#include #include /* for isdigit() and friends */ #include #include /* for verify_area */ #include /* for -EBUSY */ #include /* for check_region, request_region */ #include #include /* for loops_per_sec */ #include #include #include /* for copy_from_user */ #include #include #include #include "spk_priv.h" #include "speakup.h" #include "serialio.h" #define MAXSYNTHS 16 /* Max number of synths in array. */ static struct spk_synth *synths[MAXSYNTHS + 1]; struct spk_synth *synth; char spk_pitch_buff[32] = ""; static int module_status; bool spk_quiet_boot; struct speakup_info_t speakup_info = { /* * This spinlock is used to protect the entire speakup machinery, and * must be taken at each kernel->speakup transition and released at * each corresponding speakup->kernel transition. * * The progression thread only interferes with the speakup machinery * through the synth buffer, so only needs to take the lock * while tinkering with the buffer. * * We use spin_lock/trylock_irqsave and spin_unlock_irqrestore with this * spinlock because speakup needs to disable the keyboard IRQ. */ .spinlock = __SPIN_LOCK_UNLOCKED(speakup_info.spinlock), .flushing = 0, }; EXPORT_SYMBOL_GPL(speakup_info); static int do_synth_init(struct spk_synth *in_synth); int spk_serial_synth_probe(struct spk_synth *synth) { const struct old_serial_port *ser; int failed = 0; if ((synth->ser >= SPK_LO_TTY) && (synth->ser <= SPK_HI_TTY)) { ser = spk_serial_init(synth->ser); if (ser == NULL) { failed = -1; } else { outb_p(0, ser->port); mdelay(1); outb_p('\r', ser->port); } } else { failed = -1; pr_warn("ttyS%i is an invalid port\n", synth->ser); } if (failed) { pr_info("%s: not found\n", synth->long_name); return -ENODEV; } pr_info("%s: ttyS%i, Driver Version %s\n", synth->long_name, synth->ser, synth->version); synth->alive = 1; return 0; } EXPORT_SYMBOL_GPL(spk_serial_synth_probe); /* Main loop of the progression thread: keep eating from the buffer * and push to the serial port, waiting as needed * * For devices that have a "full" notification mechanism, the driver can * adapt the loop the way they prefer. */ void spk_do_catch_up(struct spk_synth *synth) { u_char ch; unsigned long flags; unsigned long jiff_max; struct var_t *delay_time; struct var_t *full_time; struct var_t *jiffy_delta; int jiffy_delta_val; int delay_time_val; int full_time_val; jiffy_delta = spk_get_var(JIFFY); full_time = spk_get_var(FULL); delay_time = spk_get_var(DELAY); spin_lock_irqsave(&speakup_info.spinlock, flags); jiffy_delta_val = jiffy_delta->u.n.value; spin_unlock_irqrestore(&speakup_info.spinlock, flags); jiff_max = jiffies + jiffy_delta_val; while (!kthread_should_stop()) { spin_lock_irqsave(&speakup_info.spinlock, flags); if (speakup_info.flushing) { speakup_info.flushing = 0; spin_unlock_irqrestore(&speakup_info.spinlock, flags); synth->flush(synth); continue; } if (synth_buffer_empty()) { spin_unlock_irqrestore(&speakup_info.spinlock, flags); break; } ch = synth_buffer_peek(); set_current_state(TASK_INTERRUPTIBLE); full_time_val = full_time->u.n.value; spin_unlock_irqrestore(&speakup_info.spinlock, flags); if (ch == '\n') ch = synth->procspeech; if (!spk_serial_out(ch)) { schedule_timeout(msecs_to_jiffies(full_time_val)); continue; } if (time_after_eq(jiffies, jiff_max) && (ch == SPACE)) { spin_lock_irqsave(&speakup_info.spinlock, flags); jiffy_delta_val = jiffy_delta->u.n.value; delay_time_val = delay_time->u.n.value; full_time_val = full_time->u.n.value; spin_unlock_irqrestore(&speakup_info.spinlock, flags); if (spk_serial_out(synth->procspeech)) schedule_timeout( msecs_to_jiffies(delay_time_val)); else schedule_timeout( msecs_to_jiffies(full_time_val)); jiff_max = jiffies + jiffy_delta_val; } set_current_state(TASK_RUNNING); spin_lock_irqsave(&speakup_info.spinlock, flags); synth_buffer_getc(); spin_unlock_irqrestore(&speakup_info.spinlock, flags); } spk_serial_out(synth->procspeech); } EXPORT_SYMBOL_GPL(spk_do_catch_up); const char *spk_synth_immediate(struct spk_synth *synth, const char *buff) { u_char ch; while ((ch = *buff)) { if (ch == '\n') ch = synth->procspeech; if (spk_wait_for_xmitr()) outb(ch, speakup_info.port_tts); else return buff; buff++; } return NULL; } EXPORT_SYMBOL_GPL(spk_synth_immediate); void spk_synth_flush(struct spk_synth *synth) { spk_serial_out(synth->clear); } EXPORT_SYMBOL_GPL(spk_synth_flush); int spk_synth_is_alive_nop(struct spk_synth *synth) { synth->alive = 1; return 1; } EXPORT_SYMBOL_GPL(spk_synth_is_alive_nop); int spk_synth_is_alive_restart(struct spk_synth *synth) { if (synth->alive) return 1; if (spk_wait_for_xmitr() > 0) { /* restart */ synth->alive = 1; synth_printf("%s", synth->init); return 2; /* reenabled */ } pr_warn("%s: can't restart synth\n", synth->long_name); return 0; } EXPORT_SYMBOL_GPL(spk_synth_is_alive_restart); static void thread_wake_up(u_long data) { wake_up_interruptible_all(&speakup_event); } static DEFINE_TIMER(thread_timer, thread_wake_up, 0, 0); void synth_start(void) { struct var_t *trigger_time; if (!synth->alive) { synth_buffer_clear(); return; } trigger_time = spk_get_var(TRIGGER); if (!timer_pending(&thread_timer)) mod_timer(&thread_timer, jiffies + msecs_to_jiffies(trigger_time->u.n.value)); } void spk_do_flush(void) { if (!synth) return; speakup_info.flushing = 1; synth_buffer_clear(); if (synth->alive) { if (spk_pitch_shift) { synth_printf("%s", spk_pitch_buff); spk_pitch_shift = 0; } } wake_up_interruptible_all(&speakup_event); wake_up_process(speakup_task); } void synth_write(const char *buf, size_t count) { while (count--) synth_buffer_add(*buf++); synth_start(); } void synth_printf(const char *fmt, ...) { va_list args; unsigned char buf[160], *p; int r; va_start(args, fmt); r = vsnprintf(buf, sizeof(buf), fmt, args); va_end(args); if (r > sizeof(buf) - 1) r = sizeof(buf) - 1; p = buf; while (r--) synth_buffer_add(*p++); synth_start(); } EXPORT_SYMBOL_GPL(synth_printf); static int index_count; static int sentence_count; void spk_reset_index_count(int sc) { static int first = 1; if (first) first = 0; else synth->get_index(); index_count = 0; sentence_count = sc; } int synth_supports_indexing(void) { if (synth->get_index != NULL) return 1; return 0; } void synth_insert_next_index(int sent_num) { int out; if (synth->alive) { if (sent_num == 0) { synth->indexing.currindex++; index_count++; if (synth->indexing.currindex > synth->indexing.highindex) synth->indexing.currindex = synth->indexing.lowindex; } out = synth->indexing.currindex * 10 + sent_num; synth_printf(synth->indexing.command, out, out); } } void spk_get_index_count(int *linecount, int *sentcount) { int ind = synth->get_index(); if (ind) { sentence_count = ind % 10; if ((ind / 10) <= synth->indexing.currindex) index_count = synth->indexing.currindex-(ind/10); else index_count = synth->indexing.currindex -synth->indexing.lowindex + synth->indexing.highindex-(ind/10)+1; } *sentcount = sentence_count; *linecount = index_count; } static struct resource synth_res; int synth_request_region(unsigned long start, unsigned long n) { struct resource *parent = &ioport_resource; memset(&synth_res, 0, sizeof(synth_res)); synth_res.name = synth->name; synth_res.start = start; synth_res.end = start + n - 1; synth_res.flags = IORESOURCE_BUSY; return request_resource(parent, &synth_res); } EXPORT_SYMBOL_GPL(synth_request_region); int synth_release_region(unsigned long start, unsigned long n) { return release_resource(&synth_res); } EXPORT_SYMBOL_GPL(synth_release_region); struct var_t synth_time_vars[] = { { DELAY, .u.n = {NULL, 100, 100, 2000, 0, 0, NULL } }, { TRIGGER, .u.n = {NULL, 20, 10, 2000, 0, 0, NULL } }, { JIFFY, .u.n = {NULL, 50, 20, 200, 0, 0, NULL } }, { FULL, .u.n = {NULL, 400, 200, 60000, 0, 0, NULL } }, V_LAST_VAR }; /* called by: speakup_init() */ int synth_init(char *synth_name) { int i; int ret = 0; struct spk_synth *synth = NULL; if (synth_name == NULL) return 0; if (strcmp(synth_name, "none") == 0) { mutex_lock(&spk_mutex); synth_release(); mutex_unlock(&spk_mutex); return 0; } mutex_lock(&spk_mutex); /* First, check if we already have it loaded. */ for (i = 0; i < MAXSYNTHS && synths[i] != NULL; i++) if (strcmp(synths[i]->name, synth_name) == 0) synth = synths[i]; /* If we got one, initialize it now. */ if (synth) ret = do_synth_init(synth); else ret = -ENODEV; mutex_unlock(&spk_mutex); return ret; } /* called by: synth_add() */ static int do_synth_init(struct spk_synth *in_synth) { struct var_t *var; synth_release(); if (in_synth->checkval != SYNTH_CHECK) return -EINVAL; synth = in_synth; synth->alive = 0; pr_warn("synth probe\n"); if (synth->probe(synth) < 0) { pr_warn("%s: device probe failed\n", in_synth->name); synth = NULL; return -ENODEV; } synth_time_vars[0].u.n.value = synth_time_vars[0].u.n.default_val = synth->delay; synth_time_vars[1].u.n.value = synth_time_vars[1].u.n.default_val = synth->trigger; synth_time_vars[2].u.n.value = synth_time_vars[2].u.n.default_val = synth->jiffies; synth_time_vars[3].u.n.value = synth_time_vars[3].u.n.default_val = synth->full; synth_printf("%s", synth->init); for (var = synth->vars; (var->var_id >= 0) && (var->var_id < MAXVARS); var++) speakup_register_var(var); if (!spk_quiet_boot) synth_printf("%s found\n", synth->long_name); if (synth->attributes.name && sysfs_create_group(speakup_kobj, &(synth->attributes)) < 0) return -ENOMEM; synth_flags = synth->flags; wake_up_interruptible_all(&speakup_event); if (speakup_task) wake_up_process(speakup_task); return 0; } void synth_release(void) { struct var_t *var; unsigned long flags; if (synth == NULL) return; spin_lock_irqsave(&speakup_info.spinlock, flags); pr_info("releasing synth %s\n", synth->name); synth->alive = 0; del_timer(&thread_timer); spin_unlock_irqrestore(&speakup_info.spinlock, flags); if (synth->attributes.name) sysfs_remove_group(speakup_kobj, &(synth->attributes)); for (var = synth->vars; var->var_id != MAXVARS; var++) speakup_unregister_var(var->var_id); spk_stop_serial_interrupt(); synth->release(); synth = NULL; } /* called by: all_driver_init() */ int synth_add(struct spk_synth *in_synth) { int i; int status = 0; mutex_lock(&spk_mutex); for (i = 0; i < MAXSYNTHS && synths[i] != NULL; i++) /* synth_remove() is responsible for rotating the array down */ if (in_synth == synths[i]) { mutex_unlock(&spk_mutex); return 0; } if (i == MAXSYNTHS) { pr_warn("Error: attempting to add a synth past end of array\n"); mutex_unlock(&spk_mutex); return -1; } synths[i++] = in_synth; synths[i] = NULL; if (in_synth->startup) status = do_synth_init(in_synth); mutex_unlock(&spk_mutex); return status; } EXPORT_SYMBOL_GPL(synth_add); void synth_remove(struct spk_synth *in_synth) { int i; mutex_lock(&spk_mutex); if (synth == in_synth) synth_release(); for (i = 0; synths[i] != NULL; i++) { if (in_synth == synths[i]) break; } for ( ; synths[i] != NULL; i++) /* compress table */ synths[i] = synths[i+1]; module_status = 0; mutex_unlock(&spk_mutex); } EXPORT_SYMBOL_GPL(synth_remove); short spk_punc_masks[] = { 0, SOME, MOST, PUNC, PUNC|B_SYM };