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/***
This file is part of PulseAudio.
Copyright 2014 David Henningsson, Canonical Ltd.
PulseAudio is free software; you can redistribute it and/or modify
it under the terms of the GNU Lesser General Public License as
published by the Free Software Foundation; either version 2.1 of the
License, or (at your option) any later version.
PulseAudio is distributed in the hope that it will be useful, but
WITHOUT ANY WARRANTY; without even the implied warranty of
MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
Lesser General Public License for more details.
You should have received a copy of the GNU Lesser General Public
License along with PulseAudio; if not, write to the Free Software
Foundation, Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307
USA.
***/
#ifdef HAVE_CONFIG_H
#include <config.h>
#endif
#include "srbchannel.h"
#include <pulsecore/atomic.h>
#include <pulse/xmalloc.h>
/* #define DEBUG_SRBCHANNEL */
/* This ringbuffer might be useful in other contexts too, but
* right now it's only used inside the srbchannel, so let's keep it here
* for the time being. */
typedef struct pa_ringbuffer pa_ringbuffer;
struct pa_ringbuffer {
pa_atomic_t *count; /* amount of data in the buffer */
int capacity;
uint8_t *memory;
int readindex, writeindex;
};
static void *pa_ringbuffer_peek(pa_ringbuffer *r, int *count) {
int c = pa_atomic_load(r->count);
if (r->readindex + c > r->capacity)
*count = r->capacity - r->readindex;
else
*count = c;
return r->memory + r->readindex;
}
/* Returns true only if the buffer was completely full before the drop. */
static bool pa_ringbuffer_drop(pa_ringbuffer *r, int count) {
bool b = pa_atomic_sub(r->count, count) >= r->capacity;
r->readindex += count;
r->readindex %= r->capacity;
return b;
}
static void *pa_ringbuffer_begin_write(pa_ringbuffer *r, int *count) {
int c = pa_atomic_load(r->count);
*count = PA_MIN(r->capacity - r->writeindex, r->capacity - c);
return r->memory + r->writeindex;
}
static void pa_ringbuffer_end_write(pa_ringbuffer *r, int count) {
pa_atomic_add(r->count, count);
r->writeindex += count;
r->writeindex %= r->capacity;
}
struct pa_srbchannel {
pa_ringbuffer rb_read, rb_write;
pa_fdsem *sem_read, *sem_write;
pa_memblock *memblock;
void *cb_userdata;
pa_srbchannel_cb_t callback;
pa_io_event *read_event;
pa_defer_event *defer_event;
pa_mainloop_api *mainloop;
};
/* We always listen to sem_read, and always signal on sem_write.
*
* This means we signal the same semaphore for two scenarios:
* 1) We have written something to our send buffer, and want the other
* side to read it
* 2) We have read something from our receive buffer that was previously
* completely full, and want the other side to continue writing
*/
size_t pa_srbchannel_write(pa_srbchannel *sr, const void *data, size_t l) {
size_t written = 0;
while (l > 0) {
int towrite;
void *ptr = pa_ringbuffer_begin_write(&sr->rb_write, &towrite);
if ((size_t) towrite > l)
towrite = l;
if (towrite == 0) {
#ifdef DEBUG_SRBCHANNEL
pa_log("srbchannel output buffer full");
#endif
break;
}
memcpy(ptr, data, towrite);
pa_ringbuffer_end_write(&sr->rb_write, towrite);
written += towrite;
data = (uint8_t*) data + towrite;
l -= towrite;
}
#ifdef DEBUG_SRBCHANNEL
pa_log("Wrote %d bytes to srbchannel, signalling fdsem", (int) written);
#endif
pa_fdsem_post(sr->sem_write);
return written;
}
size_t pa_srbchannel_read(pa_srbchannel *sr, void *data, size_t l) {
size_t isread = 0;
while (l > 0) {
int toread;
void *ptr = pa_ringbuffer_peek(&sr->rb_read, &toread);
if ((size_t) toread > l)
toread = l;
if (toread == 0)
break;
memcpy(data, ptr, toread);
if (pa_ringbuffer_drop(&sr->rb_read, toread)) {
#ifdef DEBUG_SRBCHANNEL
pa_log("Read from full output buffer, signalling fdsem");
#endif
pa_fdsem_post(sr->sem_write);
}
isread += toread;
data = (uint8_t*) data + toread;
l -= toread;
}
#ifdef DEBUG_SRBCHANNEL
pa_log("Read %d bytes from srbchannel", (int) isread);
#endif
return isread;
}
/* This is the memory layout of the ringbuffer shm block. It is followed by
read and write ringbuffer memory. */
struct srbheader {
pa_atomic_t read_count;
pa_atomic_t write_count;
pa_fdsem_data read_semdata;
pa_fdsem_data write_semdata;
int capacity;
int readbuf_offset;
int writebuf_offset;
/* TODO: Maybe a marker here to make sure we talk to a server with equally sized struct */
};
static void srbchannel_rwloop(pa_srbchannel* sr) {
do {
#ifdef DEBUG_SRBCHANNEL
int q;
pa_ringbuffer_peek(&sr->rb_read, &q);
pa_log("In rw loop from srbchannel, before callback, count = %d", q);
#endif
if (sr->callback) {
if (!sr->callback(sr, sr->cb_userdata)) {
#ifdef DEBUG_SRBCHANNEL
pa_log("Aborting read loop from srbchannel");
#endif
return;
}
}
#ifdef DEBUG_SRBCHANNEL
pa_ringbuffer_peek(&sr->rb_read, &q);
pa_log("In rw loop from srbchannel, after callback, count = %d", q);
#endif
} while (pa_fdsem_before_poll(sr->sem_read) < 0);
}
static void semread_cb(pa_mainloop_api *m, pa_io_event *e, int fd, pa_io_event_flags_t events, void *userdata) {
pa_srbchannel* sr = userdata;
pa_fdsem_after_poll(sr->sem_read);
srbchannel_rwloop(sr);
}
static void defer_cb(pa_mainloop_api *m, pa_defer_event *e, void *userdata) {
pa_srbchannel* sr = userdata;
#ifdef DEBUG_SRBCHANNEL
pa_log("Calling rw loop from deferred event");
#endif
m->defer_enable(e, 0);
srbchannel_rwloop(sr);
}
pa_srbchannel* pa_srbchannel_new(pa_mainloop_api *m, pa_mempool *p) {
int capacity;
int readfd;
struct srbheader *srh;
pa_srbchannel* sr = pa_xmalloc0(sizeof(pa_srbchannel));
sr->mainloop = m;
sr->memblock = pa_memblock_new_pool(p, -1);
if (!sr->memblock)
goto fail;
srh = pa_memblock_acquire(sr->memblock);
pa_zero(*srh);
sr->rb_read.memory = (uint8_t*) srh + PA_ALIGN(sizeof(*srh));
srh->readbuf_offset = sr->rb_read.memory - (uint8_t*) srh;
capacity = (pa_memblock_get_length(sr->memblock) - srh->readbuf_offset) / 2;
sr->rb_write.memory = PA_ALIGN_PTR(sr->rb_read.memory + capacity);
srh->writebuf_offset = sr->rb_write.memory - (uint8_t*) srh;
capacity = PA_MIN(capacity, srh->writebuf_offset - srh->readbuf_offset);
pa_log_debug("SHM block is %d bytes, ringbuffer capacity is 2 * %d bytes",
(int) pa_memblock_get_length(sr->memblock), capacity);
srh->capacity = sr->rb_read.capacity = sr->rb_write.capacity = capacity;
sr->rb_read.count = &srh->read_count;
sr->rb_write.count = &srh->write_count;
sr->sem_read = pa_fdsem_new_shm(&srh->read_semdata);
if (!sr->sem_read)
goto fail;
sr->sem_write = pa_fdsem_new_shm(&srh->write_semdata);
if (!sr->sem_write)
goto fail;
readfd = pa_fdsem_get(sr->sem_read);
#ifdef DEBUG_SRBCHANNEL
pa_log("Enabling io event on fd %d", readfd);
#endif
sr->read_event = m->io_new(m, readfd, PA_IO_EVENT_INPUT, semread_cb, sr);
m->io_enable(sr->read_event, PA_IO_EVENT_INPUT);
return sr;
fail:
pa_srbchannel_free(sr);
return NULL;
}
static void pa_srbchannel_swap(pa_srbchannel *sr) {
pa_srbchannel temp = *sr;
sr->sem_read = temp.sem_write;
sr->sem_write = temp.sem_read;
sr->rb_read = temp.rb_write;
sr->rb_write = temp.rb_read;
}
pa_srbchannel* pa_srbchannel_new_from_template(pa_mainloop_api *m, pa_srbchannel_template *t)
{
int temp;
struct srbheader *srh;
pa_srbchannel* sr = pa_xmalloc0(sizeof(pa_srbchannel));
sr->mainloop = m;
sr->memblock = t->memblock;
pa_memblock_ref(sr->memblock);
srh = pa_memblock_acquire(sr->memblock);
sr->rb_read.capacity = sr->rb_write.capacity = srh->capacity;
sr->rb_read.count = &srh->read_count;
sr->rb_write.count = &srh->write_count;
sr->rb_read.memory = (uint8_t*) srh + srh->readbuf_offset;
sr->rb_write.memory = (uint8_t*) srh + srh->writebuf_offset;
sr->sem_read = pa_fdsem_open_shm(&srh->read_semdata, t->readfd);
if (!sr->sem_read)
goto fail;
sr->sem_write = pa_fdsem_open_shm(&srh->write_semdata, t->writefd);
if (!sr->sem_write)
goto fail;
pa_srbchannel_swap(sr);
temp = t->readfd; t->readfd = t->writefd; t->writefd = temp;
#ifdef DEBUG_SRBCHANNEL
pa_log("Enabling io event on fd %d", t->readfd);
#endif
sr->read_event = m->io_new(m, t->readfd, PA_IO_EVENT_INPUT, semread_cb, sr);
m->io_enable(sr->read_event, PA_IO_EVENT_INPUT);
return sr;
fail:
pa_srbchannel_free(sr);
return NULL;
}
void pa_srbchannel_export(pa_srbchannel *sr, pa_srbchannel_template *t) {
t->memblock = sr->memblock;
t->readfd = pa_fdsem_get(sr->sem_read);
t->writefd = pa_fdsem_get(sr->sem_write);
}
void pa_srbchannel_set_callback(pa_srbchannel *sr, pa_srbchannel_cb_t callback, void *userdata) {
if (sr->callback)
pa_fdsem_after_poll(sr->sem_read);
sr->callback = callback;
sr->cb_userdata = userdata;
if (sr->callback) {
/* If there are events to be read already in the ringbuffer, we will not get any IO event for that,
because that's how pa_fdsem works. Therefore check the ringbuffer in a defer event instead. */
if (!sr->defer_event)
sr->defer_event = sr->mainloop->defer_new(sr->mainloop, defer_cb, sr);
sr->mainloop->defer_enable(sr->defer_event, 1);
}
}
void pa_srbchannel_free(pa_srbchannel *sr)
{
#ifdef DEBUG_SRBCHANNEL
pa_log("Freeing srbchannel");
#endif
pa_assert(sr);
if (sr->defer_event)
sr->mainloop->defer_free(sr->defer_event);
if (sr->read_event)
sr->mainloop->io_free(sr->read_event);
if (sr->sem_read)
pa_fdsem_free(sr->sem_read);
if (sr->sem_write)
pa_fdsem_free(sr->sem_write);
if (sr->memblock) {
pa_memblock_release(sr->memblock);
pa_memblock_unref(sr->memblock);
}
pa_xfree(sr);
}
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