/*
* nncmpp -- the MPD client you never knew you needed
*
* Copyright (c) 2016, Přemysl Janouch
* All rights reserved.
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR ANY
* SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN ACTION
* OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF OR IN
* CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*
*/
#include "config.h"
// We "need" to have an enum for attributes before including liberty.
// Avoiding colours in the defaults here in order to support dumb terminals.
#define ATTRIBUTE_TABLE(XX) \
XX( HEADER, "header", -1, -1, 0 ) \
XX( HIGHLIGHT, "highlight", -1, -1, A_BOLD ) \
/* Gauge */ \
XX( ELAPSED, "elapsed", -1, -1, A_REVERSE ) \
XX( REMAINS, "remains", -1, -1, A_UNDERLINE ) \
/* Tab bar */ \
XX( TAB_BAR, "tab_bar", -1, -1, A_REVERSE ) \
XX( TAB_ACTIVE, "tab_active", -1, -1, A_UNDERLINE ) \
/* Listview */ \
XX( EVEN, "even", -1, -1, 0 ) \
XX( ODD, "odd", -1, -1, 0 ) \
XX( SELECTION, "selection", -1, -1, A_REVERSE ) \
XX( SCROLLBAR, "scrollbar", -1, -1, 0 ) \
/* These are for debugging only */ \
XX( WARNING, "warning", 3, -1, 0 ) \
XX( ERROR, "error", 1, -1, 0 ) \
XX( INCOMING, "incoming", 2, -1, 0 ) \
XX( OUTGOING, "outgoing", 4, -1, 0 )
enum
{
#define XX(name, config, fg_, bg_, attrs_) ATTRIBUTE_ ## name,
ATTRIBUTE_TABLE (XX)
#undef XX
ATTRIBUTE_COUNT
};
// My battle-tested C framework acting as a GLib replacement. Its one big
// disadvantage is missing support for i18n but that can eventually be added
// as an optional feature. Localised applications look super awkward, though.
// User data for logger functions to enable formatted logging
#define print_fatal_data ((void *) ATTRIBUTE_ERROR)
#define print_error_data ((void *) ATTRIBUTE_ERROR)
#define print_warning_data ((void *) ATTRIBUTE_WARNING)
#define LIBERTY_WANT_POLLER
#define LIBERTY_WANT_ASYNC
#define LIBERTY_WANT_PROTO_HTTP
#define LIBERTY_WANT_PROTO_MPD
#include "liberty/liberty.c"
#include
#include
#ifndef TIOCGWINSZ
#include
#endif // ! TIOCGWINSZ
#include
// ncurses is notoriously retarded for input handling, we need something
// different if only to receive mouse events reliably.
#include "termo.h"
// It is surprisingly hard to find a good library to handle Unicode shenanigans,
// and there's enough of those for it to be impractical to reimplement them.
//
// GLib ICU libunistring utf8proc
// Decently sized . . x x
// Grapheme breaks . x . x
// Character width x . x x
// Locale handling . . x .
// Liberal license . x . x
//
// Also note that the ICU API is icky and uses UTF-16 for its primary encoding.
//
// Currently we're chugging along with libunistring but utf8proc seems viable.
// Non-Unicode locales can mostly be handled with simple iconv like in sdtui.
// Similarly grapheme breaks can be guessed at using character width (a basic
// test here is Zalgo text).
//
// None of this is ever going to work too reliably anyway because terminals
// and Unicode don't go awfully well together. In particular, character cell
// devices have some problems with double-wide characters.
#include
#include
#include
// We need cURL to extract links from Internet stream playlists. It'd be way
// too much code to do this all by ourselves, and there's nothing better around.
#include
#define APP_TITLE PROGRAM_NAME ///< Left top corner
// --- Utilities ---------------------------------------------------------------
// The standard endwin/refresh sequence makes the terminal flicker
static void
update_curses_terminal_size (void)
{
#if defined (HAVE_RESIZETERM) && defined (TIOCGWINSZ)
struct winsize size;
if (!ioctl (STDOUT_FILENO, TIOCGWINSZ, (char *) &size))
{
char *row = getenv ("LINES");
char *col = getenv ("COLUMNS");
unsigned long tmp;
resizeterm (
(row && xstrtoul (&tmp, row, 10)) ? tmp : size.ws_row,
(col && xstrtoul (&tmp, col, 10)) ? tmp : size.ws_col);
}
#else // HAVE_RESIZETERM && TIOCGWINSZ
endwin ();
refresh ();
#endif // HAVE_RESIZETERM && TIOCGWINSZ
}
static int64_t
clock_msec (clockid_t clock)
{
struct timespec tp;
hard_assert (clock_gettime (clock, &tp) != -1);
return (int64_t) tp.tv_sec * 1000 + (int64_t) tp.tv_nsec / 1000000;
}
static bool
xstrtoul_map (const struct str_map *map, const char *key, unsigned long *out)
{
const char *field = str_map_find (map, key);
return field && xstrtoul (out, field, 10);
}
static char *
latin1_to_utf8 (const char *latin1)
{
struct str converted;
str_init (&converted);
while (*latin1)
{
uint8_t c = *latin1++;
if (c < 0x80)
str_append_c (&converted, c);
else
{
str_append_c (&converted, 0xC0 | (c >> 6));
str_append_c (&converted, 0x80 | (c & 0x3F));
}
}
return str_steal (&converted);
}
static int
print_curl_debug (CURL *easy, curl_infotype type, char *data, size_t len,
void *ud)
{
(void) easy;
(void) ud;
(void) type;
char copy[len + 1];
for (size_t i = 0; i < len; i++)
{
uint8_t c = data[i];
copy[i] = c >= 32 || c == '\n' ? c : '.';
}
copy[len] = '\0';
char *next;
for (char *p = copy; p; p = next)
{
if ((next = strchr (p, '\n')))
*next++ = '\0';
if (!*p)
continue;
if (!utf8_validate (p, strlen (p)))
{
char *fixed = latin1_to_utf8 (p);
print_debug ("cURL: %s", fixed);
free (fixed);
}
else
print_debug ("cURL: %s", p);
}
return 0;
}
// --- cURL async wrapper ------------------------------------------------------
// You are meant to subclass this structure, no user_data pointers needed
struct poller_curl_task;
/// Receives notification for finished transfers
typedef void (*poller_curl_done_fn)
(CURLMsg *msg, struct poller_curl_task *task);
struct poller_curl_task
{
CURL *easy; ///< cURL easy interface handle
char curl_error[CURL_ERROR_SIZE]; ///< cURL error info buffer
poller_curl_done_fn on_done; ///< Done callback
};
struct poller_curl_fd
{
LIST_HEADER (struct poller_curl_fd)
struct poller_fd fd; ///< Poller FD
};
struct poller_curl
{
struct poller *poller; ///< Parent poller
struct poller_timer timer; ///< cURL timer
CURLM *multi; ///< cURL multi interface handle
struct poller_curl_fd *fds; ///< List of all FDs
};
static void
poller_curl_collect (struct poller_curl *self, curl_socket_t s, int ev_bitmask)
{
int running = 0;
CURLMcode res;
// XXX: ignoring errors, in particular CURLM_CALL_MULTI_PERFORM
if ((res = curl_multi_socket_action (self->multi, s, ev_bitmask, &running)))
print_debug ("cURL: %s", curl_multi_strerror (res));
CURLMsg *msg;
while ((msg = curl_multi_info_read (self->multi, &running)))
if (msg->msg == CURLMSG_DONE)
{
struct poller_curl_task *task = NULL;
hard_assert (!curl_easy_getinfo
(msg->easy_handle, CURLINFO_PRIVATE, &task));
task->on_done (msg, task);
}
}
static void
poller_curl_on_socket (const struct pollfd *pfd, void *user_data)
{
int mask = 0;
if (pfd->revents & POLLIN) mask |= CURL_CSELECT_IN;
if (pfd->revents & POLLOUT) mask |= CURL_CSELECT_OUT;
if (pfd->revents & POLLERR) mask |= CURL_CSELECT_ERR;
poller_curl_collect (user_data, pfd->fd, mask);
}
static int
poller_curl_on_socket_action (CURL *easy, curl_socket_t s, int what,
void *user_data, void *socket_data)
{
(void) easy;
struct poller_curl *self = user_data;
struct poller_curl_fd *fd;
if (!(fd = socket_data))
{
fd = xmalloc (sizeof *fd);
LIST_PREPEND (self->fds, fd);
poller_fd_init (&fd->fd, self->poller, s);
fd->fd.dispatcher = poller_curl_on_socket;
fd->fd.user_data = self;
curl_multi_assign (self->multi, s, fd);
}
if (what == CURL_POLL_REMOVE)
{
poller_fd_reset (&fd->fd);
LIST_UNLINK (self->fds, fd);
free (fd);
}
else
{
short events = 0;
if (what == CURL_POLL_IN) events = POLLIN;
if (what == CURL_POLL_OUT) events = POLLOUT;
if (what == CURL_POLL_INOUT) events = POLLIN | POLLOUT;
poller_fd_set (&fd->fd, events);
}
return 0;
}
static void
poller_curl_on_timer (void *user_data)
{
poller_curl_collect (user_data, CURL_SOCKET_TIMEOUT, 0);
}
static int
poller_curl_on_timer_change (CURLM *multi, long timeout_ms, void *user_data)
{
(void) multi;
struct poller_curl *self = user_data;
if (timeout_ms < 0)
poller_timer_reset (&self->timer);
else
poller_timer_set (&self->timer, timeout_ms);
return 0;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static bool
poller_curl_init (struct poller_curl *self, struct poller *poller,
struct error **e)
{
memset (self, 0, sizeof *self);
if (!(self->multi = curl_multi_init ()))
return error_set (e, "cURL setup failed");
CURLMcode mres;
if ((mres = curl_multi_setopt (self->multi,
CURLMOPT_SOCKETFUNCTION, poller_curl_on_socket_action))
|| (mres = curl_multi_setopt (self->multi,
CURLMOPT_TIMERFUNCTION, poller_curl_on_timer_change))
|| (mres = curl_multi_setopt (self->multi, CURLMOPT_SOCKETDATA, self))
|| (mres = curl_multi_setopt (self->multi, CURLMOPT_TIMERDATA, self)))
{
curl_multi_cleanup (self->multi);
return error_set (e, "%s: %s",
"cURL setup failed", curl_multi_strerror (mres));
}
poller_timer_init (&self->timer, (self->poller = poller));
self->timer.dispatcher = poller_curl_on_timer;
self->timer.user_data = self;
return true;
}
static void
poller_curl_free (struct poller_curl *self)
{
curl_multi_cleanup (self->multi);
poller_timer_reset (&self->timer);
LIST_FOR_EACH (struct poller_curl_fd, iter, self->fds)
{
poller_fd_reset (&iter->fd);
free (iter);
}
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
/// Initialize a task with a new easy instance that can be used with the poller
static bool
poller_curl_spawn (struct poller_curl_task *task, struct error **e)
{
CURL *easy;
if (!(easy = curl_easy_init ()))
return error_set (e, "cURL setup failed");
// We already take care of SIGPIPE, and native DNS timeouts are only
// a problem for people without the AsynchDNS feature.
//
// Unfortunately, cURL doesn't allow custom callbacks for DNS.
// The most we could try is parse out the hostname and provide an address
// override for it using CURLOPT_RESOLVE. Or be our own SOCKS4A/5 proxy.
CURLcode res;
if ((res = curl_easy_setopt (easy, CURLOPT_NOSIGNAL, 1L))
|| (res = curl_easy_setopt (easy, CURLOPT_ERRORBUFFER, task->curl_error))
|| (res = curl_easy_setopt (easy, CURLOPT_PRIVATE, task)))
{
curl_easy_cleanup (easy);
return error_set (e, "%s", curl_easy_strerror (res));
}
task->easy = easy;
return true;
}
static bool
poller_curl_add (struct poller_curl *self, CURL *easy, struct error **e)
{
CURLMcode mres;
// "CURLMOPT_TIMERFUNCTION [...] will be called from within this function"
if ((mres = curl_multi_add_handle (self->multi, easy)))
return error_set (e, "%s", curl_multi_strerror (mres));
return true;
}
static bool
poller_curl_remove (struct poller_curl *self, CURL *easy, struct error **e)
{
CURLMcode mres;
if ((mres = curl_multi_remove_handle (self->multi, easy)))
return error_set (e, "%s", curl_multi_strerror (mres));
return true;
}
// --- Application -------------------------------------------------------------
// Function names are prefixed mostly because of curses which clutters the
// global namespace and makes it harder to distinguish what functions relate to.
// The user interface is focused on conceptual simplicity. That is important
// since we're not using any TUI framework (which are mostly a lost cause to me
// in the post-Unicode era and not worth pursuing), and the code would get
// bloated and incomprehensible fast. We mostly rely on app_add_utf8_string()
// to write text from left to right row after row while keeping track of cells.
//
// There is an independent top pane displaying general status information,
// followed by a tab bar and a listview served by a per-tab event handler.
//
// For simplicity, the listview can only work with items that are one row high.
struct tab;
struct row_buffer;
enum user_action;
/// Try to handle an action in the tab
typedef bool (*tab_action_fn) (enum user_action action);
/// Draw an item to the screen using the row buffer API
typedef void (*tab_item_draw_fn)
(size_t item_index, struct row_buffer *buffer, int width);
struct tab
{
LIST_HEADER (struct tab)
char *name; ///< Visible identifier
size_t name_width; ///< Visible width of the name
// Implementation:
// TODO: free() callback?
tab_action_fn on_action; ///< User action handler callback
tab_item_draw_fn on_item_draw; ///< Item draw callback
// Provided by tab owner:
bool can_multiselect; ///< Multiple items can be selected
size_t item_count; ///< Total item count
// Managed by the common handler:
int item_top; ///< Index of the topmost item
int item_selected; ///< Index of the selected item
};
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
struct playlist
{
struct str_map *items; ///< Current playlist
size_t len; ///< Length
size_t alloc; ///< Allocated items
};
struct attrs
{
short fg; ///< Foreground colour index
short bg; ///< Background colour index
chtype attrs; ///< Other attributes
};
enum player_state { PLAYER_STOPPED, PLAYER_PLAYING, PLAYER_PAUSED };
// Basically a container for most of the globals; no big sense in handing
// around a pointer to this, hence it is a simple global variable as well.
// There is enough global state as it is.
static struct app_context
{
// Event loop:
struct poller poller; ///< Poller
bool quitting; ///< Quit signal for the event loop
bool polling; ///< The event loop is running
struct poller_fd tty_event; ///< Terminal input event
struct poller_fd signal_event; ///< Signal FD event
// Connection:
struct mpd_client client; ///< MPD client interface
struct poller_timer connect_event; ///< MPD reconnect timer
enum player_state state; ///< Player state
struct str_map playback_info; ///< Current song info
struct poller_timer elapsed_event; ///< Seconds elapsed event
int64_t elapsed_since; ///< Time of the next tick
// TODO: initialize these to -1
int song; ///< Current song index
int song_elapsed; ///< Song elapsed in seconds
int song_duration; ///< Song duration in seconds
int volume; ///< Current volume
struct playlist playlist; ///< Current playlist
uint32_t playlist_version; ///< Playlist version
// Data:
struct config config; ///< Program configuration
struct str_vector streams; ///< List of "name NUL URI NUL"
struct tab *help_tab; ///< Special help tab
struct tab *tabs; ///< All other tabs
struct tab *active_tab; ///< Active tab
struct tab *last_tab; ///< Previous tab
// Emulated widgets:
int header_height; ///< Height of the header
int controls_offset; ///< Offset to player controls or -1
int gauge_offset; ///< Offset to the gauge or -1
int gauge_width; ///< Width of the gauge, if present
struct poller_idle refresh_event; ///< Refresh the screen
// Terminal:
termo_t *tk; ///< termo handle
struct poller_timer tk_timer; ///< termo timeout timer
bool locale_is_utf8; ///< The locale is Unicode
bool use_partial_boxes; ///< Use Unicode box drawing chars
struct attrs attrs[ATTRIBUTE_COUNT];
}
g_ctx;
/// Shortcut to retrieve named terminal attributes
#define APP_ATTR(name) g_ctx.attrs[ATTRIBUTE_ ## name].attrs
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
tab_init (struct tab *self, const char *name)
{
memset (self, 0, sizeof *self);
// Add some padding for decorative purposes
self->name = xstrdup_printf (" %s ", name);
// Assuming tab names are pure ASCII, otherwise this would be inaccurate
// and we'd need to filter it first to replace invalid chars with '?'
self->name_width = u8_strwidth ((uint8_t *) self->name, locale_charset ());
self->item_selected = -1;
}
static void
tab_free (struct tab *self)
{
free (self->name);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
playlist_init (struct playlist *self)
{
memset (self, 0, sizeof *self);
self->items = xcalloc (sizeof *self->items, (self->alloc = 16));
}
static void
playlist_free (struct playlist *self)
{
for (size_t i = 0; i < self->len; i++)
str_map_free (&self->items[i]);
free (self->items);
}
static bool
playlist_set (struct playlist *self, int i, struct str_map *item)
{
if (i < 0 || (size_t) i >= self->len)
return false;
str_map_free (&self->items[i]);
self->items[i] = *item;
return true;
}
static struct str_map *
playlist_get (struct playlist *self, int i)
{
if (i < 0 || (size_t) i >= self->len)
return false;
return &self->items[i];
}
static void
playlist_resize (struct playlist *self, size_t len)
{
// Make the allocated array big enough but not too large
size_t new_alloc = self->alloc;
while (new_alloc < len)
new_alloc <<= 1;
while (len < (new_alloc >> 2)
&& new_alloc >= (STR_MAP_MIN_ALLOC << 1))
new_alloc >>= 1;
// Dispose of items that are out of range and resize the array if needed
for (size_t i = len; i < self->len; i++)
str_map_free (&self->items[i]);
if (new_alloc != self->alloc)
self->items = xreallocarray (self->items,
sizeof *self->items, new_alloc);
// We need to initialize placeholders so that str_map_find() succeeds
for (size_t i = self->len; i < len; i++)
str_map_init (&self->items[i]);
self->len = len;
}
// --- Configuration -----------------------------------------------------------
static struct config_schema g_config_settings[] =
{
{ .name = "address",
.comment = "Address to connect to the MPD server",
.type = CONFIG_ITEM_STRING,
.default_ = "localhost" },
{ .name = "password",
.comment = "Password to use for MPD authentication",
.type = CONFIG_ITEM_STRING },
{ .name = "root",
.comment = "Where all the files MPD is playing are located",
.type = CONFIG_ITEM_STRING },
{}
};
static struct config_schema g_config_colors[] =
{
#define XX(name_, config, fg_, bg_, attrs_) \
{ .name = config, .type = CONFIG_ITEM_STRING },
ATTRIBUTE_TABLE (XX)
#undef XX
{}
};
static const char *
get_config_string (struct config_item *root, const char *key)
{
struct config_item *item = config_item_get (root, key, NULL);
hard_assert (item);
if (item->type == CONFIG_ITEM_NULL)
return NULL;
hard_assert (config_item_type_is_string (item->type));
return item->value.string.str;
}
/// Load configuration for a color using a subset of git config colors
static void
app_load_color (struct config_item *subtree, const char *name, int id)
{
const char *value = get_config_string (subtree, name);
if (!value)
return;
struct str_vector v;
str_vector_init (&v);
cstr_split (value, " ", true, &v);
int colors = 0;
struct attrs attrs = { -1, -1, 0 };
for (char **it = v.vector; *it; it++)
{
char *end = NULL;
long n = strtol (*it, &end, 10);
if (*it != end && !*end && n >= SHRT_MIN && n <= SHRT_MAX)
{
if (colors == 0) attrs.fg = n;
if (colors == 1) attrs.bg = n;
colors++;
}
else if (!strcmp (*it, "bold")) attrs.attrs |= A_BOLD;
else if (!strcmp (*it, "dim")) attrs.attrs |= A_DIM;
else if (!strcmp (*it, "ul")) attrs.attrs |= A_UNDERLINE;
else if (!strcmp (*it, "blink")) attrs.attrs |= A_BLINK;
else if (!strcmp (*it, "reverse")) attrs.attrs |= A_REVERSE;
#ifdef A_ITALIC
else if (!strcmp (*it, "italic")) attrs.attrs |= A_ITALIC;
#endif // A_ITALIC
}
str_vector_free (&v);
g_ctx.attrs[id] = attrs;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
load_config_settings (struct config_item *subtree, void *user_data)
{
config_schema_apply_to_object (g_config_settings, subtree, user_data);
}
static void
load_config_colors (struct config_item *subtree, void *user_data)
{
config_schema_apply_to_object (g_config_colors, subtree, user_data);
// The attributes cannot be changed dynamically right now, so it doesn't
// make much sense to make use of "on_change" callbacks either.
// For simplicity, we should reload the entire table on each change anyway.
#define XX(name, config, fg_, bg_, attrs_) \
app_load_color (subtree, config, ATTRIBUTE_ ## name);
ATTRIBUTE_TABLE (XX)
#undef XX
}
static int
str_vector_sort_utf8_cb (const void *a, const void *b)
{
return u8_strcmp (*(const uint8_t **) a, *(const uint8_t **) b);
}
static void
load_config_streams (struct config_item *subtree, void *user_data)
{
(void) user_data;
// XXX: we can't use the tab in load_config_streams() because it hasn't
// been initialized yet, and we cannot initialize it before the
// configuration has been loaded. Thus we load it into the app_context.
struct str_map_iter iter;
str_map_iter_init (&iter, &subtree->value.object);
struct config_item *item;
while ((item = str_map_iter_next (&iter)))
if (!config_item_type_is_string (item->type))
print_warning ("`%s': stream URIs must be strings", iter.link->key);
else
{
struct str s;
str_init (&s);
str_append (&s, iter.link->key);
str_append_c (&s, '\0');
str_append_str (&s, &item->value.string);
str_vector_add_owned (&g_ctx.streams, str_steal (&s));
}
qsort (g_ctx.streams.vector, g_ctx.streams.len,
sizeof *g_ctx.streams.vector, str_vector_sort_utf8_cb);
}
static void
app_load_configuration (void)
{
struct config *config = &g_ctx.config;
config_register_module (config, "settings", load_config_settings, NULL);
config_register_module (config, "colors", load_config_colors, NULL);
config_register_module (config, "streams", load_config_streams, NULL);
char *filename = resolve_filename
(PROGRAM_NAME ".conf", resolve_relative_config_filename);
if (!filename)
return;
struct error *e = NULL;
struct config_item *root = config_read_from_file (filename, &e);
free (filename);
if (e)
{
print_error ("error loading configuration: %s", e->message);
error_free (e);
exit (EXIT_FAILURE);
}
if (root)
{
config_load (&g_ctx.config, root);
config_schema_call_changed (g_ctx.config.root);
}
}
// --- Application -------------------------------------------------------------
static void
app_init_attributes (void)
{
#define XX(name, config, fg_, bg_, attrs_) \
g_ctx.attrs[ATTRIBUTE_ ## name].fg = fg_; \
g_ctx.attrs[ATTRIBUTE_ ## name].bg = bg_; \
g_ctx.attrs[ATTRIBUTE_ ## name].attrs = attrs_;
ATTRIBUTE_TABLE (XX)
#undef XX
}
static void
app_init_context (void)
{
memset (&g_ctx, 0, sizeof g_ctx);
poller_init (&g_ctx.poller);
mpd_client_init (&g_ctx.client, &g_ctx.poller);
config_init (&g_ctx.config);
str_vector_init (&g_ctx.streams);
playlist_init (&g_ctx.playlist);
// This is also approximately what libunistring does internally,
// since the locale name is canonicalized by locale_charset().
// Note that non-Unicode locales are handled pretty inefficiently.
g_ctx.locale_is_utf8 = !strcasecmp_ascii (locale_charset (), "UTF-8");
// It doesn't work 100% (e.g. incompatible with undelining in urxvt)
// TODO: make this configurable
g_ctx.use_partial_boxes = g_ctx.locale_is_utf8;
app_init_attributes ();
}
static void
app_init_terminal (void)
{
TERMO_CHECK_VERSION;
if (!(g_ctx.tk = termo_new (STDIN_FILENO, NULL, 0)))
abort ();
if (!initscr () || nonl () == ERR)
abort ();
// Disable cursor, we're not going to use it most of the time
curs_set (0);
// By default we don't use any colors so they're not required...
if (start_color () == ERR
|| use_default_colors () == ERR
|| COLOR_PAIRS <= ATTRIBUTE_COUNT)
return;
for (int a = 0; a < ATTRIBUTE_COUNT; a++)
{
// ...thus we can reset back to defaults even after initializing some
if (g_ctx.attrs[a].fg >= COLORS || g_ctx.attrs[a].fg < -1
|| g_ctx.attrs[a].bg >= COLORS || g_ctx.attrs[a].bg < -1)
{
app_init_attributes ();
return;
}
init_pair (a + 1, g_ctx.attrs[a].fg, g_ctx.attrs[a].bg);
g_ctx.attrs[a].attrs |= COLOR_PAIR (a + 1);
}
}
static void
app_free_context (void)
{
mpd_client_free (&g_ctx.client);
str_map_free (&g_ctx.playback_info);
str_vector_free (&g_ctx.streams);
playlist_free (&g_ctx.playlist);
config_free (&g_ctx.config);
poller_free (&g_ctx.poller);
if (g_ctx.tk)
termo_destroy (g_ctx.tk);
}
static void
app_quit (void)
{
g_ctx.quitting = true;
// TODO: bring down the MPD interface (if that's needed at all);
// so far there's nothing for us to wait on, so let's just stop looping
g_ctx.polling = false;
}
static bool
app_is_character_in_locale (ucs4_t ch)
{
// Avoid the overhead joined with calling iconv() for all characters.
if (g_ctx.locale_is_utf8)
return true;
// The library really creates a new conversion object every single time
// and doesn't provide any smarter APIs. Luckily, most users use UTF-8.
size_t len;
char *tmp = u32_conv_to_encoding (locale_charset (), iconveh_error,
&ch, 1, NULL, NULL, &len);
if (!tmp)
return false;
free (tmp);
return true;
}
// --- Terminal output ---------------------------------------------------------
// Necessary abstraction to simplify aligned, formatted character output
struct row_char
{
ucs4_t c; ///< Unicode codepoint
chtype attrs; ///< Special attributes
int width; ///< How many cells this takes
};
struct row_buffer
{
struct row_char *chars; ///< Characters
size_t chars_len; ///< Character count
size_t chars_alloc; ///< Characters allocated
int total_width; ///< Total width of all characters
};
static void
row_buffer_init (struct row_buffer *self)
{
memset (self, 0, sizeof *self);
self->chars = xcalloc (sizeof *self->chars, (self->chars_alloc = 256));
}
static void
row_buffer_free (struct row_buffer *self)
{
free (self->chars);
}
/// Replace invalid chars and push all codepoints to the array w/ attributes.
static void
row_buffer_append (struct row_buffer *self, const char *str, chtype attrs)
{
// The encoding is only really used internally for some corner cases
const char *encoding = locale_charset ();
// Note that this function is a hotspot, try to keep it decently fast
struct row_char current = { .attrs = attrs };
struct row_char invalid = { .attrs = attrs, .c = '?', .width = 1 };
const uint8_t *next = (const uint8_t *) str;
while ((next = u8_next (¤t.c, next)))
{
if (self->chars_len >= self->chars_alloc)
self->chars = xreallocarray (self->chars,
sizeof *self->chars, (self->chars_alloc <<= 1));
current.width = uc_width (current.c, encoding);
if (current.width < 0 || !app_is_character_in_locale (current.c))
current = invalid;
self->chars[self->chars_len++] = current;
self->total_width += current.width;
}
}
static void
row_buffer_addv (struct row_buffer *self, const char *s, ...)
ATTRIBUTE_SENTINEL;
static void
row_buffer_addv (struct row_buffer *self, const char *s, ...)
{
va_list ap;
va_start (ap, s);
while (s)
{
row_buffer_append (self, s, va_arg (ap, chtype));
s = va_arg (ap, const char *);
}
va_end (ap);
}
/// Pop as many codepoints as needed to free up "space" character cells.
/// Given the suffix nature of combining marks, this should work pretty fine.
static int
row_buffer_pop_cells (struct row_buffer *self, int space)
{
int made = 0;
while (self->chars_len && made < space)
made += self->chars[--self->chars_len].width;
self->total_width -= made;
return made;
}
static void
row_buffer_space (struct row_buffer *self, int width, chtype attrs)
{
if (width < 0)
return;
while (self->chars_len + width >= self->chars_alloc)
self->chars = xreallocarray (self->chars,
sizeof *self->chars, (self->chars_alloc <<= 1));
struct row_char space = { .attrs = attrs, .c = ' ', .width = 1 };
self->total_width += width;
while (width-- > 0)
self->chars[self->chars_len++] = space;
}
static void
row_buffer_ellipsis (struct row_buffer *self, int target)
{
if (self->total_width <= target
|| !row_buffer_pop_cells (self, self->total_width - target))
return;
// We use attributes from the last character we've removed,
// assuming that we don't shrink the array (and there's no real need)
ucs4_t ellipsis = L'…';
if (app_is_character_in_locale (ellipsis))
{
if (self->total_width >= target)
row_buffer_pop_cells (self, 1);
if (self->total_width + 1 <= target)
row_buffer_append (self, "…", self->chars[self->chars_len].attrs);
}
else if (target >= 3)
{
if (self->total_width >= target)
row_buffer_pop_cells (self, 3);
if (self->total_width + 3 <= target)
row_buffer_append (self, "...", self->chars[self->chars_len].attrs);
}
}
static void
row_buffer_align (struct row_buffer *self, int target, chtype attrs)
{
row_buffer_ellipsis (self, target);
row_buffer_space (self, target - self->total_width, attrs);
}
static void
row_buffer_print (uint32_t *ucs4, chtype attrs)
{
// This assumes that we can reset the attribute set without consequences
char *str = u32_strconv_to_locale (ucs4);
if (str)
{
attrset (attrs);
addstr (str);
attrset (0);
free (str);
}
}
static void
row_buffer_flush (struct row_buffer *self)
{
if (!self->chars_len)
return;
// We only NUL-terminate the chunks because of the libunistring API
uint32_t chunk[self->chars_len + 1], *insertion_point = chunk;
for (size_t i = 0; i < self->chars_len; i++)
{
struct row_char *iter = self->chars + i;
if (i && iter[0].attrs != iter[-1].attrs)
{
row_buffer_print (chunk, iter[-1].attrs);
insertion_point = chunk;
}
*insertion_point++ = iter->c;
*insertion_point = 0;
}
row_buffer_print (chunk, self->chars[self->chars_len - 1].attrs);
}
// --- Rendering ---------------------------------------------------------------
// TODO: rewrite this so that it's fine-grained but not complicated
static void
app_invalidate (void)
{
poller_idle_set (&g_ctx.refresh_event);
}
static void
app_flush_buffer (struct row_buffer *buf, int width, chtype attrs)
{
row_buffer_align (buf, width, attrs);
row_buffer_flush (buf);
row_buffer_free (buf);
}
/// Write the given UTF-8 string padded with spaces.
/// @param[in] attrs Text attributes for the text, including padding.
static void
app_write_line (const char *str, chtype attrs)
{
struct row_buffer buf;
row_buffer_init (&buf);
row_buffer_append (&buf, str, attrs);
app_flush_buffer (&buf, COLS, attrs);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
app_flush_header (struct row_buffer *buf, chtype attrs)
{
move (g_ctx.header_height++, 0);
app_flush_buffer (buf, COLS, attrs);
}
static void
app_draw_song_info (void)
{
struct str_map *map;
if (!(map = playlist_get (&g_ctx.playlist, g_ctx.song))
|| !soft_assert (map->len != 0))
return;
// XXX: can we get rid of this and still make it look acceptable?
chtype a_normal = APP_ATTR (HEADER);
chtype a_highlight = APP_ATTR (HIGHLIGHT);
char *title;
if ((title = str_map_find (map, "title"))
|| (title = str_map_find (map, "name"))
|| (title = str_map_find (map, "file")))
{
struct row_buffer buf;
row_buffer_init (&buf);
row_buffer_append (&buf, title, a_highlight);
app_flush_header (&buf, a_highlight);
}
char *artist = str_map_find (map, "artist");
char *album = str_map_find (map, "album");
if (!artist && !album)
return;
struct row_buffer buf;
row_buffer_init (&buf);
if (artist)
{
if (buf.total_width)
row_buffer_append (&buf, " ", a_normal);
row_buffer_addv (&buf, "by ", a_normal, artist, a_highlight, NULL);
}
if (album)
{
if (buf.total_width)
row_buffer_append (&buf, " ", a_normal);
row_buffer_addv (&buf, "from ", a_normal, album, a_highlight, NULL);
}
app_flush_header (&buf, a_normal);
}
static void
app_write_time (struct row_buffer *buf, int seconds, chtype attrs)
{
int minutes = seconds / 60; seconds %= 60;
int hours = minutes / 60; minutes %= 60;
struct str s;
str_init (&s);
if (hours)
str_append_printf (&s, "%d:%02d:", hours, minutes);
else
str_append_printf (&s, "%d:", minutes);
str_append_printf (&s, "%02d", seconds);
row_buffer_append (buf, s.str, attrs);
str_free (&s);
}
static void
app_write_gauge (struct row_buffer *buf, float ratio, int width)
{
if (ratio < 0) ratio = 0;
if (ratio > 1) ratio = 1;
// Always compute it in exactly eight times the resolution,
// because sometimes Unicode is even useful
int len_left = ratio * width * 8 + 0.5;
static const char *partials[] = { " ", "▏", "▎", "▍", "▌", "▋", "▊", "▉" };
int remainder = len_left % 8;
len_left /= 8;
const char *partial = NULL;
if (g_ctx.use_partial_boxes)
partial = partials[remainder];
else
len_left += remainder >= (int) 4;
int len_right = width - len_left;
row_buffer_space (buf, len_left, APP_ATTR (ELAPSED));
if (partial && len_right-- > 0)
row_buffer_append (buf, partial, APP_ATTR (REMAINS));
row_buffer_space (buf, len_right, APP_ATTR (REMAINS));
}
static void
app_draw_status (void)
{
if (g_ctx.state != PLAYER_STOPPED)
app_draw_song_info ();
// XXX: can we get rid of this and still make it look acceptable?
chtype a_normal = APP_ATTR (HEADER);
chtype a_highlight = APP_ATTR (HIGHLIGHT);
struct row_buffer buf;
row_buffer_init (&buf);
bool stopped = g_ctx.state == PLAYER_STOPPED;
chtype a_song_action = stopped ? a_normal : a_highlight;
row_buffer_addv (&buf, "<<", a_song_action, " ", a_normal, NULL);
if (g_ctx.state == PLAYER_PLAYING)
row_buffer_addv (&buf, "||", a_highlight, " ", a_normal, NULL);
else
row_buffer_addv (&buf, "|>", a_highlight, " ", a_normal, NULL);
row_buffer_addv (&buf, "[]", a_song_action, " ", a_normal, NULL);
row_buffer_addv (&buf, ">>", a_song_action, " ", a_normal, NULL);
if (stopped)
row_buffer_append (&buf, "Stopped", a_normal);
else
{
if (g_ctx.song_elapsed >= 0)
{
app_write_time (&buf, g_ctx.song_elapsed, a_normal);
row_buffer_append (&buf, " ", a_normal);
}
if (g_ctx.song_duration >= 1)
{
row_buffer_append (&buf, "/ ", a_normal);
app_write_time (&buf, g_ctx.song_duration, a_normal);
row_buffer_append (&buf, " ", a_normal);
}
row_buffer_append (&buf, " ", a_normal);
}
// It gets a bit complicated due to the only right-aligned item on the row
char *volume = NULL;
int remaining = COLS - buf.total_width;
if (g_ctx.volume >= 0)
{
volume = xstrdup_printf (" %3d%%", g_ctx.volume);
remaining -= strlen (volume);
}
if (!stopped && g_ctx.song_elapsed >= 0 && g_ctx.song_duration >= 1
&& remaining > 0)
{
g_ctx.gauge_offset = buf.total_width;
g_ctx.gauge_width = remaining;
app_write_gauge (&buf,
(float) g_ctx.song_elapsed / g_ctx.song_duration, remaining);
}
else
row_buffer_space (&buf, remaining, a_normal);
if (volume)
{
row_buffer_append (&buf, volume, a_normal);
free (volume);
}
g_ctx.controls_offset = g_ctx.header_height;
app_flush_header (&buf, a_normal);
}
static void
app_draw_header (void)
{
// TODO: call app_fix_view_range() if it changes from the previous value
g_ctx.header_height = 0;
g_ctx.controls_offset = -1;
g_ctx.gauge_offset = -1;
g_ctx.gauge_width = 0;
switch (g_ctx.client.state)
{
case MPD_CONNECTED:
app_draw_status ();
break;
case MPD_CONNECTING:
move (g_ctx.header_height++, 0);
app_write_line ("Connecting to MPD...", APP_ATTR (HEADER));
break;
case MPD_DISCONNECTED:
move (g_ctx.header_height++, 0);
app_write_line ("Disconnected", APP_ATTR (HEADER));
}
// XXX: can we get rid of this and still make it look acceptable?
chtype a_normal = APP_ATTR (TAB_BAR);
chtype a_active = APP_ATTR (TAB_ACTIVE);
struct row_buffer buf;
row_buffer_init (&buf);
// The help tab is disguised so that it's not too intruding
row_buffer_append (&buf, APP_TITLE,
g_ctx.active_tab == g_ctx.help_tab ? a_active : a_normal);
row_buffer_append (&buf, " ", a_normal);
LIST_FOR_EACH (struct tab, iter, g_ctx.tabs)
{
row_buffer_append (&buf, iter->name,
iter == g_ctx.active_tab ? a_active : a_normal);
}
app_flush_header (&buf, a_normal);
}
static int
app_visible_items (void)
{
// This may eventually include a header bar and/or a status bar
return MAX (0, LINES - g_ctx.header_height);
}
static void
app_draw_scrollbar (void)
{
// This assumes that we can write to the one-before-last column,
// i.e. that it's not covered by any double-wide character (and that
// ncurses comes to the right results when counting characters).
//
// We could also precompute the scrollbar and append it to each row
// as we render them, plus all the unoccupied rows.
struct tab *tab = g_ctx.active_tab;
int visible_items = app_visible_items ();
if (!g_ctx.use_partial_boxes)
{
// Apparently here we don't want the 0.5 rounding constant
int length = (float) visible_items / (int) tab->item_count
* (visible_items - 1);
int start = (float) tab->item_top / (int) tab->item_count
* (visible_items - 1);
for (int row = 0; row < visible_items; row++)
{
move (g_ctx.header_height + row, COLS - 1);
if (row < start || row > start + length + 1)
addch (' ' | APP_ATTR (SCROLLBAR));
else
addch (' ' | APP_ATTR (SCROLLBAR) | A_REVERSE);
}
return;
}
// TODO: clamp the values, make sure they follow the right order
// We subtract half a character from both the top and the bottom, hence -1
int length = (float) visible_items / (int) tab->item_count
* (visible_items - 1) * 8 + 0.5;
int start = (float) tab->item_top / (int) tab->item_count
* (visible_items - 1) * 8 + 0.5;
// Then we make sure the bar is high at least one character, hence +8
int end = start + length + 8;
int start_part = start % 8; start /= 8;
int end_part = end % 8; end /= 8;
// Even with this, the solid part must be at least one character high
static const char *partials[] = { "█", "▇", "▆", "▅", "▄", "▃", "▂", "▁" };
for (int row = 0; row < visible_items; row++)
{
chtype attrs = APP_ATTR (SCROLLBAR);
if (row > start && row <= end)
attrs ^= A_REVERSE;
const char *c = " ";
if (row == start) c = partials[start_part];
if (row == end) c = partials[end_part];
move (g_ctx.header_height + row, COLS - 1);
struct row_buffer buf;
row_buffer_init (&buf);
row_buffer_append (&buf, c, attrs);
row_buffer_flush (&buf);
row_buffer_free (&buf);
}
}
static void
app_draw_view (void)
{
move (g_ctx.header_height, 0);
clrtobot ();
struct tab *tab = g_ctx.active_tab;
bool want_scrollbar = (int) tab->item_count > app_visible_items ();
int view_width = COLS - want_scrollbar;
int to_show = MIN (LINES - g_ctx.header_height,
(int) tab->item_count - tab->item_top);
for (int row = 0; row < to_show; row++)
{
int item_index = tab->item_top + row;
int row_attrs = (item_index & 1) ? APP_ATTR (ODD) : APP_ATTR (EVEN);
if (item_index == tab->item_selected)
row_attrs = APP_ATTR (SELECTION);
struct row_buffer buf;
row_buffer_init (&buf);
tab->on_item_draw (item_index, &buf, view_width);
// Combine attributes used by the handler with the defaults.
// Avoiding attrset() because of row_buffer_flush().
for (size_t i = 0; i < buf.chars_len; i++)
{
chtype *attrs = &buf.chars[i].attrs;
if (item_index == tab->item_selected)
*attrs = (*attrs & ~(A_COLOR | A_REVERSE)) | row_attrs;
else if ((*attrs & A_COLOR) && (row_attrs & A_COLOR))
*attrs |= (row_attrs & ~A_COLOR);
else
*attrs |= row_attrs;
}
move (g_ctx.header_height + row, 0);
app_flush_buffer (&buf, view_width, row_attrs);
}
if (want_scrollbar)
app_draw_scrollbar ();
}
static void
app_on_refresh (void *user_data)
{
(void) user_data;
poller_idle_reset (&g_ctx.refresh_event);
app_draw_header ();
app_draw_view ();
refresh ();
}
// --- Actions -----------------------------------------------------------------
/// Checks what items are visible and returns if fixes were needed
static bool
app_fix_view_range (void)
{
struct tab *tab = g_ctx.active_tab;
if (tab->item_top < 0)
{
tab->item_top = 0;
app_invalidate ();
return false;
}
// If the contents are at least as long as the screen, always fill it
int max_item_top = (int) tab->item_count - app_visible_items ();
// But don't let that suggest a negative offset
max_item_top = MAX (max_item_top, 0);
if (tab->item_top > max_item_top)
{
tab->item_top = max_item_top;
app_invalidate ();
return false;
}
return true;
}
/// Scroll down (positive) or up (negative) @a n items
static bool
app_scroll (int n)
{
g_ctx.active_tab->item_top += n;
app_invalidate ();
return app_fix_view_range ();
}
static void
app_ensure_selection_visible (void)
{
struct tab *tab = g_ctx.active_tab;
if (tab->item_selected < 0)
return;
int too_high = tab->item_top - tab->item_selected;
if (too_high > 0)
app_scroll (-too_high);
int too_low = tab->item_selected
- (tab->item_top + app_visible_items () - 1);
if (too_low > 0)
app_scroll (too_low);
}
static bool
app_move_selection (int diff)
{
struct tab *tab = g_ctx.active_tab;
int fixed = tab->item_selected += diff;
fixed = MAX (fixed, 0);
fixed = MIN (fixed, (int) tab->item_count - 1);
bool result = tab->item_selected != fixed;
tab->item_selected = fixed;
app_invalidate ();
app_ensure_selection_visible ();
return result;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
app_prepend_tab (struct tab *tab)
{
LIST_PREPEND (g_ctx.tabs, tab);
app_invalidate ();
}
static void
app_switch_tab (struct tab *tab)
{
if (tab == g_ctx.active_tab)
return;
g_ctx.last_tab = g_ctx.active_tab;
g_ctx.active_tab = tab;
app_invalidate ();
}
static bool
app_goto_tab (int tab_index)
{
int i = 0;
LIST_FOR_EACH (struct tab, iter, g_ctx.tabs)
if (i++ == tab_index)
{
app_switch_tab (iter);
return true;
}
return false;
}
// --- User input handling -----------------------------------------------------
#define USER_ACTIONS(XX) \
XX( NONE, "Do nothing" ) \
\
XX( QUIT, "Quit application" ) \
XX( REDRAW, "Redraw screen" ) \
XX( HELP_TAB, "Switch to the help tab" ) \
XX( LAST_TAB, "Switch to previous tab" ) \
\
XX( MPD_PREVIOUS, "Previous song" ) \
XX( MPD_TOGGLE, "Toggle play/pause" ) \
XX( MPD_STOP, "Stop playback" ) \
XX( MPD_NEXT, "Next song" ) \
XX( MPD_VOLUME_UP, "Increase volume" ) \
XX( MPD_VOLUME_DOWN, "Decrease volume" ) \
\
XX( MPD_ADD, "Add song to playlist" ) \
XX( MPD_REPLACE, "Replace playlist with song" ) \
\
XX( CHOOSE, "Choose item" ) \
XX( DELETE, "Delete item" ) \
\
XX( SCROLL_UP, "Scroll up" ) \
XX( SCROLL_DOWN, "Scroll down" ) \
\
XX( GOTO_TOP, "Go to the top" ) \
XX( GOTO_BOTTOM, "Go to the bottom" ) \
XX( GOTO_ITEM_PREVIOUS, "Go to the previous item" ) \
XX( GOTO_ITEM_NEXT, "Go to the next item" ) \
XX( GOTO_PAGE_PREVIOUS, "Go to the previous page" ) \
XX( GOTO_PAGE_NEXT, "Go to the next page" )
enum user_action
{
#define XX(name, description) USER_ACTION_ ## name,
USER_ACTIONS (XX)
#undef XX
USER_ACTION_COUNT
};
static struct user_action_info
{
const char *name; ///< Name for user bindings
const char *description; ///< Human-readable description
}
g_user_actions[] =
{
#define XX(name, description) { #name, description },
USER_ACTIONS (XX)
#undef XX
};
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
#define MPD_SIMPLE(...) \
{ \
if (c->state != MPD_CONNECTED) \
break; \
mpd_client_send_command (c, __VA_ARGS__, NULL); \
mpd_client_add_task (c, NULL, NULL); \
mpd_client_idle (c, 0); \
}
static bool
app_process_user_action (enum user_action action)
{
// First let the tab try to handle this
struct tab *tab = g_ctx.active_tab;
if (tab->on_action && tab->on_action (action))
return true;
struct mpd_client *c = &g_ctx.client;
switch (action)
{
case USER_ACTION_QUIT:
app_quit ();
break;
case USER_ACTION_REDRAW:
clear ();
app_invalidate ();
break;
case USER_ACTION_LAST_TAB:
if (!g_ctx.last_tab)
return false;
app_switch_tab (g_ctx.last_tab);
break;
case USER_ACTION_HELP_TAB:
app_switch_tab (g_ctx.help_tab);
break;
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
case USER_ACTION_MPD_PREVIOUS:
MPD_SIMPLE ("previous")
break;
case USER_ACTION_MPD_TOGGLE:
if (g_ctx.state == PLAYER_PLAYING) MPD_SIMPLE ("pause", "1")
else if (g_ctx.state == PLAYER_PAUSED) MPD_SIMPLE ("pause", "0")
else MPD_SIMPLE ("play")
break;
case USER_ACTION_MPD_STOP:
MPD_SIMPLE ("stop")
break;
case USER_ACTION_MPD_NEXT:
MPD_SIMPLE ("next")
break;
case USER_ACTION_MPD_VOLUME_UP:
if (g_ctx.volume >= 0)
{
char *volume = xstrdup_printf ("%d", MIN (100, g_ctx.volume + 10));
MPD_SIMPLE ("setvol", volume)
free (volume);
}
break;
case USER_ACTION_MPD_VOLUME_DOWN:
if (g_ctx.volume >= 0)
{
char *volume = xstrdup_printf ("%d", MAX (0, g_ctx.volume - 10));
MPD_SIMPLE ("setvol", volume)
free (volume);
}
break;
// TODO: relative seeks
#if 0
MPD_SIMPLE (forward, "seekcur", "+10", NULL)
MPD_SIMPLE (backward, "seekcur", "-10", NULL)
#endif
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
// XXX: these should rather be parametrized
case USER_ACTION_SCROLL_UP:
app_scroll (-3);
break;
case USER_ACTION_SCROLL_DOWN:
app_scroll (3);
break;
case USER_ACTION_GOTO_TOP:
if (tab->item_count)
{
g_ctx.active_tab->item_selected = 0;
app_ensure_selection_visible ();
app_invalidate ();
}
break;
case USER_ACTION_GOTO_BOTTOM:
if (tab->item_count)
{
g_ctx.active_tab->item_selected =
(int) g_ctx.active_tab->item_count - 1;
app_ensure_selection_visible ();
app_invalidate ();
}
break;
case USER_ACTION_GOTO_ITEM_PREVIOUS:
app_move_selection (-1);
break;
case USER_ACTION_GOTO_ITEM_NEXT:
app_move_selection (1);
break;
case USER_ACTION_GOTO_PAGE_PREVIOUS:
app_scroll ((int) g_ctx.header_height - LINES);
app_move_selection ((int) g_ctx.header_height - LINES);
break;
case USER_ACTION_GOTO_PAGE_NEXT:
app_scroll (LINES - (int) g_ctx.header_height);
app_move_selection (LINES - (int) g_ctx.header_height);
break;
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
case USER_ACTION_NONE:
break;
default:
beep ();
return false;
}
return true;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static bool
app_process_left_mouse_click (int line, int column)
{
if (line == g_ctx.controls_offset)
{
// XXX: there could be a push_widget(buf, text, attrs, handler)
// function to help with this but it might not be worth it
enum user_action action = USER_ACTION_NONE;
if (column >= 0 && column <= 1) action = USER_ACTION_MPD_PREVIOUS;
if (column >= 3 && column <= 4) action = USER_ACTION_MPD_TOGGLE;
if (column >= 6 && column <= 7) action = USER_ACTION_MPD_STOP;
if (column >= 9 && column <= 10) action = USER_ACTION_MPD_NEXT;
if (action)
return app_process_user_action (action);
int gauge_offset = column - g_ctx.gauge_offset;
if (g_ctx.gauge_offset < 0
|| gauge_offset < 0 || gauge_offset >= g_ctx.gauge_width)
return false;
float position = (float) gauge_offset / g_ctx.gauge_width;
struct mpd_client *c = &g_ctx.client;
if (c->state == MPD_CONNECTED && g_ctx.song_duration >= 1)
{
char *where = xstrdup_printf ("%f", position * g_ctx.song_duration);
mpd_client_send_command (c, "seekcur", where, NULL);
free (where);
mpd_client_add_task (c, NULL, NULL);
mpd_client_idle (c, 0);
}
}
else if (line == g_ctx.header_height - 1)
{
struct tab *winner = NULL;
int indent = strlen (APP_TITLE);
if (column < indent)
{
app_switch_tab (g_ctx.help_tab);
return true;
}
for (struct tab *iter = g_ctx.tabs; !winner && iter; iter = iter->next)
{
if (column < (indent += iter->name_width))
winner = iter;
}
if (!winner)
return false;
app_switch_tab (winner);
}
else
{
struct tab *tab = g_ctx.active_tab;
int row_index = line - g_ctx.header_height;
if (row_index < 0
|| row_index >= (int) tab->item_count - tab->item_top)
return false;
// TODO: handle the scrollbar a bit better than this
int visible_items = app_visible_items ();
if ((int) tab->item_count > visible_items && column == COLS - 1)
{
tab->item_top = (float) row_index / visible_items
* (int) tab->item_count - visible_items / 2;
app_fix_view_range ();
}
else
tab->item_selected = row_index + tab->item_top;
app_invalidate ();
}
return true;
}
static bool
app_process_mouse (termo_key_t *event)
{
int line, column, button;
termo_mouse_event_t type;
termo_interpret_mouse (g_ctx.tk, event, &type, &button, &line, &column);
if (type != TERMO_MOUSE_PRESS)
return true;
if (button == 1)
return app_process_left_mouse_click (line, column);
else if (button == 4)
return app_process_user_action (USER_ACTION_SCROLL_UP);
else if (button == 5)
return app_process_user_action (USER_ACTION_SCROLL_DOWN);
return false;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static struct binding
{
const char *key; ///< Key definition
enum user_action action; ///< Action to take
}
g_default_bindings[] =
{
{ "Escape", USER_ACTION_QUIT },
{ "q", USER_ACTION_QUIT },
{ "C-l", USER_ACTION_REDRAW },
{ "M-Tab", USER_ACTION_LAST_TAB },
{ "F1", USER_ACTION_HELP_TAB },
{ "Home", USER_ACTION_GOTO_TOP },
{ "End", USER_ACTION_GOTO_BOTTOM },
{ "M-<", USER_ACTION_GOTO_TOP },
{ "M->", USER_ACTION_GOTO_BOTTOM },
{ "Up", USER_ACTION_GOTO_ITEM_PREVIOUS },
{ "Down", USER_ACTION_GOTO_ITEM_NEXT },
{ "k", USER_ACTION_GOTO_ITEM_PREVIOUS },
{ "j", USER_ACTION_GOTO_ITEM_NEXT },
{ "PageUp", USER_ACTION_GOTO_PAGE_PREVIOUS },
{ "PageDown", USER_ACTION_GOTO_PAGE_NEXT },
{ "C-p", USER_ACTION_GOTO_ITEM_PREVIOUS },
{ "C-n", USER_ACTION_GOTO_ITEM_NEXT },
{ "C-b", USER_ACTION_GOTO_PAGE_PREVIOUS },
{ "C-f", USER_ACTION_GOTO_PAGE_NEXT },
// Not sure how to set these up, they're pretty arbitrary so far
{ "Enter", USER_ACTION_CHOOSE },
{ "Delete", USER_ACTION_DELETE },
{ "a", USER_ACTION_MPD_ADD },
{ "r", USER_ACTION_MPD_REPLACE },
{ "Left", USER_ACTION_MPD_PREVIOUS },
{ "Right", USER_ACTION_MPD_NEXT },
{ "h", USER_ACTION_MPD_PREVIOUS },
{ "l", USER_ACTION_MPD_NEXT },
{ "Space", USER_ACTION_MPD_TOGGLE },
{ "C-Space", USER_ACTION_MPD_STOP },
{ "M-PageUp", USER_ACTION_MPD_VOLUME_UP },
{ "M-PageDown", USER_ACTION_MPD_VOLUME_DOWN },
};
static bool
app_process_termo_event (termo_key_t *event)
{
if (event->type == TERMO_TYPE_MOUSE)
return app_process_mouse (event);
// TODO: pre-parse the keys, order them by termo_keycmp() and binary search
for (size_t i = 0; i < N_ELEMENTS (g_default_bindings); i++)
{
struct binding *binding = &g_default_bindings[i];
termo_key_t key;
hard_assert (!*termo_strpkey_utf8 (g_ctx.tk, binding->key, &key,
TERMO_FORMAT_ALTISMETA));
if (!termo_keycmp (g_ctx.tk, event, &key))
return app_process_user_action (binding->action);
}
// TODO: parametrize actions, put this among other bindings
if (!(event->modifiers & ~TERMO_KEYMOD_ALT)
&& event->code.codepoint >= '0'
&& event->code.codepoint <= '9')
{
int n = event->code.codepoint - '0';
if (app_goto_tab ((n == 0 ? 10 : n) - 1))
return true;
}
return false;
}
// --- Current tab -------------------------------------------------------------
// TODO: remove the useless wrapper struct?
static struct
{
struct tab super; ///< Parent class
}
g_current_tab;
static void
current_tab_on_item_draw (size_t item_index, struct row_buffer *buffer,
int width)
{
// TODO: better output
struct str_map *map = playlist_get (&g_ctx.playlist, item_index);
row_buffer_append (buffer, str_map_find (map, "file"),
(int) item_index == g_ctx.song ? A_BOLD : 0);
}
static bool
current_tab_on_action (enum user_action action)
{
struct tab *self = g_ctx.active_tab;
if (self->item_selected < 0)
return false;
struct mpd_client *c = &g_ctx.client;
switch (action)
{
char *song;
case USER_ACTION_CHOOSE:
song = xstrdup_printf ("%d", self->item_selected);
MPD_SIMPLE ("play", song)
free (song);
return true;
case USER_ACTION_DELETE:
song = xstrdup_printf ("%d", self->item_selected);
MPD_SIMPLE ("delete", song)
free (song);
return true;
default:
break;
}
return false;
}
static void
current_tab_update (void)
{
g_current_tab.super.item_count = g_ctx.playlist.len;
app_invalidate ();
}
static struct tab *
current_tab_init (void)
{
struct tab *super = &g_current_tab.super;
tab_init (super, "Current");
super->on_action = current_tab_on_action;
super->on_item_draw = current_tab_on_item_draw;
return super;
}
// --- Streams -----------------------------------------------------------------
// MPD can only parse m3u8 playlists, and only when it feels like doing so
struct stream_tab_task
{
struct poller_curl_task curl; ///< Superclass
struct str data; ///< Downloaded data
bool polling; ///< Still downloading
bool replace; ///< Should playlist be replaced?
};
static bool
is_content_type (const char *content_type,
const char *expected_type, const char *expected_subtype)
{
char *type = NULL, *subtype = NULL;
bool result = http_parse_media_type (content_type, &type, &subtype, NULL)
&& !strcasecmp_ascii (type, expected_type)
&& !strcasecmp_ascii (subtype, expected_subtype);
free (type);
free (subtype);
return result;
}
static void
streams_tab_parse_playlist (const char *playlist, const char *content_type,
struct str_vector *out)
{
// We accept a lot of very broken stuff because this is the real world
struct str_vector lines;
str_vector_init (&lines);
cstr_split (playlist, "\r\n", true, &lines);
// Since this excludes '"', it should even work for XMLs (w/o entities)
const char *extract_re =
"(https?://([][a-z0-9._~:/?#@!$&'()*+,;=-]|%[a-f0-9]{2})+)";
if ((lines.len && !strcasecmp_ascii (lines.vector[0], "[playlist]"))
|| (content_type && is_content_type (content_type, "audio", "x-scpls")))
extract_re = "^File[^=]*=(.*)";
else if ((lines.len && !strcasecmp_ascii (lines.vector[0], "#EXTM3U"))
|| (content_type && is_content_type (content_type, "audio", "x-mpegurl")))
extract_re = "^([^#].*)";
regex_t *re = regex_compile (extract_re, REG_EXTENDED, NULL);
hard_assert (re != NULL);
regmatch_t groups[2];
for (size_t i = 0; i < lines.len; i++)
if (regexec (re, lines.vector[i], 2, groups, 0) != REG_NOMATCH)
{
char *target = xstrndup (lines.vector[i] + groups[1].rm_so,
groups[1].rm_eo - groups[1].rm_so);
if (utf8_validate (target, strlen (target)))
str_vector_add_owned (out, target);
else
{
str_vector_add_owned (out, latin1_to_utf8 (target));
free (target);
}
}
regex_free (re);
str_vector_free (&lines);
}
static bool
streams_tab_extract_links (struct str *data, const char *content_type,
struct str_vector *out)
{
// Since playlists are also "audio/*", this seems like a sane thing to do
for (size_t i = 0; i < data->len; i++)
{
uint8_t c = data->str[i];
if ((c < 32) & (c != '\t') & (c != '\r') & (c != '\n'))
return false;
}
streams_tab_parse_playlist (data->str, content_type, out);
return true;
}
static void
streams_tab_on_downloaded (CURLMsg *msg, struct poller_curl_task *task)
{
struct stream_tab_task *self =
CONTAINER_OF (task, struct stream_tab_task, curl);
self->polling = false;
if (msg->data.result
&& msg->data.result != CURLE_WRITE_ERROR)
{
print_error ("%s: %s", "download failed", self->curl.curl_error);
return;
}
struct mpd_client *c = &g_ctx.client;
if (c->state != MPD_CONNECTED)
return;
CURL *easy = msg->easy_handle;
CURLcode res;
long code;
char *type, *uri;
if ((res = curl_easy_getinfo (easy, CURLINFO_RESPONSE_CODE, &code))
|| (res = curl_easy_getinfo (easy, CURLINFO_CONTENT_TYPE, &type))
|| (res = curl_easy_getinfo (easy, CURLINFO_EFFECTIVE_URL, &uri)))
{
print_error ("%s: %s",
"cURL info retrieval failed", curl_easy_strerror (res));
return;
}
// cURL is not willing to parse the ICY header, the code is zero then
if (code && code != 200)
{
print_error ("%s: %ld", "unexpected HTTP response code", code);
return;
}
mpd_client_list_begin (c);
// FIXME: we also need to play it if we've been playing things already
if (self->replace)
mpd_client_send_command (c, "clear", NULL);
struct str_vector links;
str_vector_init (&links);
if (!streams_tab_extract_links (&self->data, type, &links))
str_vector_add (&links, uri);
for (size_t i = 0; i < links.len; i++)
mpd_client_send_command (c, "add", links.vector[i], NULL);
str_vector_free (&links);
mpd_client_list_end (c);
mpd_client_add_task (c, NULL, NULL);
mpd_client_idle (c, 0);
}
static size_t
write_callback (char *ptr, size_t size, size_t nmemb, void *user_data)
{
struct str *buf = user_data;
str_append_data (buf, ptr, size * nmemb);
// Invoke CURLE_WRITE_ERROR when we've received enough data for a playlist
if (buf->len >= (1 << 16))
return 0;
return size * nmemb;
}
static bool
streams_tab_process (const char *uri, bool replace, struct error **e)
{
struct poller poller;
poller_init (&poller);
struct poller_curl pc;
hard_assert (poller_curl_init (&pc, &poller, NULL));
struct stream_tab_task task;
hard_assert (poller_curl_spawn (&task.curl, NULL));
CURL *easy = task.curl.easy;
str_init (&task.data);
task.replace = replace;
bool result = false;
CURLcode res;
if ((res = curl_easy_setopt (easy, CURLOPT_FOLLOWLOCATION, 1L))
|| (res = curl_easy_setopt (easy, CURLOPT_NOPROGRESS, 1L))
// TODO: make the timeout a bit larger once we're asynchronous
|| (res = curl_easy_setopt (easy, CURLOPT_TIMEOUT, 5L))
// Not checking anything, we just want some data, any data
|| (res = curl_easy_setopt (easy, CURLOPT_SSL_VERIFYPEER, 0L))
|| (res = curl_easy_setopt (easy, CURLOPT_SSL_VERIFYHOST, 0L))
|| (res = curl_easy_setopt (easy, CURLOPT_URL, uri))
|| (res = curl_easy_setopt (easy, CURLOPT_VERBOSE, (long) g_debug_mode))
|| (res = curl_easy_setopt (easy, CURLOPT_DEBUGFUNCTION, print_curl_debug))
|| (res = curl_easy_setopt (easy, CURLOPT_WRITEDATA, &task.data))
|| (res = curl_easy_setopt (easy, CURLOPT_WRITEFUNCTION, write_callback)))
{
error_set (e, "%s: %s", "cURL setup failed", curl_easy_strerror (res));
goto error;
}
task.curl.on_done = streams_tab_on_downloaded;
hard_assert (poller_curl_add (&pc, task.curl.easy, NULL));
// TODO: don't run a subloop, run the task fully asynchronously
task.polling = true;
while (task.polling)
poller_run (&poller);
hard_assert (poller_curl_remove (&pc, task.curl.easy, NULL));
result = true;
error:
curl_easy_cleanup (task.curl.easy);
str_free (&task.data);
poller_curl_free (&pc);
poller_free (&poller);
return result;
}
static bool
streams_tab_on_action (enum user_action action)
{
struct tab *self = g_ctx.active_tab;
if (self->item_selected < 0)
return false;
// For simplicity the URL is the string following the stream name
const char *uri = 1 + strchr (g_ctx.streams.vector[self->item_selected], 0);
// TODO: show any error to the user
switch (action)
{
case USER_ACTION_MPD_REPLACE:
streams_tab_process (uri, true, NULL);
return true;
case USER_ACTION_CHOOSE:
case USER_ACTION_MPD_ADD:
streams_tab_process (uri, false, NULL);
return true;
default:
return false;
}
}
static void
streams_tab_on_item_draw (size_t item_index, struct row_buffer *buffer,
int width)
{
(void) width;
row_buffer_append (buffer, g_ctx.streams.vector[item_index], 0);
}
static struct tab *
streams_tab_init (void)
{
static struct tab super;
tab_init (&super, "Streams");
super.on_action = streams_tab_on_action;
super.on_item_draw = streams_tab_on_item_draw;
super.item_count = g_ctx.streams.len;
return &super;
}
// --- Info tab ----------------------------------------------------------------
static struct
{
struct tab super; ///< Parent class
struct str_vector keys; ///< Data keys
struct str_vector values; ///< Data values
}
g_info_tab;
static void
info_tab_on_item_draw (size_t item_index, struct row_buffer *buffer, int width)
{
(void) width;
// It looks like we could do with a generic list structure that just
// stores formatted row_buffers. Let's see for other tabs:
// - Current -- unusable, has dynamic column alignment
// - Library -- could work for the "icons"
// - Streams -- useless
// - Debug -- it'd take up considerably more space
// However so far we're only showing show key-value pairs.
row_buffer_addv (buffer,
g_info_tab.keys.vector[item_index], A_BOLD, ":", A_BOLD, NULL);
row_buffer_space (buffer, 8 - buffer->total_width, 0);
row_buffer_append (buffer, g_info_tab.values.vector[item_index], 0);
}
static void
info_tab_add (struct str_map *map, const char *field)
{
const char *value = str_map_find (map, field);
if (!value) value = "";
str_vector_add (&g_info_tab.keys, field);
str_vector_add (&g_info_tab.values, value);
g_info_tab.super.item_count++;
}
static void
info_tab_update (void)
{
str_vector_reset (&g_info_tab.keys);
str_vector_reset (&g_info_tab.values);
g_info_tab.super.item_count = 0;
struct str_map *map;
if ((map = playlist_get (&g_ctx.playlist, g_ctx.song)))
{
info_tab_add (map, "Title");
info_tab_add (map, "Artist");
info_tab_add (map, "Album");
info_tab_add (map, "Track");
info_tab_add (map, "Genre");
// Yes, it is "file", but this is also for display
info_tab_add (map, "File");
}
}
static struct tab *
info_tab_init (void)
{
str_vector_init (&g_info_tab.keys);
str_vector_init (&g_info_tab.values);
struct tab *super = &g_info_tab.super;
tab_init (super, "Info");
super->on_item_draw = info_tab_on_item_draw;
return super;
}
// --- Help tab ----------------------------------------------------------------
static void
help_tab_on_item_draw (size_t item_index, struct row_buffer *buffer, int width)
{
(void) width;
// TODO: group them the other way around for clarity
hard_assert (item_index < N_ELEMENTS (g_default_bindings));
struct binding *binding = &g_default_bindings[item_index];
char *text = xstrdup_printf ("%-12s %s",
binding->key, g_user_actions[binding->action].description);
row_buffer_append (buffer, text, 0);
free (text);
}
static struct tab *
help_tab_init (void)
{
static struct tab super;
tab_init (&super, "Help");
super.on_item_draw = help_tab_on_item_draw;
super.item_count = N_ELEMENTS (g_default_bindings);
return &super;
}
// --- Debug tab ---------------------------------------------------------------
struct debug_item
{
char *text; ///< Logged line
int64_t timestamp; ///< Timestamp
chtype attrs; ///< Line attributes
};
static struct
{
struct tab super; ///< Parent class
struct debug_item *items; ///< Items
size_t items_alloc; ///< How many items are allocated
bool active; ///< The tab is present
}
g_debug_tab;
static void
debug_tab_on_item_draw (size_t item_index, struct row_buffer *buffer, int width)
{
hard_assert (item_index <= g_debug_tab.super.item_count);
struct debug_item *item = &g_debug_tab.items[item_index];
char buf[16];
struct tm tm;
time_t when = item->timestamp / 1000;
strftime (buf, sizeof buf, "%T", localtime_r (&when, &tm));
char *prefix = xstrdup_printf
("%s.%03d", buf, (int) (item->timestamp % 1000));
row_buffer_append (buffer, prefix, 0);
free (prefix);
row_buffer_append (buffer, " ", item->attrs);
row_buffer_append (buffer, item->text, item->attrs);
// We override the formatting including colors -- do it for the whole line
row_buffer_align (buffer, width, item->attrs);
}
static void
debug_tab_push (const char *message, chtype attrs)
{
// TODO: uh... aren't we rather going to write our own abstraction?
if (g_debug_tab.items_alloc <= g_debug_tab.super.item_count)
{
g_debug_tab.items = xreallocarray (g_debug_tab.items,
sizeof *g_debug_tab.items, (g_debug_tab.items_alloc <<= 1));
}
// TODO: there should be a better, more efficient mechanism for this
struct debug_item *item =
&g_debug_tab.items[g_debug_tab.super.item_count++];
item->text = xstrdup (message);
item->attrs = attrs;
item->timestamp = clock_msec (CLOCK_REALTIME);
app_invalidate ();
}
static struct tab *
debug_tab_init (void)
{
g_debug_tab.items = xcalloc
((g_debug_tab.items_alloc = 16), sizeof *g_debug_tab.items);
g_debug_tab.active = true;
struct tab *super = &g_debug_tab.super;
tab_init (super, "Debug");
super->on_item_draw = debug_tab_on_item_draw;
return super;
}
// --- MPD interface -----------------------------------------------------------
static void
mpd_update_playback_state (void)
{
struct str_map *map = &g_ctx.playback_info;
const char *state;
g_ctx.state = PLAYER_PLAYING;
if ((state = str_map_find (map, "state")))
{
if (!strcmp (state, "stop"))
g_ctx.state = PLAYER_STOPPED;
if (!strcmp (state, "pause"))
g_ctx.state = PLAYER_PAUSED;
}
// The contents of these values overlap and we try to get what we can
// FIXME: don't change the values, for fuck's sake
char *time = str_map_find (map, "time");
char *duration = str_map_find (map, "duration");
char *elapsed = str_map_find (map, "elapsed");
if (time)
{
char *colon = strchr (time, ':');
if (colon)
{
*colon = '\0';
duration = colon + 1;
}
}
unsigned long n;
if (time && xstrtoul (&n, time, 10)) g_ctx.song_elapsed = n;
if (duration && xstrtoul (&n, duration, 10)) g_ctx.song_duration = n;
// We could also just poll the server each half a second but let's not
int msec_past_second = 0;
char *period;
if (elapsed && (period = strchr (elapsed, '.')))
{
// For some reason this is much more precise
*period++ = '\0';
if (xstrtoul (&n, elapsed, 10))
g_ctx.song_elapsed = n;
if (xstrtoul (&n, period, 10))
msec_past_second = n;
}
if (g_ctx.state == PLAYER_PLAYING)
{
poller_timer_set (&g_ctx.elapsed_event, 1000 - msec_past_second);
g_ctx.elapsed_since = clock_msec (CLOCK_BEST) - msec_past_second;
}
// The server sends -1 when nothing is being played right now
if (xstrtoul_map (map, "volume", &n)) g_ctx.volume = n;
if (xstrtoul_map (map, "playlist", &n)) g_ctx.playlist_version = n;
if (xstrtoul_map (map, "song", &n)) g_ctx.song = n;
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
mpd_init_response_map (struct str_map *map)
{
str_map_init (map);
map->key_xfrm = tolower_ascii_strxfrm;
map->free = free;
}
static void
mpd_process_info_chunk (struct str_map *map, char *file)
{
unsigned long n;
if (!file)
{
if (xstrtoul_map (map, "playlistlength", &n))
playlist_resize (&g_ctx.playlist, n);
g_ctx.playback_info = *map;
}
else if (!xstrtoul_map (map, "pos", &n)
|| !playlist_set (&g_ctx.playlist, n, map))
str_map_free (map);
mpd_init_response_map (map);
}
static void
mpd_process_info (const struct str_vector *data)
{
struct str_map map;
mpd_init_response_map (&map);
// First there's the status, followed by playlist items chunked by "file"
char *key, *value, *file = NULL;
for (size_t i = 0; i < data->len; i++)
{
if (!(key = mpd_client_parse_kv (data->vector[i], &value)))
{
print_debug ("%s: %s", "erroneous MPD output", data->vector[i]);
continue;
}
if (!strcasecmp_ascii (key, "file"))
{
mpd_process_info_chunk (&map, file);
file = value;
}
str_map_set (&map, key, xstrdup (value));
}
mpd_process_info_chunk (&map, file);
str_map_free (&map);
}
static void
mpd_on_info_response (const struct mpd_response *response,
const struct str_vector *data, void *user_data)
{
(void) user_data;
// TODO: do this also on disconnect
g_ctx.song = -1;
g_ctx.song_elapsed = -1;
g_ctx.song_duration = -1;
g_ctx.volume = -1;
str_map_free (&g_ctx.playback_info);
poller_timer_reset (&g_ctx.elapsed_event);
g_ctx.playlist_version = 0;
// TODO: preset an error player state?
if (response->success)
mpd_process_info (data);
else
{
print_debug ("%s: %s",
"retrieving MPD info failed", response->message_text);
}
mpd_update_playback_state ();
current_tab_update ();
info_tab_update ();
app_invalidate ();
}
static void
mpd_on_tick (void *user_data)
{
(void) user_data;
int64_t diff_msec = clock_msec (CLOCK_BEST) - g_ctx.elapsed_since;
int elapsed_sec = diff_msec / 1000;
int elapsed_msec = diff_msec % 1000;
g_ctx.song_elapsed += elapsed_sec;
g_ctx.elapsed_since += elapsed_sec * 1000;
poller_timer_set (&g_ctx.elapsed_event, 1000 - elapsed_msec);
app_invalidate ();
}
static void
mpd_request_info (void)
{
struct mpd_client *c = &g_ctx.client;
mpd_client_list_begin (c);
mpd_client_send_command (c, "status", NULL);
char *last_version = xstrdup_printf ("%" PRIu32, g_ctx.playlist_version);
mpd_client_send_command (c, "plchanges", last_version, NULL);
free (last_version);
mpd_client_list_end (c);
mpd_client_add_task (c, mpd_on_info_response, NULL);
mpd_client_idle (c, 0);
}
static void
mpd_on_events (unsigned subsystems, void *user_data)
{
(void) user_data;
struct mpd_client *c = &g_ctx.client;
if (subsystems & (MPD_SUBSYSTEM_PLAYER
| MPD_SUBSYSTEM_PLAYLIST | MPD_SUBSYSTEM_MIXER))
mpd_request_info ();
else
mpd_client_idle (c, 0);
}
// - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
static void
mpd_queue_reconnect (void)
{
poller_timer_set (&g_ctx.connect_event, 5 * 1000);
}
static void
mpd_on_password_response (const struct mpd_response *response,
const struct str_vector *data, void *user_data)
{
(void) data;
(void) user_data;
struct mpd_client *c = &g_ctx.client;
if (response->success)
mpd_request_info ();
else
{
print_error ("%s: %s",
"couldn't authenticate to MPD", response->message_text);
mpd_client_send_command (c, "close", NULL);
}
}
static void
mpd_on_connected (void *user_data)
{
(void) user_data;
struct mpd_client *c = &g_ctx.client;
const char *password =
get_config_string (g_ctx.config.root, "settings.password");
if (password)
{
mpd_client_send_command (c, "password", password, NULL);
mpd_client_add_task (c, mpd_on_password_response, NULL);
}
else
mpd_request_info ();
}
static void
mpd_on_failure (void *user_data)
{
(void) user_data;
// This is also triggered both by a failed connect and a clean disconnect
print_error ("connection to MPD failed");
mpd_queue_reconnect ();
}
static void
mpd_on_io_hook (void *user_data, bool outgoing, const char *line)
{
(void) user_data;
struct str s;
str_init (&s);
if (outgoing)
{
str_append_printf (&s, "<< %s", line);
debug_tab_push (s.str, APP_ATTR (OUTGOING));
}
else
{
str_append_printf (&s, ">> %s", line);
debug_tab_push (s.str, APP_ATTR (INCOMING));
}
str_free (&s);
}
static void
app_on_reconnect (void *user_data)
{
(void) user_data;
struct mpd_client *c = &g_ctx.client;
c->on_failure = mpd_on_failure;
c->on_connected = mpd_on_connected;
c->on_event = mpd_on_events;
if (g_debug_mode)
c->on_io_hook = mpd_on_io_hook;
// We accept hostname/IPv4/IPv6 in pseudo-URL format, as well as sockets
char *address = xstrdup (get_config_string (g_ctx.config.root,
"settings.address")), *p = address, *host = address, *port = "6600";
// Unwrap IPv6 addresses in format_host_port_pair() format
char *right_bracket = strchr (p, ']');
if (p[0] == '[' && right_bracket)
{
*right_bracket = '\0';
host = p + 1;
p = right_bracket + 1;
}
char *colon = strchr (p, ':');
if (colon)
{
*colon = '\0';
port = colon + 1;
}
struct error *e = NULL;
if (!mpd_client_connect (c, host, port, &e))
{
print_error ("%s: %s", "cannot connect to MPD", e->message);
error_free (e);
mpd_queue_reconnect ();
}
free (address);
}
// --- Signals -----------------------------------------------------------------
static int g_signal_pipe[2]; ///< A pipe used to signal... signals
/// Program termination has been requested by a signal
static volatile sig_atomic_t g_termination_requested;
/// The window has changed in size
static volatile sig_atomic_t g_winch_received;
static void
signals_postpone_handling (char id)
{
int original_errno = errno;
if (write (g_signal_pipe[1], &id, 1) == -1)
soft_assert (errno == EAGAIN);
errno = original_errno;
}
static void
signals_superhandler (int signum)
{
switch (signum)
{
case SIGWINCH:
g_winch_received = true;
signals_postpone_handling ('w');
break;
case SIGINT:
case SIGTERM:
g_termination_requested = true;
signals_postpone_handling ('t');
break;
default:
hard_assert (!"unhandled signal");
}
}
static void
signals_setup_handlers (void)
{
if (pipe (g_signal_pipe) == -1)
exit_fatal ("%s: %s", "pipe", strerror (errno));
set_cloexec (g_signal_pipe[0]);
set_cloexec (g_signal_pipe[1]);
// So that the pipe cannot overflow; it would make write() block within
// the signal handler, which is something we really don't want to happen.
// The same holds true for read().
set_blocking (g_signal_pipe[0], false);
set_blocking (g_signal_pipe[1], false);
signal (SIGPIPE, SIG_IGN);
struct sigaction sa;
sa.sa_flags = SA_RESTART;
sa.sa_handler = signals_superhandler;
sigemptyset (&sa.sa_mask);
if (sigaction (SIGWINCH, &sa, NULL) == -1
|| sigaction (SIGINT, &sa, NULL) == -1
|| sigaction (SIGTERM, &sa, NULL) == -1)
exit_fatal ("sigaction: %s", strerror (errno));
}
// --- Initialisation, event handling ------------------------------------------
static void
app_on_tty_readable (const struct pollfd *fd, void *user_data)
{
(void) user_data;
if (fd->revents & ~(POLLIN | POLLHUP | POLLERR))
print_debug ("fd %d: unexpected revents: %d", fd->fd, fd->revents);
poller_timer_reset (&g_ctx.tk_timer);
termo_advisereadable (g_ctx.tk);
termo_key_t event;
termo_result_t res;
while ((res = termo_getkey (g_ctx.tk, &event)) == TERMO_RES_KEY)
if (!app_process_termo_event (&event))
beep ();
if (res == TERMO_RES_AGAIN)
poller_timer_set (&g_ctx.tk_timer, termo_get_waittime (g_ctx.tk));
else if (res == TERMO_RES_ERROR || res == TERMO_RES_EOF)
{
app_quit ();
return;
}
}
static void
app_on_key_timer (void *user_data)
{
(void) user_data;
termo_key_t event;
if (termo_getkey_force (g_ctx.tk, &event) == TERMO_RES_KEY)
if (!app_process_termo_event (&event))
app_quit ();
}
static void
app_on_signal_pipe_readable (const struct pollfd *fd, void *user_data)
{
(void) user_data;
char id = 0;
(void) read (fd->fd, &id, 1);
if (g_termination_requested && !g_ctx.quitting)
app_quit ();
if (g_winch_received)
{
update_curses_terminal_size ();
app_fix_view_range ();
app_invalidate ();
g_winch_received = false;
}
}
static void
app_log_handler (void *user_data, const char *quote, const char *fmt,
va_list ap)
{
// We certainly don't want to end up in a possibly infinite recursion
static bool in_processing;
if (in_processing)
return;
in_processing = true;
struct str message;
str_init (&message);
str_append (&message, quote);
str_append_vprintf (&message, fmt, ap);
// If the standard error output isn't redirected, try our best at showing
// the message to the user; it will probably get overdrawn soon
// TODO: remember it somewhere so that it stays shown for a while
if (!isatty (STDERR_FILENO))
fprintf (stderr, "%s\n", message.str);
else if (g_debug_tab.active)
{
debug_tab_push (message.str,
user_data == NULL ? 0 : g_ctx.attrs[(intptr_t) user_data].attrs);
}
else
{
// TODO: remember the position and restore it
move (LINES - 1, 0);
app_write_line (message.str, A_REVERSE);
}
str_free (&message);
in_processing = false;
}
static void
app_init_poller_events (void)
{
poller_fd_init (&g_ctx.signal_event, &g_ctx.poller, g_signal_pipe[0]);
g_ctx.signal_event.dispatcher = app_on_signal_pipe_readable;
poller_fd_set (&g_ctx.signal_event, POLLIN);
poller_fd_init (&g_ctx.tty_event, &g_ctx.poller, STDIN_FILENO);
g_ctx.tty_event.dispatcher = app_on_tty_readable;
poller_fd_set (&g_ctx.tty_event, POLLIN);
poller_timer_init (&g_ctx.tk_timer, &g_ctx.poller);
g_ctx.tk_timer.dispatcher = app_on_key_timer;
poller_timer_init (&g_ctx.connect_event, &g_ctx.poller);
g_ctx.connect_event.dispatcher = app_on_reconnect;
poller_timer_set (&g_ctx.connect_event, 0);
poller_timer_init (&g_ctx.elapsed_event, &g_ctx.poller);
g_ctx.elapsed_event.dispatcher = mpd_on_tick;
poller_idle_init (&g_ctx.refresh_event, &g_ctx.poller);
g_ctx.refresh_event.dispatcher = app_on_refresh;
}
int
main (int argc, char *argv[])
{
static const struct opt opts[] =
{
{ 'd', "debug", NULL, 0, "run in debug mode" },
{ 'h', "help", NULL, 0, "display this help and exit" },
{ 'V', "version", NULL, 0, "output version information and exit" },
{ 0, NULL, NULL, 0, NULL }
};
struct opt_handler oh;
opt_handler_init (&oh, argc, argv, opts, NULL, "MPD client.");
int c;
while ((c = opt_handler_get (&oh)) != -1)
switch (c)
{
case 'd':
g_debug_mode = true;
break;
case 'h':
opt_handler_usage (&oh, stdout);
exit (EXIT_SUCCESS);
case 'V':
printf (PROGRAM_NAME " " PROGRAM_VERSION "\n");
exit (EXIT_SUCCESS);
default:
print_error ("wrong options");
opt_handler_usage (&oh, stderr);
exit (EXIT_FAILURE);
}
argc -= optind;
argv += optind;
if (argc)
{
opt_handler_usage (&oh, stderr);
exit (EXIT_FAILURE);
}
opt_handler_free (&oh);
// We only need to convert to and from the terminal encoding
if (!setlocale (LC_CTYPE, ""))
print_warning ("failed to set the locale");
app_init_context ();
app_load_configuration ();
app_init_terminal ();
signals_setup_handlers ();
app_init_poller_events ();
if (g_debug_mode)
app_prepend_tab (debug_tab_init ());
// Redirect all messages from liberty to a special tab so they're not lost
g_log_message_real = app_log_handler;
app_prepend_tab (info_tab_init ());
if (g_ctx.streams.len)
app_prepend_tab (streams_tab_init ());
app_prepend_tab (current_tab_init ());
app_switch_tab ((g_ctx.help_tab = help_tab_init ()));
g_ctx.polling = true;
while (g_ctx.polling)
poller_run (&g_ctx.poller);
endwin ();
g_log_message_real = log_message_stdio;
app_free_context ();
return 0;
}