > ipath &&
- !PL_minus_c &&
- !instr(s,"indir") &&
- instr(PL_origargv[0],"perl"))
+ if (!d
+ && *s == '#'
+ && ipathend > ipath
+ && !PL_minus_c
+ && !instr(s,"indir")
+ && instr(PL_origargv[0],"perl"))
{
dVAR;
char **newargv;
} while (argc && argv[0][0] == '-' && argv[0][1]);
init_argv_symbols(argc,argv);
}
- if (((PERLDB_LINE || PERLDB_SAVESRC) && !oldpdb) ||
- ((PL_minus_n || PL_minus_p) && !(oldn || oldp)))
+ if ( (PERLDB_LINE_OR_SAVESRC && !oldpdb)
+ || ((PL_minus_n || PL_minus_p) && !(oldn || oldp)))
/* if we have already added "LINE: while (<>) {",
we must not do it again */
{
PL_bufend = SvPVX(PL_linestr) + SvCUR(PL_linestr);
PL_last_lop = PL_last_uni = NULL;
PL_preambled = FALSE;
- if (PERLDB_LINE || PERLDB_SAVESRC)
+ if (PERLDB_LINE_OR_SAVESRC)
(void)gv_fetchfile(PL_origfilename);
goto retry;
}
}
if (PL_lex_formbrack && PL_lex_brackets <= PL_lex_formbrack) {
PL_lex_state = LEX_FORMLINE;
- NEXTVAL_NEXTTOKE.ival = 0;
force_next(FORMRBRACK);
TOKEN(';');
}
goto retry;
case '#':
case '\n':
- if (PL_lex_state != LEX_NORMAL ||
- (PL_in_eval && !PL_rsfp && !PL_parser->filtered)) {
+ if (PL_lex_state != LEX_NORMAL
+ || (PL_in_eval && !PL_rsfp && !PL_parser->filtered))
+ {
const bool in_comment = *s == '#';
if (*s == '#' && s == PL_linestart && PL_in_eval
&& !PL_rsfp && !PL_parser->filtered) {
incline(s);
if (PL_lex_formbrack && PL_lex_brackets <= PL_lex_formbrack) {
PL_lex_state = LEX_FORMLINE;
- NEXTVAL_NEXTTOKE.ival = 0;
force_next(FORMRBRACK);
TOKEN(';');
}
else if (*s == '>') {
s++;
s = skipspace(s);
- if (FEATURE_POSTDEREF_IS_ENABLED && (
- ((*s == '$' || *s == '&') && s[1] == '*')
+ if (((*s == '$' || *s == '&') && s[1] == '*')
||(*s == '$' && s[1] == '#' && s[2] == '*')
||((*s == '@' || *s == '%') && strchr("*[{", s[1]))
||(*s == '*' && (s[1] == '*' || s[1] == '{'))
- ))
+ )
{
- Perl_ck_warner_d(aTHX_
- packWARN(WARN_EXPERIMENTAL__POSTDEREF),
- "Postfix dereference is experimental"
- );
PL_expect = XPOSTDEREF;
TOKEN(ARROW);
}
TERM(ARROW);
}
if (PL_expect == XOPERATOR) {
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN) {
+ if (*s == '='
+ && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
s--;
TOKEN(0);
}
OPERATOR(PREINC);
}
if (PL_expect == XOPERATOR) {
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN) {
+ if (*s == '='
+ && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
s--;
TOKEN(0);
}
s++;
if (*s == '*') {
s++;
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN) {
+ if (*s == '=' && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
s -= 2;
TOKEN(0);
}
PWop(OP_POW);
}
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN) {
+ if (*s == '='
+ && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
s--;
TOKEN(0);
}
case '%':
{
if (PL_expect == XOPERATOR) {
- if (s[1] == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ if (s[1] == '='
+ && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
TOKEN(0);
+ }
++s;
PL_parser->saw_infix_sigil = 1;
Mop(OP_MODULO);
TERM('%');
}
case '^':
+ d = s;
+ bof = FEATURE_BITWISE_IS_ENABLED;
+ if (bof && s[1] == '.')
+ s++;
if (!PL_lex_allbrackets && PL_lex_fakeeof >=
(s[1] == '=' ? LEX_FAKEEOF_ASSIGN : LEX_FAKEEOF_BITWISE))
+ {
+ s = d;
TOKEN(0);
+ }
s++;
- BOop(OP_BIT_XOR);
+ BOop(bof ? d == s-2 ? OP_SBIT_XOR : OP_NBIT_XOR : OP_BIT_XOR);
case '[':
if (PL_lex_brackets > 100)
Renew(PL_lex_brackstack, PL_lex_brackets + 10, char);
Eop(OP_SMARTMATCH);
}
s++;
- OPERATOR('~');
+ if ((bof = FEATURE_BITWISE_IS_ENABLED) && *s == '.') {
+ s++;
+ BCop(OP_SCOMPLEMENT);
+ }
+ BCop(bof ? OP_NCOMPLEMENT : OP_COMPLEMENT);
case ',':
if (!PL_lex_allbrackets && PL_lex_fakeeof >= LEX_FAKEEOF_COMMA)
TOKEN(0);
sv_catsv(sv, PL_lex_stuff);
attrs = op_append_elem(OP_LIST, attrs,
newSVOP(OP_CONST, 0, sv));
- SvREFCNT_dec(PL_lex_stuff);
+ SvREFCNT_dec_NN(PL_lex_stuff);
PL_lex_stuff = NULL;
}
else {
sv_free(sv);
CvMETHOD_on(PL_compcv);
}
+ else if (!PL_in_my && len == 5
+ && strnEQ(SvPVX(sv), "const", len))
+ {
+ sv_free(sv);
+ Perl_ck_warner_d(aTHX_
+ packWARN(WARN_EXPERIMENTAL__CONST_ATTR),
+ ":const is experimental"
+ );
+ CvANONCONST_on(PL_compcv);
+ if (!CvANON(PL_compcv))
+ yyerror(":const is not permitted on named "
+ "subroutines");
+ }
/* After we've set the flags, it could be argued that
we don't need to do the attributes.pm-based setting
process, and shouldn't bother appending recognized
/* XXX losing whitespace on sequential attributes here */
}
{
- if (*s != ';' && *s != '}' &&
- !(PL_expect == XOPERATOR
- ? (*s == '=' || *s == ')')
- : (*s == '{' || *s == '('))) {
+ if (*s != ';'
+ && *s != '}'
+ && !(PL_expect == XOPERATOR
+ ? (*s == '=' || *s == ')')
+ : (*s == '{' || *s == '(')))
+ {
const char q = ((*s == '\'') ? '"' : '\'');
/* If here for an expression, and parsed no attrs, back
off. */
}
switch (PL_expect) {
case XTERM:
+ case XTERMORDORDOR:
PL_lex_brackstack[PL_lex_brackets++] = XOPERATOR;
PL_lex_allbrackets++;
OPERATOR(HASHBRACK);
Perl_warner(aTHX_ packWARN(WARN_SEMICOLON), "%s", PL_warn_nosemi);
CopLINE_inc(PL_curcop);
}
+ d = s;
+ if ((bof = FEATURE_BITWISE_IS_ENABLED) && *s == '.')
+ s++;
if (!PL_lex_allbrackets && PL_lex_fakeeof >=
(*s == '=' ? LEX_FAKEEOF_ASSIGN : LEX_FAKEEOF_BITWISE)) {
+ s = d;
s--;
TOKEN(0);
}
- PL_parser->saw_infix_sigil = 1;
- BAop(OP_BIT_AND);
+ if (d == s) {
+ PL_parser->saw_infix_sigil = 1;
+ BAop(bof ? OP_NBIT_AND : OP_BIT_AND);
+ }
+ else
+ BAop(OP_SBIT_AND);
}
PL_tokenbuf[0] = '&';
s = scan_ident(s - 1, PL_tokenbuf + 1,
sizeof PL_tokenbuf - 1, TRUE);
+ pl_yylval.ival = (OPpENTERSUB_AMPER<<8);
if (PL_tokenbuf[1]) {
- PL_expect = XOPERATOR;
force_ident_maybe_lex('&');
}
else
PREREF('&');
- pl_yylval.ival = (OPpENTERSUB_AMPER<<8);
TERM('&');
case '|':
AOPERATOR(OROR);
}
s--;
+ d = s;
+ if ((bof = FEATURE_BITWISE_IS_ENABLED) && *s == '.')
+ s++;
if (!PL_lex_allbrackets && PL_lex_fakeeof >=
(*s == '=' ? LEX_FAKEEOF_ASSIGN : LEX_FAKEEOF_BITWISE)) {
- s--;
+ s = d - 1;
TOKEN(0);
}
- BOop(OP_BIT_OR);
+ BOop(bof ? s == d ? OP_NBIT_OR : OP_SBIT_OR : OP_BIT_OR);
case '=':
s++;
{
const char tmp = *s++;
if (tmp == '=') {
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE) {
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE)
+ {
s -= 2;
TOKEN(0);
}
Eop(OP_EQ);
}
if (tmp == '>') {
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_COMMA) {
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_COMMA)
+ {
s -= 2;
TOKEN(0);
}
Perl_warner(aTHX_ packWARN(WARN_SYNTAX),
"Reversed %c= operator",(int)tmp);
s--;
- if (PL_expect == XSTATE && isALPHA(tmp) &&
- (s == PL_linestart+1 || s[-2] == '\n') )
- {
- if ((PL_in_eval && !PL_rsfp && !PL_parser->filtered)
- || PL_lex_state != LEX_NORMAL) {
- d = PL_bufend;
- while (s < d) {
- if (*s++ == '\n') {
- incline(s);
- if (strnEQ(s,"=cut",4)) {
- s = strchr(s,'\n');
- if (s)
- s++;
- else
- s = d;
- incline(s);
- goto retry;
- }
- }
- }
- goto retry;
- }
- s = PL_bufend;
- PL_parser->in_pod = 1;
- goto retry;
- }
+ if (PL_expect == XSTATE
+ && isALPHA(tmp)
+ && (s == PL_linestart+1 || s[-2] == '\n') )
+ {
+ if ((PL_in_eval && !PL_rsfp && !PL_parser->filtered)
+ || PL_lex_state != LEX_NORMAL) {
+ d = PL_bufend;
+ while (s < d) {
+ if (*s++ == '\n') {
+ incline(s);
+ if (strnEQ(s,"=cut",4)) {
+ s = strchr(s,'\n');
+ if (s)
+ s++;
+ else
+ s = d;
+ incline(s);
+ goto retry;
+ }
+ }
+ }
+ goto retry;
+ }
+ s = PL_bufend;
+ PL_parser->in_pod = 1;
+ goto retry;
+ }
}
if (PL_expect == XBLOCK) {
const char *t = s;
while (t < PL_bufend && isSPACE(*t))
++t;
- if (*t == '/' || *t == '?' ||
- ((*t == 'm' || *t == 's' || *t == 'y')
- && !isWORDCHAR(t[1])) ||
- (*t == 't' && t[1] == 'r' && !isWORDCHAR(t[2])))
+ if (*t == '/' || *t == '?'
+ || ((*t == 'm' || *t == 's' || *t == 'y')
+ && !isWORDCHAR(t[1]))
+ || (*t == 't' && t[1] == 'r' && !isWORDCHAR(t[2])))
Perl_warner(aTHX_ packWARN(WARN_SYNTAX),
"!=~ should be !~");
}
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE) {
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE)
+ {
s -= 2;
TOKEN(0);
}
{
char tmp = *s++;
if (tmp == '<') {
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN) {
+ if (*s == '=' && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
s -= 2;
TOKEN(0);
}
if (tmp == '=') {
tmp = *s++;
if (tmp == '>') {
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE) {
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE)
+ {
s -= 3;
TOKEN(0);
}
Eop(OP_NCMP);
}
s--;
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE) {
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE)
+ {
s -= 2;
TOKEN(0);
}
{
const char tmp = *s++;
if (tmp == '>') {
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN) {
+ if (*s == '=' && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
s -= 2;
TOKEN(0);
}
SHop(OP_RIGHT_SHIFT);
}
else if (tmp == '=') {
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE) {
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_COMPARE)
+ {
s -= 2;
TOKEN(0);
}
PL_tokenbuf[0] = '@';
s = scan_ident(s + 1, PL_tokenbuf + 1,
sizeof PL_tokenbuf - 1, FALSE);
- if (PL_expect == XOPERATOR)
- no_op("Array length", s);
+ if (PL_expect == XOPERATOR) {
+ d = s;
+ if (PL_bufptr > s) {
+ d = PL_bufptr-1;
+ PL_bufptr = PL_oldbufptr;
+ }
+ no_op("Array length", d);
+ }
if (!PL_tokenbuf[1])
PREREF(DOLSHARP);
PL_expect = XOPERATOR;
PL_tokenbuf[0] = '$';
s = scan_ident(s, PL_tokenbuf + 1,
sizeof PL_tokenbuf - 1, FALSE);
- if (PL_expect == XOPERATOR)
- no_op("Scalar", s);
+ if (PL_expect == XOPERATOR) {
+ d = s;
+ if (PL_bufptr > s) {
+ d = PL_bufptr-1;
+ PL_bufptr = PL_oldbufptr;
+ }
+ no_op("Scalar", d);
+ }
if (!PL_tokenbuf[1]) {
if (s == PL_bufend)
yyerror("Final $ should be \\$ or $name");
char *t = s+1;
while (isSPACE(*t) || isWORDCHAR_lazy_if(t,UTF) || *t == '$')
- t++;
+ t += UTF ? UTF8SKIP(t) : 1;
if (*t++ == ',') {
PL_bufptr = skipspace(PL_bufptr); /* XXX can realloc */
while (t < PL_bufend && *t != ']')
t++;
Perl_warner(aTHX_ packWARN(WARN_SYNTAX),
- "Multidimensional syntax %.*s not supported",
- (int)((t - PL_bufptr) + 1), PL_bufptr);
+ "Multidimensional syntax %"UTF8f" not supported",
+ UTF8fARG(UTF,(int)((t - PL_bufptr) + 1), PL_bufptr));
}
}
}
}
else if (PL_expect == XOPERATOR) {
s++;
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN) {
+ if (*s == '=' && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
s--;
TOKEN(0);
}
case '?': /* conditional */
s++;
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_IFELSE) {
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_IFELSE)
+ {
s--;
TOKEN(0);
}
if (PL_expect == XOPERATOR || !isDIGIT(s[1])) {
char tmp = *s++;
if (*s == tmp) {
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_RANGE) {
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_RANGE)
+ {
s--;
TOKEN(0);
}
pl_yylval.ival = 0;
OPERATOR(DOTDOT);
}
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN) {
+ if (*s == '=' && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
s--;
TOKEN(0);
}
case '`':
s = scan_str(s,FALSE,FALSE,FALSE,NULL);
- DEBUG_T( { printbuf("### Saw backtick string before %s\n", s); } );
+ DEBUG_T( {
+ if (s)
+ printbuf("### Saw backtick string before %s\n", s);
+ else
+ PerlIO_printf(Perl_debug_log,
+ "### Saw unterminated backtick string\n");
+ } );
if (PL_expect == XOPERATOR)
no_op("Backticks",s);
if (!s)
CV *cv;
if ((gv = gv_fetchpvn_flags(PL_tokenbuf, len,
(UTF ? SVf_UTF8 : 0)|GV_NOTQUAL,
- SVt_PVCV)) &&
- (cv = GvCVu(gv)))
+ SVt_PVCV))
+ && (cv = GvCVu(gv)))
{
if (GvIMPORTED_CV(gv))
ogv = gv;
else if (! CvMETHOD(cv))
hgv = gv;
}
- if (!ogv &&
- (gvp = (GV**)hv_fetch(PL_globalstash, PL_tokenbuf,
- len, FALSE)) &&
- (gv = *gvp) && (
- isGV_with_GP(gv)
- ? GvCVu(gv) && GvIMPORTED_CV(gv)
- : SvPCS_IMPORTED(gv)
- && (gv_init(gv, PL_globalstash, PL_tokenbuf,
- len, 0), 1)
- ))
+ if (!ogv
+ && (gvp = (GV**)hv_fetch(PL_globalstash, PL_tokenbuf,
+ len, FALSE))
+ && (gv = *gvp)
+ && (isGV_with_GP(gv)
+ ? GvCVu(gv) && GvIMPORTED_CV(gv)
+ : SvPCS_IMPORTED(gv)
+ && (gv_init(gv, PL_globalstash, PL_tokenbuf,
+ len, 0), 1)))
{
ogv = gv;
}
in which case Foo is a bareword
(and a package name). */
- if (len > 2 &&
- PL_tokenbuf[len - 2] == ':' && PL_tokenbuf[len - 1] == ':')
+ if (len > 2
+ && PL_tokenbuf[len - 2] == ':'
+ && PL_tokenbuf[len - 1] == ':')
{
if (ckWARN(WARN_BAREWORD)
&& ! gv_fetchpvn_flags(PL_tokenbuf, len, UTF ? SVf_UTF8 : 0, SVt_PVHV))
/* See if it's the indirect object for a list operator. */
- if (PL_oldoldbufptr &&
- PL_oldoldbufptr < PL_bufptr &&
- (PL_oldoldbufptr == PL_last_lop
- || PL_oldoldbufptr == PL_last_uni) &&
- /* NO SKIPSPACE BEFORE HERE! */
- (PL_expect == XREF ||
- ((PL_opargs[PL_last_lop_op] >> OASHIFT)& 7) == OA_FILEREF))
+ if (PL_oldoldbufptr
+ && PL_oldoldbufptr < PL_bufptr
+ && (PL_oldoldbufptr == PL_last_lop
+ || PL_oldoldbufptr == PL_last_uni)
+ && /* NO SKIPSPACE BEFORE HERE! */
+ (PL_expect == XREF
+ || ((PL_opargs[PL_last_lop_op] >> OASHIFT)& 7)
+ == OA_FILEREF))
{
bool immediate_paren = *s == '(';
/* Two barewords in a row may indicate method call. */
- if ((isIDFIRST_lazy_if(s,UTF) || *s == '$') &&
- (tmp = intuit_method(s, lex ? NULL : sv, cv))) {
+ if ((isIDFIRST_lazy_if(s,UTF) || *s == '$')
+ && (tmp = intuit_method(s, lex ? NULL : sv, cv)))
+ {
goto method;
}
/* Also, if "_" follows a filetest operator, it's a bareword */
if (
- ( !immediate_paren && (PL_last_lop_op == OP_SORT ||
- (!cv &&
- (PL_last_lop_op != OP_MAPSTART &&
- PL_last_lop_op != OP_GREPSTART))))
+ ( !immediate_paren && (PL_last_lop_op == OP_SORT
+ || (!cv
+ && (PL_last_lop_op != OP_MAPSTART
+ && PL_last_lop_op != OP_GREPSTART))))
|| (PL_tokenbuf[0] == '_' && PL_tokenbuf[1] == '\0'
- && ((PL_opargs[PL_last_lop_op] & OA_CLASS_MASK) == OA_FILESTATOP))
+ && ((PL_opargs[PL_last_lop_op] & OA_CLASS_MASK)
+ == OA_FILESTATOP))
)
{
PL_expect = (PL_last_lop == PL_oldoldbufptr) ? XTERM : XOPERATOR;
op_free(rv2cv_op);
PL_last_lop = PL_oldbufptr;
PL_last_lop_op = OP_METHOD;
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ {
PL_lex_fakeeof = LEX_FAKEEOF_LOWLOGIC;
+ }
PL_expect = XBLOCKTERM;
PL_bufptr = s;
return REPORT(METHOD);
else SvUTF8_off(sv);
}
op_free(rv2cv_op);
- if (tmp == METHOD && !PL_lex_allbrackets &&
- PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ if (tmp == METHOD && !PL_lex_allbrackets
+ && PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ {
PL_lex_fakeeof = LEX_FAKEEOF_LOWLOGIC;
+ }
return REPORT(tmp);
}
sv_setpvs(PL_subname, "__ANON__");
else
sv_setpvs(PL_subname, "__ANON__::__ANON__");
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ {
PL_lex_fakeeof = LEX_FAKEEOF_LOWLOGIC;
+ }
PREBLOCK(LSTOPSUB);
}
}
NEXTVAL_NEXTTOKE.opval = pl_yylval.opval;
PL_expect = XTERM;
force_next(off ? PRIVATEREF : WORD);
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ {
PL_lex_fakeeof = LEX_FAKEEOF_LOWLOGIC;
+ }
TOKEN(NOAMP);
}
if (PL_expect == XSTATE && isIDFIRST_lazy_if(s,UTF)) {
char *p = s;
- if ((PL_bufend - p) >= 3 &&
- strnEQ(p, "my", 2) && isSPACE(*(p + 2)))
+ if ((PL_bufend - p) >= 3
+ && strnEQ(p, "my", 2) && isSPACE(*(p + 2)))
+ {
p += 2;
- else if ((PL_bufend - p) >= 4 &&
- strnEQ(p, "our", 3) && isSPACE(*(p + 3)))
+ }
+ else if ((PL_bufend - p) >= 4
+ && strnEQ(p, "our", 3) && isSPACE(*(p + 3)))
p += 3;
p = skipspace(p);
/* skip optional package name, as in "for my abc $x (..)" */
case KEY_our:
case KEY_my:
case KEY_state:
+ if (PL_in_my) {
+ yyerror(Perl_form(aTHX_
+ "Can't redeclare \"%s\" in \"%s\"",
+ tmp == KEY_my ? "my" :
+ tmp == KEY_state ? "state" : "our",
+ PL_in_my == KEY_my ? "my" :
+ PL_in_my == KEY_state ? "state" : "our"));
+ }
PL_in_my = (U16)tmp;
s = skipspace(s);
if (isIDFIRST_lazy_if(s,UTF)) {
if (*s == '(' || (s = skipspace(s), *s == '('))
FUN1(OP_NOT);
else {
- if (!PL_lex_allbrackets &&
- PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ if (!PL_lex_allbrackets
+ && PL_lex_fakeeof > LEX_FAKEEOF_LOWLOGIC)
+ {
PL_lex_fakeeof = LEX_FAKEEOF_LOWLOGIC;
+ }
OPERATOR(NOTOP);
}
}
if (!words)
words = newNULLLIST();
- if (PL_lex_stuff) {
- SvREFCNT_dec(PL_lex_stuff);
- PL_lex_stuff = NULL;
- }
+ SvREFCNT_dec_NN(PL_lex_stuff);
+ PL_lex_stuff = NULL;
PL_expect = XOPERATOR;
pl_yylval.opval = sawparens(words);
TOKEN(QWLIST);
d = s;
s = skipspace(s);
- if (isIDFIRST_lazy_if(s,UTF) || *s == '\'' ||
- (*s == ':' && s[1] == ':'))
+ if (isIDFIRST_lazy_if(s,UTF)
+ || *s == '\''
+ || (*s == ':' && s[1] == ':'))
{
PL_expect = XBLOCK;
case KEY_x:
if (PL_expect == XOPERATOR) {
- if (*s == '=' && !PL_lex_allbrackets &&
- PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ if (*s == '=' && !PL_lex_allbrackets
+ && PL_lex_fakeeof >= LEX_FAKEEOF_ASSIGN)
+ {
return REPORT(0);
+ }
Mop(OP_REPEAT);
}
check_uni();
and @foo isn't a variable we can find in the symbol
table.
*/
- if (ckWARN(WARN_AMBIGUOUS) &&
- pit == '@' && PL_lex_state != LEX_NORMAL && !PL_lex_brackets) {
+ if (ckWARN(WARN_AMBIGUOUS)
+ && pit == '@'
+ && PL_lex_state != LEX_NORMAL
+ && !PL_lex_brackets)
+ {
GV *const gv = gv_fetchpvn_flags(PL_tokenbuf + 1, tokenbuf_len - 1,
( UTF ? SVf_UTF8 : 0 ), SVt_PVAV);
if ((!gv || ((PL_tokenbuf[0] == '@') ? !GvAV(gv) : !GvHV(gv)))
/* DO NOT warn for @- and @+ */
- && !( PL_tokenbuf[2] == '\0' &&
- ( PL_tokenbuf[1] == '-' || PL_tokenbuf[1] == '+' ))
+ && !( PL_tokenbuf[2] == '\0'
+ && ( PL_tokenbuf[1] == '-' || PL_tokenbuf[1] == '+' ))
)
{
/* Downgraded from fatal to warning 20000522 mjd */
yyerror_pv(msg, UTF ? SVf_UTF8 : 0);
return SvREFCNT_inc_simple_NN(sv);
}
-now_ok:
+ now_ok:
cv = *cvp;
if (!pv && s)
pv = newSVpvn_flags(s, len, SVs_TEMP);
return s;
}
+/* Is the byte 'd' a legal single character identifier name? 'u' is true
+ * iff Unicode semantics are to be used. The legal ones are any of:
+ * a) all ASCII characters except:
+ * 1) control and space-type ones, like NUL, SOH, \t, and SPACE;
+ * 2) '{'
+ * The final case currently doesn't get this far in the program, so we
+ * don't test for it. If that were to change, it would be ok to allow it.
+ * c) When not under Unicode rules, any upper Latin1 character
+ * d) Otherwise, when unicode rules are used, all XIDS characters.
+ *
+ * Because all ASCII characters have the same representation whether
+ * encoded in UTF-8 or not, we can use the foo_A macros below and '\0' and
+ * '{' without knowing if is UTF-8 or not.
+ * EBCDIC already uses the rules that ASCII platforms will use after the
+ * deprecation cycle; see comment below about the deprecation. */
+#ifdef EBCDIC
+# define VALID_LEN_ONE_IDENT(s, is_utf8) \
+ (isGRAPH_A(*(s)) || ((is_utf8) \
+ ? isIDFIRST_utf8((U8*) (s)) \
+ : (isGRAPH_L1(*s) \
+ && LIKELY((U8) *(s) != LATIN1_TO_NATIVE(0xAD)))))
+#else
+# define VALID_LEN_ONE_IDENT(s, is_utf8) \
+ (isGRAPH_A(*(s)) || ((is_utf8) \
+ ? isIDFIRST_utf8((U8*) (s)) \
+ : ! isASCII_utf8((U8*) (s))))
+#endif
+
STATIC char *
S_scan_ident(pTHX_ char *s, char *dest, STRLEN destlen, I32 ck_uni)
{
PERL_ARGS_ASSERT_SCAN_IDENT;
- if (isSPACE(*s))
+ if (isSPACE(*s) || !*s)
s = skipspace(s);
if (isDIGIT(*s)) {
while (isDIGIT(*s)) {
*d++ = *s++;
}
}
- else {
+ else { /* See if it is a "normal" identifier */
parse_ident(&s, &d, e, 1, is_utf8);
}
*d = '\0';
PL_lex_state = LEX_INTERPENDMAYBE;
return s;
}
- if (*s == '$' && s[1] &&
- (isIDFIRST_lazy_if(s+1,is_utf8)
- || isDIGIT_A((U8)s[1])
- || s[1] == '$'
- || s[1] == '{'
- || strnEQ(s+1,"::",2)) )
+
+ /* Here, it is not a run-of-the-mill identifier name */
+
+ if (*s == '$' && s[1]
+ && (isIDFIRST_lazy_if(s+1,is_utf8)
+ || isDIGIT_A((U8)s[1])
+ || s[1] == '$'
+ || s[1] == '{'
+ || strnEQ(s+1,"::",2)) )
{
/* Dereferencing a value in a scalar variable.
The alternatives are different syntaxes for a scalar variable.
s = skipspace(s);
}
}
-
-/* Is the byte 'd' a legal single character identifier name? 'u' is true
- * iff Unicode semantics are to be used. The legal ones are any of:
- * a) all ASCII characters except:
- * 1) space-type ones, like \t and SPACE;
- 2) NUL;
- * 3) '{'
- * The final case currently doesn't get this far in the program, so we
- * don't test for it. If that were to change, it would be ok to allow it.
- * c) When not under Unicode rules, any upper Latin1 character
- * d) Otherwise, when unicode rules are used, all XIDS characters.
- *
- * Because all ASCII characters have the same representation whether
- * encoded in UTF-8 or not, we can use the foo_A macros below and '\0' and
- * '{' without knowing if is UTF-8 or not.
- * EBCDIC already uses the rules that ASCII platforms will use after the
- * deprecation cycle; see comment below about the deprecation. */
-#ifdef EBCDIC
-# define VALID_LEN_ONE_IDENT(s, is_utf8) \
- (isGRAPH_A(*(s)) || ((is_utf8) \
- ? isIDFIRST_utf8((U8*) (s)) \
- : (isGRAPH_L1(*s) \
- && LIKELY((U8) *(s) != LATIN1_TO_NATIVE(0xAD)))))
-#else
-# define VALID_LEN_ONE_IDENT(s, is_utf8) (! isSPACE_A(*(s)) \
- && LIKELY(*(s) != '\0') \
- && (! is_utf8 \
- || isASCII_utf8((U8*) (s)) \
- || isIDFIRST_utf8((U8*) (s))))
-#endif
if ((s <= PL_bufend - (is_utf8)
? UTF8SKIP(s)
: 1)
: (! isGRAPH_L1( (U8) *s)
|| UNLIKELY((U8) *(s) == LATIN1_TO_NATIVE(0xAD))))
{
- /* Split messages for back compat */
- if (isCNTRL_A( (U8) *s)) {
- deprecate("literal control characters in variable names");
- }
- else {
- deprecate("literal non-graphic characters in variable names");
- }
+ deprecate("literal non-graphic characters in variable names");
}
-
+
if (is_utf8) {
const STRLEN skip = UTF8SKIP(s);
STRLEN i;
/* if it starts as a valid identifier, assume that it is one.
(the later check for } being at the expected point will trap
cases where this doesn't pan out.) */
- d += is_utf8 ? UTF8SKIP(d) : 1;
- parse_ident(&s, &d, e, 1, is_utf8);
+ d += is_utf8 ? UTF8SKIP(d) : 1;
+ parse_ident(&s, &d, e, 1, is_utf8);
*d = '\0';
tmp_copline = CopLINE(PL_curcop);
if (s < PL_bufend && isSPACE(*s)) {
PL_expect = XREF;
}
if (PL_lex_state == LEX_NORMAL) {
- if (ckWARN(WARN_AMBIGUOUS) &&
- (keyword(dest, d - dest, 0)
- || get_cvn_flags(dest, d - dest, is_utf8 ? SVf_UTF8 : 0)))
+ if (ckWARN(WARN_AMBIGUOUS)
+ && (keyword(dest, d - dest, 0)
+ || get_cvn_flags(dest, d - dest, is_utf8
+ ? SVf_UTF8
+ : 0)))
{
SV *tmp = newSVpvn_flags( dest, d - dest,
- SVs_TEMP | (is_utf8 ? SVf_UTF8 : 0) );
+ SVs_TEMP | (is_utf8 ? SVf_UTF8 : 0) );
if (funny == '#')
funny = '@';
orig_copline = CopLINE(PL_curcop);
first_line = CopLINE(PL_curcop);
s = scan_str(s,FALSE,FALSE,FALSE,NULL);
if (!s) {
- if (PL_lex_stuff) {
- SvREFCNT_dec(PL_lex_stuff);
- PL_lex_stuff = NULL;
- }
+ SvREFCNT_dec_NN(PL_lex_stuff);
+ PL_lex_stuff = NULL;
Perl_croak(aTHX_ "Substitution replacement not terminated");
}
PL_multi_start = first_start; /* so whole substitution is taken together */
s = scan_str(s,FALSE,FALSE,FALSE,NULL);
if (!s) {
- if (PL_lex_stuff) {
- SvREFCNT_dec(PL_lex_stuff);
- PL_lex_stuff = NULL;
- }
+ SvREFCNT_dec_NN(PL_lex_stuff);
+ PL_lex_stuff = NULL;
Perl_croak(aTHX_ "Transliteration replacement not terminated");
}
term = '"';
if (!isWORDCHAR_lazy_if(s,UTF))
deprecate("bare << to mean <<\"\"");
- for (; isWORDCHAR_lazy_if(s,UTF); s++) {
- if (d < e)
- *d++ = *s;
+ peek = s;
+ while (isWORDCHAR_lazy_if(peek,UTF)) {
+ peek += UTF ? UTF8SKIP(peek) : 1;
}
+ len = (peek - s >= e - d) ? (e - d) : (peek - s);
+ Copy(s, d, len, char);
+ s += len;
+ d += len;
}
if (d >= PL_tokenbuf + sizeof PL_tokenbuf - 1)
Perl_croak(aTHX_ "Delimiter for here document is too long");
lexing scope. In a file, we will have broken out of the
loop in the previous iteration. In an eval, the string buf-
fer ends with "\n;", so the while condition above will have
- evaluated to false. So shared can never be null. */
- assert(shared);
+ evaluated to false. So shared can never be null. Or so you
+ might think. Odd syntax errors like s;@{<<; can gobble up
+ the implicit semicolon at the end of a flie, causing the
+ file handle to be closed even when we are not in a string
+ eval. So shared may be null in that case. */
+ if (UNLIKELY(!shared))
+ goto interminable;
/* A LEXSHARED struct with a null ls_prev pointer is the outer-
most lexing scope. In a file, shared->ls_linestr at that
level is just one line, so there is no body to steal. */
linestr = shared->ls_linestr;
bufend = SvEND(linestr);
d = s;
- while (s < bufend - len + 1 &&
- memNE(s,PL_tokenbuf,len) ) {
+ while (s < bufend - len + 1
+ && memNE(s,PL_tokenbuf,len) )
+ {
if (*s++ == '\n')
++PL_parser->herelines;
}
bufend - shared->re_eval_start);
shared->re_eval_start -= s-d;
}
- if (cxstack_ix >= 0 && CxTYPE(cx) == CXt_EVAL &&
- CxOLD_OP_TYPE(cx) == OP_ENTEREVAL &&
- cx->blk_eval.cur_text == linestr)
+ if (cxstack_ix >= 0
+ && CxTYPE(cx) == CXt_EVAL
+ && CxOLD_OP_TYPE(cx) == OP_ENTEREVAL
+ && cx->blk_eval.cur_text == linestr)
{
cx->blk_eval.cur_text = newSVsv(linestr);
SvSCREAM_on(cx->blk_eval.cur_text);
PL_last_lop = PL_last_uni = NULL;
#ifndef PERL_STRICT_CR
if (PL_bufend - PL_linestart >= 2) {
- if ((PL_bufend[-2] == '\r' && PL_bufend[-1] == '\n') ||
- (PL_bufend[-2] == '\n' && PL_bufend[-1] == '\r'))
+ if ( (PL_bufend[-2] == '\r' && PL_bufend[-1] == '\n')
+ || (PL_bufend[-2] == '\n' && PL_bufend[-1] == '\r'))
{
PL_bufend[-2] = '\n';
PL_bufend--;
else {
GV *gv;
++d;
-intro_sym:
+ intro_sym:
gv = gv_fetchpv(d,
GV_ADDMULTI | ( UTF ? SVf_UTF8 : 0 ),
SVt_PV);
COPLINE_INC_WITH_HERELINES;
/* backslashes can escape the open or closing characters */
if (*s == '\\' && s+1 < PL_bufend) {
- if (!keep_bracketed_quoted &&
- ((s[1] == PL_multi_open) || (s[1] == PL_multi_close)))
+ if (!keep_bracketed_quoted
+ && ((s[1] == PL_multi_open) || (s[1] == PL_multi_close)))
{
s++;
}
#ifndef PERL_STRICT_CR
if (to - SvPVX_const(sv) >= 2) {
- if ((to[-2] == '\r' && to[-1] == '\n') ||
- (to[-2] == '\n' && to[-1] == '\r'))
+ if ( (to[-2] == '\r' && to[-1] == '\n')
+ || (to[-2] == '\n' && to[-1] == '\r'))
{
to[-2] = '\n';
to--;
hexfp_exp *= 10;
hexfp_exp += *h - '0';
#ifdef NV_MIN_EXP
- if (negexp &&
- -hexfp_exp < NV_MIN_EXP - 1) {
+ if (negexp
+ && -hexfp_exp < NV_MIN_EXP - 1)
+ {
Perl_ck_warner(aTHX_ packWARN(WARN_OVERFLOW),
"Hexadecimal float: exponent underflow");
#endif
}
else {
#ifdef NV_MAX_EXP
- if (!negexp &&
- hexfp_exp > NV_MAX_EXP - 1) {
+ if (!negexp
+ && hexfp_exp > NV_MAX_EXP - 1)
+ {
Perl_ck_warner(aTHX_ packWARN(WARN_OVERFLOW),
"Hexadecimal float: exponent overflow");
break;
}
/* read next group of digits and _ and copy into d */
- while (isDIGIT(*s) || *s == '_' ||
- UNLIKELY(hexfp && isXDIGIT(*s))) {
+ while (isDIGIT(*s)
+ || *s == '_'
+ || UNLIKELY(hexfp && isXDIGIT(*s)))
+ {
/* skip underscores, checking for misplaced ones
if -w is on
*/
/* copy, ignoring underbars, until we run out of digits.
*/
- for (; isDIGIT(*s) || *s == '_' ||
- UNLIKELY(hexfp && isXDIGIT(*s));
- s++) {
+ for (; isDIGIT(*s)
+ || *s == '_'
+ || UNLIKELY(hexfp && isXDIGIT(*s));
+ s++)
+ {
/* fixed length buffer check */
if (d >= e)
Perl_croak(aTHX_ "%s", number_too_long);
*d++ = *s++;
}
else {
- if (((lastub && s == lastub + 1) ||
- (!isDIGIT(s[1]) && s[1] != '_')))
+ if (((lastub && s == lastub + 1)
+ || (!isDIGIT(s[1]) && s[1] != '_')))
Perl_ck_warner(aTHX_ packWARN(WARN_SYNTAX),
"Misplaced _ in number");
lastub = s++;
floatit = TRUE;
}
if (floatit) {
- STORE_NUMERIC_LOCAL_SET_STANDARD();
+ STORE_LC_NUMERIC_UNDERLYING_SET_STANDARD();
/* terminate the string */
*d = '\0';
if (UNLIKELY(hexfp)) {
} else {
nv = Atof(PL_tokenbuf);
}
- RESTORE_NUMERIC_LOCAL();
+ RESTORE_LC_NUMERIC_UNDERLYING();
sv = newSVnv(nv);
}
/* if it starts with a v, it could be a v-string */
case 'v':
-vstring:
+ vstring:
sv = newSV(5); /* preallocate storage space */
ENTER_with_name("scan_vstring");
SAVEFREESV(sv);
CvFLAGS(PL_compcv) |= flags;
PL_subline = CopLINE(PL_curcop);
- CvPADLIST_set(PL_compcv, pad_new(padnew_SAVE|padnew_SAVESUB));
+ CvPADLIST(PL_compcv) = pad_new(padnew_SAVE|padnew_SAVESUB);
CvOUTSIDE(PL_compcv) = MUTABLE_CV(SvREFCNT_inc_simple(outsidecv));
CvOUTSIDE_SEQ(PL_compcv) = PL_cop_seqmax;
if (outsidecv && CvPADLIST(outsidecv))
if (!yychar || (yychar == ';' && !PL_rsfp))
sv_catpvs(where_sv, "at EOF");
- else if (PL_oldoldbufptr && PL_bufptr > PL_oldoldbufptr &&
- PL_bufptr - PL_oldoldbufptr < 200 && PL_oldoldbufptr != PL_oldbufptr &&
- PL_oldbufptr != PL_bufptr) {
+ else if ( PL_oldoldbufptr
+ && PL_bufptr > PL_oldoldbufptr
+ && PL_bufptr - PL_oldoldbufptr < 200
+ && PL_oldoldbufptr != PL_oldbufptr
+ && PL_oldbufptr != PL_bufptr)
+ {
/*
Only for NetWare:
The code below is removed for NetWare because it abends/crashes on NetWare
context = PL_oldoldbufptr;
contlen = PL_bufptr - PL_oldoldbufptr;
}
- else if (PL_oldbufptr && PL_bufptr > PL_oldbufptr &&
- PL_bufptr - PL_oldbufptr < 200 && PL_oldbufptr != PL_bufptr) {
+ else if ( PL_oldbufptr
+ && PL_bufptr > PL_oldbufptr
+ && PL_bufptr - PL_oldbufptr < 200
+ && PL_oldbufptr != PL_bufptr) {
/*
Only for NetWare:
The code below is removed for NetWare because it abends/crashes on NetWare
else if (yychar > 255)
sv_catpvs(where_sv, "next token ???");
else if (yychar == YYEMPTY) {
- if (PL_lex_state == LEX_NORMAL ||
- (PL_lex_state == LEX_KNOWNEXT && PL_lex_defer == LEX_NORMAL))
+ if ( PL_lex_state == LEX_NORMAL
+ || (PL_lex_state == LEX_KNOWNEXT && PL_lex_defer == LEX_NORMAL))
sv_catpvs(where_sv, "at end of line");
else if (PL_lex_inpat)
sv_catpvs(where_sv, "within pattern");
down to the bit shift operators. The expression must be followed (and thus
terminated) either by a comparison or lower-precedence operator or by
something that would normally terminate an expression such as semicolon.
-If I<flags> includes C<PARSE_OPTIONAL> then the expression is optional,
+If C<flags> includes C<PARSE_OPTIONAL> then the expression is optional,
otherwise it is mandatory. It is up to the caller to ensure that the
dynamic parser state (L</PL_parser> et al) is correctly set to reflect
the source of the code to be parsed and the lexical context for the
down to the assignment operators. The expression must be followed (and thus
terminated) either by a comma or lower-precedence operator or by
something that would normally terminate an expression such as semicolon.
-If I<flags> includes C<PARSE_OPTIONAL> then the expression is optional,
+If C<flags> includes C<PARSE_OPTIONAL> then the expression is optional,
otherwise it is mandatory. It is up to the caller to ensure that the
dynamic parser state (L</PL_parser> et al) is correctly set to reflect
the source of the code to be parsed and the lexical context for the
down to the comma operator. The expression must be followed (and thus
terminated) either by a low-precedence logic operator such as C<or> or by
something that would normally terminate an expression such as semicolon.
-If I<flags> includes C<PARSE_OPTIONAL> then the expression is optional,
+If C<flags> includes C<PARSE_OPTIONAL> then the expression is optional,
otherwise it is mandatory. It is up to the caller to ensure that the
dynamic parser state (L</PL_parser> et al) is correctly set to reflect
the source of the code to be parsed and the lexical context for the
as C<or>. The expression must be followed (and thus terminated) by a
token that an expression would normally be terminated by: end-of-file,
closing bracketing punctuation, semicolon, or one of the keywords that
-signals a postfix expression-statement modifier. If I<flags> includes
+signals a postfix expression-statement modifier. If C<flags> includes
C<PARSE_OPTIONAL> then the expression is optional, otherwise it is
mandatory. It is up to the caller to ensure that the dynamic parser
state (L</PL_parser> et al) is correctly set to reflect the source of
level of parsing which covers all the compilation errors that occurred.
Some compilation errors, however, will throw an exception immediately.
-The I<flags> parameter is reserved for future use, and must always
+The C<flags> parameter is reserved for future use, and must always
be zero.
=cut
level of parsing which covers all the compilation errors that occurred.
Some compilation errors, however, will throw an exception immediately.
-The I<flags> parameter is reserved for future use, and must always
+The C<flags> parameter is reserved for future use, and must always
be zero.
=cut
Parse a single label, possibly optional, of the type that may prefix a
Perl statement. It is up to the caller to ensure that the dynamic parser
state (L</PL_parser> et al) is correctly set to reflect the source of
-the code to be parsed. If I<flags> includes C<PARSE_OPTIONAL> then the
+the code to be parsed. If C<flags> includes C<PARSE_OPTIONAL> then the
label is optional, otherwise it is mandatory.
The name of the label is returned in the form of a fresh scalar. If an
level of parsing which covers all the compilation errors that occurred.
Some compilation errors, however, will throw an exception immediately.
-The I<flags> parameter is reserved for future use, and must always
+The C<flags> parameter is reserved for future use, and must always
be zero.
=cut
which covers all the compilation errors that occurred. Some compilation
errors, however, will throw an exception immediately.
-The I<flags> parameter is reserved for future use, and must always
+The C<flags> parameter is reserved for future use, and must always
be zero.
=cut
"lacks default expression"));
} else {
OP *defexpr = parse_termexpr(0);
- if (defexpr->op_type == OP_UNDEF &&
- !(defexpr->op_flags & OPf_KIDS)) {
+ if (defexpr->op_type == OP_UNDEF
+ && !(defexpr->op_flags & OPf_KIDS))
+ {
op_free(defexpr);
} else {
OP *ifop =
}
/*
- * Local variables:
- * c-indentation-style: bsd
- * c-basic-offset: 4
- * indent-tabs-mode: nil
- * End:
- *
* ex: set ts=8 sts=4 sw=4 et:
*/