Avoid losing Ctrl-C keystrokes in compilation mode on MS-Windows
[emacs.git] / src / thread.h
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1 /* Thread definitions
2 Copyright (C) 2012-2017 Free Software Foundation, Inc.
4 This file is part of GNU Emacs.
6 GNU Emacs is free software: you can redistribute it and/or modify
7 it under the terms of the GNU General Public License as published by
8 the Free Software Foundation, either version 3 of the License, or
9 (at your option) any later version.
11 GNU Emacs is distributed in the hope that it will be useful,
12 but WITHOUT ANY WARRANTY; without even the implied warranty of
13 MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
14 GNU General Public License for more details.
16 You should have received a copy of the GNU General Public License
17 along with GNU Emacs. If not, see <http://www.gnu.org/licenses/>. */
19 #ifndef THREAD_H
20 #define THREAD_H
22 #include "regex.h"
24 #ifdef WINDOWSNT
25 #include <sys/socket.h>
26 #endif
28 #include "sysselect.h" /* FIXME */
29 #include "systime.h" /* FIXME */
30 #include "systhread.h"
32 struct thread_state
34 struct vectorlike_header header;
36 /* The buffer in which the last search was performed, or
37 Qt if the last search was done in a string;
38 Qnil if no searching has been done yet. */
39 Lisp_Object m_last_thing_searched;
40 #define last_thing_searched (current_thread->m_last_thing_searched)
42 Lisp_Object m_saved_last_thing_searched;
43 #define saved_last_thing_searched (current_thread->m_saved_last_thing_searched)
45 /* The thread's name. */
46 Lisp_Object name;
48 /* The thread's function. */
49 Lisp_Object function;
51 /* If non-nil, this thread has been signaled. */
52 Lisp_Object error_symbol;
53 Lisp_Object error_data;
55 /* If we are waiting for some event, this holds the object we are
56 waiting on. */
57 Lisp_Object event_object;
59 /* m_stack_bottom must be the first non-Lisp field. */
60 /* An address near the bottom of the stack.
61 Tells GC how to save a copy of the stack. */
62 char *m_stack_bottom;
63 #define stack_bottom (current_thread->m_stack_bottom)
65 /* The address of an object near the C stack top, used to determine
66 which words need to be scanned by the garbage collector. This is
67 also used to detect heuristically whether segmentation violation
68 address indicates stack overflow, as opposed to some internal
69 error in Emacs. If the C function F calls G which calls H which
70 calls ... F, then at least one of the functions in the chain
71 should set this to the address of a local variable. */
72 void *stack_top;
74 struct catchtag *m_catchlist;
75 #define catchlist (current_thread->m_catchlist)
77 /* Chain of condition handlers currently in effect.
78 The elements of this chain are contained in the stack frames
79 of Fcondition_case and internal_condition_case.
80 When an error is signaled (by calling Fsignal),
81 this chain is searched for an element that applies. */
82 struct handler *m_handlerlist;
83 #define handlerlist (current_thread->m_handlerlist)
85 struct handler *m_handlerlist_sentinel;
86 #define handlerlist_sentinel (current_thread->m_handlerlist_sentinel)
88 /* Current number of specbindings allocated in specpdl. */
89 ptrdiff_t m_specpdl_size;
90 #define specpdl_size (current_thread->m_specpdl_size)
92 /* Pointer to beginning of specpdl. */
93 union specbinding *m_specpdl;
94 #define specpdl (current_thread->m_specpdl)
96 /* Pointer to first unused element in specpdl. */
97 union specbinding *m_specpdl_ptr;
98 #define specpdl_ptr (current_thread->m_specpdl_ptr)
100 /* Depth in Lisp evaluations and function calls. */
101 EMACS_INT m_lisp_eval_depth;
102 #define lisp_eval_depth (current_thread->m_lisp_eval_depth)
104 /* This points to the current buffer. */
105 struct buffer *m_current_buffer;
106 #define current_buffer (current_thread->m_current_buffer)
108 /* Every call to re_match, etc., must pass &search_regs as the regs
109 argument unless you can show it is unnecessary (i.e., if re_match
110 is certainly going to be called again before region-around-match
111 can be called).
113 Since the registers are now dynamically allocated, we need to make
114 sure not to refer to the Nth register before checking that it has
115 been allocated by checking search_regs.num_regs.
117 The regex code keeps track of whether it has allocated the search
118 buffer using bits in the re_pattern_buffer. This means that whenever
119 you compile a new pattern, it completely forgets whether it has
120 allocated any registers, and will allocate new registers the next
121 time you call a searching or matching function. Therefore, we need
122 to call re_set_registers after compiling a new pattern or after
123 setting the match registers, so that the regex functions will be
124 able to free or re-allocate it properly. */
125 struct re_registers m_search_regs;
126 #define search_regs (current_thread->m_search_regs)
128 /* If non-zero the match data have been saved in saved_search_regs
129 during the execution of a sentinel or filter. */
130 bool m_search_regs_saved;
131 #define search_regs_saved (current_thread->m_search_regs_saved)
133 struct re_registers m_saved_search_regs;
134 #define saved_search_regs (current_thread->m_saved_search_regs)
136 /* This is the string or buffer in which we
137 are matching. It is used for looking up syntax properties.
139 If the value is a Lisp string object, we are matching text in that
140 string; if it's nil, we are matching text in the current buffer; if
141 it's t, we are matching text in a C string. */
142 Lisp_Object m_re_match_object;
143 #define re_match_object (current_thread->m_re_match_object)
145 /* This member is different from waiting_for_input.
146 It is used to communicate to a lisp process-filter/sentinel (via the
147 function Fwaiting_for_user_input_p) whether Emacs was waiting
148 for user-input when that process-filter was called.
149 waiting_for_input cannot be used as that is by definition 0 when
150 lisp code is being evalled.
151 This is also used in record_asynch_buffer_change.
152 For that purpose, this must be 0
153 when not inside wait_reading_process_output. */
154 int m_waiting_for_user_input_p;
155 #define waiting_for_user_input_p (current_thread->m_waiting_for_user_input_p)
157 /* True while doing kbd input. */
158 bool m_waiting_for_input;
159 #define waiting_for_input (current_thread->m_waiting_for_input)
161 /* The OS identifier for this thread. */
162 sys_thread_t thread_id;
164 /* The condition variable for this thread. This is associated with
165 the global lock. This thread broadcasts to it when it exits. */
166 sys_cond_t thread_condvar;
168 /* This thread might be waiting for some condition. If so, this
169 points to the condition. If the thread is interrupted, the
170 interrupter should broadcast to this condition. */
171 sys_cond_t *wait_condvar;
173 /* This thread might have released the global lock. If so, this is
174 non-zero. When a thread runs outside thread_select with this
175 flag non-zero, it means it has been interrupted by SIGINT while
176 in thread_select, and didn't have a chance of acquiring the lock.
177 It must do so ASAP. */
178 int not_holding_lock;
180 /* Threads are kept on a linked list. */
181 struct thread_state *next_thread;
184 INLINE bool
185 THREADP (Lisp_Object a)
187 return PSEUDOVECTORP (a, PVEC_THREAD);
190 INLINE void
191 CHECK_THREAD (Lisp_Object x)
193 CHECK_TYPE (THREADP (x), Qthreadp, x);
196 INLINE struct thread_state *
197 XTHREAD (Lisp_Object a)
199 eassert (THREADP (a));
200 return XUNTAG (a, Lisp_Vectorlike);
203 /* A mutex in lisp is represented by a system condition variable.
204 The system mutex associated with this condition variable is the
205 global lock.
207 Using a condition variable lets us implement interruptibility for
208 lisp mutexes. */
209 typedef struct
211 /* The owning thread, or NULL if unlocked. */
212 struct thread_state *owner;
213 /* The lock count. */
214 unsigned int count;
215 /* The underlying system condition variable. */
216 sys_cond_t condition;
217 } lisp_mutex_t;
219 /* A mutex as a lisp object. */
220 struct Lisp_Mutex
222 struct vectorlike_header header;
224 /* The name of the mutex, or nil. */
225 Lisp_Object name;
227 /* The lower-level mutex object. */
228 lisp_mutex_t mutex;
231 INLINE bool
232 MUTEXP (Lisp_Object a)
234 return PSEUDOVECTORP (a, PVEC_MUTEX);
237 INLINE void
238 CHECK_MUTEX (Lisp_Object x)
240 CHECK_TYPE (MUTEXP (x), Qmutexp, x);
243 INLINE struct Lisp_Mutex *
244 XMUTEX (Lisp_Object a)
246 eassert (MUTEXP (a));
247 return XUNTAG (a, Lisp_Vectorlike);
250 /* A condition variable as a lisp object. */
251 struct Lisp_CondVar
253 struct vectorlike_header header;
255 /* The associated mutex. */
256 Lisp_Object mutex;
258 /* The name of the condition variable, or nil. */
259 Lisp_Object name;
261 /* The lower-level condition variable object. */
262 sys_cond_t cond;
265 INLINE bool
266 CONDVARP (Lisp_Object a)
268 return PSEUDOVECTORP (a, PVEC_CONDVAR);
271 INLINE void
272 CHECK_CONDVAR (Lisp_Object x)
274 CHECK_TYPE (CONDVARP (x), Qcondition_variable_p, x);
277 INLINE struct Lisp_CondVar *
278 XCONDVAR (Lisp_Object a)
280 eassert (CONDVARP (a));
281 return XUNTAG (a, Lisp_Vectorlike);
284 extern struct thread_state *current_thread;
286 extern void finalize_one_thread (struct thread_state *state);
287 extern void finalize_one_mutex (struct Lisp_Mutex *);
288 extern void finalize_one_condvar (struct Lisp_CondVar *);
289 extern void maybe_reacquire_global_lock (void);
291 extern void init_threads_once (void);
292 extern void init_threads (void);
293 extern void syms_of_threads (void);
294 extern bool main_thread_p (void *);
296 typedef int select_func (int, fd_set *, fd_set *, fd_set *,
297 const struct timespec *, const sigset_t *);
299 int thread_select (select_func *func, int max_fds, fd_set *rfds,
300 fd_set *wfds, fd_set *efds, struct timespec *timeout,
301 sigset_t *sigmask);
303 bool thread_check_current_buffer (struct buffer *);
305 #endif /* THREAD_H */