Google Git
Sign in
nest-open-source / nest-learning-thermostat / 5.1 / ncurses / a926b186d1da1a64c3b4b62898d1d3cd3096ea45 / . / ncurses-5.7 / ncurses / base / lib_mouse.c
blob: 95f29aa69111a47c8577536b921c31d823efa3cc [file] [log] [blame]
/****************************************************************************
* Copyright (c) 1998-2007,2008 Free Software Foundation, Inc. *
* *
* Permission is hereby granted, free of charge, to any person obtaining a *
* copy of this software and associated documentation files (the *
* "Software"), to deal in the Software without restriction, including *
* without limitation the rights to use, copy, modify, merge, publish, *
* distribute, distribute with modifications, sublicense, and/or sell *
* copies of the Software, and to permit persons to whom the Software is *
* furnished to do so, subject to the following conditions: *
* *
* The above copyright notice and this permission notice shall be included *
* in all copies or substantial portions of the Software. *
* *
* THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS *
* OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF *
* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. *
* IN NO EVENT SHALL THE ABOVE COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, *
* DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR *
* OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR *
* THE USE OR OTHER DEALINGS IN THE SOFTWARE. *
* *
* Except as contained in this notice, the name(s) of the above copyright *
* holders shall not be used in advertising or otherwise to promote the *
* sale, use or other dealings in this Software without prior written *
* authorization. *
****************************************************************************/
/****************************************************************************
* Author: Zeyd M. Ben-Halim <zmbenhal@netcom.com> 1992,1995 *
* and: Eric S. Raymond <esr@snark.thyrsus.com> *
* and: Thomas E. Dickey 1996-on *
****************************************************************************/
/*
* This module is intended to encapsulate ncurses's interface to pointing
* devices.
*
* The primary method used is xterm's internal mouse-tracking facility.
* Additional methods depend on the platform:
* Alessandro Rubini's GPM server (Linux)
* sysmouse (FreeBSD)
* special-purpose mouse interface for OS/2 EMX.
*
* Notes for implementors of new mouse-interface methods:
*
* The code is logically split into a lower level that accepts event reports
* in a device-dependent format and an upper level that parses mouse gestures
* and filters events. The mediating data structure is a circular queue of
* MEVENT structures.
*
* Functionally, the lower level's job is to pick up primitive events and
* put them on the circular queue. This can happen in one of two ways:
* either (a) _nc_mouse_event() detects a series of incoming mouse reports
* and queues them, or (b) code in lib_getch.c detects the kmous prefix in
* the keyboard input stream and calls _nc_mouse_inline to queue up a series
* of adjacent mouse reports.
*
* In either case, _nc_mouse_parse() should be called after the series is
* accepted to parse the digested mouse reports (low-level MEVENTs) into
* a gesture (a high-level or composite MEVENT).
*
* Don't be too shy about adding new event types or modifiers, if you can find
* room for them in the 32-bit mask. The API is written so that users get
* feedback on which theoretical event types they won't see when they call
* mousemask. There's one bit per button (the RESERVED_EVENT bit) not being
* used yet, and a couple of bits open at the high end.
*/
#ifdef __EMX__
# include <io.h>
# define INCL_DOS
# define INCL_VIO
# define INCL_KBD
# define INCL_MOU
# define INCL_DOSPROCESS
# include <os2.h> /* Need to include before the others */
#endif
#include <curses.priv.h>
MODULE_ID("$Id: lib_mouse.c,v 1.102 2008/10/18 21:48:55 tom Exp $")
#include <term.h>
#include <tic.h>
#if USE_GPM_SUPPORT
#include <linux/keyboard.h> /* defines KG_* macros */
#ifdef HAVE_LIBDL
/* use dynamic loader to avoid linkage dependency */
#include <dlfcn.h>
#ifdef RTLD_NOW
#define my_RTLD RTLD_NOW
#else
#ifdef RTLD_LAZY
#define my_RTLD RTLD_LAZY
#else
make an error
#endif
#endif /* RTLD_NOW */
#endif /* HAVE_LIBDL */
#endif /* USE_GPM_SUPPORT */
#if USE_SYSMOUSE
#undef buttons /* symbol conflict in consio.h */
#undef mouse_info /* symbol conflict in consio.h */
#include <osreldate.h>
#if (__FreeBSD_version >= 400017)
#include <sys/consio.h>
#include <sys/fbio.h>
#else
#include <machine/console.h>
#endif
#endif /* use_SYSMOUSE */
#define MY_TRACE TRACE_ICALLS|TRACE_IEVENT
#define MASK_RELEASE(x) NCURSES_MOUSE_MASK(x, 001)
#define MASK_PRESS(x) NCURSES_MOUSE_MASK(x, 002)
#define MASK_CLICK(x) NCURSES_MOUSE_MASK(x, 004)
#define MASK_DOUBLE_CLICK(x) NCURSES_MOUSE_MASK(x, 010)
#define MASK_TRIPLE_CLICK(x) NCURSES_MOUSE_MASK(x, 020)
#define MASK_RESERVED_EVENT(x) NCURSES_MOUSE_MASK(x, 040)
#if NCURSES_MOUSE_VERSION == 1
#define BUTTON_CLICKED (BUTTON1_CLICKED | BUTTON2_CLICKED | BUTTON3_CLICKED | BUTTON4_CLICKED)
#define BUTTON_PRESSED (BUTTON1_PRESSED | BUTTON2_PRESSED | BUTTON3_PRESSED | BUTTON4_PRESSED)
#define BUTTON_RELEASED (BUTTON1_RELEASED | BUTTON2_RELEASED | BUTTON3_RELEASED | BUTTON4_RELEASED)
#define BUTTON_DOUBLE_CLICKED (BUTTON1_DOUBLE_CLICKED | BUTTON2_DOUBLE_CLICKED | BUTTON3_DOUBLE_CLICKED | BUTTON4_DOUBLE_CLICKED)
#define BUTTON_TRIPLE_CLICKED (BUTTON1_TRIPLE_CLICKED | BUTTON2_TRIPLE_CLICKED | BUTTON3_TRIPLE_CLICKED | BUTTON4_TRIPLE_CLICKED)
#define MAX_BUTTONS 4
#else
#define BUTTON_CLICKED (BUTTON1_CLICKED | BUTTON2_CLICKED | BUTTON3_CLICKED | BUTTON4_CLICKED | BUTTON5_CLICKED)
#define BUTTON_PRESSED (BUTTON1_PRESSED | BUTTON2_PRESSED | BUTTON3_PRESSED | BUTTON4_PRESSED | BUTTON5_PRESSED)
#define BUTTON_RELEASED (BUTTON1_RELEASED | BUTTON2_RELEASED | BUTTON3_RELEASED | BUTTON4_RELEASED | BUTTON5_RELEASED)
#define BUTTON_DOUBLE_CLICKED (BUTTON1_DOUBLE_CLICKED | BUTTON2_DOUBLE_CLICKED | BUTTON3_DOUBLE_CLICKED | BUTTON4_DOUBLE_CLICKED | BUTTON5_DOUBLE_CLICKED)
#define BUTTON_TRIPLE_CLICKED (BUTTON1_TRIPLE_CLICKED | BUTTON2_TRIPLE_CLICKED | BUTTON3_TRIPLE_CLICKED | BUTTON4_TRIPLE_CLICKED | BUTTON5_TRIPLE_CLICKED)
#define MAX_BUTTONS 5
#endif
#define INVALID_EVENT -1
#define NORMAL_EVENT 0
#if USE_GPM_SUPPORT
#ifndef LIBGPM_SONAME
#define LIBGPM_SONAME "libgpm.so"
#endif
#define GET_DLSYM(name) (my_##name = (TYPE_##name) dlsym(SP->_dlopen_gpm, #name))
#endif /* USE_GPM_SUPPORT */
static bool _nc_mouse_parse(SCREEN *, int);
static void _nc_mouse_resume(SCREEN *);
static void _nc_mouse_wrap(SCREEN *);
/* maintain a circular list of mouse events */
#define FirstEV(sp) ((sp)->_mouse_events)
#define LastEV(sp) ((sp)->_mouse_events + EV_MAX - 1)
#undef NEXT
#define NEXT(ep) ((ep >= LastEV(sp)) \
? FirstEV(sp) \
: ep + 1)
#undef PREV
#define PREV(ep) ((ep <= FirstEV(sp)) \
? LastEV(sp) \
: ep - 1)
#define IndexEV(sp, ep) (ep - FirstEV(sp))
#define RunParams(sp, eventp, runp) \
(long) IndexEV(sp, runp), \
(long) (IndexEV(sp, eventp) + (EV_MAX - 1)) % EV_MAX
#ifdef TRACE
static void
_trace_slot(SCREEN *sp, const char *tag)
{
MEVENT *ep;
_tracef(tag);
for (ep = FirstEV(sp); ep <= LastEV(sp); ep++)
_tracef("mouse event queue slot %ld = %s",
(long) IndexEV(sp, ep),
_nc_tracemouse(sp, ep));
}
#endif
#if USE_EMX_MOUSE
# define TOP_ROW 0
# define LEFT_COL 0
# define M_FD(sp) sp->_mouse_fd
static void
write_event(SCREEN *sp, int down, int button, int x, int y)
{
char buf[6];
unsigned long ignore;
strncpy(buf, key_mouse, 3); /* should be "\033[M" */
buf[3] = ' ' + (button - 1) + (down ? 0 : 0x40);
buf[4] = ' ' + x - LEFT_COL + 1;
buf[5] = ' ' + y - TOP_ROW + 1;
DosWrite(sp->_emxmouse_wfd, buf, 6, &ignore);
}
static void
mouse_server(unsigned long param)
{
SCREEN *sp = (SCREEN *) param;
unsigned short fWait = MOU_WAIT;
/* NOPTRRECT mourt = { 0,0,24,79 }; */
MOUEVENTINFO mouev;
HMOU hmou;
unsigned short mask = MOUSE_BN1_DOWN | MOUSE_BN2_DOWN | MOUSE_BN3_DOWN;
int nbuttons = 3;
int oldstate = 0;
char err[80];
unsigned long rc;
/* open the handle for the mouse */
if (MouOpen(NULL, &hmou) == 0) {
rc = MouSetEventMask(&mask, hmou);
if (rc) { /* retry with 2 buttons */
mask = MOUSE_BN1_DOWN | MOUSE_BN2_DOWN;
rc = MouSetEventMask(&mask, hmou);
nbuttons = 2;
}
if (rc == 0 && MouDrawPtr(hmou) == 0) {
for (;;) {
/* sit and wait on the event queue */
rc = MouReadEventQue(&mouev, &fWait, hmou);
if (rc) {
sprintf(err, "Error reading mouse queue, rc=%lu.\r\n", rc);
break;
}
if (!sp->_emxmouse_activated)
goto finish;
/*
* OS/2 numbers a 3-button mouse inconsistently from other
* platforms:
* 1 = left
* 2 = right
* 3 = middle.
*/
if ((mouev.fs ^ oldstate) & MOUSE_BN1_DOWN)
write_event(sp, mouev.fs & MOUSE_BN1_DOWN,
sp->_emxmouse_buttons[1], mouev.col, mouev.row);
if ((mouev.fs ^ oldstate) & MOUSE_BN2_DOWN)
write_event(sp, mouev.fs & MOUSE_BN2_DOWN,
sp->_emxmouse_buttons[3], mouev.col, mouev.row);
if ((mouev.fs ^ oldstate) & MOUSE_BN3_DOWN)
write_event(sp, mouev.fs & MOUSE_BN3_DOWN,
sp->_emxmouse_buttons[2], mouev.col, mouev.row);
finish:
oldstate = mouev.fs;
}
} else
sprintf(err, "Error setting event mask, buttons=%d, rc=%lu.\r\n",
nbuttons, rc);
DosWrite(2, err, strlen(err), &rc);
MouClose(hmou);
}
DosExit(EXIT_THREAD, 0L);
}
#endif /* USE_EMX_MOUSE */
#if USE_SYSMOUSE
static void
sysmouse_server(SCREEN *sp)
{
struct mouse_info the_mouse;
MEVENT *work;
the_mouse.operation = MOUSE_GETINFO;
if (sp != 0
&& sp->_mouse_fd >= 0
&& sp->_sysmouse_tail < FIFO_SIZE
&& ioctl(sp->_mouse_fd, CONS_MOUSECTL, &the_mouse) != -1) {
if (sp->_sysmouse_head > sp->_sysmouse_tail) {
sp->_sysmouse_tail = 0;
sp->_sysmouse_head = 0;
}
work = &(sp->_sysmouse_fifo[sp->_sysmouse_tail]);
memset(work, 0, sizeof(*work));
work->id = NORMAL_EVENT; /* there's only one mouse... */
sp->_sysmouse_old_buttons = sp->_sysmouse_new_buttons;
sp->_sysmouse_new_buttons = the_mouse.u.data.buttons & 0x7;
if (sp->_sysmouse_new_buttons) {
if (sp->_sysmouse_new_buttons & 1)
work->bstate |= BUTTON1_PRESSED;
if (sp->_sysmouse_new_buttons & 2)
work->bstate |= BUTTON2_PRESSED;
if (sp->_sysmouse_new_buttons & 4)
work->bstate |= BUTTON3_PRESSED;
} else {
if (sp->_sysmouse_old_buttons & 1)
work->bstate |= BUTTON1_RELEASED;
if (sp->_sysmouse_old_buttons & 2)
work->bstate |= BUTTON2_RELEASED;
if (sp->_sysmouse_old_buttons & 4)
work->bstate |= BUTTON3_RELEASED;
}
/* for cosmetic bug in syscons.c on FreeBSD 3.[34] */
the_mouse.operation = MOUSE_HIDE;
ioctl(sp->_mouse_fd, CONS_MOUSECTL, &the_mouse);
the_mouse.operation = MOUSE_SHOW;
ioctl(sp->_mouse_fd, CONS_MOUSECTL, &the_mouse);
/*
* We're only interested if the button is pressed or released.
* FIXME: implement continuous event-tracking.
*/
if (sp->_sysmouse_new_buttons != sp->_sysmouse_old_buttons) {
sp->_sysmouse_tail += 1;
}
work->x = the_mouse.u.data.x / sp->_sysmouse_char_width;
work->y = the_mouse.u.data.y / sp->_sysmouse_char_height;
}
}
static void
handle_sysmouse(int sig GCC_UNUSED)
{
sysmouse_server(SP);
}
#endif /* USE_SYSMOUSE */
static void
init_xterm_mouse(SCREEN *sp)
{
sp->_mouse_type = M_XTERM;
sp->_mouse_xtermcap = tigetstr("XM");
if (!VALID_STRING(sp->_mouse_xtermcap))
sp->_mouse_xtermcap = "\033[?1000%?%p1%{1}%=%th%el%;";
}
static void
enable_xterm_mouse(SCREEN *sp, int enable)
{
#if USE_EMX_MOUSE
sp->_emxmouse_activated = enable;
#else
putp(TPARM_1(sp->_mouse_xtermcap, enable));
#endif
sp->_mouse_active = enable;
}
#if USE_GPM_SUPPORT
static bool
allow_gpm_mouse(void)
{
bool result = FALSE;
/* GPM does printf's without checking if stdout is a terminal */
if (isatty(fileno(stdout))) {
char *list = getenv("NCURSES_GPM_TERMS");
char *env = getenv("TERM");
if (list != 0) {
if (env != 0) {
result = _nc_name_match(list, env, "|:");
}
} else {
/* GPM checks the beginning of the $TERM variable to decide if it
* should pass xterm events through. There is no real advantage in
* allowing GPM to do this. Recent versions relax that check, and
* pretend that GPM can work with any terminal having the kmous
* capability. Perhaps that works for someone. If so, they can
* set the environment variable (above).
*/
if (env != 0 && strstr(env, "linux") != 0) {
result = TRUE;
}
}
}
return result;
}
#ifdef HAVE_LIBDL
static void
unload_gpm_library(SCREEN *sp)
{
if (SP->_dlopen_gpm != 0) {
T(("unload GPM library"));
sp->_mouse_gpm_loaded = FALSE;
sp->_mouse_fd = -1;
dlclose(sp->_dlopen_gpm);
sp->_dlopen_gpm = 0;
}
}
static void
load_gpm_library(SCREEN *sp)
{
sp->_mouse_gpm_found = FALSE;
if ((sp->_dlopen_gpm = dlopen(LIBGPM_SONAME, my_RTLD)) != 0) {
if (GET_DLSYM(gpm_fd) == 0 ||
GET_DLSYM(Gpm_Open) == 0 ||
GET_DLSYM(Gpm_Close) == 0 ||
GET_DLSYM(Gpm_GetEvent) == 0) {
T(("GPM initialization failed: %s", dlerror()));
unload_gpm_library(sp);
} else {
sp->_mouse_gpm_found = TRUE;
sp->_mouse_gpm_loaded = TRUE;
}
}
}
#endif
static bool
enable_gpm_mouse(SCREEN *sp, bool enable)
{
bool result;
T((T_CALLED("enable_gpm_mouse(%d)"), enable));
if (enable && !sp->_mouse_active) {
#ifdef HAVE_LIBDL
if (sp->_mouse_gpm_found && !sp->_mouse_gpm_loaded) {
load_gpm_library(sp);
}
#endif
if (sp->_mouse_gpm_loaded) {
/* GPM: initialize connection to gpm server */
sp->_mouse_gpm_connect.eventMask = GPM_DOWN | GPM_UP;
sp->_mouse_gpm_connect.defaultMask =
(unsigned short) (~(sp->_mouse_gpm_connect.eventMask | GPM_HARD));
sp->_mouse_gpm_connect.minMod = 0;
sp->_mouse_gpm_connect.maxMod =
(unsigned short) (~((1 << KG_SHIFT) |
(1 << KG_SHIFTL) |
(1 << KG_SHIFTR)));
/*
* Note: GPM hardcodes \E[?1001s and \E[?1000h during its open.
* The former is recognized by wscons (SunOS), and the latter by
* xterm. Those will not show up in ncurses' traces.
*/
result = (my_Gpm_Open(&sp->_mouse_gpm_connect, 0) >= 0);
} else {
result = FALSE;
}
sp->_mouse_active = result;
T(("GPM open %s", result ? "succeeded" : "failed"));
} else {
if (!enable && sp->_mouse_active) {
/* GPM: close connection to gpm server */
my_Gpm_Close();
sp->_mouse_active = FALSE;
T(("GPM closed"));
}
result = enable;
}
#ifdef HAVE_LIBDL
if (!result) {
unload_gpm_library(sp);
}
#endif
returnBool(result);
}
#endif /* USE_GPM_SUPPORT */
#define xterm_kmous "\033[M"
static void
initialize_mousetype(SCREEN *sp)
{
T((T_CALLED("initialize_mousetype()")));
/* Try gpm first, because gpm may be configured to run in xterm */
#if USE_GPM_SUPPORT
if (allow_gpm_mouse()) {
if (!sp->_mouse_gpm_loaded) {
#ifdef HAVE_LIBDL
load_gpm_library(sp);
#else /* !HAVE_LIBDL */
sp->_mouse_gpm_found = TRUE;
sp->_mouse_gpm_loaded = TRUE;
#endif
}
/*
* The gpm_fd file-descriptor may be negative (xterm). So we have to
* maintain our notion of whether the mouse connection is active
* without testing the file-descriptor.
*/
if (sp->_mouse_gpm_found && enable_gpm_mouse(sp, TRUE)) {
sp->_mouse_type = M_GPM;
sp->_mouse_fd = *(my_gpm_fd);
T(("GPM mouse_fd %d", sp->_mouse_fd));
returnVoid;
}
}
#endif /* USE_GPM_SUPPORT */
/* OS/2 VIO */
#if USE_EMX_MOUSE
if (!sp->_emxmouse_thread
&& strstr(cur_term->type.term_names, "xterm") == 0
&& key_mouse) {
int handles[2];
if (pipe(handles) < 0) {
perror("mouse pipe error");
returnVoid;
} else {
int rc;
if (!sp->_emxmouse_buttons[0]) {
char *s = getenv("MOUSE_BUTTONS_123");
sp->_emxmouse_buttons[0] = 1;
if (s && strlen(s) >= 3) {
sp->_emxmouse_buttons[1] = s[0] - '0';
sp->_emxmouse_buttons[2] = s[1] - '0';
sp->_emxmouse_buttons[3] = s[2] - '0';
} else {
sp->_emxmouse_buttons[1] = 1;
sp->_emxmouse_buttons[2] = 3;
sp->_emxmouse_buttons[3] = 2;
}
}
sp->_emxmouse_wfd = handles[1];
M_FD(sp) = handles[0];
/* Needed? */
setmode(handles[0], O_BINARY);
setmode(handles[1], O_BINARY);
/* Do not use CRT functions, we may single-threaded. */
rc = DosCreateThread((unsigned long *) &sp->_emxmouse_thread,
mouse_server, (long) sp, 0, 8192);
if (rc) {
printf("mouse thread error %d=%#x", rc, rc);
} else {
sp->_mouse_type = M_XTERM;
}
returnVoid;
}
}
#endif /* USE_EMX_MOUSE */
#if USE_SYSMOUSE
{
struct mouse_info the_mouse;
char *the_device = 0;
if (isatty(sp->_ifd))
the_device = ttyname(sp->_ifd);
if (the_device == 0)
the_device = "/dev/tty";
sp->_mouse_fd = open(the_device, O_RDWR);
if (sp->_mouse_fd >= 0) {
/*
* sysmouse does not have a usable user interface for obtaining
* mouse events. The logical way to proceed (reading data on a
* stream) only works if one opens the device as root. Even in
* that mode, careful examination shows we lose events
* occasionally. The interface provided for user programs is to
* establish a signal handler. really.
*
* Take over SIGUSR2 for this purpose since SIGUSR1 is more
* likely to be used by an application. getch() will have to
* handle the misleading EINTR's.
*/
signal(SIGUSR2, SIG_IGN);
the_mouse.operation = MOUSE_MODE;
the_mouse.u.mode.mode = 0;
the_mouse.u.mode.signal = SIGUSR2;
if (ioctl(sp->_mouse_fd, CONS_MOUSECTL, &the_mouse) != -1) {
signal(SIGUSR2, handle_sysmouse);
the_mouse.operation = MOUSE_SHOW;
ioctl(sp->_mouse_fd, CONS_MOUSECTL, &the_mouse);
#if defined(FBIO_MODEINFO) || defined(CONS_MODEINFO) /* FreeBSD > 2.x */
{
#ifndef FBIO_GETMODE /* FreeBSD 3.x */
#define FBIO_GETMODE CONS_GET
#define FBIO_MODEINFO CONS_MODEINFO
#endif /* FBIO_GETMODE */
video_info_t the_video;
if (ioctl(sp->_mouse_fd,
FBIO_GETMODE,
&the_video.vi_mode) != -1
&& ioctl(sp->_mouse_fd,
FBIO_MODEINFO,
&the_video) != -1) {
sp->_sysmouse_char_width = the_video.vi_cwidth;
sp->_sysmouse_char_height = the_video.vi_cheight;
}
}
#endif /* defined(FBIO_MODEINFO) || defined(CONS_MODEINFO) */
if (sp->_sysmouse_char_width <= 0)
sp->_sysmouse_char_width = 8;
if (sp->_sysmouse_char_height <= 0)
sp->_sysmouse_char_height = 16;
sp->_mouse_type = M_SYSMOUSE;
returnVoid;
}
}
}
#endif /* USE_SYSMOUSE */
/* we know how to recognize mouse events under "xterm" */
if (key_mouse != 0) {
if (!strcmp(key_mouse, xterm_kmous)
|| strstr(cur_term->type.term_names, "xterm") != 0) {
init_xterm_mouse(sp);
}
} else if (strstr(cur_term->type.term_names, "xterm") != 0) {
if (_nc_add_to_try(&(sp->_keytry), xterm_kmous, KEY_MOUSE) == OK)
init_xterm_mouse(sp);
}
returnVoid;
}
static bool
_nc_mouse_init(SCREEN *sp)
/* initialize the mouse */
{
bool result = FALSE;
int i;
if (sp != 0) {
if (!sp->_mouse_initialized) {
sp->_mouse_initialized = TRUE;
TR(MY_TRACE, ("_nc_mouse_init() called"));
sp->_mouse_eventp = FirstEV(sp);
for (i = 0; i < EV_MAX; i++)
sp->_mouse_events[i].id = INVALID_EVENT;
initialize_mousetype(sp);
T(("_nc_mouse_init() set mousetype to %d", sp->_mouse_type));
}
result = sp->_mouse_initialized;
}
return result;
}
/*
* Query to see if there is a pending mouse event. This is called from
* fifo_push() in lib_getch.c
*/
static bool
_nc_mouse_event(SCREEN *sp GCC_UNUSED)
{
MEVENT *eventp = sp->_mouse_eventp;
bool result = FALSE;
(void) eventp;
switch (sp->_mouse_type) {
case M_XTERM:
/* xterm: never have to query, mouse events are in the keyboard stream */
#if USE_EMX_MOUSE
{
char kbuf[3];
int i, res = read(M_FD(sp), &kbuf, 3); /* Eat the prefix */
if (res != 3)
printf("Got %d chars instead of 3 for prefix.\n", res);
for (i = 0; i < res; i++) {
if (kbuf[i] != key_mouse[i])
printf("Got char %d instead of %d for prefix.\n",
(int) kbuf[i], (int) key_mouse[i]);
}
result = TRUE;
}
#endif /* USE_EMX_MOUSE */
break;
#if USE_GPM_SUPPORT
case M_GPM:
{
/* query server for event, return TRUE if we find one */
Gpm_Event ev;
if (my_Gpm_GetEvent(&ev) == 1) {
/* there's only one mouse... */
eventp->id = NORMAL_EVENT;
eventp->bstate = 0;
switch (ev.type & 0x0f) {
case (GPM_DOWN):
if (ev.buttons & GPM_B_LEFT)
eventp->bstate |= BUTTON1_PRESSED;
if (ev.buttons & GPM_B_MIDDLE)
eventp->bstate |= BUTTON2_PRESSED;
if (ev.buttons & GPM_B_RIGHT)
eventp->bstate |= BUTTON3_PRESSED;
break;
case (GPM_UP):
if (ev.buttons & GPM_B_LEFT)
eventp->bstate |= BUTTON1_RELEASED;
if (ev.buttons & GPM_B_MIDDLE)
eventp->bstate |= BUTTON2_RELEASED;
if (ev.buttons & GPM_B_RIGHT)
eventp->bstate |= BUTTON3_RELEASED;
break;
default:
break;
}
eventp->x = ev.x - 1;
eventp->y = ev.y - 1;
eventp->z = 0;
/* bump the next-free pointer into the circular list */
sp->_mouse_eventp = eventp = NEXT(eventp);
result = TRUE;
}
}
break;
#endif
#if USE_SYSMOUSE
case M_SYSMOUSE:
if (sp->_sysmouse_head < sp->_sysmouse_tail) {
*eventp = sp->_sysmouse_fifo[sp->_sysmouse_head];
/*
* Point the fifo-head to the next possible location. If there
* are none, reset the indices. This may be interrupted by the
* signal handler, doing essentially the same reset.
*/
sp->_sysmouse_head += 1;
if (sp->_sysmouse_head == sp->_sysmouse_tail) {
sp->_sysmouse_tail = 0;
sp->_sysmouse_head = 0;
}
/* bump the next-free pointer into the circular list */
sp->_mouse_eventp = eventp = NEXT(eventp);
result = TRUE;
}
break;
#endif /* USE_SYSMOUSE */
case M_NONE:
break;
}
return result; /* true if we found an event */
}
static bool
_nc_mouse_inline(SCREEN *sp)
/* mouse report received in the keyboard stream -- parse its info */
{
int b;
bool result = FALSE;
MEVENT *eventp = sp->_mouse_eventp;
TR(MY_TRACE, ("_nc_mouse_inline() called"));
if (sp->_mouse_type == M_XTERM) {
unsigned char kbuf[4];
mmask_t prev;
size_t grabbed;
int res;
/* This code requires that your xterm entry contain the kmous
* capability and that it be set to the \E[M documented in the
* Xterm Control Sequences reference. This is how we
* arrange for mouse events to be reported via a KEY_MOUSE
* return value from wgetch(). After this value is received,
* _nc_mouse_inline() gets called and is immediately
* responsible for parsing the mouse status information
* following the prefix.
*
* The following quotes from the ctrlseqs.ms document in the
* X distribution, describing the X mouse tracking feature:
*
* Parameters for all mouse tracking escape sequences
* generated by xterm encode numeric parameters in a single
* character as value+040. For example, ! is 1.
*
* On button press or release, xterm sends ESC [ M CbCxCy.
* The low two bits of Cb encode button information: 0=MB1
* pressed, 1=MB2 pressed, 2=MB3 pressed, 3=release. The
* upper bits encode what modifiers were down when the
* button was pressed and are added together. 4=Shift,
* 8=Meta, 16=Control. Cx and Cy are the x and y coordinates
* of the mouse event. The upper left corner is (1,1).
*
* (End quote) By the time we get here, we've eaten the
* key prefix. FYI, the loop below is necessary because
* mouse click info isn't guaranteed to present as a
* single clist item.
*
* Wheel mice may return buttons 4 and 5 when the wheel is turned.
* We encode those as button presses.
*/
for (grabbed = 0; grabbed < 3; grabbed += (size_t) res) {
/* For VIO mouse we add extra bit 64 to disambiguate button-up. */
#if USE_EMX_MOUSE
res = read(M_FD(sp) >= 0 ? M_FD(sp) : sp->_ifd, &kbuf, 3);
#else
res = read(sp->_ifd, kbuf + grabbed, 3 - grabbed);
#endif
if (res == -1)
break;
}
kbuf[3] = '\0';
TR(TRACE_IEVENT,
("_nc_mouse_inline sees the following xterm data: '%s'", kbuf));
/* there's only one mouse... */
eventp->id = NORMAL_EVENT;
/* processing code goes here */
eventp->bstate = 0;
prev = PREV(eventp)->bstate;
#if USE_EMX_MOUSE
#define PRESS_POSITION(n) \
eventp->bstate = MASK_PRESS(n); \
if (kbuf[0] & 0x40) \
eventp->bstate = MASK_RELEASE(n)
#else
#define PRESS_POSITION(n) \
eventp->bstate = (mmask_t) (prev & MASK_PRESS(n) \
? REPORT_MOUSE_POSITION \
: MASK_PRESS(n))
#endif
switch (kbuf[0] & 0x3) {
case 0x0:
if (kbuf[0] & 64)
eventp->bstate = MASK_PRESS(4);
else
PRESS_POSITION(1);
break;
case 0x1:
#if NCURSES_MOUSE_VERSION == 2
if (kbuf[0] & 64)
eventp->bstate = MASK_PRESS(5);
else
#endif
PRESS_POSITION(2);
break;
case 0x2:
PRESS_POSITION(3);
break;
case 0x3:
/*
* Release events aren't reported for individual buttons, just for
* the button set as a whole. However, because there are normally
* no mouse events under xterm that intervene between press and
* release, we can infer the button actually released by looking at
* the previous event.
*/
if (prev & (BUTTON_PRESSED | BUTTON_RELEASED)) {
eventp->bstate = BUTTON_RELEASED;
for (b = 1; b <= MAX_BUTTONS; ++b) {
if (!(prev & MASK_PRESS(b)))
eventp->bstate &= ~MASK_RELEASE(b);
}
} else {
/*
* XFree86 xterm will return a stream of release-events to
* let the application know where the mouse is going, if the
* private mode 1002 or 1003 is enabled.
*/
eventp->bstate = REPORT_MOUSE_POSITION;
}
break;
}
result = (eventp->bstate & REPORT_MOUSE_POSITION) ? TRUE : FALSE;
if (kbuf[0] & 4) {
eventp->bstate |= BUTTON_SHIFT;
}
if (kbuf[0] & 8) {
eventp->bstate |= BUTTON_ALT;
}
if (kbuf[0] & 16) {
eventp->bstate |= BUTTON_CTRL;
}
eventp->x = (kbuf[1] - ' ') - 1;
eventp->y = (kbuf[2] - ' ') - 1;
TR(MY_TRACE,
("_nc_mouse_inline: primitive mouse-event %s has slot %ld",
_nc_tracemouse(sp, eventp),
(long) IndexEV(sp, eventp)));
/* bump the next-free pointer into the circular list */
sp->_mouse_eventp = NEXT(eventp);
#if 0 /* this return would be needed for QNX's mods to lib_getch.c */
return (TRUE);
#endif
}
return (result);
}
static void
mouse_activate(SCREEN *sp, bool on)
{
if (!on && !sp->_mouse_initialized)
return;
if (!_nc_mouse_init(sp))
return;
if (on) {
switch (sp->_mouse_type) {
case M_XTERM:
#if NCURSES_EXT_FUNCS
keyok(KEY_MOUSE, on);
#endif
TPUTS_TRACE("xterm mouse initialization");
enable_xterm_mouse(sp, 1);
break;
#if USE_GPM_SUPPORT
case M_GPM:
if (enable_gpm_mouse(sp, TRUE)) {
sp->_mouse_fd = *(my_gpm_fd);
T(("GPM mouse_fd %d", sp->_mouse_fd));
}
break;
#endif
#if USE_SYSMOUSE
case M_SYSMOUSE:
signal(SIGUSR2, handle_sysmouse);
sp->_mouse_active = TRUE;
break;
#endif
case M_NONE:
return;
}
/* Make runtime binding to cut down on object size of applications that
* do not use the mouse (e.g., 'clear').
*/
sp->_mouse_event = _nc_mouse_event;
sp->_mouse_inline = _nc_mouse_inline;
sp->_mouse_parse = _nc_mouse_parse;
sp->_mouse_resume = _nc_mouse_resume;
sp->_mouse_wrap = _nc_mouse_wrap;
} else {
switch (sp->_mouse_type) {
case M_XTERM:
TPUTS_TRACE("xterm mouse deinitialization");
enable_xterm_mouse(sp, 0);
break;
#if USE_GPM_SUPPORT
case M_GPM:
enable_gpm_mouse(sp, FALSE);
break;
#endif
#if USE_SYSMOUSE
case M_SYSMOUSE:
signal(SIGUSR2, SIG_IGN);
sp->_mouse_active = FALSE;
break;
#endif
case M_NONE:
return;
}
}
_nc_flush();
}
/**************************************************************************
*
* Device-independent code
*
**************************************************************************/
static bool
_nc_mouse_parse(SCREEN *sp, int runcount)
/* parse a run of atomic mouse events into a gesture */
{
MEVENT *eventp = sp->_mouse_eventp;
MEVENT *ep, *runp, *next, *prev = PREV(eventp);
int n;
int b;
bool merge;
TR(MY_TRACE, ("_nc_mouse_parse(%d) called", runcount));
/*
* When we enter this routine, the event list next-free pointer
* points just past a run of mouse events that we know were separated
* in time by less than the critical click interval. The job of this
* routine is to collapse this run into a single higher-level event
* or gesture.
*
* We accomplish this in two passes. The first pass merges press/release
* pairs into click events. The second merges runs of click events into
* double or triple-click events.
*
* It's possible that the run may not resolve to a single event (for
* example, if the user quadruple-clicks). If so, leading events
* in the run are ignored.
*
* Note that this routine is independent of the format of the specific
* format of the pointing-device's reports. We can use it to parse
* gestures on anything that reports press/release events on a per-
* button basis, as long as the device-dependent mouse code puts stuff
* on the queue in MEVENT format.
*/
if (runcount == 1) {
TR(MY_TRACE,
("_nc_mouse_parse: returning simple mouse event %s at slot %ld",
_nc_tracemouse(sp, prev),
(long) IndexEV(sp, prev)));
return (prev->id >= NORMAL_EVENT)
? ((prev->bstate & sp->_mouse_mask) ? TRUE : FALSE)
: FALSE;
}
/* find the start of the run */
runp = eventp;
for (n = runcount; n > 0; n--) {
runp = PREV(runp);
}
#ifdef TRACE
if (USE_TRACEF(TRACE_IEVENT)) {
_trace_slot(sp, "before mouse press/release merge:");
_tracef("_nc_mouse_parse: run starts at %ld, ends at %ld, count %d",
RunParams(sp, eventp, runp),
runcount);
_nc_unlock_global(tracef);
}
#endif /* TRACE */
/* first pass; merge press/release pairs */
do {
merge = FALSE;
for (ep = runp; (next = NEXT(ep)) != eventp; ep = next) {
#define MASK_CHANGED(x) (!(ep->bstate & MASK_PRESS(x)) \
== !(next->bstate & MASK_RELEASE(x)))
if (ep->x == next->x && ep->y == next->y
&& (ep->bstate & BUTTON_PRESSED)
&& MASK_CHANGED(1)
&& MASK_CHANGED(2)
&& MASK_CHANGED(3)
&& MASK_CHANGED(4)
#if NCURSES_MOUSE_VERSION == 2
&& MASK_CHANGED(5)
#endif
) {
for (b = 1; b <= MAX_BUTTONS; ++b) {
if ((sp->_mouse_mask & MASK_CLICK(b))
&& (ep->bstate & MASK_PRESS(b))) {
ep->bstate &= ~MASK_PRESS(b);
ep->bstate |= MASK_CLICK(b);
merge = TRUE;
}
}
if (merge)
next->id = INVALID_EVENT;
}
}
} while
(merge);
#ifdef TRACE
if (USE_TRACEF(TRACE_IEVENT)) {
_trace_slot(sp, "before mouse click merge:");
_tracef("_nc_mouse_parse: run starts at %ld, ends at %ld, count %d",
RunParams(sp, eventp, runp),
runcount);
_nc_unlock_global(tracef);
}
#endif /* TRACE */
/*
* Second pass; merge click runs. At this point, click events are
* each followed by one invalid event. We merge click events
* forward in the queue.
*
* NOTE: There is a problem with this design! If the application
* allows enough click events to pile up in the circular queue so
* they wrap around, it will cheerfully merge the newest forward
* into the oldest, creating a bogus doubleclick and confusing
* the queue-traversal logic rather badly. Generally this won't
* happen, because calling getmouse() marks old events invalid and
* ineligible for merges. The true solution to this problem would
* be to timestamp each MEVENT and perform the obvious sanity check,
* but the timer element would have to have sub-second resolution,
* which would get us into portability trouble.
*/
do {
MEVENT *follower;
merge = FALSE;
for (ep = runp; (next = NEXT(ep)) != eventp; ep = next)
if (ep->id != INVALID_EVENT) {
if (next->id != INVALID_EVENT)
continue;
follower = NEXT(next);
if (follower->id == INVALID_EVENT)
continue;
/* merge click events forward */
if ((ep->bstate & BUTTON_CLICKED)
&& (follower->bstate & BUTTON_CLICKED)) {
for (b = 1; b <= MAX_BUTTONS; ++b) {
if ((sp->_mouse_mask & MASK_DOUBLE_CLICK(b))
&& (follower->bstate & MASK_CLICK(b))) {
follower->bstate &= ~MASK_CLICK(b);
follower->bstate |= MASK_DOUBLE_CLICK(b);
merge = TRUE;
}
}
if (merge)
ep->id = INVALID_EVENT;
}
/* merge double-click events forward */
if ((ep->bstate & BUTTON_DOUBLE_CLICKED)
&& (follower->bstate & BUTTON_CLICKED)) {
for (b = 1; b <= MAX_BUTTONS; ++b) {
if ((sp->_mouse_mask & MASK_TRIPLE_CLICK(b))
&& (follower->bstate & MASK_CLICK(b))) {
follower->bstate &= ~MASK_CLICK(b);
follower->bstate |= MASK_TRIPLE_CLICK(b);
merge = TRUE;
}
}
if (merge)
ep->id = INVALID_EVENT;
}
}
} while
(merge);
#ifdef TRACE
if (USE_TRACEF(TRACE_IEVENT)) {
_trace_slot(sp, "before mouse event queue compaction:");
_tracef("_nc_mouse_parse: run starts at %ld, ends at %ld, count %d",
RunParams(sp, eventp, runp),
runcount);
_nc_unlock_global(tracef);
}
#endif /* TRACE */
/*
* Now try to throw away trailing events flagged invalid, or that
* don't match the current event mask.
*/
for (; runcount; prev = PREV(eventp), runcount--)
if (prev->id == INVALID_EVENT || !(prev->bstate & sp->_mouse_mask)) {
sp->_mouse_eventp = eventp = prev;
}
#ifdef TRACE
if (USE_TRACEF(TRACE_IEVENT)) {
_trace_slot(sp, "after mouse event queue compaction:");
_tracef("_nc_mouse_parse: run starts at %ld, ends at %ld, count %d",
RunParams(sp, eventp, runp),
runcount);
_nc_unlock_global(tracef);
}
for (ep = runp; ep != eventp; ep = NEXT(ep))
if (ep->id != INVALID_EVENT)
TR(MY_TRACE,
("_nc_mouse_parse: returning composite mouse event %s at slot %ld",
_nc_tracemouse(sp, ep),
(long) IndexEV(sp, ep)));
#endif /* TRACE */
/* after all this, do we have a valid event? */
return (PREV(eventp)->id != INVALID_EVENT);
}
static void
_nc_mouse_wrap(SCREEN *sp)
/* release mouse -- called by endwin() before shellout/exit */
{
TR(MY_TRACE, ("_nc_mouse_wrap() called"));
switch (sp->_mouse_type) {
case M_XTERM:
if (sp->_mouse_mask)
mouse_activate(sp, FALSE);
break;
#if USE_GPM_SUPPORT
/* GPM: pass all mouse events to next client */
case M_GPM:
if (sp->_mouse_mask)
mouse_activate(sp, FALSE);
break;
#endif
#if USE_SYSMOUSE
case M_SYSMOUSE:
mouse_activate(sp, FALSE);
break;
#endif
case M_NONE:
break;
}
}
static void
_nc_mouse_resume(SCREEN *sp)
/* re-connect to mouse -- called by doupdate() after shellout */
{
TR(MY_TRACE, ("_nc_mouse_resume() called"));
switch (sp->_mouse_type) {
case M_XTERM:
/* xterm: re-enable reporting */
if (sp->_mouse_mask)
mouse_activate(sp, TRUE);
break;
#if USE_GPM_SUPPORT
case M_GPM:
/* GPM: reclaim our event set */
if (sp->_mouse_mask)
mouse_activate(sp, TRUE);
break;
#endif
#if USE_SYSMOUSE
case M_SYSMOUSE:
mouse_activate(sp, TRUE);
break;
#endif
case M_NONE:
break;
}
}
/**************************************************************************
*
* Mouse interface entry points for the API
*
**************************************************************************/
static int
_nc_getmouse(SCREEN *sp, MEVENT * aevent)
{
T((T_CALLED("getmouse(%p)"), aevent));
if ((aevent != 0) && (sp != 0) && (sp->_mouse_type != M_NONE)) {
MEVENT *eventp = sp->_mouse_eventp;
/* compute the current-event pointer */
MEVENT *prev = PREV(eventp);
/* copy the event we find there */
*aevent = *prev;
TR(TRACE_IEVENT, ("getmouse: returning event %s from slot %ld",
_nc_tracemouse(sp, prev),
(long) IndexEV(sp, prev)));
prev->id = INVALID_EVENT; /* so the queue slot becomes free */
returnCode(OK);
}
returnCode(ERR);
}
/* grab a copy of the current mouse event */
NCURSES_EXPORT(int)
getmouse(MEVENT * aevent)
{
return _nc_getmouse(SP, aevent);
}
static int
_nc_ungetmouse(SCREEN *sp, MEVENT * aevent)
{
int result = ERR;
T((T_CALLED("ungetmouse(%p)"), aevent));
if (aevent != 0 && sp != 0) {
MEVENT *eventp = sp->_mouse_eventp;
/* stick the given event in the next-free slot */
*eventp = *aevent;
/* bump the next-free pointer into the circular list */
sp->_mouse_eventp = NEXT(eventp);
/* push back the notification event on the keyboard queue */
result = _nc_ungetch(sp, KEY_MOUSE);
}
returnCode(result);
}
/* enqueue a synthesized mouse event to be seen by the next wgetch() */
NCURSES_EXPORT(int)
ungetmouse(MEVENT * aevent)
{
return _nc_ungetmouse(SP, aevent);
}
NCURSES_EXPORT(mmask_t)
mousemask(mmask_t newmask, mmask_t * oldmask)
/* set the mouse event mask */
{
mmask_t result = 0;
T((T_CALLED("mousemask(%#lx,%p)"), (unsigned long) newmask, oldmask));
if (SP != 0) {
if (oldmask)
*oldmask = SP->_mouse_mask;
if (newmask || SP->_mouse_initialized) {
_nc_mouse_init(SP);
if (SP->_mouse_type != M_NONE) {
result = newmask &
(REPORT_MOUSE_POSITION
| BUTTON_ALT
| BUTTON_CTRL
| BUTTON_SHIFT
| BUTTON_PRESSED
| BUTTON_RELEASED
| BUTTON_CLICKED
| BUTTON_DOUBLE_CLICKED
| BUTTON_TRIPLE_CLICKED);
mouse_activate(SP, (bool) (result != 0));
SP->_mouse_mask = result;
}
}
}
returnBits(result);
}
NCURSES_EXPORT(bool)
wenclose(const WINDOW *win, int y, int x)
/* check to see if given window encloses given screen location */
{
bool result = FALSE;
T((T_CALLED("wenclose(%p,%d,%d)"), win, y, x));
if (win != 0) {
y -= win->_yoffset;
result = ((win->_begy <= y &&
win->_begx <= x &&
(win->_begx + win->_maxx) >= x &&
(win->_begy + win->_maxy) >= y) ? TRUE : FALSE);
}
returnBool(result);
}
NCURSES_EXPORT(int)
mouseinterval(int maxclick)
/* set the maximum mouse interval within which to recognize a click */
{
int oldval;
T((T_CALLED("mouseinterval(%d)"), maxclick));
if (SP != 0) {
oldval = SP->_maxclick;
if (maxclick >= 0)
SP->_maxclick = maxclick;
} else {
oldval = DEFAULT_MAXCLICK;
}
returnCode(oldval);
}
/* This may be used by other routines to ask for the existence of mouse
support */
NCURSES_EXPORT(int)
_nc_has_mouse(void)
{
return (SP->_mouse_type == M_NONE ? 0 : 1);
}
NCURSES_EXPORT(bool)
wmouse_trafo(const WINDOW *win, int *pY, int *pX, bool to_screen)
{
bool result = FALSE;
T((T_CALLED("wmouse_trafo(%p,%p,%p,%d)"), win, pY, pX, to_screen));
if (win && pY && pX) {
int y = *pY;
int x = *pX;
if (to_screen) {
y += win->_begy + win->_yoffset;
x += win->_begx;
if (wenclose(win, y, x))
result = TRUE;
} else {
if (wenclose(win, y, x)) {
y -= (win->_begy + win->_yoffset);
x -= win->_begx;
result = TRUE;
}
}
if (result) {
*pX = x;
*pY = y;
}
}
returnBool(result);
}