1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
357
358
359
360
361
362
363
364
365
366
367
368
369
370
371
372
373
374
375
376
377
378
379
380
381
382
383
384
385
386
387
388
389
390
391
392
393
394
395
396
397
398
399
400
401
402
|
/* perlvars.h
*
* Copyright (C) 1999, 2000, 2001, 2002, 2003, 2004, 2005, 2006, 2007,
* by Larry Wall and others
*
* You may distribute under the terms of either the GNU General Public
* License or the Artistic License, as specified in the README file.
*
*/
/*
=head1 Global Variables
These variables are global to an entire process. They are shared between
all interpreters and all threads in a process. Any variables not documented
here may be changed or removed without notice, so don't use them!
If you feel you really do need to use an unlisted variable, first send email to
L<perl5-porters@perl.org|mailto:perl5-porters@perl.org>. It may be that
someone there will point out a way to accomplish what you need without using an
internal variable. But if not, you should get a go-ahead to document and then
use the variable.
=cut
*/
/* Don't forget to re-run regen/embed.pl to propagate changes! */
/* This file describes the "global" variables used by perl
* This used to be in perl.h directly but we want to abstract out into
* distinct files which are per-thread, per-interpreter or really global,
* and how they're initialized.
*
* The 'G' prefix is only needed for vars that need appropriate #defines
* generated in embed*.h. Such symbols are also used to generate
* the appropriate export list for win32. */
/* global state */
#if defined(USE_ITHREADS)
PERLVAR(G, op_mutex, perl_mutex) /* Mutex for op refcounting */
#endif
PERLVARI(G, curinterp, PerlInterpreter *, NULL)
/* currently running interpreter
* (initial parent interpreter under
* useithreads) */
#if defined(USE_ITHREADS)
PERLVAR(G, thr_key, perl_key) /* key to retrieve per-thread struct */
#endif
/* XXX does anyone even use this? */
PERLVARI(G, do_undump, bool, FALSE) /* -u or dump seen? */
#if defined(FAKE_PERSISTENT_SIGNAL_HANDLERS)||defined(FAKE_DEFAULT_SIGNAL_HANDLERS)
PERLVARI(G, sig_handlers_initted, int, 0)
#endif
#ifdef FAKE_PERSISTENT_SIGNAL_HANDLERS
PERLVARA(G, sig_ignoring, SIG_SIZE, int)
/* which signals we are ignoring */
#endif
#ifdef FAKE_DEFAULT_SIGNAL_HANDLERS
PERLVARA(G, sig_defaulting, SIG_SIZE, int)
#endif
/* XXX signals are process-wide anyway, so we
* ignore the implications of this for threading */
#ifndef HAS_SIGACTION
PERLVARI(G, sig_trapped, int, 0)
#endif
#ifndef PERL_MICRO
/* If Perl has to ignore SIGPFE, this is its saved state.
* See perl.h macros PERL_FPU_INIT and PERL_FPU_{PRE,POST}_EXEC. */
PERLVAR(G, sigfpe_saved, Sighandler_t)
/* these ptrs to functions are to avoid linkage problems; see
* perl-5.8.0-2193-g5c1546dc48
*/
PERLVARI(G, csighandlerp, Sighandler_t, Perl_csighandler)
PERLVARI(G, csighandler1p, Sighandler1_t, Perl_csighandler1)
PERLVARI(G, csighandler3p, Sighandler3_t, Perl_csighandler3)
#endif
/* This is constant on most architectures, a global on OS/2 */
#ifdef OS2
PERLVARI(G, sh_path, char *, SH_PATH) /* full path of shell */
#endif
#ifdef USE_PERLIO
# if defined(USE_ITHREADS)
PERLVAR(G, perlio_mutex, perl_mutex) /* Mutex for perlio fd refcounts */
# endif
PERLVARI(G, perlio_fd_refcnt, int *, 0) /* Pointer to array of fd refcounts. */
PERLVARI(G, perlio_fd_refcnt_size, int, 0) /* Size of the array */
PERLVARI(G, perlio_debug_fd, int, 0) /* the fd to write perlio debug into, 0 means not set yet */
#endif
#ifdef HAS_MMAP
PERLVARI(G, mmap_page_size, IV, 0)
#endif
#if defined(USE_ITHREADS)
PERLVAR(G, hints_mutex, perl_mutex) /* Mutex for refcounted he refcounting */
PERLVAR(G, env_mutex, perl_RnW1_mutex_t) /* Mutex for accessing ENV */
PERLVAR(G, locale_mutex, perl_mutex) /* Mutex related to locale handling */
#endif
#ifdef USE_POSIX_2008_LOCALE
PERLVARI(G, C_locale_obj, locale_t, NULL)
#endif
PERLVARI(G, watch_pvx, char *, NULL)
/*
=for apidoc AmnU|Perl_check_t *|PL_check
Array, indexed by opcode, of functions that will be called for the "check"
phase of optree building during compilation of Perl code. For most (but
not all) types of op, once the op has been initially built and populated
with child ops it will be filtered through the check function referenced
by the appropriate element of this array. The new op is passed in as the
sole argument to the check function, and the check function returns the
completed op. The check function may (as the name suggests) check the op
for validity and signal errors. It may also initialise or modify parts of
the ops, or perform more radical surgery such as adding or removing child
ops, or even throw the op away and return a different op in its place.
This array of function pointers is a convenient place to hook into the
compilation process. An XS module can put its own custom check function
in place of any of the standard ones, to influence the compilation of a
particular type of op. However, a custom check function must never fully
replace a standard check function (or even a custom check function from
another module). A module modifying checking must instead B<wrap> the
preexisting check function. A custom check function must be selective
about when to apply its custom behaviour. In the usual case where
it decides not to do anything special with an op, it must chain the
preexisting op function. Check functions are thus linked in a chain,
with the core's base checker at the end.
For thread safety, modules should not write directly to this array.
Instead, use the function L</wrap_op_checker>.
=for apidoc Amn|enum perl_phase|PL_phase
A value that indicates the current Perl interpreter's phase. Possible values
include C<PERL_PHASE_CONSTRUCT>, C<PERL_PHASE_START>, C<PERL_PHASE_CHECK>,
C<PERL_PHASE_INIT>, C<PERL_PHASE_RUN>, C<PERL_PHASE_END>, and
C<PERL_PHASE_DESTRUCT>.
For example, the following determines whether the interpreter is in
global destruction:
if (PL_phase == PERL_PHASE_DESTRUCT) {
// we are in global destruction
}
C<PL_phase> was introduced in Perl 5.14; in prior perls you can use
C<PL_dirty> (boolean) to determine whether the interpreter is in global
destruction. (Use of C<PL_dirty> is discouraged since 5.14.)
=cut
*/
#if defined(USE_ITHREADS)
PERLVAR(G, check_mutex, perl_mutex) /* Mutex for PL_check */
#endif
/* allocate a unique index to every module that calls MY_CXT_INIT */
#ifdef MULTIPLICITY
# ifdef USE_ITHREADS
PERLVAR(G, my_ctx_mutex, perl_mutex)
PERLVARI(G, veto_switch_non_tTHX_context, int, FALSE)
# endif
PERLVARI(G, my_cxt_index, int, 0)
#endif
/* this is currently set without MUTEX protection, so keep it a type which
* can be set atomically (ie not a bit field) */
PERLVARI(G, veto_cleanup, int, FALSE) /* exit without cleanup */
/*
=for apidoc AmnUx|Perl_keyword_plugin_t|PL_keyword_plugin
Function pointer, pointing at a function used to handle extended keywords.
The function should be declared as
int keyword_plugin_function(pTHX_
char *keyword_ptr, STRLEN keyword_len,
OP **op_ptr)
The function is called from the tokeniser, whenever a possible keyword
is seen. C<keyword_ptr> points at the word in the parser's input
buffer, and C<keyword_len> gives its length; it is not null-terminated.
The function is expected to examine the word, and possibly other state
such as L<%^H|perlvar/%^H>, to decide whether it wants to handle it
as an extended keyword. If it does not, the function should return
C<KEYWORD_PLUGIN_DECLINE>, and the normal parser process will continue.
If the function wants to handle the keyword, it first must
parse anything following the keyword that is part of the syntax
introduced by the keyword. See L</Lexer interface> for details.
When a keyword is being handled, the plugin function must build
a tree of C<OP> structures, representing the code that was parsed.
The root of the tree must be stored in C<*op_ptr>. The function then
returns a constant indicating the syntactic role of the construct that
it has parsed: C<KEYWORD_PLUGIN_STMT> if it is a complete statement, or
C<KEYWORD_PLUGIN_EXPR> if it is an expression. Note that a statement
construct cannot be used inside an expression (except via C<do BLOCK>
and similar), and an expression is not a complete statement (it requires
at least a terminating semicolon).
When a keyword is handled, the plugin function may also have
(compile-time) side effects. It may modify C<%^H>, define functions, and
so on. Typically, if side effects are the main purpose of a handler,
it does not wish to generate any ops to be included in the normal
compilation. In this case it is still required to supply an op tree,
but it suffices to generate a single null op.
That's how the C<*PL_keyword_plugin> function needs to behave overall.
Conventionally, however, one does not completely replace the existing
handler function. Instead, take a copy of C<PL_keyword_plugin> before
assigning your own function pointer to it. Your handler function should
look for keywords that it is interested in and handle those. Where it
is not interested, it should call the saved plugin function, passing on
the arguments it received. Thus C<PL_keyword_plugin> actually points
at a chain of handler functions, all of which have an opportunity to
handle keywords, and only the last function in the chain (built into
the Perl core) will normally return C<KEYWORD_PLUGIN_DECLINE>.
For thread safety, modules should not set this variable directly.
Instead, use the function L</wrap_keyword_plugin>.
=cut
*/
#if defined(USE_ITHREADS)
PERLVAR(G, keyword_plugin_mutex, perl_mutex) /* Mutex for PL_keyword_plugin and PL_infix_plugin */
#endif
PERLVARI(G, keyword_plugin, Perl_keyword_plugin_t, Perl_keyword_plugin_standard)
/*
=for apidoc AmnUx|Perl_infix_plugin_t|PL_infix_plugin
B<NOTE:> This API exists entirely for the purpose of making the CPAN module
C<XS::Parse::Infix> work. It is not expected that additional modules will make
use of it; rather, that they should use C<XS::Parse::Infix> to provide parsing
of new infix operators.
Function pointer, pointing at a function used to handle extended infix
operators. The function should be declared as
int infix_plugin_function(pTHX_
char *opname, STRLEN oplen,
struct Perl_custom_infix **infix_ptr)
The function is called from the tokenizer whenever a possible infix operator
is seen. C<opname> points to the operator name in the parser's input buffer,
and C<oplen> gives the I<maximum> number of bytes of it that should be
consumed; it is not null-terminated. The function is expected to examine the
operator name and possibly other state such as L<%^H|perlvar/%^H>, to
determine whether it wants to handle the operator name.
As compared to the single stage of C<PL_keyword_plugin>, parsing of additional
infix operators occurs in three separate stages. This is because of the more
complex interactions it has with the parser, to ensure that operator
precedence rules work correctly. These stages are co-ordinated by the use of
an additional information structure.
If the function wants to handle the infix operator, it must set the variable
pointed to by C<infix_ptr> to the address of a structure that provides this
additional information about the subsequent parsing stages. If it does not,
it should make a call to the next function in the chain.
This structure has the following definition:
struct Perl_custom_infix {
enum Perl_custom_infix_precedence prec;
void (*parse)(pTHX_ SV **opdata,
struct Perl_custom_infix *);
OP *(*build_op)(pTHX_ SV **opdata, OP *lhs, OP *rhs,
struct Perl_custom_infix *);
};
The function must then return an integer giving the number of bytes consumed
by the name of this operator. In the case of an operator whose name is
composed of identifier characters, this must be equal to C<oplen>. In the case
of an operator named by non-identifier characters, this is permitted to be
shorter than C<oplen>, and any additional characters after it will not be
claimed by the infix operator but instead will be consumed by the tokenizer
and parser as normal.
If the optional C<parse> function is provided, it is called immediately by the
parser to let the operator's definition consume any additional syntax from the
source code. This should I<not> be used for normal operand parsing, but it may
be useful when implementing things like parametric operators or meta-operators
that consume more syntax themselves. This function may use the variable
pointed to by C<opdata> to provide an SV containing additional data to be
passed into the C<build_op> function later on.
The information structure gives the operator precedence level in the C<prec>
field. This is used to tell the parser how much of the surrounding syntax
before and after should be considered as operands to the operator.
The tokenizer and parser will then continue to operate as normal until enough
additional input has been parsed to form both the left- and right-hand side
operands to the operator, according to the precedence level. At this point the
C<build_op> function is called, being passed the left- and right-hand operands
as optree fragments. It is expected to combine them into the resulting optree
fragment, which it should return.
After the C<build_op> function has returned, if the variable pointed to by
C<opdata> was set to a non-C<NULL> value, it will then be destroyed by calling
C<SvREFCNT_dec()>.
For thread safety, modules should not set this variable directly.
Instead, use the function L</wrap_infix_plugin>.
However, that all said, the introductory note above still applies. This
variable is provided in core perl only for the benefit of the
C<XS::Parse::Infix> module. That module acts as a central registry for infix
operators, automatically handling things like deparse support and
discovery/reflection, and these abilities only work because it knows all the
registered operators. Other modules should not use this interpreter variable
directly to implement them because then those central features would no longer
work properly.
Furthermore, it is likely that this (experimental) API will be replaced in a
future Perl version by a more complete API that fully implements the central
registry and other semantics currently provided by C<XS::Parse::Infix>, once
the module has had sufficient experimental testing time. This current
mechanism exists only as an interim measure to get to that stage.
=cut
*/
PERLVARI(G, infix_plugin, Perl_infix_plugin_t, Perl_infix_plugin_standard)
PERLVARI(G, op_sequence, HV *, NULL) /* dump.c */
PERLVARI(G, op_seq, UV, 0) /* dump.c */
#ifdef USE_ITHREADS
PERLVAR(G, dollarzero_mutex, perl_mutex) /* Modifying $0 */
#endif
/* Restricted hashes placeholder value.
In theory, the contents are never used, only the address.
In practice, &PL_sv_placeholder is returned by some APIs, and the calling
code is checking SvOK(). */
PERLVAR(G, sv_placeholder, SV)
#if defined(MYMALLOC) && defined(USE_ITHREADS)
PERLVAR(G, malloc_mutex, perl_mutex) /* Mutex for malloc */
#endif
PERLVARI(G, hash_seed_set, bool, FALSE) /* perl.c */
PERLVARA(G, hash_seed_w, PERL_HASH_SEED_WORDS, PVT__PERL_HASH_WORD_TYPE) /* perl.c and hv.h */
#if defined(PERL_HASH_STATE_BYTES)
PERLVARA(G, hash_state_w, PERL_HASH_STATE_WORDS, PVT__PERL_HASH_WORD_TYPE) /* perl.c and hv.h */
#endif
#if defined(PERL_USE_SINGLE_CHAR_HASH_CACHE)
#define PERL_SINGLE_CHAR_HASH_CACHE_ELEMS ((1+256) * sizeof(U32))
PERLVARA(G, hash_chars, PERL_SINGLE_CHAR_HASH_CACHE_ELEMS, unsigned char) /* perl.c and hv.h */
#endif
/* The path separator can vary depending on whether we're running under DCL or
* a Unix shell.
*/
#ifdef __VMS
PERLVAR(G, perllib_sep, char)
#endif
/* Definitions of user-defined \p{} properties, as the subs that define them
* are only called once */
PERLVARI(G, user_def_props, HV *, NULL)
#if defined(USE_ITHREADS)
PERLVAR(G, user_def_props_aTHX, PerlInterpreter *) /* aTHX that user_def_props
was defined in */
PERLVAR(G, user_prop_mutex, perl_mutex) /* Mutex for manipulating
PL_user_defined_properties */
#endif
/* these record the best way to perform certain IO operations while
* atomically setting FD_CLOEXEC. On the first call, a probe is done
* and the result recorded for use by subsequent calls.
* In theory these variables aren't thread-safe, but the worst that can
* happen is that two treads will both do an initial probe
*/
PERLVARI(G, strategy_dup, int, 0) /* doio.c */
PERLVARI(G, strategy_dup2, int, 0) /* doio.c */
PERLVARI(G, strategy_open, int, 0) /* doio.c */
PERLVARI(G, strategy_open3, int, 0) /* doio.c */
PERLVARI(G, strategy_mkstemp, int, 0) /* doio.c */
PERLVARI(G, strategy_socket, int, 0) /* doio.c */
PERLVARI(G, strategy_accept, int, 0) /* doio.c */
PERLVARI(G, strategy_pipe, int, 0) /* doio.c */
PERLVARI(G, strategy_socketpair, int, 0) /* doio.c */
PERLVARI(G, my_environ, char **, NULL)
PERLVARI(G, origenviron, char **, NULL)
|