/* audio_pcm.c - pcm audio decoder driver * * Copyright (c) 2009-2012, The Linux Foundation. All rights reserved. * * Based on the mp3 decoder driver in arch/arm/mach-msm/qdsp5/audio_mp3.c * * Copyright (C) 2008 Google, Inc. * Copyright (C) 2008 HTC Corporation * * All source code in this file is licensed under the following license except * where indicated. * * This program is free software; you can redistribute it and/or modify it * under the terms of the GNU General Public License version 2 as published * by the Free Software Foundation. * * This program 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 General Public License for more details. * You should have received a copy of the GNU General Public License * along with this program; if not, you can find it at http://www.fsf.org */ #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include "audmgr.h" /* for queue ids - should be relative to module number*/ #include "adsp.h" #define ADRV_STATUS_AIO_INTF 0x00000001 #define ADRV_STATUS_OBUF_GIVEN 0x00000002 #define ADRV_STATUS_IBUF_GIVEN 0x00000004 #define ADRV_STATUS_FSYNC 0x00000008 /* Size must be power of 2 */ #define BUFSZ_MAX 32768 #define BUFSZ_MIN 4096 #define DMASZ_MAX (BUFSZ_MAX * 2) #define DMASZ_MIN (BUFSZ_MIN * 2) #define AUDDEC_DEC_PCM 0 /* Decoder status received from AUDPPTASK */ #define AUDPP_DEC_STATUS_SLEEP 0 #define AUDPP_DEC_STATUS_INIT 1 #define AUDPP_DEC_STATUS_CFG 2 #define AUDPP_DEC_STATUS_PLAY 3 #define AUDPCM_EVENT_NUM 10 /* Default number of pre-allocated event packets */ #define __CONTAINS(r, v, l) ({ \ typeof(r) __r = r; \ typeof(v) __v = v; \ typeof(v) __e = __v + l; \ int res = ((__v >= __r->vaddr) && \ (__e <= __r->vaddr + __r->len)); \ res; \ }) #define CONTAINS(r1, r2) ({ \ typeof(r2) __r2 = r2; \ __CONTAINS(r1, __r2->vaddr, __r2->len); \ }) #define IN_RANGE(r, v) ({ \ typeof(r) __r = r; \ typeof(v) __vv = v; \ int res = ((__vv >= __r->vaddr) && \ (__vv < (__r->vaddr + __r->len))); \ res; \ }) #define OVERLAPS(r1, r2) ({ \ typeof(r1) __r1 = r1; \ typeof(r2) __r2 = r2; \ typeof(__r2->vaddr) __v = __r2->vaddr; \ typeof(__v) __e = __v + __r2->len - 1; \ int res = (IN_RANGE(__r1, __v) || IN_RANGE(__r1, __e)); \ res; \ }) struct audio; struct buffer { void *data; unsigned size; unsigned used; /* Input usage actual DSP produced PCM size */ unsigned addr; }; #ifdef CONFIG_HAS_EARLYSUSPEND struct audpcm_suspend_ctl { struct early_suspend node; struct audio *audio; }; #endif struct audpcm_event { struct list_head list; int event_type; union msm_audio_event_payload payload; }; struct audpcm_ion_region { struct list_head list; struct ion_handle *handle; int fd; void *vaddr; unsigned long paddr; unsigned long kvaddr; unsigned long len; unsigned ref_cnt; }; struct audpcm_buffer_node { struct list_head list; struct msm_audio_aio_buf buf; unsigned long paddr; }; struct audpcm_drv_operations { void (*send_data)(struct audio *, unsigned); void (*out_flush)(struct audio *); int (*fsync)(struct audio *); }; struct audio { struct buffer out[2]; spinlock_t dsp_lock; uint8_t out_head; uint8_t out_tail; uint8_t out_needed; /* number of buffers the dsp is waiting for */ unsigned out_dma_sz; struct list_head out_queue; /* queue to retain output buffers */ atomic_t out_bytes; struct mutex lock; struct mutex write_lock; wait_queue_head_t write_wait; struct msm_adsp_module *audplay; /* configuration to use on next enable */ uint32_t out_sample_rate; uint32_t out_channel_mode; uint32_t out_bits; /* bits per sample */ struct audmgr audmgr; /* data allocated for various buffers */ char *data; int32_t phys; void *map_v_write; uint32_t drv_status; int wflush; /* Write flush */ int opened; int enabled; int running; int stopped; /* set when stopped, cleared on flush */ int teos; /* valid only if tunnel mode & no data left for decoder */ int rmt_resource_released; enum msm_aud_decoder_state dec_state; /* Represents decoder state */ int reserved; /* A byte is being reserved */ char rsv_byte; /* Handle odd length user data */ const char *module_name; unsigned queue_id; unsigned volume; uint16_t dec_id; #ifdef CONFIG_HAS_EARLYSUSPEND struct audpcm_suspend_ctl suspend_ctl; #endif #ifdef CONFIG_DEBUG_FS struct dentry *dentry; #endif wait_queue_head_t wait; struct list_head free_event_queue; struct list_head event_queue; wait_queue_head_t event_wait; spinlock_t event_queue_lock; struct mutex get_event_lock; int event_abort; struct list_head ion_region_queue; struct audpcm_drv_operations drv_ops; struct ion_client *client; struct ion_handle *output_buff_handle; }; static int auddec_dsp_config(struct audio *audio, int enable); static void audpp_cmd_cfg_adec_params(struct audio *audio); static void audplay_send_data(struct audio *audio, unsigned needed); static void audio_dsp_event(void *private, unsigned id, uint16_t *msg); static void audpcm_post_event(struct audio *audio, int type, union msm_audio_event_payload payload); static unsigned long audpcm_ion_fixup(struct audio *audio, void *addr, unsigned long len, int ref_up); static int rmt_put_resource(struct audio *audio) { struct aud_codec_config_cmd cmd; unsigned short client_idx; cmd.cmd_id = RM_CMD_AUD_CODEC_CFG; cmd.client_id = RM_AUD_CLIENT_ID; cmd.task_id = audio->dec_id; cmd.enable = RMT_DISABLE; cmd.dec_type = AUDDEC_DEC_PCM; client_idx = ((cmd.client_id << 8) | cmd.task_id); return put_adsp_resource(client_idx, &cmd, sizeof(cmd)); } static int rmt_get_resource(struct audio *audio) { struct aud_codec_config_cmd cmd; unsigned short client_idx; cmd.cmd_id = RM_CMD_AUD_CODEC_CFG; cmd.client_id = RM_AUD_CLIENT_ID; cmd.task_id = audio->dec_id; cmd.enable = RMT_ENABLE; cmd.dec_type = AUDDEC_DEC_PCM; client_idx = ((cmd.client_id << 8) | cmd.task_id); return get_adsp_resource(client_idx, &cmd, sizeof(cmd)); } /* must be called with audio->lock held */ static int audio_enable(struct audio *audio) { struct audmgr_config cfg; int rc; MM_DBG("\n"); /* Macro prints the file name and function */ if (audio->enabled) return 0; if (audio->rmt_resource_released == 1) { audio->rmt_resource_released = 0; rc = rmt_get_resource(audio); if (rc) { MM_ERR("ADSP resources are not available for PCM \ session 0x%08x on decoder: %d\n Ignoring \ error and going ahead with the playback\n", (int)audio, audio->dec_id); } } audio->dec_state = MSM_AUD_DECODER_STATE_NONE; audio->out_tail = 0; audio->out_needed = 0; cfg.tx_rate = RPC_AUD_DEF_SAMPLE_RATE_NONE; cfg.rx_rate = RPC_AUD_DEF_SAMPLE_RATE_48000; cfg.def_method = RPC_AUD_DEF_METHOD_PLAYBACK; cfg.codec = RPC_AUD_DEF_CODEC_PCM; cfg.snd_method = RPC_SND_METHOD_MIDI; rc = audmgr_enable(&audio->audmgr, &cfg); if (rc < 0) { msm_adsp_dump(audio->audplay); return rc; } if (msm_adsp_enable(audio->audplay)) { MM_ERR("msm_adsp_enable(audplay) failed\n"); audmgr_disable(&audio->audmgr); return -ENODEV; } if (audpp_enable(audio->dec_id, audio_dsp_event, audio)) { MM_ERR("audpp_enable() failed\n"); msm_adsp_disable(audio->audplay); audmgr_disable(&audio->audmgr); return -ENODEV; } audio->enabled = 1; return 0; } /* must be called with audio->lock held */ static int audio_disable(struct audio *audio) { int rc = 0; MM_DBG("\n"); /* Macro prints the file name and function */ if (audio->enabled) { audio->enabled = 0; audio->dec_state = MSM_AUD_DECODER_STATE_NONE; auddec_dsp_config(audio, 0); rc = wait_event_interruptible_timeout(audio->wait, audio->dec_state != MSM_AUD_DECODER_STATE_NONE, msecs_to_jiffies(MSM_AUD_DECODER_WAIT_MS)); if (rc == 0) rc = -ETIMEDOUT; else if (audio->dec_state != MSM_AUD_DECODER_STATE_CLOSE) rc = -EFAULT; else rc = 0; audio->stopped = 1; wake_up(&audio->write_wait); msm_adsp_disable(audio->audplay); audpp_disable(audio->dec_id, audio); rc = audmgr_disable(&audio->audmgr); if (rc < 0) msm_adsp_dump(audio->audplay); audio->out_needed = 0; rmt_put_resource(audio); audio->rmt_resource_released = 1; } return rc; } /* ------------------- dsp --------------------- */ static void audplay_dsp_event(void *data, unsigned id, size_t len, void (*getevent) (void *ptr, size_t len)) { struct audio *audio = data; uint32_t msg[28]; getevent(msg, sizeof(msg)); MM_DBG("msg_id=%x\n", id); switch (id) { case AUDPLAY_MSG_DEC_NEEDS_DATA: audio->drv_ops.send_data(audio, 1); break; case ADSP_MESSAGE_ID: MM_DBG("Received ADSP event: module enable(audplaytask)\n"); break; default: MM_ERR("unexpected message from decoder \n"); break; } } static void audio_dsp_event(void *private, unsigned id, uint16_t *msg) { struct audio *audio = private; switch (id) { case AUDPP_MSG_STATUS_MSG:{ unsigned status = msg[1]; switch (status) { case AUDPP_DEC_STATUS_SLEEP: { uint16_t reason = msg[2]; MM_DBG("decoder status: sleep reason = \ 0x%04x\n", reason); if ((reason == AUDPP_MSG_REASON_MEM) || (reason == AUDPP_MSG_REASON_NODECODER)) { audio->dec_state = MSM_AUD_DECODER_STATE_FAILURE; wake_up(&audio->wait); } else if (reason == AUDPP_MSG_REASON_NONE) { /* decoder is in disable state */ audio->dec_state = MSM_AUD_DECODER_STATE_CLOSE; wake_up(&audio->wait); } break; } case AUDPP_DEC_STATUS_INIT: MM_DBG("decoder status: init\n"); audpp_cmd_cfg_adec_params(audio); break; case AUDPP_DEC_STATUS_CFG: MM_DBG("decoder status: cfg \n"); break; case AUDPP_DEC_STATUS_PLAY: MM_DBG("decoder status: play \n"); audio->dec_state = MSM_AUD_DECODER_STATE_SUCCESS; wake_up(&audio->wait); break; default: MM_ERR("unknown decoder status \n"); break; } break; } case AUDPP_MSG_CFG_MSG: if (msg[0] == AUDPP_MSG_ENA_ENA) { MM_DBG("CFG_MSG ENABLE\n"); auddec_dsp_config(audio, 1); audio->out_needed = 0; audio->running = 1; audpp_set_volume_and_pan(audio->dec_id, audio->volume, 0); } else if (msg[0] == AUDPP_MSG_ENA_DIS) { MM_DBG("CFG_MSG DISABLE\n"); audio->running = 0; } else { MM_ERR("CFG_MSG %d?\n", msg[0]); } break; case AUDPP_MSG_FLUSH_ACK: MM_DBG("FLUSH_ACK\n"); audio->wflush = 0; wake_up(&audio->write_wait); break; case AUDPP_MSG_PCMDMAMISSED: MM_DBG("PCMDMAMISSED\n"); audio->teos = 1; wake_up(&audio->write_wait); break; default: MM_ERR("UNKNOWN (%d)\n", id); } } struct msm_adsp_ops audpcmdec_adsp_ops = { .event = audplay_dsp_event, }; #define audplay_send_queue0(audio, cmd, len) \ msm_adsp_write(audio->audplay, audio->queue_id, \ cmd, len) static int auddec_dsp_config(struct audio *audio, int enable) { u16 cfg_dec_cmd[AUDPP_CMD_CFG_DEC_TYPE_LEN / sizeof(unsigned short)]; memset(cfg_dec_cmd, 0, sizeof(cfg_dec_cmd)); cfg_dec_cmd[0] = AUDPP_CMD_CFG_DEC_TYPE; if (enable) cfg_dec_cmd[1 + audio->dec_id] = AUDPP_CMD_UPDATDE_CFG_DEC | AUDPP_CMD_ENA_DEC_V | AUDDEC_DEC_PCM; else cfg_dec_cmd[1 + audio->dec_id] = AUDPP_CMD_UPDATDE_CFG_DEC | AUDPP_CMD_DIS_DEC_V; return audpp_send_queue1(&cfg_dec_cmd, sizeof(cfg_dec_cmd)); } static void audpp_cmd_cfg_adec_params(struct audio *audio) { audpp_cmd_cfg_adec_params_wav cmd; memset(&cmd, 0, sizeof(cmd)); cmd.common.cmd_id = AUDPP_CMD_CFG_ADEC_PARAMS; cmd.common.length = AUDPP_CMD_CFG_ADEC_PARAMS_WAV_LEN; cmd.common.dec_id = audio->dec_id; cmd.common.input_sampling_frequency = audio->out_sample_rate; cmd.stereo_cfg = audio->out_channel_mode; cmd.pcm_width = audio->out_bits; cmd.sign = 0; audpp_send_queue2(&cmd, sizeof(cmd)); } static int audplay_dsp_send_data_avail(struct audio *audio, unsigned idx, unsigned len) { audplay_cmd_bitstream_data_avail cmd; cmd.cmd_id = AUDPLAY_CMD_BITSTREAM_DATA_AVAIL; cmd.decoder_id = audio->dec_id; cmd.buf_ptr = audio->out[idx].addr; cmd.buf_size = len/2; cmd.partition_number = 0; /* complete writes to the input buffer */ wmb(); return audplay_send_queue0(audio, &cmd, sizeof(cmd)); } static void audpcm_async_send_data(struct audio *audio, unsigned needed) { unsigned long flags; if (!audio->running) return; spin_lock_irqsave(&audio->dsp_lock, flags); if (needed && !audio->wflush) { audio->out_needed = 1; if (audio->drv_status & ADRV_STATUS_OBUF_GIVEN) { /* pop one node out of queue */ union msm_audio_event_payload payload; struct audpcm_buffer_node *used_buf; MM_DBG("consumed\n"); BUG_ON(list_empty(&audio->out_queue)); used_buf = list_first_entry(&audio->out_queue, struct audpcm_buffer_node, list); list_del(&used_buf->list); payload.aio_buf = used_buf->buf; audpcm_post_event(audio, AUDIO_EVENT_WRITE_DONE, payload); kfree(used_buf); audio->drv_status &= ~ADRV_STATUS_OBUF_GIVEN; } } if (audio->out_needed) { struct audpcm_buffer_node *next_buf; audplay_cmd_bitstream_data_avail cmd; if (!list_empty(&audio->out_queue)) { next_buf = list_first_entry(&audio->out_queue, struct audpcm_buffer_node, list); MM_DBG("next_buf %p\n", next_buf); if (next_buf) { MM_DBG("next buf phy %lx len %d\n", next_buf->paddr, next_buf->buf.data_len); cmd.cmd_id = AUDPLAY_CMD_BITSTREAM_DATA_AVAIL; if (next_buf->buf.data_len) cmd.decoder_id = audio->dec_id; else { cmd.decoder_id = -1; MM_DBG("input EOS signaled\n"); } cmd.buf_ptr = (unsigned) next_buf->paddr; cmd.buf_size = next_buf->buf.data_len >> 1; cmd.partition_number = 0; /* complete writes to the input buffer */ wmb(); audplay_send_queue0(audio, &cmd, sizeof(cmd)); audio->out_needed = 0; audio->drv_status |= ADRV_STATUS_OBUF_GIVEN; } } } spin_unlock_irqrestore(&audio->dsp_lock, flags); } static void audplay_send_data(struct audio *audio, unsigned needed) { struct buffer *frame; unsigned long flags; if (!audio->running) return; spin_lock_irqsave(&audio->dsp_lock, flags); if (needed && !audio->wflush) { /* We were called from the callback because the DSP * requested more data. Note that the DSP does want * more data, and if a buffer was in-flight, mark it * as available (since the DSP must now be done with * it). */ audio->out_needed = 1; frame = audio->out + audio->out_tail; if (frame->used == 0xffffffff) { MM_DBG("frame %d free\n", audio->out_tail); frame->used = 0; audio->out_tail ^= 1; wake_up(&audio->write_wait); } } if (audio->out_needed) { /* If the DSP currently wants data and we have a * buffer available, we will send it and reset * the needed flag. We'll mark the buffer as in-flight * so that it won't be recycled until the next buffer * is requested */ frame = audio->out + audio->out_tail; if (frame->used) { BUG_ON(frame->used == 0xffffffff); MM_DBG("frame %d busy\n", audio->out_tail); audplay_dsp_send_data_avail(audio, audio->out_tail, frame->used); frame->used = 0xffffffff; audio->out_needed = 0; } } spin_unlock_irqrestore(&audio->dsp_lock, flags); } /* ------------------- device --------------------- */ static void audpcm_async_flush(struct audio *audio) { struct audpcm_buffer_node *buf_node; struct list_head *ptr, *next; union msm_audio_event_payload payload; MM_DBG("\n"); /* Macro prints the file name and function */ list_for_each_safe(ptr, next, &audio->out_queue) { buf_node = list_entry(ptr, struct audpcm_buffer_node, list); list_del(&buf_node->list); payload.aio_buf = buf_node->buf; audpcm_post_event(audio, AUDIO_EVENT_WRITE_DONE, payload); kfree(buf_node); } audio->drv_status &= ~ADRV_STATUS_OBUF_GIVEN; audio->out_needed = 0; atomic_set(&audio->out_bytes, 0); } static void audio_flush(struct audio *audio) { unsigned long flags; spin_lock_irqsave(&audio->dsp_lock, flags); audio->out[0].used = 0; audio->out[1].used = 0; audio->out_head = 0; audio->out_tail = 0; audio->reserved = 0; audio->out_needed = 0; spin_unlock_irqrestore(&audio->dsp_lock, flags); atomic_set(&audio->out_bytes, 0); } static void audio_ioport_reset(struct audio *audio) { if (audio->drv_status & ADRV_STATUS_AIO_INTF) { /* If fsync is in progress, make sure * return value of fsync indicates * abort due to flush */ if (audio->drv_status & ADRV_STATUS_FSYNC) { MM_DBG("fsync in progress\n"); wake_up(&audio->write_wait); mutex_lock(&audio->write_lock); audio->drv_ops.out_flush(audio); mutex_unlock(&audio->write_lock); } else audio->drv_ops.out_flush(audio); } else { /* Make sure read/write thread are free from * sleep and knowing that system is not able * to process io request at the moment */ wake_up(&audio->write_wait); mutex_lock(&audio->write_lock); audio->drv_ops.out_flush(audio); mutex_unlock(&audio->write_lock); } } static int audpcm_events_pending(struct audio *audio) { unsigned long flags; int empty; spin_lock_irqsave(&audio->event_queue_lock, flags); empty = !list_empty(&audio->event_queue); spin_unlock_irqrestore(&audio->event_queue_lock, flags); return empty || audio->event_abort; } static void audpcm_reset_event_queue(struct audio *audio) { unsigned long flags; struct audpcm_event *drv_evt; struct list_head *ptr, *next; spin_lock_irqsave(&audio->event_queue_lock, flags); list_for_each_safe(ptr, next, &audio->event_queue) { drv_evt = list_first_entry(&audio->event_queue, struct audpcm_event, list); list_del(&drv_evt->list); kfree(drv_evt); } list_for_each_safe(ptr, next, &audio->free_event_queue) { drv_evt = list_first_entry(&audio->free_event_queue, struct audpcm_event, list); list_del(&drv_evt->list); kfree(drv_evt); } spin_unlock_irqrestore(&audio->event_queue_lock, flags); return; } static long audpcm_process_event_req(struct audio *audio, void __user *arg) { long rc; struct msm_audio_event usr_evt; struct audpcm_event *drv_evt = NULL; int timeout; unsigned long flags; if (copy_from_user(&usr_evt, arg, sizeof(struct msm_audio_event))) return -EFAULT; timeout = (int) usr_evt.timeout_ms; if (timeout > 0) { rc = wait_event_interruptible_timeout( audio->event_wait, audpcm_events_pending(audio), msecs_to_jiffies(timeout)); if (rc == 0) return -ETIMEDOUT; } else { rc = wait_event_interruptible( audio->event_wait, audpcm_events_pending(audio)); } if (rc < 0) return rc; if (audio->event_abort) { audio->event_abort = 0; return -ENODEV; } spin_lock_irqsave(&audio->event_queue_lock, flags); if (!list_empty(&audio->event_queue)) { drv_evt = list_first_entry(&audio->event_queue, struct audpcm_event, list); list_del(&drv_evt->list); } if (drv_evt) { usr_evt.event_type = drv_evt->event_type; usr_evt.event_payload = drv_evt->payload; list_add_tail(&drv_evt->list, &audio->free_event_queue); } else rc = -1; spin_unlock_irqrestore(&audio->event_queue_lock, flags); if (drv_evt && drv_evt->event_type == AUDIO_EVENT_WRITE_DONE) { mutex_lock(&audio->lock); audpcm_ion_fixup(audio, drv_evt->payload.aio_buf.buf_addr, drv_evt->payload.aio_buf.buf_len, 0); mutex_unlock(&audio->lock); } if (!rc && copy_to_user(arg, &usr_evt, sizeof(usr_evt))) rc = -EFAULT; return rc; } static int audpcm_ion_check(struct audio *audio, void *vaddr, unsigned long len) { struct audpcm_ion_region *region_elt; struct audpcm_ion_region t = {.vaddr = vaddr, .len = len }; list_for_each_entry(region_elt, &audio->ion_region_queue, list) { if (CONTAINS(region_elt, &t) || CONTAINS(&t, region_elt) || OVERLAPS(region_elt, &t)) { MM_ERR("[%p]:region (vaddr %p len %ld)" " clashes with registered region" " (vaddr %p paddr %p len %ld)\n", audio, vaddr, len, region_elt->vaddr, (void *)region_elt->paddr, region_elt->len); return -EINVAL; } } return 0; } static int audpcm_ion_add(struct audio *audio, struct msm_audio_ion_info *info) { ion_phys_addr_t paddr; size_t len; unsigned long kvaddr; struct audpcm_ion_region *region; int rc = -EINVAL; struct ion_handle *handle; unsigned long ionflag; MM_ERR("\n"); /* Macro prints the file name and function */ region = kmalloc(sizeof(*region), GFP_KERNEL); if (!region) { rc = -ENOMEM; goto end; } handle = ion_import_dma_buf(audio->client, info->fd); if (IS_ERR_OR_NULL(handle)) { pr_err("%s: could not get handle of the given fd\n", __func__); goto import_error; } rc = ion_handle_get_flags(audio->client, handle, &ionflag); if (rc) { pr_err("%s: could not get flags for the handle\n", __func__); goto flag_error; } kvaddr = (unsigned long)ion_map_kernel(audio->client, handle); if (IS_ERR_OR_NULL((void *)kvaddr)) { pr_err("%s: could not get virtual address\n", __func__); goto map_error; } rc = ion_phys(audio->client, handle, &paddr, &len); if (rc) { pr_err("%s: could not get physical address\n", __func__); goto ion_error; } rc = audpcm_ion_check(audio, info->vaddr, len); if (rc < 0) { MM_ERR("audpcm_ion_check failed\n"); goto ion_error; } region->handle = handle; region->vaddr = info->vaddr; region->fd = info->fd; region->paddr = paddr; region->kvaddr = kvaddr; region->len = len; region->ref_cnt = 0; MM_DBG("[%p]:add region paddr %lx vaddr %p, len %lu kvaddr %lx\n", audio, region->paddr, region->vaddr, region->len, region->kvaddr); list_add_tail(®ion->list, &audio->ion_region_queue); return rc; ion_error: ion_unmap_kernel(audio->client, handle); map_error: flag_error: ion_free(audio->client, handle); import_error: kfree(region); end: return rc; } static int audpcm_ion_remove(struct audio *audio, struct msm_audio_ion_info *info) { struct audpcm_ion_region *region; struct list_head *ptr, *next; int rc = -EINVAL; list_for_each_safe(ptr, next, &audio->ion_region_queue) { region = list_entry(ptr, struct audpcm_ion_region, list); if (region != NULL && (region->fd == info->fd) && (region->vaddr == info->vaddr)) { if (region->ref_cnt) { MM_DBG("%s[%p]:region %p in use ref_cnt %d\n", __func__, audio, region, region->ref_cnt); break; } MM_DBG("remove region fd %d vaddr %p\n", info->fd, info->vaddr); list_del(®ion->list); ion_unmap_kernel(audio->client, region->handle); ion_free(audio->client, region->handle); kfree(region); rc = 0; break; } } return rc; } static int audpcm_ion_lookup_vaddr(struct audio *audio, void *addr, unsigned long len, struct audpcm_ion_region **region) { struct audpcm_ion_region *region_elt; int match_count = 0; *region = NULL; /* returns physical address or zero */ list_for_each_entry(region_elt, &audio->ion_region_queue, list) { if (addr >= region_elt->vaddr && addr < region_elt->vaddr + region_elt->len && addr + len <= region_elt->vaddr + region_elt->len) { /* offset since we could pass vaddr inside a registerd * ion buffer */ match_count++; if (!*region) *region = region_elt; } } if (match_count > 1) { MM_ERR("%s[%p]:multiple hits for vaddr %p, len %ld\n", __func__, audio, addr, len); list_for_each_entry(region_elt, &audio->ion_region_queue, list) { if (addr >= region_elt->vaddr && addr < region_elt->vaddr + region_elt->len && addr + len <= region_elt->vaddr + region_elt->len) MM_ERR("\t%s[%p]:%p, %ld --> %p\n", __func__, audio, region_elt->vaddr, region_elt->len, (void *)region_elt->paddr); } } return *region ? 0 : -1; } static unsigned long audpcm_ion_fixup(struct audio *audio, void *addr, unsigned long len, int ref_up) { struct audpcm_ion_region *region; unsigned long paddr; int ret; ret = audpcm_ion_lookup_vaddr(audio, addr, len, ®ion); if (ret) { MM_ERR("%s[%p]:lookup (%p, %ld) failed\n", __func__, audio, addr, len); return 0; } if (ref_up) region->ref_cnt++; else region->ref_cnt--; MM_DBG("found region %p ref_cnt %d\n", region, region->ref_cnt); paddr = region->paddr + (addr - region->vaddr); return paddr; } /* audio -> lock must be held at this point */ static int audpcm_aio_buf_add(struct audio *audio, unsigned dir, void __user *arg) { unsigned long flags; struct audpcm_buffer_node *buf_node; buf_node = kmalloc(sizeof(*buf_node), GFP_KERNEL); if (!buf_node) return -ENOMEM; if (copy_from_user(&buf_node->buf, arg, sizeof(buf_node->buf))) { kfree(buf_node); return -EFAULT; } MM_DBG("node %p dir %x buf_addr %p buf_len %d data_len %d\n", buf_node, dir, buf_node->buf.buf_addr, buf_node->buf.buf_len, buf_node->buf.data_len); buf_node->paddr = audpcm_ion_fixup( audio, buf_node->buf.buf_addr, buf_node->buf.buf_len, 1); if (dir) { /* write */ if (!buf_node->paddr || (buf_node->paddr & 0x1) || (buf_node->buf.data_len & 0x1) || (!buf_node->buf.data_len)) { kfree(buf_node); return -EINVAL; } spin_lock_irqsave(&audio->dsp_lock, flags); list_add_tail(&buf_node->list, &audio->out_queue); spin_unlock_irqrestore(&audio->dsp_lock, flags); audio->drv_ops.send_data(audio, 0); } MM_DBG("Add buf_node %p paddr %lx\n", buf_node, buf_node->paddr); return 0; } static long audio_ioctl(struct file *file, unsigned int cmd, unsigned long arg) { struct audio *audio = file->private_data; int rc = 0; MM_DBG("cmd = %d\n", cmd); if (cmd == AUDIO_GET_STATS) { struct msm_audio_stats stats; stats.byte_count = audpp_avsync_byte_count(audio->dec_id); stats.sample_count = audpp_avsync_sample_count(audio->dec_id); if (copy_to_user((void *) arg, &stats, sizeof(stats))) return -EFAULT; return 0; } if (cmd == AUDIO_SET_VOLUME) { unsigned long flags; spin_lock_irqsave(&audio->dsp_lock, flags); audio->volume = arg; if (audio->running) audpp_set_volume_and_pan(audio->dec_id, arg, 0); spin_unlock_irqrestore(&audio->dsp_lock, flags); return 0; } if (cmd == AUDIO_GET_EVENT) { MM_DBG("AUDIO_GET_EVENT\n"); if (mutex_trylock(&audio->get_event_lock)) { rc = audpcm_process_event_req(audio, (void __user *) arg); mutex_unlock(&audio->get_event_lock); } else rc = -EBUSY; return rc; } if (cmd == AUDIO_ABORT_GET_EVENT) { audio->event_abort = 1; wake_up(&audio->event_wait); return 0; } mutex_lock(&audio->lock); switch (cmd) { case AUDIO_START: MM_DBG("AUDIO_START\n"); rc = audio_enable(audio); if (!rc) { rc = wait_event_interruptible_timeout(audio->wait, audio->dec_state != MSM_AUD_DECODER_STATE_NONE, msecs_to_jiffies(MSM_AUD_DECODER_WAIT_MS)); MM_INFO("dec_state %d rc = %d\n", audio->dec_state, rc); if (audio->dec_state != MSM_AUD_DECODER_STATE_SUCCESS) rc = -ENODEV; else rc = 0; } break; case AUDIO_STOP: MM_DBG("AUDIO_STOP\n"); rc = audio_disable(audio); audio_ioport_reset(audio); audio->stopped = 0; break; case AUDIO_FLUSH: MM_DBG("AUDIO_FLUSH\n"); audio->wflush = 1; audio_ioport_reset(audio); if (audio->running) { audpp_flush(audio->dec_id); rc = wait_event_interruptible(audio->write_wait, !audio->wflush); if (rc < 0) { MM_ERR("AUDIO_FLUSH interrupted\n"); rc = -EINTR; } } else { audio->wflush = 0; } break; case AUDIO_SET_CONFIG: { struct msm_audio_config config; if (copy_from_user(&config, (void *) arg, sizeof(config))) { rc = -EFAULT; break; } if (config.channel_count == 1) { config.channel_count = AUDPP_CMD_PCM_INTF_MONO_V; } else if (config.channel_count == 2) { config.channel_count = AUDPP_CMD_PCM_INTF_STEREO_V; } else { rc = -EINVAL; break; } if (config.bits == 8) config.bits = AUDPP_CMD_WAV_PCM_WIDTH_8; else if (config.bits == 16) config.bits = AUDPP_CMD_WAV_PCM_WIDTH_16; else if (config.bits == 24) config.bits = AUDPP_CMD_WAV_PCM_WIDTH_24; else { rc = -EINVAL; break; } audio->out_sample_rate = config.sample_rate; audio->out_channel_mode = config.channel_count; audio->out_bits = config.bits; break; } case AUDIO_GET_CONFIG: { struct msm_audio_config config; config.buffer_size = (audio->out_dma_sz >> 1); config.buffer_count = 2; config.sample_rate = audio->out_sample_rate; if (audio->out_channel_mode == AUDPP_CMD_PCM_INTF_MONO_V) config.channel_count = 1; else config.channel_count = 2; if (audio->out_bits == AUDPP_CMD_WAV_PCM_WIDTH_8) config.bits = 8; else if (audio->out_bits == AUDPP_CMD_WAV_PCM_WIDTH_24) config.bits = 24; else config.bits = 16; config.unused[0] = 0; config.unused[1] = 0; if (copy_to_user((void *) arg, &config, sizeof(config))) rc = -EFAULT; else rc = 0; break; } case AUDIO_PAUSE: MM_DBG("AUDIO_PAUSE %ld\n", arg); rc = audpp_pause(audio->dec_id, (int) arg); break; case AUDIO_REGISTER_ION: { struct msm_audio_ion_info info; MM_ERR("AUDIO_REGISTER_ION\n"); if (copy_from_user(&info, (void *) arg, sizeof(info))) rc = -EFAULT; else rc = audpcm_ion_add(audio, &info); break; } case AUDIO_DEREGISTER_ION: { struct msm_audio_ion_info info; MM_ERR("AUDIO_DEREGISTER_ION\n"); if (copy_from_user(&info, (void *) arg, sizeof(info))) rc = -EFAULT; else rc = audpcm_ion_remove(audio, &info); break; } case AUDIO_ASYNC_WRITE: if (audio->drv_status & ADRV_STATUS_FSYNC) rc = -EBUSY; else rc = audpcm_aio_buf_add(audio, 1, (void __user *) arg); break; case AUDIO_ASYNC_READ: MM_ERR("AUDIO_ASYNC_READ not supported\n"); rc = -EPERM; break; default: rc = -EINVAL; } mutex_unlock(&audio->lock); return rc; } /* Only useful in tunnel-mode */ int audpcm_async_fsync(struct audio *audio) { int rc = 0; MM_DBG("\n"); /* Macro prints the file name and function */ /* Blocking client sends more data */ mutex_lock(&audio->lock); audio->drv_status |= ADRV_STATUS_FSYNC; mutex_unlock(&audio->lock); mutex_lock(&audio->write_lock); /* pcm dmamiss message is sent continously * when decoder is starved so no race * condition concern */ audio->teos = 0; rc = wait_event_interruptible(audio->write_wait, (audio->teos && audio->out_needed && list_empty(&audio->out_queue)) || audio->wflush || audio->stopped); if (audio->stopped || audio->wflush) rc = -EBUSY; mutex_unlock(&audio->write_lock); mutex_lock(&audio->lock); audio->drv_status &= ~ADRV_STATUS_FSYNC; mutex_unlock(&audio->lock); return rc; } int audpcm_sync_fsync(struct audio *audio) { struct buffer *frame; int rc = 0; MM_DBG("\n"); /* Macro prints the file name and function */ mutex_lock(&audio->write_lock); rc = wait_event_interruptible(audio->write_wait, (!audio->out[0].used && !audio->out[1].used && audio->out_needed) || audio->wflush); if (rc < 0) goto done; else if (audio->wflush) { rc = -EBUSY; goto done; } if (audio->reserved) { MM_DBG("send reserved byte\n"); frame = audio->out + audio->out_tail; ((char *) frame->data)[0] = audio->rsv_byte; ((char *) frame->data)[1] = 0; frame->used = 2; audio->drv_ops.send_data(audio, 0); rc = wait_event_interruptible(audio->write_wait, (!audio->out[0].used && !audio->out[1].used && audio->out_needed) || audio->wflush); if (rc < 0) goto done; else if (audio->wflush) { rc = -EBUSY; goto done; } } /* pcm dmamiss message is sent continously * when decoder is starved so no race * condition concern */ audio->teos = 0; rc = wait_event_interruptible(audio->write_wait, audio->teos || audio->wflush); if (audio->wflush) rc = -EBUSY; done: mutex_unlock(&audio->write_lock); return rc; } int audpcm_fsync(struct file *file, loff_t a, loff_t b, int datasync) { struct audio *audio = file->private_data; if (!audio->running) return -EINVAL; return audio->drv_ops.fsync(audio); } static ssize_t audio_write(struct file *file, const char __user *buf, size_t count, loff_t *pos) { struct audio *audio = file->private_data; const char __user *start = buf; struct buffer *frame; size_t xfer; char *cpy_ptr; int rc = 0; unsigned dsize; if (audio->drv_status & ADRV_STATUS_AIO_INTF) return -EPERM; MM_DBG("cnt=%d\n", count); mutex_lock(&audio->write_lock); while (count > 0) { frame = audio->out + audio->out_head; cpy_ptr = frame->data; dsize = 0; rc = wait_event_interruptible(audio->write_wait, (frame->used == 0) || (audio->stopped) || (audio->wflush)); if (rc < 0) break; if (audio->stopped || audio->wflush) { rc = -EBUSY; break; } if (audio->reserved) { MM_DBG("append reserved byte %x\n", audio->rsv_byte); *cpy_ptr = audio->rsv_byte; xfer = (count > (frame->size - 1)) ? frame->size - 1 : count; cpy_ptr++; dsize = 1; audio->reserved = 0; } else xfer = (count > frame->size) ? frame->size : count; if (copy_from_user(cpy_ptr, buf, xfer)) { rc = -EFAULT; break; } dsize += xfer; if (dsize & 1) { audio->rsv_byte = ((char *) frame->data)[dsize - 1]; MM_DBG("odd length buf reserve last byte %x\n", audio->rsv_byte); audio->reserved = 1; dsize--; } count -= xfer; buf += xfer; if (dsize > 0) { audio->out_head ^= 1; frame->used = dsize; audio->drv_ops.send_data(audio, 0); } } mutex_unlock(&audio->write_lock); if (buf > start) return buf - start; return rc; } static void audpcm_reset_ion_region(struct audio *audio) { struct audpcm_ion_region *region; struct list_head *ptr, *next; list_for_each_safe(ptr, next, &audio->ion_region_queue) { region = list_entry(ptr, struct audpcm_ion_region, list); list_del(®ion->list); ion_unmap_kernel(audio->client, region->handle); ion_free(audio->client, region->handle); kfree(region); } return; } static int audio_release(struct inode *inode, struct file *file) { struct audio *audio = file->private_data; MM_DBG("audio instance 0x%08x freeing\n", (int)audio); mutex_lock(&audio->lock); audio_disable(audio); if (audio->rmt_resource_released == 0) rmt_put_resource(audio); audio->drv_ops.out_flush(audio); audpcm_reset_ion_region(audio); msm_adsp_put(audio->audplay); audpp_adec_free(audio->dec_id); #ifdef CONFIG_HAS_EARLYSUSPEND unregister_early_suspend(&audio->suspend_ctl.node); #endif audio->opened = 0; audio->event_abort = 1; wake_up(&audio->event_wait); audpcm_reset_event_queue(audio); mutex_unlock(&audio->lock); #ifdef CONFIG_DEBUG_FS if (audio->dentry) debugfs_remove(audio->dentry); #endif ion_client_destroy(audio->client); kfree(audio); return 0; } static void audpcm_post_event(struct audio *audio, int type, union msm_audio_event_payload payload) { struct audpcm_event *e_node = NULL; unsigned long flags; spin_lock_irqsave(&audio->event_queue_lock, flags); if (!list_empty(&audio->free_event_queue)) { e_node = list_first_entry(&audio->free_event_queue, struct audpcm_event, list); list_del(&e_node->list); } else { e_node = kmalloc(sizeof(struct audpcm_event), GFP_ATOMIC); if (!e_node) { MM_ERR("No mem to post event %d\n", type); spin_unlock_irqrestore(&audio->event_queue_lock, flags); return; } } e_node->event_type = type; e_node->payload = payload; list_add_tail(&e_node->list, &audio->event_queue); spin_unlock_irqrestore(&audio->event_queue_lock, flags); wake_up(&audio->event_wait); } #ifdef CONFIG_HAS_EARLYSUSPEND static void audpcm_suspend(struct early_suspend *h) { struct audpcm_suspend_ctl *ctl = container_of(h, struct audpcm_suspend_ctl, node); union msm_audio_event_payload payload; MM_DBG("\n"); /* Macro prints the file name and function */ audpcm_post_event(ctl->audio, AUDIO_EVENT_SUSPEND, payload); } static void audpcm_resume(struct early_suspend *h) { struct audpcm_suspend_ctl *ctl = container_of(h, struct audpcm_suspend_ctl, node); union msm_audio_event_payload payload; MM_DBG("\n"); /* Macro prints the file name and function */ audpcm_post_event(ctl->audio, AUDIO_EVENT_RESUME, payload); } #endif #ifdef CONFIG_DEBUG_FS static ssize_t audpcm_debug_open(struct inode *inode, struct file *file) { file->private_data = inode->i_private; return 0; } static ssize_t audpcm_debug_read(struct file *file, char __user *buf, size_t count, loff_t *ppos) { const int debug_bufmax = 4096; static char buffer[4096]; int n = 0; struct audio *audio = file->private_data; mutex_lock(&audio->lock); n = scnprintf(buffer, debug_bufmax, "opened %d\n", audio->opened); n += scnprintf(buffer + n, debug_bufmax - n, "enabled %d\n", audio->enabled); n += scnprintf(buffer + n, debug_bufmax - n, "stopped %d\n", audio->stopped); n += scnprintf(buffer + n, debug_bufmax - n, "out_buf_sz %d\n", audio->out[0].size); n += scnprintf(buffer + n, debug_bufmax - n, "volume %x \n", audio->volume); n += scnprintf(buffer + n, debug_bufmax - n, "sample rate %d \n", audio->out_sample_rate); n += scnprintf(buffer + n, debug_bufmax - n, "channel mode %d \n", audio->out_channel_mode); mutex_unlock(&audio->lock); /* Following variables are only useful for debugging when * when playback halts unexpectedly. Thus, no mutual exclusion * enforced */ n += scnprintf(buffer + n, debug_bufmax - n, "wflush %d\n", audio->wflush); n += scnprintf(buffer + n, debug_bufmax - n, "running %d \n", audio->running); n += scnprintf(buffer + n, debug_bufmax - n, "dec state %d \n", audio->dec_state); n += scnprintf(buffer + n, debug_bufmax - n, "out_needed %d \n", audio->out_needed); n += scnprintf(buffer + n, debug_bufmax - n, "out_head %d \n", audio->out_head); n += scnprintf(buffer + n, debug_bufmax - n, "out_tail %d \n", audio->out_tail); n += scnprintf(buffer + n, debug_bufmax - n, "out[0].used %d \n", audio->out[0].used); n += scnprintf(buffer + n, debug_bufmax - n, "out[1].used %d \n", audio->out[1].used); buffer[n] = 0; return simple_read_from_buffer(buf, count, ppos, buffer, n); } static const struct file_operations audpcm_debug_fops = { .read = audpcm_debug_read, .open = audpcm_debug_open, }; #endif static int audio_open(struct inode *inode, struct file *file) { struct audio *audio = NULL; int rc, i, dec_attrb, decid; struct audpcm_event *e_node = NULL; unsigned mem_sz = DMASZ_MAX; unsigned long ionflag = 0; ion_phys_addr_t addr = 0; struct ion_handle *handle = NULL; struct ion_client *client = NULL; int len = 0; #ifdef CONFIG_DEBUG_FS /* 4 bytes represents decoder number, 1 byte for terminate string */ char name[sizeof "msm_pcm_dec_" + 5]; #endif /* Allocate audio instance, set to zero */ audio = kzalloc(sizeof(struct audio), GFP_KERNEL); if (!audio) { MM_ERR("no memory to allocate audio instance \n"); rc = -ENOMEM; goto done; } MM_DBG("audio instance 0x%08x created\n", (int)audio); /* Allocate the decoder */ dec_attrb = AUDDEC_DEC_PCM; if (file->f_mode & FMODE_READ) { MM_ERR("Non-Tunneled mode not supported\n"); rc = -EPERM; kfree(audio); goto done; } else dec_attrb |= MSM_AUD_MODE_TUNNEL; decid = audpp_adec_alloc(dec_attrb, &audio->module_name, &audio->queue_id); if (decid < 0) { MM_ERR("No free decoder available\n"); rc = -ENODEV; MM_DBG("audio instance 0x%08x freeing\n", (int)audio); kfree(audio); goto done; } audio->dec_id = decid & MSM_AUD_DECODER_MASK; client = msm_ion_client_create(UINT_MAX, "Audio_PCM_Client"); if (IS_ERR_OR_NULL(client)) { pr_err("Unable to create ION client\n"); rc = -ENOMEM; goto client_create_error; } audio->client = client; /* Non AIO interface */ if (!(file->f_flags & O_NONBLOCK)) { MM_DBG("memsz = %d\n", mem_sz); handle = ion_alloc(client, mem_sz, SZ_4K, ION_HEAP(ION_AUDIO_HEAP_ID), 0); if (IS_ERR_OR_NULL(handle)) { MM_ERR("Unable to create allocate O/P buffers\n"); rc = -ENOMEM; goto output_buff_alloc_error; } audio->output_buff_handle = handle; rc = ion_phys(client , handle, &addr, &len); if (rc) { MM_ERR("O/P buffers:Invalid phy: %x sz: %x\n", (unsigned int) addr, (unsigned int) len); goto output_buff_get_phys_error; } else { MM_INFO("O/P buffers:valid phy: %x sz: %x\n", (unsigned int) addr, (unsigned int) len); } audio->phys = (int32_t)addr; rc = ion_handle_get_flags(client, handle, &ionflag); if (rc) { MM_ERR("could not get flags for the handle\n"); goto output_buff_get_flags_error; } audio->map_v_write = ion_map_kernel(client, handle); if (IS_ERR(audio->map_v_write)) { MM_ERR("could not map write buffers\n"); rc = -ENOMEM; goto output_buff_map_error; } audio->data = audio->map_v_write; MM_DBG("write buf: phy addr 0x%08x kernel addr 0x%08x\n", audio->phys, (int)audio->data); audio->out_dma_sz = mem_sz; } rc = audmgr_open(&audio->audmgr); if (rc) goto err; rc = msm_adsp_get(audio->module_name, &audio->audplay, &audpcmdec_adsp_ops, audio); if (rc) { MM_ERR("failed to get %s module\n", audio->module_name); audmgr_close(&audio->audmgr); goto err; } rc = rmt_get_resource(audio); if (rc) { MM_ERR("ADSP resources are not available for PCM session \ 0x%08x on decoder: %d\n", (int)audio, audio->dec_id); audmgr_close(&audio->audmgr); msm_adsp_put(audio->audplay); goto err; } if (file->f_flags & O_NONBLOCK) { MM_DBG("set to aio interface\n"); audio->drv_status |= ADRV_STATUS_AIO_INTF; audio->drv_ops.send_data = audpcm_async_send_data; audio->drv_ops.out_flush = audpcm_async_flush; audio->drv_ops.fsync = audpcm_async_fsync; } else { MM_DBG("set to std io interface\n"); audio->drv_ops.send_data = audplay_send_data; audio->drv_ops.out_flush = audio_flush; audio->drv_ops.fsync = audpcm_sync_fsync; audio->out[0].data = audio->data + 0; audio->out[0].addr = audio->phys + 0; audio->out[0].size = (audio->out_dma_sz >> 1); audio->out[1].data = audio->data + audio->out[0].size; audio->out[1].addr = audio->phys + audio->out[0].size; audio->out[1].size = audio->out[0].size; } /* Initialize all locks of audio instance */ mutex_init(&audio->lock); mutex_init(&audio->write_lock); mutex_init(&audio->get_event_lock); spin_lock_init(&audio->dsp_lock); init_waitqueue_head(&audio->write_wait); INIT_LIST_HEAD(&audio->out_queue); INIT_LIST_HEAD(&audio->ion_region_queue); INIT_LIST_HEAD(&audio->free_event_queue); INIT_LIST_HEAD(&audio->event_queue); init_waitqueue_head(&audio->wait); init_waitqueue_head(&audio->event_wait); spin_lock_init(&audio->event_queue_lock); audio->out_sample_rate = 44100; audio->out_channel_mode = AUDPP_CMD_PCM_INTF_STEREO_V; audio->out_bits = AUDPP_CMD_WAV_PCM_WIDTH_16; audio->volume = 0x2000; audio->drv_ops.out_flush(audio); file->private_data = audio; audio->opened = 1; #ifdef CONFIG_DEBUG_FS snprintf(name, sizeof name, "msm_pcm_dec_%04x", audio->dec_id); audio->dentry = debugfs_create_file(name, S_IFREG | S_IRUGO, NULL, (void *) audio, &audpcm_debug_fops); if (IS_ERR(audio->dentry)) MM_DBG("debugfs_create_file failed\n"); #endif #ifdef CONFIG_HAS_EARLYSUSPEND audio->suspend_ctl.node.level = EARLY_SUSPEND_LEVEL_DISABLE_FB; audio->suspend_ctl.node.resume = audpcm_resume; audio->suspend_ctl.node.suspend = audpcm_suspend; audio->suspend_ctl.audio = audio; register_early_suspend(&audio->suspend_ctl.node); #endif for (i = 0; i < AUDPCM_EVENT_NUM; i++) { e_node = kmalloc(sizeof(struct audpcm_event), GFP_KERNEL); if (e_node) list_add_tail(&e_node->list, &audio->free_event_queue); else { MM_ERR("event pkt alloc failed\n"); break; } } done: return rc; err: ion_unmap_kernel(client, audio->output_buff_handle); output_buff_map_error: output_buff_get_flags_error: output_buff_get_phys_error: ion_free(client, audio->output_buff_handle); output_buff_alloc_error: ion_client_destroy(client); client_create_error: audpp_adec_free(audio->dec_id); MM_DBG("audio instance 0x%08x freeing\n", (int)audio); kfree(audio); return rc; } static const struct file_operations audio_pcm_fops = { .owner = THIS_MODULE, .open = audio_open, .release = audio_release, .write = audio_write, .unlocked_ioctl = audio_ioctl, .fsync = audpcm_fsync, }; struct miscdevice audio_pcm_misc = { .minor = MISC_DYNAMIC_MINOR, .name = "msm_pcm_dec", .fops = &audio_pcm_fops, }; static int __init audio_init(void) { return misc_register(&audio_pcm_misc); } device_initcall(audio_init);