termo/termo.c

1860 lines
41 KiB
C

#include "termo.h"
#include "termo-internal.h"
#include <ctype.h>
#include <errno.h>
#include <poll.h>
#include <unistd.h>
#include <string.h>
#include <strings.h>
#include <langinfo.h>
#include <stdio.h>
void
termo_check_version (int major, int minor)
{
if (major != TERMO_VERSION_MAJOR)
fprintf (stderr, "libtermo major version mismatch;"
" %d (wants) != %d (library)\n",
major, TERMO_VERSION_MAJOR);
else if (minor > TERMO_VERSION_MINOR)
fprintf (stderr, "libtermo minor version mismatch;"
" %d (wants) > %d (library)\n",
minor, TERMO_VERSION_MINOR);
else
return;
exit (1);
}
static termo_driver_t *drivers[] =
{
&termo_driver_ti,
&termo_driver_csi,
NULL,
};
// Forwards for the "protected" methods
static void emit_codepoint (termo_t *tk, uint32_t codepoint, termo_key_t *key);
static termo_result_t peekkey_simple (termo_t *tk,
termo_key_t *key, int flags, size_t *nbytes);
static termo_result_t peekkey_mouse (termo_t *tk,
termo_key_t *key, size_t *nbytes);
static termo_sym_t register_c0 (termo_t *tk, termo_sym_t sym,
unsigned char ctrl, const char *name);
static termo_sym_t register_c0_full (termo_t *tk, termo_sym_t sym,
int modifier_set, int modifier_mask, unsigned char ctrl, const char *name);
static struct
{
termo_sym_t sym;
const char *name;
}
keynames[] =
{
{ TERMO_SYM_NONE, "NONE" },
{ TERMO_SYM_BACKSPACE, "Backspace" },
{ TERMO_SYM_TAB, "Tab" },
{ TERMO_SYM_ENTER, "Enter" },
{ TERMO_SYM_ESCAPE, "Escape" },
{ TERMO_SYM_SPACE, "Space" },
{ TERMO_SYM_DEL, "DEL" },
{ TERMO_SYM_UP, "Up" },
{ TERMO_SYM_DOWN, "Down" },
{ TERMO_SYM_LEFT, "Left" },
{ TERMO_SYM_RIGHT, "Right" },
{ TERMO_SYM_BEGIN, "Begin" },
{ TERMO_SYM_FIND, "Find" },
{ TERMO_SYM_INSERT, "Insert" },
{ TERMO_SYM_DELETE, "Delete" },
{ TERMO_SYM_SELECT, "Select" },
{ TERMO_SYM_PAGEUP, "PageUp" },
{ TERMO_SYM_PAGEDOWN, "PageDown" },
{ TERMO_SYM_HOME, "Home" },
{ TERMO_SYM_END, "End" },
{ TERMO_SYM_CANCEL, "Cancel" },
{ TERMO_SYM_CLEAR, "Clear" },
{ TERMO_SYM_CLOSE, "Close" },
{ TERMO_SYM_COMMAND, "Command" },
{ TERMO_SYM_COPY, "Copy" },
{ TERMO_SYM_EXIT, "Exit" },
{ TERMO_SYM_HELP, "Help" },
{ TERMO_SYM_MARK, "Mark" },
{ TERMO_SYM_MESSAGE, "Message" },
{ TERMO_SYM_MOVE, "Move" },
{ TERMO_SYM_OPEN, "Open" },
{ TERMO_SYM_OPTIONS, "Options" },
{ TERMO_SYM_PRINT, "Print" },
{ TERMO_SYM_REDO, "Redo" },
{ TERMO_SYM_REFERENCE, "Reference" },
{ TERMO_SYM_REFRESH, "Refresh" },
{ TERMO_SYM_REPLACE, "Replace" },
{ TERMO_SYM_RESTART, "Restart" },
{ TERMO_SYM_RESUME, "Resume" },
{ TERMO_SYM_SAVE, "Save" },
{ TERMO_SYM_SUSPEND, "Suspend" },
{ TERMO_SYM_UNDO, "Undo" },
{ TERMO_SYM_KP0, "KP0" },
{ TERMO_SYM_KP1, "KP1" },
{ TERMO_SYM_KP2, "KP2" },
{ TERMO_SYM_KP3, "KP3" },
{ TERMO_SYM_KP4, "KP4" },
{ TERMO_SYM_KP5, "KP5" },
{ TERMO_SYM_KP6, "KP6" },
{ TERMO_SYM_KP7, "KP7" },
{ TERMO_SYM_KP8, "KP8" },
{ TERMO_SYM_KP9, "KP9" },
{ TERMO_SYM_KPENTER, "KPEnter" },
{ TERMO_SYM_KPPLUS, "KPPlus" },
{ TERMO_SYM_KPMINUS, "KPMinus" },
{ TERMO_SYM_KPMULT, "KPMult" },
{ TERMO_SYM_KPDIV, "KPDiv" },
{ TERMO_SYM_KPCOMMA, "KPComma" },
{ TERMO_SYM_KPPERIOD, "KPPeriod" },
{ TERMO_SYM_KPEQUALS, "KPEquals" },
{ 0, NULL },
};
#define CHARAT(i) (tk->buffer[tk->buffstart + (i)])
#ifdef DEBUG
// Some internal deubgging functions
static void
print_buffer (termo_t *tk)
{
size_t i;
for (i = 0; i < tk->buffcount && i < 20; i++)
fprintf (stderr, "%02x ", CHARAT (i));
if (tk->buffcount > 20)
fprintf (stderr, "...");
}
static void
print_key (termo_t *tk, termo_key_t *key)
{
switch (key->type)
{
case TERMO_TYPE_KEY:
fprintf (stderr, "Unicode codepoint=U+%04lx multibyte='%s'",
(long) key->code.codepoint, key->multibyte);
break;
case TERMO_TYPE_FUNCTION:
fprintf (stderr, "Function F%d", key->code.number);
break;
case TERMO_TYPE_KEYSYM:
fprintf (stderr, "Keysym sym=%d(%s)",
key->code.sym, termo_get_keyname (tk, key->code.sym));
break;
case TERMO_TYPE_MOUSE:
{
termo_mouse_event_t ev;
int button, line, col;
termo_interpret_mouse (tk, key, &ev, &button, &line, &col);
fprintf (stderr, "Mouse ev=%d button=%d pos=(%d,%d)\n",
ev, button, line, col);
break;
}
case TERMO_TYPE_FOCUS:
fprintf (stderr, "%s\n", key->code.focused ? "Focused" : "Defocused");
break;
case TERMO_TYPE_POSITION:
{
int line, col;
termo_interpret_position (tk, key, &line, &col);
fprintf (stderr, "Position report pos=(%d,%d)\n", line, col);
break;
}
case TERMO_TYPE_MODEREPORT:
{
int initial, mode, value;
termo_interpret_modereport (tk, key, &initial, &mode, &value);
fprintf (stderr, "Mode report mode=%s %d val=%d\n",
initial == '?' ? "DEC" : "ANSI", mode, value);
break;
}
case TERMO_TYPE_UNKNOWN_CSI:
fprintf (stderr, "unknown CSI\n");
}
int m = key->modifiers;
fprintf (stderr, " mod=%s%s%s+%02x",
(m & TERMO_KEYMOD_CTRL ? "C" : ""),
(m & TERMO_KEYMOD_ALT ? "A" : ""),
(m & TERMO_KEYMOD_SHIFT ? "S" : ""),
m & ~(TERMO_KEYMOD_CTRL | TERMO_KEYMOD_ALT | TERMO_KEYMOD_SHIFT));
}
static const char *
res2str (termo_result_t res)
{
static char errorbuffer[256];
switch (res)
{
case TERMO_RES_KEY:
return "TERMO_RES_KEY";
case TERMO_RES_EOF:
return "TERMO_RES_EOF";
case TERMO_RES_AGAIN:
return "TERMO_RES_AGAIN";
case TERMO_RES_NONE:
return "TERMO_RES_NONE";
case TERMO_RES_ERROR:
snprintf (errorbuffer, sizeof errorbuffer,
"TERMO_RES_ERROR(errno=%d)\n", errno);
return (const char*) errorbuffer;
}
return "unknown";
}
#endif
// Similar to snprintf(str, size, "%s", src) except it turns CamelCase into
// space separated values
static int
snprint_cameltospaces (char *str, size_t size, const char *src)
{
int prev_lower = 0;
size_t l = 0;
while (*src && l < size - 1)
{
if (isupper (*src) && prev_lower)
{
if (str)
str[l++] = ' ';
if (l >= size - 1)
break;
}
prev_lower = islower (*src);
str[l++] = tolower (*src++);
}
str[l] = 0;
// For consistency with snprintf, return the number of bytes that would
// have been written, excluding '\0'
for (; *src; src++)
{
if (isupper (*src) && prev_lower)
l++;
prev_lower = islower (*src);
l++;
}
return l;
}
// Similar to strcmp(str, strcamel, n) except that:
// it compares CamelCase in strcamel with space separated values in str;
// it takes char**s and updates them
// n counts bytes of strcamel, not str
static int
strpncmp_camel (const char **strp, const char **strcamelp, size_t n)
{
const char *str = *strp, *strcamel = *strcamelp;
int prev_lower = 0;
for (; (*str || *strcamel) && n; n--)
{
char b = tolower (*strcamel);
if (isupper (*strcamel) && prev_lower)
{
if (*str != ' ')
break;
str++;
if (*str != b)
break;
}
else if (*str != b)
break;
prev_lower = islower (*strcamel);
str++;
strcamel++;
}
*strp = str;
*strcamelp = strcamel;
return *str - *strcamel;
}
static termo_t *
termo_alloc (void)
{
termo_t *tk = malloc (sizeof *tk);
if (!tk)
return NULL;
// Default all the object fields but don't allocate anything
tk->fd = -1;
tk->flags = 0;
tk->canonflags = 0;
tk->buffer = NULL;
tk->buffstart = 0;
tk->buffcount = 0;
tk->buffsize = 256; // bytes
tk->hightide = 0;
tk->restore_termios_valid = false;
tk->waittime = 50; // msec
tk->is_closed = false;
tk->is_started = false;
tk->nkeynames = 64;
tk->keynames = NULL;
for (int i = 0; i < 32; i++)
tk->c0[i].sym = TERMO_SYM_NONE;
tk->drivers = NULL;
tk->method.emit_codepoint = &emit_codepoint;
tk->method.peekkey_simple = &peekkey_simple;
tk->method.peekkey_mouse = &peekkey_mouse;
tk->mouse_proto = TERMO_MOUSE_PROTO_NONE;
tk->mouse_tracking = TERMO_MOUSE_TRACKING_CLICK;
tk->guessed_mouse_proto = TERMO_MOUSE_PROTO_NONE;
tk->ti_data = NULL;
tk->ti_method.set_mouse_proto = NULL;
tk->ti_method.set_mouse_tracking_mode = NULL;
return tk;
}
static int
termo_init (termo_t *tk, const char *term, const char *encoding)
{
if (!encoding)
encoding = nl_langinfo (CODESET);
// If we don't specify the endianity, iconv() outputs the BOM first
static const uint16_t endianity = 0x0102;
const char *utf32 = (*(uint8_t *) &endianity == 0x01)
? "UTF-32BE" : "UTF-32LE";
if ((tk->to_utf32_conv = iconv_open (utf32, encoding)) == (iconv_t) -1)
return 0;
if ((tk->from_utf32_conv = iconv_open (encoding, utf32)) == (iconv_t) -1)
goto abort_free_to_utf32;
tk->buffer = malloc (tk->buffsize);
if (!tk->buffer)
goto abort_free_from_utf32;
tk->keynames = malloc (sizeof tk->keynames[0] * tk->nkeynames);
if (!tk->keynames)
goto abort_free_buffer;
int i;
for (i = 0; i < tk->nkeynames; i++)
tk->keynames[i] = NULL;
for (i = 0; keynames[i].name; i++)
if (termo_register_keyname (tk,
keynames[i].sym, keynames[i].name) == -1)
goto abort_free_keynames;
register_c0 (tk, TERMO_SYM_TAB, 0x09, NULL);
register_c0 (tk, TERMO_SYM_ENTER, 0x0d, NULL);
register_c0 (tk, TERMO_SYM_ESCAPE, 0x1b, NULL);
termo_driver_node_t **tail = &tk->drivers;
for (i = 0; drivers[i]; i++)
{
void *info = (*drivers[i]->new_driver) (tk, term);
if (!info)
continue;
#ifdef DEBUG
fprintf (stderr, "Loading the %s driver...\n", drivers[i]->name);
#endif
termo_driver_node_t *thisdrv = malloc (sizeof *thisdrv);
if (!thisdrv)
goto abort_free_drivers;
thisdrv->driver = drivers[i];
thisdrv->info = info;
thisdrv->next = NULL;
*tail = thisdrv;
tail = &thisdrv->next;
#ifdef DEBUG
fprintf (stderr, "Loaded %s driver\n", drivers[i]->name);
#endif
}
if (!tk->drivers)
{
errno = ENOENT;
goto abort_free_keynames;
}
return 1;
abort_free_drivers:
for (termo_driver_node_t *p = tk->drivers; p; )
{
(*p->driver->free_driver) (p->info);
termo_driver_node_t *next = p->next;
free (p);
p = next;
}
abort_free_keynames:
free (tk->keynames);
abort_free_buffer:
free (tk->buffer);
abort_free_from_utf32:
iconv_close (tk->from_utf32_conv);
abort_free_to_utf32:
iconv_close (tk->to_utf32_conv);
return 0;
}
termo_t *
termo_new (int fd, const char *encoding, int flags)
{
termo_t *tk = termo_alloc ();
if (!tk)
return NULL;
tk->fd = fd;
termo_set_flags (tk, flags);
const char *term = getenv ("TERM");
if (!termo_init (tk, term, encoding))
free (tk);
else if (!(flags & TERMO_FLAG_NOSTART) && !termo_start (tk))
termo_free (tk);
else
return tk;
return NULL;
}
termo_t *
termo_new_abstract (const char *term, const char *encoding, int flags)
{
termo_t *tk = termo_alloc ();
if (!tk)
return NULL;
tk->fd = -1;
termo_set_flags (tk, flags);
if (!termo_init (tk, term, encoding))
free (tk);
else if (!(flags & TERMO_FLAG_NOSTART) && !termo_start (tk))
termo_free (tk);
else
return tk;
return NULL;
}
void
termo_free (termo_t *tk)
{
free (tk->buffer); tk->buffer = NULL;
free (tk->keynames); tk->keynames = NULL;
iconv_close (tk->to_utf32_conv);
tk->to_utf32_conv = (iconv_t) -1;
iconv_close (tk->from_utf32_conv);
tk->from_utf32_conv = (iconv_t) -1;
termo_driver_node_t *p, *next;
for (p = tk->drivers; p; p = next)
{
(*p->driver->free_driver) (p->info);
next = p->next;
free (p);
}
free (tk);
}
void
termo_destroy (termo_t *tk)
{
if (tk->is_started)
termo_stop (tk);
termo_free (tk);
}
int
termo_start (termo_t *tk)
{
if (tk->is_started)
return 1;
if (tk->fd != -1 && !(tk->flags & TERMO_FLAG_NOTERMIOS))
{
struct termios termios;
if (tcgetattr (tk->fd, &termios) == 0)
{
tk->restore_termios = termios;
tk->restore_termios_valid = true;
termios.c_iflag &= ~(IXON|INLCR|ICRNL);
termios.c_lflag &= ~(ICANON|ECHO);
termios.c_cc[VMIN] = 1;
termios.c_cc[VTIME] = 0;
if (tk->flags & TERMO_FLAG_CTRLC)
// want no signal keys at all, so just disable ISIG
termios.c_lflag &= ~ISIG;
else
{
// Disable ^\ == VQUIT and ^D == VSUSP but leave ^C as SIGINT
termios.c_cc[VQUIT] = _POSIX_VDISABLE;
termios.c_cc[VSUSP] = _POSIX_VDISABLE;
// Some OSes have ^Y == VDSUSP
#ifdef VDSUSP
termios.c_cc[VDSUSP] = _POSIX_VDISABLE;
#endif
}
#ifdef DEBUG
fprintf (stderr, "Setting termios(3) flags\n");
#endif
tcsetattr (tk->fd, TCSANOW, &termios);
}
}
termo_driver_node_t *p;
for (p = tk->drivers; p; p = p->next)
if (p->driver->start_driver)
if (!(*p->driver->start_driver) (tk, p->info))
return 0;
#ifdef DEBUG
fprintf (stderr, "Drivers started; termo instance %p is ready\n", tk);
#endif
tk->is_started = 1;
return 1;
}
int
termo_stop (termo_t *tk)
{
if (!tk->is_started)
return 1;
struct termo_driver_node *p;
for (p = tk->drivers; p; p = p->next)
if (p->driver->stop_driver)
(*p->driver->stop_driver) (tk, p->info);
if (tk->restore_termios_valid)
tcsetattr (tk->fd, TCSANOW, &tk->restore_termios);
tk->is_started = false;
return 1;
}
int
termo_is_started (termo_t *tk)
{
return tk->is_started;
}
int
termo_get_fd (termo_t *tk)
{
return tk->fd;
}
int
termo_get_flags (termo_t *tk)
{
return tk->flags;
}
void
termo_set_flags (termo_t *tk, int newflags)
{
tk->flags = newflags;
if (tk->flags & TERMO_FLAG_SPACESYMBOL)
tk->canonflags |= TERMO_CANON_SPACESYMBOL;
else
tk->canonflags &= ~TERMO_CANON_SPACESYMBOL;
}
void
termo_set_waittime (termo_t *tk, int msec)
{
tk->waittime = msec;
}
int
termo_get_waittime (termo_t *tk)
{
return tk->waittime;
}
int
termo_get_canonflags (termo_t *tk)
{
return tk->canonflags;
}
void
termo_set_canonflags (termo_t *tk, int flags)
{
tk->canonflags = flags;
if (tk->canonflags & TERMO_CANON_SPACESYMBOL)
tk->flags |= TERMO_FLAG_SPACESYMBOL;
else
tk->flags &= ~TERMO_FLAG_SPACESYMBOL;
}
size_t
termo_get_buffer_size (termo_t *tk)
{
return tk->buffsize;
}
int
termo_set_buffer_size (termo_t *tk, size_t size)
{
unsigned char *buffer = realloc (tk->buffer, size);
if (!buffer)
return 0;
tk->buffer = buffer;
tk->buffsize = size;
return 1;
}
size_t
termo_get_buffer_remaining (termo_t *tk)
{
// Return the total number of free bytes in the buffer,
// because that's what is available to the user.
return tk->buffsize - tk->buffcount;
}
termo_mouse_proto_t
termo_get_mouse_proto (termo_t *tk)
{
return tk->mouse_proto;
}
termo_mouse_proto_t
termo_guess_mouse_proto (termo_t *tk)
{
return tk->guessed_mouse_proto;
}
int
termo_set_mouse_proto (termo_t *tk, termo_mouse_proto_t proto)
{
termo_mouse_proto_t old_proto = tk->mouse_proto;
tk->mouse_proto = proto;
// Call the TI driver to apply the change if needed
if (proto == old_proto
|| !tk->is_started
|| !tk->ti_method.set_mouse_proto)
return true;
// Unsetting the protocol disables tracking; this is a bit hackish
if (!tk->ti_method.set_mouse_tracking_mode (tk->ti_data,
tk->mouse_tracking, proto != TERMO_MOUSE_PROTO_NONE))
return false;
return tk->ti_method.set_mouse_proto (tk->ti_data, old_proto, false)
&& tk->ti_method.set_mouse_proto (tk->ti_data, proto, true);
}
termo_mouse_tracking_t
termo_get_mouse_tracking_mode (termo_t *tk)
{
return tk->mouse_tracking;
}
int
termo_set_mouse_tracking_mode (termo_t *tk, termo_mouse_tracking_t mode)
{
termo_mouse_tracking_t old_mode = tk->mouse_tracking;
tk->mouse_tracking = mode;
// Call the TI driver to apply the change if needed
if (mode == old_mode
|| !tk->is_started
|| !tk->ti_method.set_mouse_tracking_mode)
return true;
return tk->ti_method.set_mouse_tracking_mode (tk->ti_data, old_mode, false)
&& tk->ti_method.set_mouse_tracking_mode (tk->ti_data, mode, true);
}
static void
eat_bytes (termo_t *tk, size_t count)
{
if (count >= tk->buffcount)
{
tk->buffstart = 0;
tk->buffcount = 0;
return;
}
tk->buffstart += count;
tk->buffcount -= count;
}
#define MULTIBYTE_INVALID '?'
static void
fill_multibyte (termo_t *tk, termo_key_t *key)
{
size_t codepoint_len = sizeof key->code.codepoint;
char *codepoint_ptr = (char *) &key->code.codepoint;
size_t multibyte_len = sizeof key->multibyte;
char *multibyte_ptr = (char *) key->multibyte;
size_t result = iconv (tk->from_utf32_conv,
&codepoint_ptr, &codepoint_len, &multibyte_ptr, &multibyte_len);
size_t output = sizeof key->multibyte - multibyte_len;
// Something broke
if (result == (size_t) -1 || output == 0)
{
key->multibyte[0] = MULTIBYTE_INVALID;
key->multibyte[1] = 0;
return;
}
// Append a null character, as it wasn't part of the input
key->multibyte[output] = 0;
}
static termo_result_t
parse_multibyte (termo_t *tk, const unsigned char *bytes, size_t len,
uint32_t *cp, size_t *nbytep)
{
size_t multibyte_len = len;
char *multibyte_ptr = (char *) bytes;
size_t codepoint_len = sizeof *cp;
char *codepoint_ptr = (char *) cp;
// Fingers crossed...
errno = 0;
iconv (tk->to_utf32_conv,
&multibyte_ptr, &multibyte_len, &codepoint_ptr, &codepoint_len);
// Only one Unicode character could have been processed at maximum,
// so let's just set the number of processed bytes to the difference
*nbytep = len - multibyte_len;
// Nothing has been converted, let's examine what happened
if (codepoint_ptr == (char *) cp)
{
if (errno == 0)
// The input was probably a shift sequence
return TERMO_RES_AGAIN;
if (errno == EINVAL)
// Incomplete character or shift sequence
return TERMO_RES_AGAIN;
if (errno == EILSEQ)
{
// Invalid multibyte sequence in the input, let's try going
// byte after byte in hope we skip it completely
*cp = MULTIBYTE_INVALID;
*nbytep = 1;
return TERMO_RES_KEY;
}
// We can't really get E2BIG so what the fuck is going on here
abort ();
}
return TERMO_RES_KEY;
}
static void
emit_codepoint (termo_t *tk, uint32_t codepoint, termo_key_t *key)
{
if (codepoint == 0)
{
// ASCII NUL = Ctrl-Space as well as Ctrl-@ but let's prefer
// the former to follow the behaviour of libtermkey
key->type = TERMO_TYPE_KEYSYM;
key->code.sym = TERMO_SYM_SPACE;
key->modifiers = TERMO_KEYMOD_CTRL;
}
else if (codepoint < 0x20)
{
// C0 range
key->code.codepoint = 0;
key->modifiers = 0;
if (!(tk->flags & TERMO_FLAG_NOINTERPRET)
&& tk->c0[codepoint].sym != TERMO_SYM_UNKNOWN)
{
key->code.sym = tk->c0[codepoint].sym;
key->modifiers |= tk->c0[codepoint].modifier_set;
}
if (!key->code.sym)
{
key->type = TERMO_TYPE_KEY;
// Generically modified Unicode ought not report the SHIFT state,
// or else we get into complications trying to report Shift-; vs :
// and so on... In order to be able to represent Ctrl-Shift-A as
// CTRL modified unicode A, we need to call Ctrl-A simply 'a',
// lowercase
if (codepoint + 0x40 >= 'A' && codepoint + 0x40 <= 'Z')
// It's a letter - use lowercase instead
key->code.codepoint = codepoint + 0x60;
else
key->code.codepoint = codepoint + 0x40;
key->modifiers = TERMO_KEYMOD_CTRL;
}
else
key->type = TERMO_TYPE_KEYSYM;
}
else if (codepoint == 0x7f && !(tk->flags & TERMO_FLAG_NOINTERPRET))
{
// ASCII DEL
key->type = TERMO_TYPE_KEYSYM;
key->code.sym = TERMO_SYM_DEL;
key->modifiers = 0;
}
else
{
key->type = TERMO_TYPE_KEY;
key->code.codepoint = codepoint;
key->modifiers = 0;
}
termo_canonicalise (tk, key);
if (key->type == TERMO_TYPE_KEY)
fill_multibyte (tk, key);
}
void
termo_canonicalise (termo_t *tk, termo_key_t *key)
{
int flags = tk->canonflags;
if (flags & TERMO_CANON_SPACESYMBOL)
{
if (key->type == TERMO_TYPE_KEY && key->code.codepoint == 0x20)
{
key->type = TERMO_TYPE_KEYSYM;
key->code.sym = TERMO_SYM_SPACE;
}
}
else
{
if (key->type == TERMO_TYPE_KEYSYM
&& key->code.sym == TERMO_SYM_SPACE)
{
key->type = TERMO_TYPE_KEY;
key->code.codepoint = 0x20;
fill_multibyte (tk, key);
}
}
if (flags & TERMO_CANON_DELBS)
if (key->type == TERMO_TYPE_KEYSYM
&& key->code.sym == TERMO_SYM_DEL)
key->code.sym = TERMO_SYM_BACKSPACE;
}
static termo_result_t
peekkey (termo_t *tk, termo_key_t *key, int flags, size_t *nbytep)
{
int again = 0;
if (!tk->is_started)
{
errno = EINVAL;
return TERMO_RES_ERROR;
}
#ifdef DEBUG
fprintf (stderr, "getkey(force=%d): buffer ", force);
print_buffer (tk);
fprintf (stderr, "\n");
#endif
if (tk->hightide)
{
tk->buffstart += tk->hightide;
tk->buffcount -= tk->hightide;
tk->hightide = 0;
}
termo_result_t ret;
termo_driver_node_t *p;
for (p = tk->drivers; p; p = p->next)
{
ret = (p->driver->peekkey) (tk, p->info, key, flags, nbytep);
#ifdef DEBUG
fprintf (stderr, "Driver %s yields %s\n",
p->driver->name, res2str (ret));
#endif
switch (ret)
{
case TERMO_RES_KEY:
{
#ifdef DEBUG
print_key (tk, key); fprintf (stderr, "\n");
#endif
// Slide the data down to stop it running away
size_t halfsize = tk->buffsize / 2;
if (tk->buffstart > halfsize)
{
memcpy (tk->buffer, tk->buffer + halfsize, halfsize);
tk->buffstart -= halfsize;
}
// Fallthrough
}
case TERMO_RES_EOF:
case TERMO_RES_ERROR:
return ret;
case TERMO_RES_AGAIN:
if (!(flags & PEEKKEY_FORCE))
again = 1;
case TERMO_RES_NONE:
break;
}
}
if (again)
return TERMO_RES_AGAIN;
ret = peekkey_simple (tk, key, flags, nbytep);
#ifdef DEBUG
fprintf (stderr, "getkey_simple(force=%d) yields %s\n",
force, res2str (ret));
if (ret == TERMO_RES_KEY)
{
print_key (tk, key);
fprintf (stderr, "\n");
}
#endif
return ret;
}
static termo_result_t
peekkey_simple (termo_t *tk, termo_key_t *key, int flags, size_t *nbytep)
{
if (tk->buffcount == 0)
return tk->is_closed ? TERMO_RES_EOF : TERMO_RES_NONE;
unsigned char b0 = CHARAT (0);
if (b0 == 0x1b)
{
if (flags & PEEKKEY_ALT_PREFIXED)
{
// We got back here recursively, which means that no driver has
// returned TERMO_RES_AGAIN -> just return the Escape. Otherwise
// we would interpret an indefinite number of <Esc>s as Alt+Esc.
(*tk->method.emit_codepoint) (tk, b0, key);
*nbytep = 1;
return TERMO_RES_KEY;
}
// Escape-prefixed value? Might therefore be Alt+key
if (tk->buffcount == 1)
{
// This might be an <Esc> press, or it may want to be part
// of a longer sequence
if (!(flags & PEEKKEY_FORCE))
return TERMO_RES_AGAIN;
(*tk->method.emit_codepoint) (tk, b0, key);
*nbytep = 1;
return TERMO_RES_KEY;
}
// Try another key there
tk->buffstart++;
tk->buffcount--;
// Run the full driver
termo_result_t metakey_result =
peekkey (tk, key, flags | PEEKKEY_ALT_PREFIXED, nbytep);
tk->buffstart--;
tk->buffcount++;
switch (metakey_result)
{
case TERMO_RES_KEY:
key->modifiers |= TERMO_KEYMOD_ALT;
(*nbytep)++;
break;
case TERMO_RES_NONE:
case TERMO_RES_EOF:
case TERMO_RES_AGAIN:
case TERMO_RES_ERROR:
break;
}
return metakey_result;
}
else if (!(tk->flags & TERMO_FLAG_RAW))
{
// XXX: this way DEL is never recognised as backspace, even if it is
// specified in the terminfo entry key_backspace. Just because it
// doesn't form an escape sequence.
uint32_t codepoint = MULTIBYTE_INVALID;
termo_result_t res = parse_multibyte
(tk, tk->buffer + tk->buffstart, tk->buffcount, &codepoint, nbytep);
if (res == TERMO_RES_AGAIN && (flags & PEEKKEY_FORCE))
{
// There weren't enough bytes for a complete character but
// caller demands an answer. About the best thing we can do here
// is eat as many bytes as we have, and emit a MULTIBYTE_INVALID.
// If the remaining bytes arrive later, they'll be invalid too.
*nbytep = tk->buffcount;
res = TERMO_RES_KEY;
}
key->type = TERMO_TYPE_KEY;
key->modifiers = 0;
(*tk->method.emit_codepoint) (tk, codepoint, key);
return res;
}
else
{
// Non multibyte case - just report the raw byte
key->type = TERMO_TYPE_KEY;
key->code.codepoint = b0;
key->modifiers = 0;
key->multibyte[0] = b0;
key->multibyte[1] = 0;
*nbytep = 1;
return TERMO_RES_KEY;
}
}
// REPLACEMENT CHARACTER
#define UTF8_INVALID 0xFFFD
static size_t
parse_utf8_fast (const unsigned char *bytes, size_t len, uint32_t *cp)
{
size_t nbytes;
unsigned char b0 = bytes[0];
if (b0 < 0x80)
{
// Single byte ASCII
*cp = b0;
return 1;
}
else if (b0 < 0xc0)
{
// Starts with a continuation byte - that's not right
*cp = UTF8_INVALID;
return 1;
}
else if (b0 < 0xe0)
{
nbytes = 2;
*cp = b0 & 0x1f;
}
else if (b0 < 0xf0)
{
nbytes = 3;
*cp = b0 & 0x0f;
}
else if (b0 < 0xf8)
{
nbytes = 4;
*cp = b0 & 0x07;
}
else if (b0 < 0xfc)
{
nbytes = 5;
*cp = b0 & 0x03;
}
else if (b0 < 0xfe)
{
nbytes = 6;
*cp = b0 & 0x01;
}
else
{
*cp = UTF8_INVALID;
return 1;
}
for (size_t b = 1; b < nbytes; b++)
{
if (b >= len)
return 0;
unsigned char cb = bytes[b];
if (cb < 0x80 || cb >= 0xc0)
{
*cp = UTF8_INVALID;
return b;
}
*cp <<= 6;
*cp |= cb & 0x3f;
}
return nbytes;
}
static termo_result_t
parse_1005_value (const unsigned char **bytes, size_t *len, uint32_t *cp)
{
size_t nbytes = parse_utf8_fast (*bytes, *len, cp);
if (nbytes == 0)
return TERMO_RES_AGAIN;
// XXX: With the current infrastructure I'm not sure how to properly handle
// this. peekkey() isn't made for skipping invalid inputs.
if (*cp == UTF8_INVALID)
*cp = 0x20;
(*bytes) += nbytes;
(*len) -= nbytes;
return TERMO_RES_KEY;
}
static termo_result_t
peekkey_mouse (termo_t *tk, termo_key_t *key, size_t *nbytep)
{
uint32_t b, x, y;
if (tk->mouse_proto == TERMO_MOUSE_PROTO_UTF8)
{
const unsigned char *buff = tk->buffer + tk->buffstart;
size_t len = tk->buffcount;
if (parse_1005_value (&buff, &len, &b) == TERMO_RES_AGAIN
|| parse_1005_value (&buff, &len, &x) == TERMO_RES_AGAIN
|| parse_1005_value (&buff, &len, &y) == TERMO_RES_AGAIN)
return TERMO_RES_AGAIN;
*nbytep = tk->buffcount - len;
}
else
{
if (tk->buffcount < 3)
return TERMO_RES_AGAIN;
b = CHARAT (0);
x = CHARAT (1);
y = CHARAT (2);
*nbytep = 3;
}
key->type = TERMO_TYPE_MOUSE;
key->code.mouse.info = b - 0x20;
key->code.mouse.x = x - 0x20 - 1;
key->code.mouse.y = y - 0x20 - 1;
key->modifiers = (key->code.mouse.info & 0x1c) >> 2;
key->code.mouse.info &= ~0x1c;
return TERMO_RES_KEY;
}
termo_result_t
termo_getkey (termo_t *tk, termo_key_t *key)
{
size_t nbytes = 0;
termo_result_t ret = peekkey (tk, key, 0, &nbytes);
if (ret == TERMO_RES_KEY)
eat_bytes (tk, nbytes);
if (ret == TERMO_RES_AGAIN)
// Call peekkey() again in force mode to obtain whatever it can
(void) peekkey (tk, key, PEEKKEY_FORCE, &nbytes);
// Don't eat it yet though
return ret;
}
termo_result_t
termo_getkey_force (termo_t *tk, termo_key_t *key)
{
size_t nbytes = 0;
termo_result_t ret = peekkey (tk, key, PEEKKEY_FORCE, &nbytes);
if (ret == TERMO_RES_KEY)
eat_bytes (tk, nbytes);
return ret;
}
termo_result_t
termo_waitkey (termo_t *tk, termo_key_t *key)
{
if (tk->fd == -1)
{
errno = EBADF;
return TERMO_RES_ERROR;
}
while (1)
{
termo_result_t ret = termo_getkey (tk, key);
switch (ret)
{
case TERMO_RES_KEY:
case TERMO_RES_EOF:
case TERMO_RES_ERROR:
return ret;
case TERMO_RES_NONE:
ret = termo_advisereadable (tk);
if (ret == TERMO_RES_ERROR)
return ret;
break;
case TERMO_RES_AGAIN:
{
if (tk->is_closed)
// We're closed now. Never going to get more bytes
// so just go with what we have
return termo_getkey_force (tk, key);
struct pollfd fd;
retry:
fd.fd = tk->fd;
fd.events = POLLIN;
int pollret = poll (&fd, 1, tk->waittime);
if (pollret == -1)
{
if (errno == EINTR && !(tk->flags & TERMO_FLAG_EINTR))
goto retry;
return TERMO_RES_ERROR;
}
if (fd.revents & (POLLIN | POLLHUP | POLLERR))
ret = termo_advisereadable (tk);
else
ret = TERMO_RES_NONE;
if (ret == TERMO_RES_ERROR)
return ret;
if (ret == TERMO_RES_NONE)
return termo_getkey_force (tk, key);
}
}
}
// UNREACHABLE
}
termo_result_t
termo_advisereadable (termo_t *tk)
{
if (tk->fd == -1)
{
errno = EBADF;
return TERMO_RES_ERROR;
}
if (tk->buffstart)
{
memmove (tk->buffer, tk->buffer + tk->buffstart, tk->buffcount);
tk->buffstart = 0;
}
// Not expecting it ever to be greater but doesn't hurt to handle that
if (tk->buffcount >= tk->buffsize)
{
errno = ENOMEM;
return TERMO_RES_ERROR;
}
ssize_t len;
retry:
len = read (tk->fd, tk->buffer + tk->buffcount,
tk->buffsize - tk->buffcount);
if (len == -1)
{
if (errno == EAGAIN)
return TERMO_RES_NONE;
if (errno == EINTR && !(tk->flags & TERMO_FLAG_EINTR))
goto retry;
return TERMO_RES_ERROR;
}
if (len < 1)
{
tk->is_closed = true;
return TERMO_RES_NONE;
}
tk->buffcount += len;
return TERMO_RES_AGAIN;
}
size_t
termo_push_bytes (termo_t *tk, const char *bytes, size_t len)
{
if (tk->buffstart)
{
memmove (tk->buffer, tk->buffer + tk->buffstart, tk->buffcount);
tk->buffstart = 0;
}
// Not expecting it ever to be greater but doesn't hurt to handle that
if (tk->buffcount >= tk->buffsize)
{
errno = ENOMEM;
return (size_t)-1;
}
if (len > tk->buffsize - tk->buffcount)
len = tk->buffsize - tk->buffcount;
// memcpy(), not strncpy() in case of null bytes in input
memcpy (tk->buffer + tk->buffcount, bytes, len);
tk->buffcount += len;
return len;
}
termo_sym_t
termo_register_keyname (termo_t *tk, termo_sym_t sym, const char *name)
{
if (!sym)
sym = tk->nkeynames;
if (sym >= tk->nkeynames)
{
const char **new_keynames =
realloc (tk->keynames, sizeof new_keynames[0] * (sym + 1));
if (!new_keynames)
return -1;
tk->keynames = new_keynames;
// Fill in the hole
for (int i = tk->nkeynames; i < sym; i++)
tk->keynames[i] = NULL;
tk->nkeynames = sym + 1;
}
tk->keynames[sym] = name;
return sym;
}
const char *
termo_get_keyname (termo_t *tk, termo_sym_t sym)
{
if (sym == TERMO_SYM_UNKNOWN)
return "UNKNOWN";
if (sym < tk->nkeynames)
return tk->keynames[sym];
return "UNKNOWN";
}
static const char *
termo_lookup_keyname_format (termo_t *tk,
const char *str, termo_sym_t *sym, termo_format_t format)
{
// We store an array, so we can't do better than a linear search. Doesn't
// matter because user won't be calling this too often
for (*sym = 0; *sym < tk->nkeynames; (*sym)++)
{
const char *thiskey = tk->keynames[*sym];
if (!thiskey)
continue;
size_t len = strlen (thiskey);
if (format & TERMO_FORMAT_LOWERSPACE)
{
const char *thisstr = str;
if (strpncmp_camel (&thisstr, &thiskey, len) == 0)
return thisstr;
}
else if (!strncmp (str, thiskey, len))
return (char *) str + len;
}
return NULL;
}
const char *
termo_lookup_keyname (termo_t *tk, const char *str, termo_sym_t *sym)
{
return termo_lookup_keyname_format (tk, str, sym, 0);
}
termo_sym_t
termo_keyname2sym (termo_t *tk, const char *keyname)
{
termo_sym_t sym;
const char *endp = termo_lookup_keyname (tk, keyname, &sym);
if (!endp || endp[0])
return TERMO_SYM_UNKNOWN;
return sym;
}
static termo_sym_t
register_c0 (termo_t *tk,
termo_sym_t sym, unsigned char ctrl, const char *name)
{
return register_c0_full (tk, sym, 0, 0, ctrl, name);
}
static termo_sym_t
register_c0_full (termo_t *tk, termo_sym_t sym,
int modifier_set, int modifier_mask, unsigned char ctrl, const char *name)
{
if (ctrl >= 0x20)
{
errno = EINVAL;
return -1;
}
if (name)
sym = termo_register_keyname (tk, sym, name);
tk->c0[ctrl].sym = sym;
tk->c0[ctrl].modifier_set = modifier_set;
tk->c0[ctrl].modifier_mask = modifier_mask;
return sym;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static struct modnames
{
const char *shift, *alt, *ctrl;
}
modnames[] =
{
{ "S", "A", "C" }, // 0
{ "Shift", "Alt", "Ctrl" }, // LONGMOD
{ "S", "M", "C" }, // ALTISMETA
{ "Shift", "Meta", "Ctrl" }, // ALTISMETA+LONGMOD
{ "s", "a", "c" }, // LOWERMOD
{ "shift", "alt", "ctrl" }, // LOWERMOD+LONGMOD
{ "s", "m", "c" }, // LOWERMOD+ALTISMETA
{ "shift", "meta", "ctrl" }, // LOWERMOD+ALTISMETA+LONGMOD
};
typedef const char *(*strfkey_emit_fn) (termo_t *, termo_key_t *, char *);
static size_t
termo_strfkey_generic (termo_t *tk, char *buffer, size_t len,
termo_key_t *key, termo_format_t format, strfkey_emit_fn emit)
{
size_t pos = 0;
int l = 0;
struct modnames *mods = &modnames[
!!(format & TERMO_FORMAT_LONGMOD) +
!!(format & TERMO_FORMAT_ALTISMETA) * 2 +
!!(format & TERMO_FORMAT_LOWERMOD) * 4];
int wrapbracket = (format & TERMO_FORMAT_WRAPBRACKET) &&
(key->type != TERMO_TYPE_KEY || key->modifiers != 0);
char sep = (format & TERMO_FORMAT_SPACEMOD) ? ' ' : '-';
if (format & TERMO_FORMAT_CARETCTRL &&
key->type == TERMO_TYPE_KEY &&
key->modifiers == TERMO_KEYMOD_CTRL)
{
uint32_t codepoint = key->code.codepoint;
// Handle some of the special casesfirst
if (codepoint >= 'a' && codepoint <= 'z')
{
l = snprintf (buffer + pos, len - pos,
wrapbracket ? "<^%c>" : "^%c", (char) codepoint - 0x20);
if (l <= 0)
return pos;
pos += l;
return pos;
}
else if ((codepoint >= '@' && codepoint < 'A') ||
(codepoint > 'Z' && codepoint <= '_'))
{
l = snprintf (buffer + pos, len - pos,
wrapbracket ? "<^%c>" : "^%c", (char) codepoint);
if (l <= 0)
return pos;
pos += l;
return pos;
}
}
if (wrapbracket)
{
l = snprintf (buffer + pos, len - pos, "<");
if (l <= 0)
return pos;
pos += l;
}
if (key->modifiers & TERMO_KEYMOD_ALT)
{
l = snprintf (buffer + pos, len - pos, "%s%c", mods->alt, sep);
if (l <= 0)
return pos;
pos += l;
}
if (key->modifiers & TERMO_KEYMOD_CTRL)
{
l = snprintf (buffer + pos, len - pos, "%s%c", mods->ctrl, sep);
if (l <= 0)
return pos;
pos += l;
}
if (key->modifiers & TERMO_KEYMOD_SHIFT)
{
l = snprintf (buffer + pos, len - pos, "%s%c", mods->shift, sep);
if (l <= 0)
return pos;
pos += l;
}
switch (key->type)
{
case TERMO_TYPE_KEY:
{
char buf[MB_LEN_MAX + 1];
l = snprintf (buffer + pos, len - pos, "%s", emit (tk, key, buf));
break;
}
case TERMO_TYPE_KEYSYM:
{
const char *name = termo_get_keyname (tk, key->code.sym);
if (format & TERMO_FORMAT_LOWERSPACE)
l = snprint_cameltospaces (buffer + pos, len - pos, name);
else
l = snprintf (buffer + pos, len - pos, "%s", name);
break;
}
case TERMO_TYPE_FUNCTION:
l = snprintf (buffer + pos, len - pos, "%c%d",
(format & TERMO_FORMAT_LOWERSPACE ? 'f' : 'F'), key->code.number);
break;
case TERMO_TYPE_MOUSE:
{
termo_mouse_event_t ev;
int button;
int line, col;
termo_interpret_mouse (tk, key, &ev, &button, &line, &col);
static const char *evnames[] =
{ "Unknown", "Press", "Drag", "Release" };
l = snprintf (buffer + pos, len - pos,
"Mouse%s(%d)", evnames[ev], button);
if (format & TERMO_FORMAT_MOUSE_POS)
{
if (l <= 0)
return pos;
pos += l;
l = snprintf (buffer + pos, len - pos, " @ (%u,%u)", col, line);
}
break;
}
case TERMO_TYPE_FOCUS:
l = snprintf (buffer + pos, len - pos, "Focus(%d)", key->code.focused);
case TERMO_TYPE_POSITION:
l = snprintf (buffer + pos, len - pos, "Position");
break;
case TERMO_TYPE_MODEREPORT:
{
int initial, mode, value;
termo_interpret_modereport (tk, key, &initial, &mode, &value);
if (initial)
l = snprintf (buffer + pos, len - pos,
"Mode(%c%d=%d)", initial, mode, value);
else
l = snprintf (buffer + pos, len - pos,
"Mode(%d=%d)", mode, value);
break;
}
case TERMO_TYPE_UNKNOWN_CSI:
l = snprintf (buffer + pos, len - pos,
"CSI %c", key->code.number & 0xff);
break;
}
if (l <= 0)
return pos;
pos += l;
if (wrapbracket)
{
l = snprintf (buffer + pos, len - pos, ">");
if (l <= 0)
return pos;
pos += l;
}
return pos;
}
static const char *
strfkey_emit_locale (termo_t *tk, termo_key_t *key, char buf[])
{
(void) buf;
if (!key->multibyte[0]) // In case of user-supplied key structures
fill_multibyte (tk, key);
return key->multibyte;
}
size_t
termo_strfkey (termo_t *tk, char *buffer, size_t len,
termo_key_t *key, termo_format_t format)
{
return termo_strfkey_generic
(tk, buffer, len, key, format, strfkey_emit_locale);
}
static inline size_t
utf8_seqlen (uint32_t codepoint)
{
if (codepoint < 0x0000080) return 1;
if (codepoint < 0x0000800) return 2;
if (codepoint < 0x0010000) return 3;
if (codepoint < 0x0200000) return 4;
if (codepoint < 0x4000000) return 5;
return 6;
}
static const char *
strfkey_emit_utf8 (termo_t *tk, termo_key_t *key, char buf[])
{
(void) tk;
uint32_t codepoint = key->code.codepoint;
int nbytes = utf8_seqlen (codepoint);
buf[nbytes] = 0;
// This is easier done backwards
for (int b = nbytes; b-- > 1; codepoint >>= 6)
buf[b] = 0x80 | (codepoint & 0x3f);
switch (nbytes)
{
case 1: buf[0] = (codepoint & 0x7f); break;
case 2: buf[0] = 0xc0 | (codepoint & 0x1f); break;
case 3: buf[0] = 0xe0 | (codepoint & 0x0f); break;
case 4: buf[0] = 0xf0 | (codepoint & 0x07); break;
case 5: buf[0] = 0xf8 | (codepoint & 0x03); break;
case 6: buf[0] = 0xfc | (codepoint & 0x01); break;
}
return buf;
}
size_t
termo_strfkey_utf8 (termo_t *tk, char *buffer, size_t len,
termo_key_t *key, termo_format_t format)
{
return termo_strfkey_generic
(tk, buffer, len, key, format, strfkey_emit_utf8);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
typedef termo_result_t (*strpkey_parse_fn)
(termo_t *, const unsigned char *, size_t, uint32_t *, size_t *);
static const char *
termo_strpkey_generic (termo_t *tk, const char *str, termo_key_t *key,
termo_format_t format, strpkey_parse_fn parse)
{
struct modnames *mods = &modnames[
!!(format & TERMO_FORMAT_LONGMOD) +
!!(format & TERMO_FORMAT_ALTISMETA) * 2 +
!!(format & TERMO_FORMAT_LOWERMOD) * 4];
key->modifiers = 0;
if ((format & TERMO_FORMAT_CARETCTRL) && str[0] == '^' && str[1])
{
str = termo_strpkey_generic (tk,
str + 1, key, format & ~TERMO_FORMAT_CARETCTRL, parse);
if (!str
|| key->type != TERMO_TYPE_KEY
|| key->code.codepoint < '@'
|| key->code.codepoint > '_'
|| key->modifiers != 0)
return NULL;
if (key->code.codepoint >= 'A'
&& key->code.codepoint <= 'Z')
key->code.codepoint += 0x20;
key->modifiers = TERMO_KEYMOD_CTRL;
fill_multibyte (tk, key);
return (char *) str;
}
const char *sep_at;
while ((sep_at = strchr (str,
(format & TERMO_FORMAT_SPACEMOD) ? ' ' : '-')))
{
size_t n = sep_at - str;
if (n == strlen (mods->alt) && !strncmp (mods->alt, str, n))
key->modifiers |= TERMO_KEYMOD_ALT;
else if (n == strlen (mods->ctrl) && !strncmp (mods->ctrl, str, n))
key->modifiers |= TERMO_KEYMOD_CTRL;
else if (n == strlen (mods->shift) && !strncmp (mods->shift, str, n))
key->modifiers |= TERMO_KEYMOD_SHIFT;
else
break;
str = sep_at + 1;
}
size_t nbytes;
ssize_t snbytes;
const char *endstr;
if ((endstr = termo_lookup_keyname_format
(tk, str, &key->code.sym, format)))
{
key->type = TERMO_TYPE_KEYSYM;
str = endstr;
}
else if (sscanf (str, "F%d%zn", &key->code.number, &snbytes) == 1)
{
key->type = TERMO_TYPE_FUNCTION;
str += snbytes;
}
// Multibyte must be last
else if (parse (tk, (unsigned const char *) str, strlen (str),
&key->code.codepoint, &nbytes) == TERMO_RES_KEY)
{
key->type = TERMO_TYPE_KEY;
fill_multibyte (tk, key);
str += nbytes;
}
// TODO: Consider mouse events?
else
return NULL;
termo_canonicalise (tk, key);
return (char *) str;
}
const char *
termo_strpkey (termo_t *tk,
const char *str, termo_key_t *key, termo_format_t format)
{
return termo_strpkey_generic (tk, str, key, format, parse_multibyte);
}
static termo_result_t
parse_utf8 (termo_t *tk, const unsigned char *bytes, size_t len,
uint32_t *cp, size_t *nbytep)
{
(void) tk;
size_t nbytes = parse_utf8_fast (bytes, len, cp);
if (nbytes == 0)
return TERMO_RES_AGAIN;
// Check for overlong sequences
if (nbytes > utf8_seqlen (*cp))
*cp = UTF8_INVALID;
// Check for UTF-16 surrogates or invalid *cps
if ((*cp >= 0xD800 && *cp <= 0xDFFF)
|| *cp == 0xFFFE
|| *cp == 0xFFFF)
*cp = UTF8_INVALID;
*nbytep = nbytes;
return TERMO_RES_KEY;
}
const char *
termo_strpkey_utf8 (termo_t *tk,
const char *str, termo_key_t *key, termo_format_t format)
{
return termo_strpkey_generic (tk, str, key, format, parse_utf8);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
int
termo_keycmp (termo_t *tk,
const termo_key_t *key1p, const termo_key_t *key2p)
{
// Copy the key structs since we'll be modifying them
termo_key_t key1 = *key1p, key2 = *key2p;
termo_canonicalise (tk, &key1);
termo_canonicalise (tk, &key2);
if (key1.type != key2.type)
return key1.type - key2.type;
switch (key1.type)
{
case TERMO_TYPE_KEY:
if (key1.code.codepoint != key2.code.codepoint)
return key1.code.codepoint - key2.code.codepoint;
break;
case TERMO_TYPE_KEYSYM:
if (key1.code.sym != key2.code.sym)
return key1.code.sym - key2.code.sym;
break;
case TERMO_TYPE_FUNCTION:
case TERMO_TYPE_UNKNOWN_CSI:
if (key1.code.number != key2.code.number)
return key1.code.number - key2.code.number;
break;
case TERMO_TYPE_MOUSE:
{
int cmp = memcmp (&key1.code.mouse, &key2.code.mouse,
sizeof key1.code.mouse);
if (cmp != 0)
return cmp;
break;
}
case TERMO_TYPE_FOCUS:
return key1.code.focused - key2.code.focused;
case TERMO_TYPE_POSITION:
{
int line1, col1, line2, col2;
termo_interpret_position (tk, &key1, &line1, &col1);
termo_interpret_position (tk, &key2, &line2, &col2);
if (line1 != line2)
return line1 - line2;
return col1 - col2;
}
case TERMO_TYPE_MODEREPORT:
{
int initial1, initial2, mode1, mode2, value1, value2;
termo_interpret_modereport (tk, &key1, &initial1, &mode1, &value1);
termo_interpret_modereport (tk, &key2, &initial2, &mode2, &value2);
if (initial1 != initial2)
return initial1 - initial2;
if (mode1 != mode2)
return mode1 - mode2;
return value1 - value2;
}
}
return key1.modifiers - key2.modifiers;
}