Mercurial > vim
view src/channel.c @ 8041:c6443e78cf2d v7.4.1315
commit https://github.com/vim/vim/commit/7707344ddec9069b495b2a5ed41f2104466fc88b
Author: Bram Moolenaar <Bram@vim.org>
Date: Sat Feb 13 23:23:53 2016 +0100
patch 7.4.1315
Problem: Using a channel handle does not allow for freeing it when unused.
Solution: Add the Channel variable type.
| author | Christian Brabandt <cb@256bit.org> |
|---|---|
| date | Sat, 13 Feb 2016 23:30:05 +0100 |
| parents | 72324c2e890a |
| children | 7c74cafac0a1 |
line wrap: on
line source
/* vi:set ts=8 sts=4 sw=4: * * VIM - Vi IMproved by Bram Moolenaar * * Do ":help uganda" in Vim to read copying and usage conditions. * Do ":help credits" in Vim to see a list of people who contributed. */ /* * Implements communication through a socket or any file handle. */ #include "vim.h" #if defined(FEAT_CHANNEL) || defined(PROTO) /* TRUE when netbeans is running with a GUI. */ #ifdef FEAT_GUI # define CH_HAS_GUI (gui.in_use || gui.starting) #endif /* Note: when making changes here also adjust configure.in. */ #ifdef WIN32 /* WinSock API is separated from C API, thus we can't use read(), write(), * errno... */ # define SOCK_ERRNO errno = WSAGetLastError() # undef ECONNREFUSED # define ECONNREFUSED WSAECONNREFUSED # undef EWOULDBLOCK # define EWOULDBLOCK WSAEWOULDBLOCK # ifdef EINTR # undef EINTR # endif # define EINTR WSAEINTR # define sock_write(sd, buf, len) send(sd, buf, len, 0) # define sock_read(sd, buf, len) recv(sd, buf, len, 0) # define sock_close(sd) closesocket(sd) # define sleep(t) Sleep(t*1000) /* WinAPI Sleep() accepts milliseconds */ #else # include <netdb.h> # include <netinet/in.h> # include <sys/socket.h> # ifdef HAVE_LIBGEN_H # include <libgen.h> # endif # define SOCK_ERRNO # define sock_write(sd, buf, len) write(sd, buf, len) # define sock_read(sd, buf, len) read(sd, buf, len) # define sock_close(sd) close(sd) #endif #ifdef FEAT_GUI_W32 extern HWND s_hwnd; /* Gvim's Window handle */ #endif /* Log file opened with ch_logfile(). */ static FILE *log_fd = NULL; void ch_logfile(FILE *file) { if (log_fd != NULL) fclose(log_fd); log_fd = file; if (log_fd != NULL) fprintf(log_fd, "==== start log session ====\n"); } static void ch_log_lead(char *what, channel_T *ch) { if (log_fd != NULL) { if (ch != NULL) fprintf(log_fd, "%son %d: ", what, ch->ch_id); else fprintf(log_fd, "%s: ", what); } } static void ch_log(channel_T *ch, char *msg) { if (log_fd != NULL) { ch_log_lead("", ch); fputs(msg, log_fd); fflush(log_fd); } } static void ch_logn(channel_T *ch, char *msg, int nr) { if (log_fd != NULL) { ch_log_lead("", ch); fprintf(log_fd, msg, nr); fflush(log_fd); } } static void ch_logs(channel_T *ch, char *msg, char *name) { if (log_fd != NULL) { ch_log_lead("", ch); fprintf(log_fd, msg, name); fflush(log_fd); } } static void ch_logsn(channel_T *ch, char *msg, char *name, int nr) { if (log_fd != NULL) { ch_log_lead("", ch); fprintf(log_fd, msg, name, nr); fflush(log_fd); } } static void ch_error(channel_T *ch, char *msg) { if (log_fd != NULL) { ch_log_lead("ERR ", ch); fputs(msg, log_fd); fflush(log_fd); } } static void ch_errorn(channel_T *ch, char *msg, int nr) { if (log_fd != NULL) { ch_log_lead("ERR ", ch); fprintf(log_fd, msg, nr); fflush(log_fd); } } static void ch_errors(channel_T *ch, char *msg, char *arg) { if (log_fd != NULL) { ch_log_lead("ERR ", ch); fprintf(log_fd, msg, arg); fflush(log_fd); } } #ifdef _WIN32 # undef PERROR # define PERROR(msg) (void)emsg3((char_u *)"%s: %s", \ (char_u *)msg, (char_u *)strerror_win32(errno)) static char * strerror_win32(int eno) { static LPVOID msgbuf = NULL; char_u *ptr; if (msgbuf) LocalFree(msgbuf); FormatMessage( FORMAT_MESSAGE_ALLOCATE_BUFFER | FORMAT_MESSAGE_FROM_SYSTEM | FORMAT_MESSAGE_IGNORE_INSERTS, NULL, eno, MAKELANGID(LANG_ENGLISH, SUBLANG_DEFAULT), (LPTSTR) &msgbuf, 0, NULL); /* chomp \r or \n */ for (ptr = (char_u *)msgbuf; *ptr; ptr++) switch (*ptr) { case '\r': STRMOVE(ptr, ptr + 1); ptr--; break; case '\n': if (*(ptr + 1) == '\0') *ptr = '\0'; else *ptr = ' '; break; } return msgbuf; } #endif /* * The list of all allocated channels. */ static channel_T *first_channel = NULL; static int next_ch_id = 0; /* * Allocate a new channel. The refcount is set to 1. * The channel isn't actually used until it is opened. * Returns NULL if out of memory. */ channel_T * add_channel(void) { channel_T *channel = (channel_T *)alloc_clear((int)sizeof(channel_T)); if (channel == NULL) return NULL; channel->ch_id = next_ch_id++; ch_log(channel, "Opening channel\n"); channel->ch_sock = (sock_T)-1; #ifdef CHANNEL_PIPES channel->ch_in = -1; channel->ch_out = -1; channel->ch_err = -1; #endif #ifdef FEAT_GUI_X11 channel->ch_inputHandler = (XtInputId)NULL; #endif #ifdef FEAT_GUI_GTK channel->ch_inputHandler = 0; #endif #ifdef FEAT_GUI_W32 channel->ch_inputHandler = -1; #endif channel->ch_timeout = 2000; if (first_channel != NULL) { first_channel->ch_prev = channel; channel->ch_next = first_channel; } first_channel = channel; channel->ch_refcount = 1; return channel; } /* * Close a channel and free all its resources. */ void channel_free(channel_T *channel) { channel_close(channel); if (channel->ch_next != NULL) channel->ch_next->ch_prev = channel->ch_prev; if (channel->ch_prev == NULL) first_channel = channel->ch_next; else channel->ch_prev->ch_next = channel->ch_next; vim_free(channel); } #if defined(FEAT_GUI_X11) || defined(FEAT_GUI_GTK) static channel_T * channel_from_id(int id) { channel_T *channel; for (channel = first_channel; channel != NULL; channel = channel->ch_next) if (channel->ch_id == id) return channel; return NULL; } #endif #if defined(FEAT_GUI) || defined(PROTO) #if defined(FEAT_GUI_X11) || defined(FEAT_GUI_GTK) static void channel_read_netbeans(int id) { channel_T *channel = channel_from_id(id); if (channel == NULL) ch_errorn(NULL, "Channel %d not found", id); else channel_read(channel, FALSE, "messageFromNetbeans"); } #endif /* * Read a command from netbeans. */ #ifdef FEAT_GUI_X11 static void messageFromNetbeans(XtPointer clientData, int *unused1 UNUSED, XtInputId *unused2 UNUSED) { channel_read_netbeans((int)(long)clientData); } #endif #ifdef FEAT_GUI_GTK static void messageFromNetbeans(gpointer clientData, gint unused1 UNUSED, GdkInputCondition unused2 UNUSED) { channel_read_netbeans((int)(long)clientData); } #endif static void channel_gui_register(channel_T *channel) { if (!CH_HAS_GUI) return; /* TODO: pipes */ # ifdef FEAT_GUI_X11 /* tell notifier we are interested in being called * when there is input on the editor connection socket */ if (channel->ch_inputHandler == (XtInputId)NULL) channel->ch_inputHandler = XtAppAddInput((XtAppContext)app_context, channel->ch_sock, (XtPointer)(XtInputReadMask + XtInputExceptMask), messageFromNetbeans, (XtPointer)(long)channel->ch_id); # else # ifdef FEAT_GUI_GTK /* * Tell gdk we are interested in being called when there * is input on the editor connection socket */ if (channel->ch_inputHandler == 0) channel->ch_inputHandler = gdk_input_add((gint)channel->ch_sock, (GdkInputCondition) ((int)GDK_INPUT_READ + (int)GDK_INPUT_EXCEPTION), messageFromNetbeans, (gpointer)(long)channel->ch_id); # else # ifdef FEAT_GUI_W32 /* * Tell Windows we are interested in receiving message when there * is input on the editor connection socket. */ if (channel->ch_inputHandler == -1) channel->ch_inputHandler = WSAAsyncSelect(channel->ch_sock, s_hwnd, WM_NETBEANS, FD_READ); # endif # endif # endif } /* * Register any of our file descriptors with the GUI event handling system. * Called when the GUI has started. */ void channel_gui_register_all(void) { channel_T *channel; for (channel = first_channel; channel != NULL; channel = channel->ch_next) /* TODO: pipes */ if (channel->ch_sock >= 0) channel_gui_register(channel); } static void channel_gui_unregister(channel_T *channel) { /* TODO: pipes */ # ifdef FEAT_GUI_X11 if (channel->ch_inputHandler != (XtInputId)NULL) { XtRemoveInput(channel->ch_inputHandler); channel->ch_inputHandler = (XtInputId)NULL; } # else # ifdef FEAT_GUI_GTK if (channel->ch_inputHandler != 0) { gdk_input_remove(channel->ch_inputHandler); channel->ch_inputHandler = 0; } # else # ifdef FEAT_GUI_W32 if (channel->ch_inputHandler == 0) { WSAAsyncSelect(channel->ch_sock, s_hwnd, 0, 0); channel->ch_inputHandler = -1; } # endif # endif # endif } #endif /* * Open a socket channel to "hostname":"port". * Returns the channel for success. * Returns NULL for failure. */ channel_T * channel_open(char *hostname, int port_in, int waittime, void (*close_cb)(void)) { int sd; struct sockaddr_in server; struct hostent * host; #ifdef WIN32 u_short port = port_in; u_long val = 1; #else int port = port_in; #endif channel_T *channel; int ret; #ifdef WIN32 channel_init_winsock(); #endif channel = add_channel(); if (channel == NULL) { ch_error(NULL, "Cannot allocate channel.\n"); EMSG(_("E897: All channels are in use")); return NULL; } if ((sd = (sock_T)socket(AF_INET, SOCK_STREAM, 0)) == (sock_T)-1) { ch_error(NULL, "in socket() in channel_open().\n"); PERROR("E898: socket() in channel_open()"); return NULL; } /* Get the server internet address and put into addr structure */ /* fill in the socket address structure and connect to server */ vim_memset((char *)&server, 0, sizeof(server)); server.sin_family = AF_INET; server.sin_port = htons(port); if ((host = gethostbyname(hostname)) == NULL) { ch_error(NULL, "in gethostbyname() in channel_open()\n"); PERROR("E901: gethostbyname() in channel_open()"); sock_close(sd); return NULL; } memcpy((char *)&server.sin_addr, host->h_addr, host->h_length); if (waittime >= 0) { /* Make connect non-blocking. */ if ( #ifdef _WIN32 ioctlsocket(sd, FIONBIO, &val) < 0 #else fcntl(sd, F_SETFL, O_NONBLOCK) < 0 #endif ) { SOCK_ERRNO; ch_errorn(NULL, "channel_open: Connect failed with errno %d\n", errno); sock_close(sd); return NULL; } } /* Try connecting to the server. */ ch_logsn(NULL, "Connecting to %s port %d", hostname, port); ret = connect(sd, (struct sockaddr *)&server, sizeof(server)); SOCK_ERRNO; if (ret < 0) { if (errno != EWOULDBLOCK #ifdef EINPROGRESS && errno != EINPROGRESS #endif ) { ch_errorn(NULL, "channel_open: Connect failed with errno %d\n", errno); PERROR(_("E902: Cannot connect to port")); sock_close(sd); return NULL; } } if (waittime >= 0 && ret < 0) { struct timeval tv; fd_set wfds; FD_ZERO(&wfds); FD_SET(sd, &wfds); tv.tv_sec = waittime / 1000; tv.tv_usec = (waittime % 1000) * 1000; ret = select((int)sd + 1, NULL, &wfds, NULL, &tv); if (ret < 0) { SOCK_ERRNO; ch_errorn(NULL, "channel_open: Connect failed with errno %d\n", errno); PERROR(_("E902: Cannot connect to port")); sock_close(sd); return NULL; } if (!FD_ISSET(sd, &wfds)) { /* don't give an error, we just timed out. */ sock_close(sd); return NULL; } } if (waittime >= 0) { #ifdef _WIN32 val = 0; ioctlsocket(sd, FIONBIO, &val); #else (void)fcntl(sd, F_SETFL, 0); #endif } /* Only retry for netbeans. TODO: can we use a waittime instead? */ if (errno == ECONNREFUSED && close_cb != NULL) { sock_close(sd); if ((sd = (sock_T)socket(AF_INET, SOCK_STREAM, 0)) == (sock_T)-1) { SOCK_ERRNO; ch_log(NULL, "socket() retry in channel_open()\n"); PERROR("E900: socket() retry in channel_open()"); return NULL; } if (connect(sd, (struct sockaddr *)&server, sizeof(server))) { int retries = 36; int success = FALSE; SOCK_ERRNO; while (retries-- && ((errno == ECONNREFUSED) || (errno == EINTR))) { ch_log(NULL, "retrying...\n"); mch_delay(3000L, TRUE); ui_breakcheck(); if (got_int) { errno = EINTR; break; } if (connect(sd, (struct sockaddr *)&server, sizeof(server)) == 0) { success = TRUE; break; } SOCK_ERRNO; } if (!success) { /* Get here when the server can't be found. */ ch_error(NULL, "Cannot connect to port after retry\n"); PERROR(_("E899: Cannot connect to port after retry2")); sock_close(sd); return NULL; } } } channel->ch_sock = sd; channel->ch_close_cb = close_cb; #ifdef FEAT_GUI channel_gui_register(channel); #endif return channel; } #if defined(CHANNEL_PIPES) || defined(PROTO) void channel_set_pipes(channel_T *channel, int in, int out, int err) { channel->ch_in = in; channel->ch_out = out; channel->ch_err = err; } #endif void channel_set_job(channel_T *channel, job_T *job) { channel->ch_job = job; } /* * Set the json mode of channel "channel" to "ch_mode". */ void channel_set_json_mode(channel_T *channel, ch_mode_T ch_mode) { channel->ch_mode = ch_mode; } /* * Set the read timeout of channel "channel". */ void channel_set_timeout(channel_T *channel, int timeout) { channel->ch_timeout = timeout; } /* * Set the callback for channel "channel". */ void channel_set_callback(channel_T *channel, char_u *callback) { vim_free(channel->ch_callback); channel->ch_callback = vim_strsave(callback); } /* * Set the callback for channel "channel" for the response with "id". */ void channel_set_req_callback(channel_T *channel, char_u *callback, int id) { cbq_T *head = &channel->ch_cb_head; cbq_T *item = (cbq_T *)alloc((int)sizeof(cbq_T)); if (item != NULL) { item->cq_callback = vim_strsave(callback); item->cq_seq_nr = id; item->cq_prev = head->cq_prev; head->cq_prev = item; item->cq_next = NULL; if (item->cq_prev == NULL) head->cq_next = item; else item->cq_prev->cq_next = item; } } /* * Invoke the "callback" on channel "channel". */ static void invoke_callback(channel_T *channel, char_u *callback, typval_T *argv) { typval_T rettv; int dummy; argv[0].v_type = VAR_CHANNEL; argv[0].vval.v_channel = channel; call_func(callback, (int)STRLEN(callback), &rettv, 2, argv, 0L, 0L, &dummy, TRUE, NULL); /* If an echo command was used the cursor needs to be put back where * it belongs. */ setcursor(); cursor_on(); out_flush(); } /* * Return the first buffer from the channel and remove it. * The caller must free it. * Returns NULL if there is nothing. */ char_u * channel_get(channel_T *channel) { readq_T *head = &channel->ch_head; readq_T *node = head->rq_next; char_u *p; if (node == NULL) return NULL; /* dispose of the node but keep the buffer */ p = node->rq_buffer; head->rq_next = node->rq_next; if (node->rq_next == NULL) head->rq_prev = NULL; else node->rq_next->rq_prev = NULL; vim_free(node); return p; } /* * Returns the whole buffer contents concatenated. */ static char_u * channel_get_all(channel_T *channel) { /* Concatenate everything into one buffer. * TODO: avoid multiple allocations. */ while (channel_collapse(channel) == OK) ; return channel_get(channel); } /* * Collapses the first and second buffer in the channel "channel". * Returns FAIL if that is not possible. */ int channel_collapse(channel_T *channel) { readq_T *head = &channel->ch_head; readq_T *node = head->rq_next; char_u *p; if (node == NULL || node->rq_next == NULL) return FAIL; p = alloc((unsigned)(STRLEN(node->rq_buffer) + STRLEN(node->rq_next->rq_buffer) + 1)); if (p == NULL) return FAIL; /* out of memory */ STRCPY(p, node->rq_buffer); STRCAT(p, node->rq_next->rq_buffer); vim_free(node->rq_next->rq_buffer); node->rq_next->rq_buffer = p; /* dispose of the node and its buffer */ head->rq_next = node->rq_next; head->rq_next->rq_prev = NULL; vim_free(node->rq_buffer); vim_free(node); return OK; } /* * Use the read buffer of channel "channel" and parse a JSON messages that is * complete. The messages are added to the queue. * Return TRUE if there is more to read. */ static int channel_parse_json(channel_T *channel) { js_read_T reader; typval_T listtv; jsonq_T *item; jsonq_T *head = &channel->ch_json_head; int ret; if (channel_peek(channel) == NULL) return FALSE; /* TODO: make reader work properly */ /* reader.js_buf = channel_peek(channel); */ reader.js_buf = channel_get_all(channel); reader.js_used = 0; reader.js_fill = NULL; /* reader.js_fill = channel_fill; */ reader.js_cookie = channel; ret = json_decode(&reader, &listtv, channel->ch_mode == MODE_JS ? JSON_JS : 0); if (ret == OK) { /* Only accept the response when it is a list with at least two * items. */ if (listtv.v_type != VAR_LIST || listtv.vval.v_list->lv_len < 2) { /* TODO: give error */ clear_tv(&listtv); } else { item = (jsonq_T *)alloc((unsigned)sizeof(jsonq_T)); if (item == NULL) clear_tv(&listtv); else { item->jq_value = alloc_tv(); if (item->jq_value == NULL) { vim_free(item); clear_tv(&listtv); } else { *item->jq_value = listtv; item->jq_prev = head->jq_prev; head->jq_prev = item; item->jq_next = NULL; if (item->jq_prev == NULL) head->jq_next = item; else item->jq_prev->jq_next = item; } } } } /* Put the unread part back into the channel. * TODO: insert in front */ if (reader.js_buf[reader.js_used] != NUL) { channel_save(channel, reader.js_buf + reader.js_used, (int)(reader.js_end - reader.js_buf) - reader.js_used); ret = TRUE; } else ret = FALSE; vim_free(reader.js_buf); return ret; } /* * Remove "node" from the queue that it is in and free it. * Also frees the contained callback name. */ static void remove_cb_node(cbq_T *head, cbq_T *node) { if (node->cq_prev == NULL) head->cq_next = node->cq_next; else node->cq_prev->cq_next = node->cq_next; if (node->cq_next == NULL) head->cq_prev = node->cq_prev; else node->cq_next->cq_prev = node->cq_prev; vim_free(node->cq_callback); vim_free(node); } /* * Remove "node" from the queue that it is in and free it. * Caller should have freed or used node->jq_value. */ static void remove_json_node(jsonq_T *head, jsonq_T *node) { if (node->jq_prev == NULL) head->jq_next = node->jq_next; else node->jq_prev->jq_next = node->jq_next; if (node->jq_next == NULL) head->jq_prev = node->jq_prev; else node->jq_next->jq_prev = node->jq_prev; vim_free(node); } /* * Get a message from the JSON queue for channel "channel". * When "id" is positive it must match the first number in the list. * When "id" is zero or negative jut get the first message. But not the one * with id ch_block_id. * Return OK when found and return the value in "rettv". * Return FAIL otherwise. */ static int channel_get_json(channel_T *channel, int id, typval_T **rettv) { jsonq_T *head = &channel->ch_json_head; jsonq_T *item = head->jq_next; while (item != NULL) { list_T *l = item->jq_value->vval.v_list; typval_T *tv = &l->lv_first->li_tv; if ((id > 0 && tv->v_type == VAR_NUMBER && tv->vval.v_number == id) || (id <= 0 && (tv->v_type != VAR_NUMBER || tv->vval.v_number == 0 || tv->vval.v_number != channel->ch_block_id))) { *rettv = item->jq_value; remove_json_node(head, item); return OK; } item = item->jq_next; } return FAIL; } /* * Execute a command received over channel "channel". * "cmd" is the command string, "arg2" the second argument. * "arg3" is the third argument, NULL if missing. */ static void channel_exe_cmd(channel_T *channel, char_u *cmd, typval_T *arg2, typval_T *arg3) { char_u *arg; if (arg2->v_type != VAR_STRING) { if (p_verbose > 2) EMSG("E903: received ex command with non-string argument"); return; } arg = arg2->vval.v_string; if (arg == NULL) arg = (char_u *)""; if (STRCMP(cmd, "ex") == 0) { do_cmdline_cmd(arg); } else if (STRCMP(cmd, "normal") == 0) { exarg_T ea; ea.arg = arg; ea.addr_count = 0; ea.forceit = TRUE; /* no mapping */ ex_normal(&ea); } else if (STRCMP(cmd, "redraw") == 0) { exarg_T ea; ea.forceit = *arg != NUL; ex_redraw(&ea); showruler(FALSE); setcursor(); out_flush(); #ifdef FEAT_GUI if (gui.in_use) { gui_update_cursor(FALSE, FALSE); gui_mch_flush(); } #endif } else if (STRCMP(cmd, "expr") == 0 || STRCMP(cmd, "eval") == 0) { int is_eval = cmd[1] == 'v'; if (is_eval && (arg3 == NULL || arg3->v_type != VAR_NUMBER)) { if (p_verbose > 2) EMSG("E904: third argument for eval must be a number"); } else { typval_T *tv; typval_T err_tv; char_u *json = NULL; int options = channel->ch_mode == MODE_JS ? JSON_JS : 0; /* Don't pollute the display with errors. */ ++emsg_skip; tv = eval_expr(arg, NULL); if (is_eval) { if (tv != NULL) json = json_encode_nr_expr(arg3->vval.v_number, tv, options); if (tv == NULL || (json != NULL && *json == NUL)) { /* If evaluation failed or the result can't be encoded * then return the string "ERROR". */ vim_free(json); free_tv(tv); err_tv.v_type = VAR_STRING; err_tv.vval.v_string = (char_u *)"ERROR"; tv = &err_tv; json = json_encode_nr_expr(arg3->vval.v_number, tv, options); } if (json != NULL) { channel_send(channel, json, "eval"); vim_free(json); } } --emsg_skip; if (tv != &err_tv) free_tv(tv); } } else if (p_verbose > 2) EMSG2("E905: received unknown command: %s", cmd); } /* * Invoke a callback for channel "channel" if needed. * Return OK when a message was handled, there might be another one. */ static int may_invoke_callback(channel_T *channel) { char_u *msg = NULL; typval_T *listtv = NULL; list_T *list; typval_T *typetv; typval_T argv[3]; int seq_nr = -1; ch_mode_T ch_mode = channel->ch_mode; if (channel->ch_close_cb != NULL) /* this channel is handled elsewhere (netbeans) */ return FALSE; if (ch_mode != MODE_RAW) { /* Get any json message in the queue. */ if (channel_get_json(channel, -1, &listtv) == FAIL) { /* Parse readahead, return when there is still no message. */ channel_parse_json(channel); if (channel_get_json(channel, -1, &listtv) == FAIL) return FALSE; } list = listtv->vval.v_list; argv[1] = list->lv_first->li_next->li_tv; typetv = &list->lv_first->li_tv; if (typetv->v_type == VAR_STRING) { typval_T *arg3 = NULL; char_u *cmd = typetv->vval.v_string; /* ["cmd", arg] or ["cmd", arg, arg] */ if (list->lv_len == 3) arg3 = &list->lv_last->li_tv; ch_logs(channel, "Executing %s command", (char *)cmd); channel_exe_cmd(channel, cmd, &argv[1], arg3); free_tv(listtv); return TRUE; } if (typetv->v_type != VAR_NUMBER) { ch_error(channel, "Dropping message with invalid sequence number type\n"); free_tv(listtv); return FALSE; } seq_nr = typetv->vval.v_number; } else if (channel_peek(channel) == NULL) { /* nothing to read on raw channel */ return FALSE; } else { /* If there is no callback, don't do anything. */ if (channel->ch_callback == NULL) return FALSE; /* For a raw channel we don't know where the message ends, just get * everything. */ msg = channel_get_all(channel); argv[1].v_type = VAR_STRING; argv[1].vval.v_string = msg; } if (seq_nr > 0) { cbq_T *head = &channel->ch_cb_head; cbq_T *item = head->cq_next; int done = FALSE; /* invoke the one-time callback with the matching nr */ while (item != NULL) { if (item->cq_seq_nr == seq_nr) { ch_log(channel, "Invoking one-time callback\n"); invoke_callback(channel, item->cq_callback, argv); remove_cb_node(head, item); done = TRUE; break; } item = item->cq_next; } if (!done) ch_log(channel, "Dropping message without callback\n"); } else if (channel->ch_callback != NULL) { /* invoke the channel callback */ ch_log(channel, "Invoking channel callback\n"); invoke_callback(channel, channel->ch_callback, argv); } else ch_log(channel, "Dropping message\n"); if (listtv != NULL) free_tv(listtv); vim_free(msg); return TRUE; } /* * Return TRUE when channel "channel" is open for writing to. * Also returns FALSE or invalid "channel". */ int channel_can_write_to(channel_T *channel) { return channel != NULL && (channel->ch_sock >= 0 #ifdef CHANNEL_PIPES || channel->ch_in >= 0 #endif ); } /* * Return TRUE when channel "channel" is open for reading or writing. * Also returns FALSE for invalid "channel". */ int channel_is_open(channel_T *channel) { return channel != NULL && (channel->ch_sock >= 0 #ifdef CHANNEL_PIPES || channel->ch_in >= 0 || channel->ch_out >= 0 || channel->ch_err >= 0 #endif ); } /* * Return a string indicating the status of the channel. */ char * channel_status(channel_T *channel) { if (channel == NULL) return "fail"; if (channel_is_open(channel)) return "open"; return "closed"; } /* * Close channel "channel". * This does not trigger the close callback. */ void channel_close(channel_T *channel) { ch_log(channel, "Closing channel"); if (channel->ch_sock >= 0) { sock_close(channel->ch_sock); channel->ch_sock = -1; channel->ch_close_cb = NULL; #ifdef FEAT_GUI channel_gui_unregister(channel); #endif vim_free(channel->ch_callback); channel->ch_callback = NULL; } #if defined(CHANNEL_PIPES) if (channel->ch_in >= 0) { close(channel->ch_in); channel->ch_in = -1; } if (channel->ch_out >= 0) { close(channel->ch_out); channel->ch_out = -1; } if (channel->ch_err >= 0) { close(channel->ch_err); channel->ch_err = -1; } #endif channel_clear(channel); } /* * Store "buf[len]" on channel "channel". * Returns OK or FAIL. */ int channel_save(channel_T *channel, char_u *buf, int len) { readq_T *node; readq_T *head = &channel->ch_head; node = (readq_T *)alloc(sizeof(readq_T)); if (node == NULL) return FAIL; /* out of memory */ node->rq_buffer = alloc(len + 1); if (node->rq_buffer == NULL) { vim_free(node); return FAIL; /* out of memory */ } mch_memmove(node->rq_buffer, buf, (size_t)len); node->rq_buffer[len] = NUL; /* append node to the tail of the queue */ node->rq_next = NULL; node->rq_prev = head->rq_prev; if (head->rq_prev == NULL) head->rq_next = node; else head->rq_prev->rq_next = node; head->rq_prev = node; if (log_fd != NULL) { ch_log_lead("RECV ", channel); fprintf(log_fd, "'"); if (fwrite(buf, len, 1, log_fd) != 1) return FAIL; fprintf(log_fd, "'\n"); } return OK; } /* * Return the first buffer from the channel without removing it. * Returns NULL if there is nothing. */ char_u * channel_peek(channel_T *channel) { readq_T *head = &channel->ch_head; if (head->rq_next == NULL) return NULL; return head->rq_next->rq_buffer; } /* * Clear the read buffer on channel "channel". */ void channel_clear(channel_T *channel) { jsonq_T *json_head = &channel->ch_json_head; cbq_T *cb_head = &channel->ch_cb_head; while (channel_peek(channel) != NULL) vim_free(channel_get(channel)); while (cb_head->cq_next != NULL) remove_cb_node(cb_head, cb_head->cq_next); while (json_head->jq_next != NULL) { free_tv(json_head->jq_next->jq_value); remove_json_node(json_head, json_head->jq_next); } } #if defined(EXITFREE) || defined(PROTO) void channel_free_all(void) { channel_T *channel; for (channel = first_channel; channel != NULL; channel = channel->ch_next) channel_clear(channel); } #endif /* Sent when the channel is found closed when reading. */ #define DETACH_MSG "\"DETACH\"\n" /* Buffer size for reading incoming messages. */ #define MAXMSGSIZE 4096 /* * Check for reading from "fd" with "timeout" msec. * Return FAIL when there is nothing to read. * Always returns OK for FEAT_GUI_W32. */ static int channel_wait(channel_T *channel, int fd, int timeout) { #if defined(HAVE_SELECT) && !defined(FEAT_GUI_W32) struct timeval tval; fd_set rfds; int ret; if (timeout > 0) ch_logn(channel, "Waiting for %d msec\n", timeout); FD_ZERO(&rfds); FD_SET(fd, &rfds); tval.tv_sec = timeout / 1000; tval.tv_usec = (timeout % 1000) * 1000; for (;;) { ret = select(fd + 1, &rfds, NULL, NULL, &tval); # ifdef EINTR if (ret == -1 && errno == EINTR) continue; # endif if (ret <= 0) { ch_log(channel, "Nothing to read\n"); return FAIL; } break; } #else # ifdef HAVE_POLL struct pollfd fds; if (timeout > 0) ch_logn(channel, "Waiting for %d msec\n", timeout); fds.fd = fd; fds.events = POLLIN; if (poll(&fds, 1, timeout) <= 0) { ch_log(channel, "Nothing to read\n"); return FAIL; } # endif #endif return OK; } /* * Return a unique ID to be used in a message. */ int channel_get_id(void) { static int next_id = 1; return next_id++; } /* * Get the file descriptor to read from, either the socket or stdout. */ static int get_read_fd(channel_T *channel, int use_stderr) { if (channel->ch_sock >= 0) return channel->ch_sock; #if defined(CHANNEL_PIPES) if (!use_stderr && channel->ch_out >= 0) return channel->ch_out; if (use_stderr && channel->ch_err >= 0) return channel->ch_err; #endif ch_error(channel, "channel_read() called while socket is closed\n"); return -1; } /* * Read from channel "channel" for as long as there is something to read. * The data is put in the read queue. */ void channel_read(channel_T *channel, int use_stderr, char *func) { static char_u *buf = NULL; int len = 0; int readlen = 0; int fd; int use_socket = FALSE; fd = get_read_fd(channel, use_stderr); if (fd < 0) return; use_socket = channel->ch_sock >= 0; /* Allocate a buffer to read into. */ if (buf == NULL) { buf = alloc(MAXMSGSIZE); if (buf == NULL) return; /* out of memory! */ } /* Keep on reading for as long as there is something to read. * Use select() or poll() to avoid blocking on a message that is exactly * MAXMSGSIZE long. */ for (;;) { if (channel_wait(channel, fd, 0) == FAIL) break; if (use_socket) len = sock_read(fd, buf, MAXMSGSIZE); else len = read(fd, buf, MAXMSGSIZE); if (len <= 0) break; /* error or nothing more to read */ /* Store the read message in the queue. */ channel_save(channel, buf, len); readlen += len; if (len < MAXMSGSIZE) break; /* did read everything that's available */ } #ifdef FEAT_GUI_W32 if (use_socket && len == SOCKET_ERROR) { /* For Win32 GUI channel_wait() always returns OK and we handle the * situation that there is nothing to read here. * TODO: how about a timeout? */ if (WSAGetLastError() == WSAEWOULDBLOCK) return; } #endif /* Reading a socket disconnection (readlen == 0), or a socket error. */ if (readlen <= 0) { /* Queue a "DETACH" netbeans message in the command queue in order to * terminate the netbeans session later. Do not end the session here * directly as we may be running in the context of a call to * netbeans_parse_messages(): * netbeans_parse_messages * -> autocmd triggered while processing the netbeans cmd * -> ui_breakcheck * -> gui event loop or select loop * -> channel_read() */ ch_errors(channel, "%s(): Cannot read\n", func); channel_save(channel, (char_u *)DETACH_MSG, (int)STRLEN(DETACH_MSG)); if (use_socket) { channel_close(channel); if (channel->ch_close_cb != NULL) (*channel->ch_close_cb)(); } #if defined(CHANNEL_PIPES) else { close(fd); channel->ch_out = -1; } #endif if (len < 0) { ch_error(channel, "channel_read(): cannot read from channel\n"); PERROR(_("E896: read from channel")); } } #if defined(CH_HAS_GUI) && defined(FEAT_GUI_GTK) /* signal the main loop that there is something to read */ if (CH_HAS_GUI && gtk_main_level() > 0) gtk_main_quit(); #endif } /* * Read from raw channel "channel". Blocks until there is something to read or * the timeout expires. * Returns what was read in allocated memory. * Returns NULL in case of error or timeout. */ char_u * channel_read_block(channel_T *channel) { ch_log(channel, "Reading raw\n"); if (channel_peek(channel) == NULL) { int fd = get_read_fd(channel, FALSE); ch_log(channel, "No readahead\n"); /* Wait for up to the channel timeout. */ if (fd < 0 || channel_wait(channel, fd, channel->ch_timeout) == FAIL) return NULL; channel_read(channel, FALSE, "channel_read_block"); } /* TODO: only get the first message */ ch_log(channel, "Returning readahead\n"); return channel_get_all(channel); } /* * Read one JSON message with ID "id" from channel "channel" and store the * result in "rettv". * Blocks until the message is received or the timeout is reached. */ int channel_read_json_block(channel_T *channel, int id, typval_T **rettv) { int more; int fd; ch_log(channel, "Reading JSON\n"); channel->ch_block_id = id; for (;;) { more = channel_parse_json(channel); /* search for messsage "id" */ if (channel_get_json(channel, id, rettv) == OK) { channel->ch_block_id = 0; return OK; } if (!more) { /* Handle any other messages in the queue. If done some more * messages may have arrived. */ if (channel_parse_messages()) continue; /* Wait for up to the channel timeout. */ fd = get_read_fd(channel, FALSE); if (fd < 0 || channel_wait(channel, fd, channel->ch_timeout) == FAIL) break; channel_read(channel, FALSE, "channel_read_json_block"); } } channel->ch_block_id = 0; return FAIL; } # if defined(WIN32) || defined(PROTO) /* * Lookup the channel from the socket. * Returns NULL when the socket isn't found. */ channel_T * channel_fd2channel(sock_T fd) { channel_T *channel; if (fd >= 0) for (channel = first_channel; channel != NULL; channel = channel->ch_next) if (channel->ch_sock == fd # if defined(CHANNEL_PIPES) || channel->ch_out == fd || channel->ch_err == fd # endif ) return channel; return NULL; } # endif /* * Write "buf" (NUL terminated string) to channel "channel". * When "fun" is not NULL an error message might be given. * Return FAIL or OK. */ int channel_send(channel_T *channel, char_u *buf, char *fun) { int len = (int)STRLEN(buf); int res; int fd = -1; int use_socket = FALSE; if (channel->ch_sock >= 0) { fd = channel->ch_sock; use_socket = TRUE; } #if defined(CHANNEL_PIPES) else if (channel->ch_in >= 0) fd = channel->ch_in; #endif if (fd < 0) { if (!channel->ch_error && fun != NULL) { ch_errors(channel, "%s(): write while not connected\n", fun); EMSG2("E630: %s(): write while not connected", fun); } channel->ch_error = TRUE; return FAIL; } if (log_fd != NULL) { ch_log_lead("SEND ", channel); fprintf(log_fd, "'"); ignored = fwrite(buf, len, 1, log_fd); fprintf(log_fd, "'\n"); fflush(log_fd); } if (use_socket) res = sock_write(fd, buf, len); else res = write(fd, buf, len); if (res != len) { if (!channel->ch_error && fun != NULL) { ch_errors(channel, "%s(): write failed\n", fun); EMSG2("E631: %s(): write failed", fun); } channel->ch_error = TRUE; return FAIL; } channel->ch_error = FALSE; return OK; } # if (defined(UNIX) && !defined(HAVE_SELECT)) || defined(PROTO) /* * Add open channels to the poll struct. * Return the adjusted struct index. * The type of "fds" is hidden to avoid problems with the function proto. */ int channel_poll_setup(int nfd_in, void *fds_in) { int nfd = nfd_in; channel_T *channel; struct pollfd *fds = fds_in; for (channel = first_channel; channel != NULL; channel = channel->ch_next) { if (channel->ch_sock >= 0) { channel->ch_sock_idx = nfd; fds[nfd].fd = channel->ch_sock; fds[nfd].events = POLLIN; nfd++; } else channel->ch_sock_idx = -1; # ifdef CHANNEL_PIPES if (channel->ch_out >= 0) { channel->ch_out_idx = nfd; fds[nfd].fd = channel->ch_out; fds[nfd].events = POLLIN; nfd++; } else channel->ch_out_idx = -1; if (channel->ch_err >= 0) { channel->ch_err_idx = nfd; fds[nfd].fd = channel->ch_err; fds[nfd].events = POLLIN; nfd++; } else channel->ch_err_idx = -1; # endif } return nfd; } /* * The type of "fds" is hidden to avoid problems with the function proto. */ int channel_poll_check(int ret_in, void *fds_in) { int ret = ret_in; channel_T *channel; struct pollfd *fds = fds_in; for (channel = first_channel; channel != NULL; channel = channel->ch_next) { if (ret > 0 && channel->ch_sock_idx != -1 && fds[channel->ch_sock_idx].revents & POLLIN) { channel_read(channel, FALSE, "channel_poll_check"); --ret; } # ifdef CHANNEL_PIPES if (ret > 0 && channel->ch_out_idx != -1 && fds[channel->ch_out_idx].revents & POLLIN) { channel_read(channel, FALSE, "channel_poll_check"); --ret; } if (ret > 0 && channel->ch_err_idx != -1 && fds[channel->ch_err_idx].revents & POLLIN) { channel_read(channel, TRUE, "channel_poll_check"); --ret; } # endif } return ret; } # endif /* UNIX && !HAVE_SELECT */ # if (!defined(FEAT_GUI_W32) && defined(HAVE_SELECT)) || defined(PROTO) /* * The type of "rfds" is hidden to avoid problems with the function proto. */ int channel_select_setup(int maxfd_in, void *rfds_in) { int maxfd = maxfd_in; channel_T *channel; fd_set *rfds = rfds_in; for (channel = first_channel; channel != NULL; channel = channel->ch_next) { if (channel->ch_sock >= 0) { FD_SET(channel->ch_sock, rfds); if (maxfd < channel->ch_sock) maxfd = channel->ch_sock; } # ifdef CHANNEL_PIPES if (channel->ch_out >= 0) { FD_SET(channel->ch_out, rfds); if (maxfd < channel->ch_out) maxfd = channel->ch_out; } if (channel->ch_err >= 0) { FD_SET(channel->ch_err, rfds); if (maxfd < channel->ch_err) maxfd = channel->ch_err; } # endif } return maxfd; } /* * The type of "rfds" is hidden to avoid problems with the function proto. */ int channel_select_check(int ret_in, void *rfds_in) { int ret = ret_in; channel_T *channel; fd_set *rfds = rfds_in; for (channel = first_channel; channel != NULL; channel = channel->ch_next) { if (ret > 0 && channel->ch_sock >= 0 && FD_ISSET(channel->ch_sock, rfds)) { channel_read(channel, FALSE, "channel_select_check"); --ret; } # ifdef CHANNEL_PIPES if (ret > 0 && channel->ch_out >= 0 && FD_ISSET(channel->ch_out, rfds)) { channel_read(channel, FALSE, "channel_select_check"); --ret; } if (ret > 0 && channel->ch_err >= 0 && FD_ISSET(channel->ch_err, rfds)) { channel_read(channel, TRUE, "channel_select_check"); --ret; } # endif } return ret; } # endif /* !FEAT_GUI_W32 && HAVE_SELECT */ /* * Execute queued up commands. * Invoked from the main loop when it's safe to execute received commands. * Return TRUE when something was done. */ int channel_parse_messages(void) { channel_T *channel; int ret = FALSE; for (channel = first_channel; channel != NULL; channel = channel->ch_next) while (may_invoke_callback(channel) == OK) { channel = first_channel; /* start over */ ret = TRUE; } return ret; } /* * Mark references to lists used in channels. */ int set_ref_in_channel(int copyID) { int abort = FALSE; channel_T *channel; for (channel = first_channel; channel != NULL; channel = channel->ch_next) { jsonq_T *head = &channel->ch_json_head; jsonq_T *item = head->jq_next; while (item != NULL) { list_T *l = item->jq_value->vval.v_list; if (l->lv_copyID != copyID) { l->lv_copyID = copyID; abort = abort || set_ref_in_list(l, copyID, NULL); } item = item->jq_next; } } return abort; } /* * Return the mode of channel "channel". * If "channel" is invalid returns MODE_JSON. */ ch_mode_T channel_get_mode(channel_T *channel) { if (channel == NULL) return MODE_JSON; return channel->ch_mode; } #endif /* FEAT_CHANNEL */