nuttx/drivers/audio/vs1053.c
jinxiuxu b874d95beb drivers/audio: fix samp rate conversion issue
Signed-off-by: jinxiuxu <jinxiuxu@xiaomi.com>
2024-08-22 09:13:51 -03:00

1937 lines
56 KiB
C

/****************************************************************************
* drivers/audio/vs1053.c
*
* Licensed to the Apache Software Foundation (ASF) under one or more
* contributor license agreements. See the NOTICE file distributed with
* this work for additional information regarding copyright ownership. The
* ASF licenses this file to you under the Apache License, Version 2.0 (the
* "License"); you may not use this file except in compliance with the
* License. You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS, WITHOUT
* WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the
* License for the specific language governing permissions and limitations
* under the License.
*
****************************************************************************/
/****************************************************************************
* Included Files
****************************************************************************/
#include <nuttx/config.h>
#include <sys/types.h>
#include <sys/ioctl.h>
#include <inttypes.h>
#include <stdint.h>
#include <stdbool.h>
#include <stdio.h>
#include <fcntl.h>
#include <string.h>
#include <assert.h>
#include <debug.h>
#include <errno.h>
#include <nuttx/kmalloc.h>
#include <nuttx/signal.h>
#include <nuttx/mqueue.h>
#include <nuttx/queue.h>
#include <nuttx/fs/fs.h>
#include <nuttx/fs/ioctl.h>
#include <nuttx/audio/audio.h>
#include <nuttx/audio/vs1053.h>
#include "vs1053.h"
/****************************************************************************
* Pre-processor Definitions
****************************************************************************/
#ifndef CONFIG_VS1053_SPIMODE
# define CONFIG_VS1053_SPIMODE SPIDEV_MODE0
#endif
#ifndef CONFIG_VS1053_XTALI
# define CONFIG_VS1053_XTALI 12288000
#endif
#ifndef CONFIG_VS1053_MP3_DECODE_FREQ
# define CONFIG_VS1053_MP3_DECODE_FREQ 43000000
#endif
#ifndef CONFIG_VS1053_MSG_PRIO
# define CONFIG_VS1053_MSG_PRIO 1
#endif
#ifndef CONFIG_VS1053_BUFFER_SIZE
# define CONFIG_VS1053_BUFFER_SIZE 8192
#endif
#ifndef CONFIG_VS1053_NUM_BUFFERS
# define CONFIG_VS1053_NUM_BUFFERS 2
#endif
#ifndef CONFIG_VS1053_WORKER_STACKSIZE
# define CONFIG_VS1053_WORKER_STACKSIZE 768
#endif
#define VS1053_DUMMY 0xFF
#define VS1053_DEFAULT_XTALI 12288000
#define VS1053_DATA_FREQ 20000000
#define VS1053_RST_USECS 2000
/****************************************************************************
* Private Types
****************************************************************************/
struct vs1053_struct_s
{
/* We are an audio lower half driver */
struct audio_lowerhalf_s lower;
/* Our specific driver data goes here */
FAR const struct vs1053_lower_s *hw_lower; /* Pointer to the hardware lower functions */
FAR struct spi_dev_s *spi; /* Pointer to the SPI bus */
FAR struct ap_buffer_s *apb; /* Pointer to the buffer we are processing */
struct dq_queue_s apbq; /* Our queue for enqueued buffers */
unsigned long spi_freq; /* Frequency to run the SPI bus at. */
unsigned long chip_freq; /* Current chip frequency */
struct file mq; /* Message queue for receiving messages */
char mqname[16]; /* Our message queue name */
pthread_t threadid; /* ID of our thread */
mutex_t apbq_lock; /* Audio Pipeline Buffer Queue mutex access */
#ifndef CONFIG_AUDIO_EXCLUDE_VOLUME
int16_t volume; /* Current volume level */
#ifndef CONFIG_AUDIO_EXCLUDE_BALANCE
int16_t balance; /* Current balance level */
#endif /* CONFIG_AUDIO_EXCLUDE_BALANCE */
#endif /* CONFIG_AUDIO_EXCLUDE_VOLUME */
#ifndef CONFIG_AUDIO_EXCLUDE_TONE
uint8_t bass; /* Bass level */
uint8_t treble; /* Bass level */
#endif
uint16_t endfillbytes;
uint8_t endfillchar; /* Fill char to send when no more data */
bool running;
bool paused;
bool endmode;
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
bool cancelmode;
#endif
bool busy; /* Set true when device reserved */
};
/****************************************************************************
* Private Function Prototypes
****************************************************************************/
static int vs1053_getcaps(FAR struct audio_lowerhalf_s *lower, int type,
FAR struct audio_caps_s *caps);
static int vs1053_shutdown(FAR struct audio_lowerhalf_s *lower);
#ifdef CONFIG_AUDIO_MULTI_SESSION
static int vs1053_configure(FAR struct audio_lowerhalf_s *lower,
FAR void *session, FAR const struct audio_caps_s *caps);
static int vs1053_start(FAR struct audio_lowerhalf_s *lower,
FAR void *session);
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
static int vs1053_stop(FAR struct audio_lowerhalf_s *lower,
FAR void *session);
#endif
#ifndef CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME
static int vs1053_pause(FAR struct audio_lowerhalf_s *lower,
FAR void *session);
static int vs1053_resume(FAR struct audio_lowerhalf_s *lower,
FAR void *session);
#endif /* CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME */
static int vs1053_reserve(FAR struct audio_lowerhalf_s *lower,
FAR void** session);
static int vs1053_release(FAR struct audio_lowerhalf_s *lower,
FAR void *session);
#else
static int vs1053_configure(FAR struct audio_lowerhalf_s *lower,
FAR const struct audio_caps_s *caps);
static int vs1053_start(FAR struct audio_lowerhalf_s *lower);
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
static int vs1053_stop(FAR struct audio_lowerhalf_s *lower);
#endif
#ifndef CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME
static int vs1053_pause(FAR struct audio_lowerhalf_s *lower);
static int vs1053_resume(FAR struct audio_lowerhalf_s *lower);
#endif /* CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME */
static int vs1053_reserve(FAR struct audio_lowerhalf_s *lower);
static int vs1053_release(FAR struct audio_lowerhalf_s *lower);
#endif /* CONFIG_AUDIO_MULTI_SESION */
static int vs1053_enqueuebuffer(FAR struct audio_lowerhalf_s *lower,
FAR struct ap_buffer_s *apb);
static int vs1053_cancelbuffer(FAR struct audio_lowerhalf_s *lower,
FAR struct ap_buffer_s *apb);
static int vs1053_ioctl(FAR struct audio_lowerhalf_s *lower, int cmd,
unsigned long arg);
/****************************************************************************
* Private Data
****************************************************************************/
static const struct audio_ops_s g_audioops =
{
vs1053_getcaps, /* getcaps */
vs1053_configure, /* configure */
vs1053_shutdown, /* shutdown */
vs1053_start, /* start */
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
vs1053_stop, /* stop */
#endif
#ifndef CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME
vs1053_pause, /* pause */
vs1053_resume, /* resume */
#endif
NULL, /* alloc_buffer */
NULL, /* free_buffer */
vs1053_enqueuebuffer, /* enqueue_buffer */
vs1053_cancelbuffer, /* cancel_buffer */
vs1053_ioctl, /* ioctl */
NULL, /* read */
NULL, /* write */
vs1053_reserve, /* reserve */
vs1053_release /* release */
};
/* Volume control log table. This table is in increments of 2% of
* requested volume level and is the register value that should be
* programmed to the VS1053 to achieve that volume percentage.
*/
#ifndef CONFIG_AUDIO_EXCLUDE_VOLUME
static const uint8_t g_logtable [] =
{
254, 170, 140, 122, 110, /* 0 - 8 */
100, 92, 85, 80, 74, /* 10 - 18 */
70, 66, 62, 59, 55, /* 20 - 28 */
52, 49, 47, 44, 42, /* 30 - 38 */
40, 38, 36, 34, 32, /* 40 - 48 */
30, 28, 27, 25, 24, /* 50 - 58 */
22, 21, 19, 18, 17, /* 60 - 68 */
15, 14, 13, 12, 11, /* 70 - 78 */
10, 9, 8, 7, 6, /* 80 - 88 */
5, 4, 3, 2, 1, /* 90 - 98 */
0 /* 100 */
};
#endif /* CONFIG_AUDIO_EXCLUDE_VOLUME */
/****************************************************************************
* Private Functions
****************************************************************************/
/****************************************************************************
* Name: vs1053_spi_lock
****************************************************************************/
static void vs1053_spi_lock(FAR struct spi_dev_s *dev,
unsigned long freq_mhz)
{
/* On SPI buses where there are multiple devices, it will be necessary to
* lock SPI to have exclusive access to the buses for a sequence of
* transfers. The bus should be locked before the chip is selected.
*
* This is a blocking call and will not return until we have exclusive
* access to the SPI bus.
* We will retain that exclusive access until the bus is unlocked.
*/
SPI_LOCK(dev, true);
/* After locking the SPI bus, the we also need call the setfrequency,
* setbits, and setmode methods to make sure that the SPI is properly
* configured for the device.
* If the SPI bus is being shared, then it may have been left in an
* incompatible state.
*/
SPI_SETMODE(dev, CONFIG_VS1053_SPIMODE);
SPI_SETBITS(dev, 8);
SPI_HWFEATURES(dev, 0);
SPI_SETFREQUENCY(dev, freq_mhz);
}
/****************************************************************************
* Name: vs1053_spi_unlock
****************************************************************************/
static inline void vs1053_spi_unlock(FAR struct spi_dev_s *dev)
{
SPI_LOCK(dev, false);
}
/****************************************************************************
* Name: vs1053_readreg - Read the specified 16-bit register from the
* VS1053 device. Caller must hold the SPI lock.
****************************************************************************/
static uint16_t vs1053_readreg(FAR struct vs1053_struct_s *dev, uint8_t reg)
{
uint16_t ret;
FAR struct spi_dev_s *spi = dev->spi;
/* Select the AUDIO_CTRL device on the SPI bus */
SPI_SELECT(spi, SPIDEV_AUDIO_CTRL(0), true);
/* Send the WRITE command followed by the address */
SPI_SEND(spi, VS1053_OPCODE_READ);
SPI_SEND(spi, reg);
/* Now read the 16-bit value */
ret = SPI_SEND(spi, VS1053_DUMMY) << 8;
ret |= SPI_SEND(spi, VS1053_DUMMY);
/* Deselect the CODEC */
SPI_SELECT(spi, SPIDEV_AUDIO_CTRL(0), false);
return ret;
}
/****************************************************************************
* Name: vs1053_writereg - Write the specified 16-bit register to the
* VS1053 device. Caller must hold the SPI lock.
****************************************************************************/
static void vs1053_writereg(FAR struct vs1053_struct_s *dev,
uint8_t reg,
uint16_t val)
{
FAR struct spi_dev_s *spi = dev->spi;
/* Select the AUDIO_CTRL device on the SPI bus */
audinfo("Write Reg %d = 0x%0X\n", reg, val);
SPI_SELECT(spi, SPIDEV_AUDIO_CTRL(0), true);
/* Send the WRITE command followed by the address */
SPI_SEND(spi, VS1053_OPCODE_WRITE);
SPI_SEND(spi, reg);
/* Now read the 16-bit value */
SPI_SEND(spi, val >> 8);
SPI_SEND(spi, val & 0xff);
/* Deselect the CODEC */
SPI_SELECT(spi, SPIDEV_AUDIO_CTRL(0), false);
/* Short delay after a write for VS1053 processing time */
nxsig_usleep(10);
}
/****************************************************************************
* Name: vs1053_setfrequency
*
* Description: Get the audio device capabilities
*
****************************************************************************/
static int vs1053_setfrequency(FAR struct vs1053_struct_s *dev,
uint32_t freq)
{
double factor;
uint16_t reg;
uint8_t timeout;
audinfo("Entry\n");
/* Calculate the clock divisor based on the input frequency */
factor = (double) freq / (double) CONFIG_VS1053_XTALI * 10.0 + 0.5;
/* Check the input frequency against bounds */
if (factor > 50.0)
{
audinfo("Frequency too high! Limiting to XTALI * 5\n");
factor = 50.0;
return -EINVAL;
}
if (factor < 10.0)
{
factor = 10.0;
}
/* Calculate the clock mulit register based on the factor */
if ((int) factor == 10)
{
reg = 0;
}
else
{
reg = (((int) factor - 15) / 5) << VS1053_SC_MULT_SHIFT;
}
/* Set the MULT_ADD factor to the max to allow the chip to dynamically
* increase the frequency the maximum amount as needed
*/
reg |= (VS1053_SC_ADD_XTALI_X20 << VS1053_SC_ADD_SHIFT);
/* If we aren't running with a 12.228Mhz input crystal, then we
* must tell the chip what the frequency is
*/
if (CONFIG_VS1053_XTALI != VS1053_DEFAULT_XTALI)
{
/* Calculate register value based on equation: (XTALI - 8000000) / 4000
* per the datasheet.
*/
reg |= (CONFIG_VS1053_XTALI - 8000000) / 4000;
}
/* Now set the new clock multiplier register */
vs1053_writereg(dev, VS1053_SCI_CLOCKF, reg);
/* Wait for DREQ to go active */
timeout = 200;
while (!dev->hw_lower->read_dreq(dev->hw_lower) && timeout)
{
nxsig_usleep(1000);
timeout--;
}
/* Update our internal variables */
dev->chip_freq = freq;
dev->spi_freq = freq / 7;
return OK;
}
/****************************************************************************
* Name: vs1053_logapprox -
* Approximate the register value in .5 dB increments
* level based on the percentage using a log table since
* math libraries aren't available.
****************************************************************************/
#ifndef CONFIG_AUDIO_EXCLUDE_VOLUME
uint8_t vs1053_logapprox(int percent)
{
/* Check percentage for bounds */
if (percent >= 100)
{
return 0;
}
return (g_logtable[percent >> 1] + g_logtable[(percent + 1) >> 1]) >> 1;
}
#endif /* CONFIG_AUDIO_EXCLUDE_VOLUME */
/****************************************************************************
* Name: vs1053_setvolume -
* Set the right and left volume values in the VS1053
* device based on the current volume and balance settings.
****************************************************************************/
#ifndef CONFIG_AUDIO_EXCLUDE_VOLUME
static void vs1053_setvolume(FAR struct vs1053_struct_s *dev)
{
FAR struct spi_dev_s *spi = dev->spi;
uint32_t leftlevel;
uint32_t rightlevel;
uint8_t leftreg;
uint8_t rightreg;
/* Constrain balance */
#ifndef CONFIG_AUDIO_EXCLUDE_BALANCE
if (dev->balance > 1000)
{
dev->balance = 1000;
}
/* Calculate the left channel volume level */
if (dev->balance <= 500)
{
leftlevel = dev->volume;
}
else if (dev->balance == 1000)
{
leftlevel = 0;
}
else
{
leftlevel = dev->volume * (1000 - dev->balance) / 500;
}
/* Calculate the right channel volume level */
if (dev->balance >= 500)
{
rightlevel = dev->volume;
}
else if (dev->balance == 0)
{
rightlevel = 0;
}
else
{
rightlevel = dev->volume * dev->balance / 500;
}
#else
leftlevel = rightlevel = dev->volume;
#endif
/* Calculate the left and right register values */
/* The register sets the volume in dB which is a logrithmic scale,
* so we must use log() to calculate the register value.
*/
leftreg = vs1053_logapprox(leftlevel / 10);
rightreg = vs1053_logapprox(rightlevel / 10);
/* Lock the SPI bus to get exclusive access to the chip. */
vs1053_spi_lock(spi, dev->spi_freq);
vs1053_writereg(dev, VS1053_SCI_VOL, (leftreg << 8) | rightreg);
vs1053_spi_unlock(spi);
}
#endif /* CONFIG_AUDIO_EXCLUDE_VOLUME */
/****************************************************************************
* Name: vs1053_setbass - Set the bass and treble level as specified in the
* context's bass and treble variables..
*
* The level and range are in whole percentage levels (0-100).
*
****************************************************************************/
#ifndef CONFIG_AUDIO_EXCLUDE_TONE
static void vs1053_setbass(FAR struct vs1053_struct_s *dev)
{
FAR struct spi_dev_s *spi = dev->spi;
int bass_range;
int bass_boost;
int treble_range;
int treble_boost;
/* Calculate range and boost based on level */
bass_boost = 15 * dev->bass / 100;
bass_range = 15;
treble_boost = 15 * dev->treble / 100;
treble_range = 15;
/* Lock the SPI bus to get exclsive access to the chip. */
vs1053_spi_lock(spi, dev->spi_freq);
vs1053_writereg(dev, VS1053_SCI_BASS,
(treble_boost << 12) | (treble_range << 8) |
(bass_boost << 4) | bass_range);
vs1053_spi_unlock(spi);
}
#endif /* CONFIG_AUDIO_EXCLUDE_TONE */
/****************************************************************************
* Name: vs1053_getcaps
*
* Description: Get the audio device capabilities
*
****************************************************************************/
static int vs1053_getcaps(FAR struct audio_lowerhalf_s *lower, int type,
FAR struct audio_caps_s *caps)
{
audinfo("Entry\n");
/* Validate the structure */
DEBUGASSERT(caps->ac_len >= sizeof(struct audio_caps_s));
uint16_t *ptr;
/* Fill in the caller's structure based on requested info */
caps->ac_format.hw = 0;
caps->ac_controls.w = 0;
switch (caps->ac_type)
{
/* Caller is querying for the types of units we support */
case AUDIO_TYPE_QUERY:
/* Provide our overall capabilities. The interfacing software
* must then call us back for specific info for each capability.
*/
caps->ac_channels = 2; /* Stereo output */
switch (caps->ac_subtype)
{
case AUDIO_TYPE_QUERY:
/* The input formats we can decode / accept */
caps->ac_format.hw = 0
#ifdef CONFIG_AUDIO_FORMAT_AC3
| (1 << (AUDIO_FMT_AC3 - 1))
#endif
#ifdef CONFIG_AUDIO_FORMAT_MP3
| (1 << (AUDIO_FMT_MP3 - 1))
#endif
#ifdef CONFIG_AUDIO_FORMAT_WMA
| (1 << (AUDIO_FMT_WMA - 1))
#endif
#ifdef CONFIG_AUDIO_FORMAT_MIDI
| (1 << (AUDIO_FMT_MIDI - 1))
#endif
#ifdef CONFIG_AUDIO_FORMAT_PCM
| (1 << (AUDIO_FMT_PCM - 1))
#endif
#ifdef CONFIG_AUDIO_FORMAT_OGG_VORBIS
| (1 << (AUDIO_FMT_OGG_VORBIS - 1))
#endif
;
/* The types of audio units we implement */
caps->ac_controls.b[0] = AUDIO_TYPE_OUTPUT |
AUDIO_TYPE_FEATURE |
AUDIO_TYPE_PROCESSING;
break;
/* Report sub-formats for MIDI if requested */
#ifdef CONFIG_AUDIO_FORMAT_MIDI
case AUDIO_FMT_MIDI:
/* We only support Format 0 */
caps->ac_controls.b[0] = AUDIO_SUBFMT_MIDI_0;
caps->ac_controls.b[1] = AUDIO_SUBFMT_END;
break;
#endif
default:
caps->ac_controls.b[0] = AUDIO_SUBFMT_END;
break;
}
break;
/* Provide capabilities of our OUTPUT unit */
case AUDIO_TYPE_OUTPUT:
caps->ac_channels = 2;
switch (caps->ac_subtype)
{
case AUDIO_TYPE_QUERY:
/* Report the Sample rates we support */
ptr = (uint16_t *)caps->ac_controls.b;
*ptr = AUDIO_SAMP_RATE_8K |
AUDIO_SAMP_RATE_11K |
AUDIO_SAMP_RATE_16K |
AUDIO_SAMP_RATE_22K |
AUDIO_SAMP_RATE_32K |
AUDIO_SAMP_RATE_44K |
AUDIO_SAMP_RATE_48K;
break;
case AUDIO_FMT_MP3:
case AUDIO_FMT_WMA:
case AUDIO_FMT_PCM:
/* Report the Bit rates we support.
* The bit rate support is actually a complex function of the
* format and selected sample rate, and the datasheet has
* multiple tables to indicate the supported bit rate vs sample
* rate vsformat.
* The selected sample rate should be provided in the ac_format
* field of the query, and only a single sample rate should be
* given.
*/
/* TODO: Create a table or set of tables to report this! */
break;
default:
break;
}
break;
/* Provide capabilities of our FEATURE units */
case AUDIO_TYPE_FEATURE:
/* If the sub-type is UNDEF,
* then report the Feature Units we support
*/
if (caps->ac_subtype == AUDIO_FU_UNDEF)
{
/* Fill in the ac_controls section with the
* Feature Units we have
*/
caps->ac_controls.b[0] = AUDIO_FU_VOLUME |
AUDIO_FU_BASS |
AUDIO_FU_TREBLE;
caps->ac_controls.b[1] = AUDIO_FU_BALANCE >> 8;
}
else
{
/* TODO:
* Do we need to provide specific info for the Feature Units,
* such as volume setting ranges, etc.?
*/
}
break;
/* Provide capabilities of our PROCESSING unit */
case AUDIO_TYPE_PROCESSING:
switch (caps->ac_subtype)
{
case AUDIO_PU_UNDEF:
/* Provide the type of Processing Units we support */
caps->ac_controls.b[0] = AUDIO_PU_STEREO_EXTENDER;
break;
case AUDIO_PU_STEREO_EXTENDER:
/* Proivde capabilities of our Stereo Extender */
caps->ac_controls.b[0] = AUDIO_STEXT_ENABLE |
AUDIO_STEXT_WIDTH;
break;
default:
/* Other types of processing uint we don't support */
break;
}
break;
/* All others we don't support */
default:
/* Zero out the fields to indicate no support */
caps->ac_subtype = 0;
caps->ac_channels = 0;
break;
}
/* Return the length of the audio_caps_s struct for validation of
* proper Audio device type.
*/
return caps->ac_len;
}
/****************************************************************************
* Name: vs1053_configure
*
* Description: Configure the audio device for the specified mode of
* operation.
*
****************************************************************************/
#ifdef CONFIG_AUDIO_MULTI_SESSION
static int vs1053_configure(FAR struct audio_lowerhalf_s *lower,
FAR void *session, FAR const struct audio_caps_s *caps)
#else
static int vs1053_configure(FAR struct audio_lowerhalf_s *lower,
FAR const struct audio_caps_s *caps)
#endif
{
int ret = OK;
#if !defined(CONFIG_AUDIO_EXCLUDE_VOLUME) || !defined(CONFIG_AUDIO_EXCLUDE_TONE)
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) lower;
#endif
audinfo("Entry\n");
/* Process the configure operation */
switch (caps->ac_type)
{
case AUDIO_TYPE_FEATURE:
/* Process based on Feature Unit */
switch (caps->ac_format.hw)
{
#ifndef CONFIG_AUDIO_EXCLUDE_VOLUME
case AUDIO_FU_VOLUME:
/* Set the volume */
dev->volume = caps->ac_controls.hw[0];
vs1053_setvolume(dev);
break;
#endif /* CONFIG_AUDIO_EXCLUDE_VOLUME */
#if !defined(CONFIG_AUDIO_EXCLUDE_TONE) && !defined(CONFIG_AUDIO_EXCLUDE_VOLUME)
case AUDIO_FU_BALANCE:
/* Set the volume */
dev->balance = caps->ac_controls.hw[0];
vs1053_setvolume(dev);
break;
#endif
#ifndef CONFIG_AUDIO_EXCLUDE_TONE
case AUDIO_FU_BASS:
/* Set the bass. The percentage level (0-100) is in the
* ac_controls[0] parameter.
*/
dev->bass = caps->ac_controls.b[0];
if (dev->bass > 100)
dev->bass = 100;
vs1053_setbass(dev);
break;
case AUDIO_FU_TREBLE:
/* Set the treble. The percentage level (0-100) is in the
* ac_controls.b[0] parameter.
*/
dev->treble = caps->ac_controls.b[0];
if (dev->treble > 100)
dev->treble = 100;
vs1053_setbass(dev);
break;
#endif /* CONFIG_AUDIO_EXCLUDE_TONE */
default:
/* Others we don't support */
break;
}
break;
case AUDIO_TYPE_OUTPUT:
break;
case AUDIO_TYPE_PROCESSING:
/* We only support STEREO_EXTENDER */
if (caps->ac_format.hw == AUDIO_PU_STEREO_EXTENDER)
{
}
break;
}
return ret;
}
/****************************************************************************
* Name: vs1053_softreset
*
* Description: Performs a soft reset on the VS1053 chip by setting the
* RESET bit of the MODE register.
*
****************************************************************************/
static int vs1053_softreset(FAR struct vs1053_struct_s *dev)
{
uint16_t reg;
uint16_t timeout;
/* First disable interrupts, lower the frequency and lock the SPI bus */
dev->hw_lower->disable(dev->hw_lower); /* Disable the DREQ interrupt */
vs1053_spi_lock(dev->spi, VS1053_DEFAULT_XTALI / 7);
/* Now issue a reset command */
reg = vs1053_readreg(dev, VS1053_SCI_MODE);
vs1053_writereg(dev, VS1053_SCI_MODE, reg | VS1053_SM_RESET);
/* Now wait for the SM_RESET to go inactive */
timeout = 1000;
while (vs1053_readreg(dev, VS1053_SCI_MODE) & VS1053_SM_RESET && timeout)
{
timeout--;
}
/* Switch to low frequency, Unlock the SPI bus and exit */
vs1053_setfrequency(dev, CONFIG_VS1053_XTALI);
vs1053_spi_unlock(dev->spi);
return OK;
}
/****************************************************************************
* Name: vs1053_hardreset
*
* Description: Performs a hardware reset on the VS1053 chip by toggling
* the RST line, disabling IRQ, and setting the default
* XTALI frequency.
*
****************************************************************************/
static int vs1053_hardreset(FAR struct vs1053_struct_s *dev)
{
dev->hw_lower->disable(dev->hw_lower); /* Disable the DREQ interrupt */
dev->hw_lower->reset(dev->hw_lower, false);
nxsig_usleep(10);
dev->hw_lower->reset(dev->hw_lower, true);
nxsig_usleep(VS1053_RST_USECS);
vs1053_setfrequency(dev, CONFIG_VS1053_XTALI); /* Slow speed at first */
return OK;
}
/****************************************************************************
* Name: vs1053_shutdown
*
* Description: Shutdown the VS1053 chip and put it in the lowest power
* state possible.
*
****************************************************************************/
static int vs1053_shutdown(FAR struct audio_lowerhalf_s *lower)
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) lower;
FAR struct spi_dev_s *spi = dev->spi;
audinfo("Entry\n");
vs1053_spi_lock(spi, dev->spi_freq); /* Lock the device */
vs1053_setfrequency(dev, CONFIG_VS1053_XTALI); /* Reduce speed to minimum */
vs1053_writereg(dev, VS1053_SCI_VOL, 0xfefe); /* Power down the DAC outputs */
vs1053_spi_unlock(spi); /* Unlock the device */
return OK;
}
/****************************************************************************
* Name: vs1053_feeddata
*
* Description: Feeds more data to the vs1053 chip from the enqueued
* buffers. It will continue feeding data until the DREQ
* line indicates it can't accept any more data.
*
****************************************************************************/
static void vs1053_feeddata(FAR struct vs1053_struct_s *dev)
{
int bytecount;
int ret;
uint8_t *samp = NULL;
uint16_t reg;
struct ap_buffer_s *apb;
FAR struct spi_dev_s *spi = dev->spi;
/* Check for false interrupt caused by an SCI transaction */
if (!dev->hw_lower->read_dreq(dev->hw_lower) || dev->paused)
{
return;
}
/* Grab the SPI bus. We can run at 20Mhz because we increased the
* chip frequency above 40Mhz for the decode operation.
*/
vs1053_spi_lock(spi, VS1053_DATA_FREQ); /* Lock the SPI bus */
SPI_SELECT(spi, SPIDEV_AUDIO_DATA(0), true); /* Select the VS1053 data bus */
/* Local stack copy of our active buffer */
apb = dev->apb;
/* audinfo("Entry apb=%p, Bytes left=%d\n",
* apb, apb->nbytes - apb->curbyte);
*/
/* Setup pointer to the next sample in the buffer */
if (apb)
{
samp = &apb->samp[apb->curbyte];
}
else if (!dev->endmode)
{
SPI_SELECT(spi, SPIDEV_AUDIO_DATA(0), false);
vs1053_spi_unlock(spi);
return;
}
/* Loop until the FIFO is full */
while (dev->hw_lower->read_dreq(dev->hw_lower))
{
/* If endmode, then send fill characters */
if (dev->endmode)
{
bytecount = 32;
while (bytecount)
{
SPI_SEND(spi, dev->endfillchar);
bytecount--;
}
/* For the VS1053, after the file has been played, we must
* send 2052 bytes of endfillchar per the datasheet.
*/
dev->endfillbytes += 32;
/* Process end mode logic. We send 2080 bytes of endfillchar as
* directed by the datasheet, then set SM_CANCEL. Then we wait
* until the chip clears SM_CANCEL while sending endfillchar
* 32 bytes at a time.
*/
if (dev->endfillbytes == 32 * 65)
{
/* After at least 2052 bytes, we send an SM_CANCEL */
dev->hw_lower->disable(dev->hw_lower); /* Disable the DREQ interrupt */
SPI_SETFREQUENCY(dev->spi, dev->spi_freq);
reg = vs1053_readreg(dev, VS1053_SCI_MODE);
vs1053_writereg(dev, VS1053_SCI_MODE, reg | VS1053_SM_CANCEL);
dev->hw_lower->enable(dev->hw_lower); /* Enable the DREQ interrupt */
}
else if (dev->endfillbytes >= 32 * 130)
{
/* Do a hard reset and terminate */
vs1053_hardreset(dev);
dev->running = false;
dev->endmode = false;
break;
}
else if (dev->endfillbytes > 32 * 65)
{
/* After each 32 byte of endfillchar, check the status
* register to see if SM_CANCEL has been cleared. If
* it has been cleared, then we're done.
*/
if (!(vs1053_readreg(dev, VS1053_SCI_STATUS) &
VS1053_SM_CANCEL))
{
SPI_SETFREQUENCY(dev->spi, dev->spi_freq);
dev->hw_lower->disable(dev->hw_lower); /* Disable the DREQ interrupt */
audinfo("HDAT1: 0x%0X HDAT0: 0x%0X\n",
vs1053_readreg(dev, VS1053_SCI_HDAT1),
vs1053_readreg(dev, VS1053_SCI_HDAT0));
vs1053_writereg(dev,
VS1053_SCI_WRAMADDR,
VS1053_END_FILL_BYTE);
dev->endfillchar = vs1053_readreg(dev,
VS1053_SCI_WRAM) >> 8;
audinfo("EndFillChar: 0x%0X\n", dev->endfillchar);
reg = vs1053_readreg(dev, VS1053_SCI_MODE);
vs1053_writereg(dev,
VS1053_SCI_MODE,
reg | VS1053_SM_RESET);
dev->running = false;
dev->endmode = false;
break;
}
}
}
else
{
/* Send 32 more bytes. We only send 32 at a time because this is
* the meaning of DREQ active from the chip ... that it can
* accept at least 32 more bytes. After each 32 byte block, we
* will recheck the DREQ line again.
*/
bytecount = apb->nbytes - apb->curbyte;
if (bytecount > 32)
{
bytecount = 32;
}
#if 1
SPI_SNDBLOCK(spi, samp, bytecount);
samp += bytecount;
#else
bytecount = bytecount;
while (bytecount--)
{
/* Send next byte from the buffer */
SPI_SEND(spi, *samp);
samp++;
}
#endif
apb->curbyte += bytecount;
/* Test if we are in cancel mode. If we are, then we need
* to continue sending file data and check for the SM_CANCEL
* bit going inactive.
*/
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
if (dev->cancelmode)
{
/* Read the VS1053 MODE register */
dev->hw_lower->disable(dev->hw_lower); /* Disable the DREQ interrupt */
SPI_SETFREQUENCY(dev->spi, dev->spi_freq);
reg = vs1053_readreg(dev, VS1053_SCI_MODE);
SPI_SETFREQUENCY(dev->spi, VS1053_DATA_FREQ);
dev->hw_lower->enable(dev->hw_lower); /* Enable the DREQ interrupt */
/* Check the SM_CANCEL bit */
if (!(reg & VS1053_SM_CANCEL))
{
/* Cancel has begun. Switch to endmode */
apb->nbytes = 0;
apb->curbyte = 0;
}
}
#endif /* CONFIG_AUDIO_EXCLUDE_STOP */
/* Test if we are at the end of the buffer */
if (apb->curbyte >= apb->nbytes)
{
/* Check if this was the final buffer in stream */
if ((apb->flags & AUDIO_APB_FINAL) != 0)
{
/* This is the final buffer. Get the VS1053 endfillchar */
dev->hw_lower->disable(dev->hw_lower); /* Disable the DREQ interrupt */
SPI_SETFREQUENCY(dev->spi, dev->spi_freq);
vs1053_writereg(dev,
VS1053_SCI_WRAMADDR,
VS1053_END_FILL_BYTE);
dev->endfillchar = vs1053_readreg(dev,
VS1053_SCI_WRAM) >> 8;
SPI_SETFREQUENCY(dev->spi, VS1053_DATA_FREQ);
dev->hw_lower->enable(dev->hw_lower); /* Enable the DREQ interrupt */
/* Mark the device as endmode */
dev->endmode = true;
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
if (dev->cancelmode)
{
/* If we are in cancel mode, then we don't dequeue the
* buffer or need to send another SM_CANCEL, so jump
* into the middle of the stop sequence.
*/
dev->endfillbytes = 32 * 65 + 1;
continue;
}
else
#endif /* CONFIG_AUDIO_EXCLUDE_STOP */
{
dev->endfillbytes = 0;
}
}
/* We referenced the buffer so we must free it */
apb_free(apb);
#ifdef CONFIG_AUDIO_MULTI_SESSION
dev->lower.upper(dev->lower.priv, AUDIO_CALLBACK_DEQUEUE,
apb, OK, NULL);
#else
dev->lower.upper(dev->lower.priv, AUDIO_CALLBACK_DEQUEUE,
apb, OK);
#endif
/* Lock the buffer queue to pop the next buffer */
if ((ret = nxmutex_lock(&dev->apbq_lock)) < 0)
{
#ifdef CONFIG_AUDIO_MULTI_SESSION
dev->lower.upper(dev->lower.priv,
AUDIO_CALLBACK_IOERR, NULL, ret, NULL);
#else
dev->lower.upper(dev->lower.priv,
AUDIO_CALLBACK_IOERR, NULL, ret);
#endif
auderr("ERROR: I/O error!\n");
goto err_out;
}
/* Pop the next entry */
apb = (struct ap_buffer_s *) dq_remfirst(&dev->apbq);
dev->apb = apb;
/* audinfo("Next Buffer = %p, bytes = %d\n",
* apb, apb ? apb->nbytes : 0);
*/
if (apb == NULL)
{
nxmutex_unlock(&dev->apbq_lock);
break;
}
samp = &apb->samp[apb->curbyte];
apb_reference(apb); /* Add our buffer reference */
nxmutex_unlock(&dev->apbq_lock);
}
}
}
/* Deselect the SPI bus and unlock it */
err_out:
SPI_SELECT(spi, SPIDEV_AUDIO_DATA(0), false);
vs1053_spi_unlock(spi);
}
/****************************************************************************
* Name: vs1053_dreq_isr
*
* This is the ISR that services the DREQ pin from the VS1053, which
* indicates the chip is ready to receive additional data. We use it to
* send a message to our workertherad message queue so it knows to wake
* up and send more data.
*
****************************************************************************/
static int vs1053_dreq_isr(int irq, FAR void *context, FAR void *arg)
{
struct vs1053_struct_s *dev = (struct vs1053_struct_s *)arg;
struct audio_msg_s msg;
DEBUGASSERT(dev != NULL);
/* Now create a message and send it to the workerthread */
if (dev->running)
{
msg.msg_id = AUDIO_MSG_DATA_REQUEST;
file_mq_send(&dev->mq, (FAR const char *)&msg, sizeof(msg),
CONFIG_VS1053_MSG_PRIO);
}
else
{
msg.msg_id = AUDIO_MSG_DATA_REQUEST;
}
return 0;
}
/****************************************************************************
* Name: vs1053_workerthread
*
* This is the thread that feeds data to the chip and keeps the audio
* stream going.
*
****************************************************************************/
static void *vs1053_workerthread(pthread_addr_t pvarg)
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) pvarg;
struct audio_msg_s msg;
FAR struct ap_buffer_s *apb;
int size;
unsigned int prio;
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
uint16_t reg;
#endif
uint8_t timeout;
audinfo("Entry\n");
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
dev->cancelmode = false;
#endif
dev->endmode = false;
dev->endfillbytes = 0;
/* Fill the VS1053 FIFO with initial data. */
vs1053_feeddata(dev); /* Fill the VS1053 FIFO */
/* Wait for DREQ to go active so we can issue a READ command */
timeout = 200;
while (!dev->hw_lower->read_dreq(dev->hw_lower) && timeout)
{
nxsig_usleep(100);
timeout--;
}
/* Loop as long as we are supposed to be running */
dev->running = true;
dev->hw_lower->enable(dev->hw_lower); /* Enable the DREQ interrupt */
while (dev->running || dev->endmode)
{
if (dev->hw_lower->read_dreq(dev->hw_lower))
{
vs1053_feeddata(dev); /* Feed more data to the VS1053 FIFO */
}
/* Wait for messages from our message queue */
size = file_mq_receive(&dev->mq, (FAR char *)&msg, sizeof(msg), &prio);
/* Handle the case when we return with no message */
if (size == 0)
{
/* Should we just stop running? */
dev->running = false;
break;
}
/* Process the message */
switch (msg.msg_id)
{
/* The ISR has requested more data */
case AUDIO_MSG_DATA_REQUEST:
nxsig_usleep(500);
vs1053_feeddata(dev); /* Feed more data to the VS1053 FIFO */
break;
/* Stop the playback */
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
case AUDIO_MSG_STOP:
if (!dev->hw_lower->read_dreq(dev->hw_lower))
{
nxsig_usleep(300);
}
/* Send CANCEL message to VS1053 */
dev->hw_lower->disable(dev->hw_lower);
vs1053_spi_lock(dev->spi, dev->spi_freq);
reg = vs1053_readreg(dev, VS1053_SCI_MODE);
vs1053_writereg(dev, VS1053_SCI_MODE, reg | VS1053_SM_CANCEL);
vs1053_spi_unlock(dev->spi);
dev->hw_lower->enable(dev->hw_lower);
/* Set cancelmode */
dev->cancelmode = true;
break;
#endif
/* We will wake up when a new buffer enqueued just in case */
case AUDIO_MSG_ENQUEUE:
break;
default:
break;
}
}
/* Disable the DREQ interrupt */
dev->hw_lower->disable(dev->hw_lower);
/* Cancel any leftover buffer in our queue */
if (nxmutex_lock(&dev->apbq_lock) == OK)
{
/* Get the next buffer from the queue */
while ((apb = (FAR struct ap_buffer_s *) dq_remfirst(&dev->apbq))
!= NULL)
;
}
nxmutex_unlock(&dev->apbq_lock);
/* Free the active buffer */
if (dev->apb != NULL)
{
apb_free(dev->apb);
dev->apb = NULL;
}
/* Close the message queue */
file_mq_close(&dev->mq);
file_mq_unlink(dev->mqname);
/* Send an AUDIO_MSG_COMPLETE message to the client */
#ifdef CONFIG_AUDIO_MULTI_SESSION
dev->lower.upper(dev->lower.priv, AUDIO_CALLBACK_COMPLETE, NULL, OK, NULL);
#else
dev->lower.upper(dev->lower.priv, AUDIO_CALLBACK_COMPLETE, NULL, OK);
#endif
audinfo("Exit\n");
return NULL;
}
/****************************************************************************
* Name: vs1053_start
*
* Description: Start the configured operation (audio streaming, volume
* enabled, etc.).
*
****************************************************************************/
#ifdef CONFIG_AUDIO_MULTI_SESSION
static int vs1053_start(FAR struct audio_lowerhalf_s *lower,
FAR void *session)
#else
static int vs1053_start(FAR struct audio_lowerhalf_s *lower)
#endif
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) lower;
struct mq_attr attr;
struct sched_param sparam;
pthread_attr_t tattr;
int ret;
void *value;
audinfo("Entry\n");
vs1053_spi_lock(dev->spi, dev->spi_freq); /* Lock the device */
audinfo("Entry HDAT1=0x%0X HDAT0=0x%0X\n",
vs1053_readreg(dev, VS1053_SCI_HDAT1),
vs1053_readreg(dev, VS1053_SCI_HDAT0));
vs1053_spi_unlock(dev->spi);
/* Do a soft reset, just in case */
vs1053_softreset(dev);
/* Increase the frequency of the part during processing */
vs1053_spi_lock(dev->spi, dev->spi_freq); /* Lock the device */
vs1053_setfrequency(dev, CONFIG_VS1053_MP3_DECODE_FREQ);
audinfo("Reset HDAT1=0x%0X HDAT0=0x%0X\n",
vs1053_readreg(dev, VS1053_SCI_HDAT1),
vs1053_readreg(dev, VS1053_SCI_HDAT0));
vs1053_spi_unlock(dev->spi);
/* Create a message queue for the worker thread */
snprintf(dev->mqname, sizeof(dev->mqname), "/tmp/%" PRIXPTR,
(uintptr_t)dev);
attr.mq_maxmsg = 16;
attr.mq_msgsize = sizeof(struct audio_msg_s);
attr.mq_curmsgs = 0;
attr.mq_flags = 0;
ret = file_mq_open(&dev->mq, dev->mqname,
O_RDWR | O_CREAT, 0644, &attr);
if (ret < 0)
{
/* Error creating message queue! */
auderr("ERROR: Couldn't allocate message queue\n");
return ret;
}
/* Pop the first enqueued buffer */
if ((ret = nxmutex_lock(&dev->apbq_lock)) == OK)
{
dev->apb = (FAR struct ap_buffer_s *) dq_remfirst(&dev->apbq);
apb_reference(dev->apb); /* Add our buffer reference */
nxmutex_unlock(&dev->apbq_lock);
}
else
{
auderr("ERROR: Error getting APB Queue sem\n");
return ret;
}
/* Join any old worker thread we had created to prevent a memory leak */
if (dev->threadid != 0)
{
audinfo("Joining old thread\n");
pthread_join(dev->threadid, &value);
}
/* Start our thread for sending data to the device */
pthread_attr_init(&tattr);
sparam.sched_priority = sched_get_priority_max(SCHED_FIFO) - 3;
pthread_attr_setschedparam(&tattr, &sparam);
pthread_attr_setstacksize(&tattr, CONFIG_VS1053_WORKER_STACKSIZE);
audinfo("Starting workerthread\n");
ret = pthread_create(&dev->threadid, &tattr, vs1053_workerthread,
(pthread_addr_t) dev);
if (ret != OK)
{
auderr("ERROR: Can't create worker thread, ret=%d\n", ret);
}
else
{
pthread_setname_np(dev->threadid, "vs1053");
audinfo("Created worker thread\n");
}
return ret;
}
/****************************************************************************
* Name: vs1053_stop
*
* Description: Stop the configured operation (audio streaming, volume
* disabled, etc.).
*
****************************************************************************/
#ifndef CONFIG_AUDIO_EXCLUDE_STOP
#ifdef CONFIG_AUDIO_MULTI_SESSION
static int vs1053_stop(FAR struct audio_lowerhalf_s *lower,
FAR void *session)
#else
static int vs1053_stop(FAR struct audio_lowerhalf_s *lower)
#endif
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) lower;
struct audio_msg_s term_msg;
FAR void *value;
/* Send a message to stop all audio streaming */
term_msg.msg_id = AUDIO_MSG_STOP;
term_msg.u.data = 0;
file_mq_send(&dev->mq, (FAR const char *)&term_msg, sizeof(term_msg),
CONFIG_VS1053_MSG_PRIO);
/* Join the worker thread */
pthread_join(dev->threadid, &value);
dev->threadid = 0;
/* Reduce the decoder's operating frequency to save power */
vs1053_spi_lock(dev->spi, dev->spi_freq); /* Lock the device */
vs1053_setfrequency(dev, CONFIG_VS1053_XTALI);
vs1053_spi_unlock(dev->spi);
/* Wait for a bit */
up_mdelay(40);
return OK;
}
#endif
/****************************************************************************
* Name: vs1053_pause
*
* Description: Pauses the playback.
*
****************************************************************************/
#ifndef CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME
#ifdef CONFIG_AUDIO_MULTI_SESSION
static int vs1053_pause(FAR struct audio_lowerhalf_s *lower,
FAR void *session)
#else
static int vs1053_pause(FAR struct audio_lowerhalf_s *lower)
#endif
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) lower;
if (!dev->running)
{
return OK;
}
/* Disable interrupts to prevent us from supplying any more data */
dev->paused = true;
dev->hw_lower->disable(dev->hw_lower); /* Disable the DREQ interrupt */
return OK;
}
#endif /* CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME */
/****************************************************************************
* Name: vs1053_resume
*
* Description: Resuems the playback.
*
****************************************************************************/
#ifndef CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME
#ifdef CONFIG_AUDIO_MULTI_SESSION
static int vs1053_resume(FAR struct audio_lowerhalf_s *lower,
FAR void *session)
#else
static int vs1053_resume(FAR struct audio_lowerhalf_s *lower)
#endif
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) lower;
if (!dev->running)
{
return OK;
}
/* Enable interrupts to allow suppling data */
dev->paused = false;
vs1053_feeddata(dev);
dev->hw_lower->enable(dev->hw_lower); /* Enable the DREQ interrupt */
return OK;
}
#endif /* CONFIG_AUDIO_EXCLUDE_PAUSE_RESUME */
/****************************************************************************
* Name: vs1053_enqueuebuffer
*
* Description: Enqueue an Audio Pipeline Buffer for playback/ processing.
*
****************************************************************************/
static int vs1053_enqueuebuffer(FAR struct audio_lowerhalf_s *lower,
FAR struct ap_buffer_s *apb)
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *)lower;
struct audio_msg_s term_msg;
int ret;
audinfo("Entry\n");
/* Lock access to the apbq */
if ((ret = nxmutex_lock(&dev->apbq_lock)) == OK)
{
/* We can now safely add the buffer to the queue */
apb->curbyte = 0;
apb->flags |= AUDIO_APB_OUTPUT_ENQUEUED;
dq_addlast(&apb->dq_entry, &dev->apbq);
nxmutex_unlock(&dev->apbq_lock);
/* Send a message indicating a new buffer enqueued */
if (dev->mq.f_inode != NULL)
{
term_msg.msg_id = AUDIO_MSG_ENQUEUE;
term_msg.u.data = 0;
file_mq_send(&dev->mq, (FAR const char *)&term_msg,
sizeof(term_msg), CONFIG_VS1053_MSG_PRIO);
}
}
return ret;
}
/****************************************************************************
* Name: vs1053_cancelbuffer
*
* Description: Called when an enqueued buffer is being cancelled.
*
****************************************************************************/
static int vs1053_cancelbuffer(FAR struct audio_lowerhalf_s *lower,
FAR struct ap_buffer_s *apb)
{
return OK;
}
/****************************************************************************
* Name: vs1053_ioctl
*
* Description: Perform a device ioctl
*
****************************************************************************/
static int vs1053_ioctl(FAR struct audio_lowerhalf_s *lower, int cmd,
unsigned long arg)
{
int ret = OK;
#ifdef CONFIG_AUDIO_DRIVER_SPECIFIC_BUFFERS
FAR struct ap_buffer_info_s *bufinfo;
#endif
/* Deal with ioctls passed from the upper-half driver */
switch (cmd)
{
/* Check for AUDIOIOC_HWRESET ioctl. This ioctl is passed straight
* through from the upper-half audio driver.
*/
case AUDIOIOC_HWRESET:
vs1053_hardreset((FAR struct vs1053_struct_s *) lower);
break;
/* Report our preferred buffer size and quantity */
#ifdef CONFIG_AUDIO_DRIVER_SPECIFIC_BUFFERS
case AUDIOIOC_GETBUFFERINFO:
bufinfo = (FAR struct ap_buffer_info_s *) arg;
bufinfo->buffer_size = CONFIG_VS1053_BUFFER_SIZE;
bufinfo->nbuffers = CONFIG_VS1053_NUM_BUFFERS;
break;
#endif
default:
ret = -ENOTTY;
break;
}
return ret;
}
/****************************************************************************
* Name: vs1053_reserve
*
* Description: Reserves a session (the only one we have).
*
****************************************************************************/
#ifdef CONFIG_AUDIO_MULTI_SESSION
static int vs1053_reserve(FAR struct audio_lowerhalf_s *lower,
FAR void **psession)
#else
static int vs1053_reserve(FAR struct audio_lowerhalf_s *lower)
#endif
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) lower;
int ret;
/* Borrow the APBQ mutex for thread sync */
ret = nxmutex_lock(&dev->apbq_lock);
if (ret < 0)
{
return ret;
}
if (dev->busy)
{
ret = -EBUSY;
}
else
{
/* Initialize the session context. We don't really use it. */
#ifdef CONFIG_AUDIO_MULTI_SESSION
*psession = NULL;
#endif
dev->busy = true;
dev->running = false;
dev->paused = false;
}
nxmutex_unlock(&dev->apbq_lock);
return ret;
}
/****************************************************************************
* Name: vs1053_release
*
* Description: Releases the session (the only one we have).
*
****************************************************************************/
#ifdef CONFIG_AUDIO_MULTI_SESSION
static int vs1053_release(FAR struct audio_lowerhalf_s *lower,
FAR void *psession)
#else
static int vs1053_release(FAR struct audio_lowerhalf_s *lower)
#endif
{
FAR struct vs1053_struct_s *dev = (struct vs1053_struct_s *) lower;
void *value;
int ret;
/* Join any old worker thread we had created to prevent a memory leak */
if (dev->threadid != 0)
{
pthread_join(dev->threadid, &value);
dev->threadid = 0;
}
/* Borrow the APBQ mutex for thread sync */
ret = nxmutex_lock(&dev->apbq_lock);
if (ret < 0)
{
return ret;
}
/* Really we should free any queued buffers here */
dev->busy = false;
nxmutex_unlock(&dev->apbq_lock);
return OK;
}
/****************************************************************************
* Public Functions
****************************************************************************/
/****************************************************************************
* Name: vs1053_initialize
*
* Description:
* Initialize the VS1053 device
*
* Input Parameters:
* spidevice - This is a placeholder argument until the Audio interface
* has been flushed out a bit.
*
****************************************************************************/
struct audio_lowerhalf_s *vs1053_initialize(FAR struct spi_dev_s *spi,
FAR const struct vs1053_lower_s *lower,
unsigned int devno)
{
FAR struct vs1053_struct_s *dev;
uint16_t status;
uint8_t id;
uint8_t retry;
/* Sanity check */
DEBUGASSERT(spi != NULL);
DEBUGASSERT(lower != NULL);
DEBUGASSERT(lower->reset != NULL);
/* Allocate a VS1053 device structure */
dev = kmm_zalloc(sizeof(struct vs1053_struct_s));
if (dev)
{
/* Initialize the VS1053 device structure */
dev->lower.ops = &g_audioops;
dev->hw_lower = lower;
dev->spi_freq = CONFIG_VS1053_XTALI / 7;
dev->spi = spi;
#ifndef CONFIG_AUDIO_EXCLUDE_VOLUME
dev->volume = 250; /* 25% volume as default */
#ifndef CONFIG_AUDIO_EXCLUDE_BALANCE
dev->balance = 500; /* Center balance */
#endif
#endif
nxmutex_init(&dev->apbq_lock);
dq_init(&dev->apbq);
/* Reset the VS1053 chip */
lower->reset(lower, false);
up_udelay(10);
lower->reset(lower, true);
up_udelay(VS1053_RST_USECS);
#if CONFIG_VS1053_XTALI == VS1053_DEFAULT_XTALI
/* If we have a standard crystal, then wait extra time
* for the DREQ to be active indicating the device is ready
*/
retry = 200;
while (!lower->read_dreq(lower) && retry)
{
up_udelay(10);
retry--;
}
#endif
/* Do device detection to validate the chip is there.
* We have to hold the SPI lock during reads / writes.
*/
vs1053_spi_lock(spi, dev->spi_freq);
status = vs1053_readreg(dev, VS1053_SCI_STATUS);
vs1053_spi_unlock(spi);
/* Validate the device ID read from the chip */
id = (status & VS1053_SS_VER) >> VS1053_VER_SHIFT;
if (id != VS1053_VER_VS1053)
{
auderr("ERROR: Unexpected VER bits: 0x%0X\n", id);
kmm_free(dev);
return NULL;
}
else
{
audinfo("VS1053 Detected!\n");
}
/* Attach our ISR to this device */
dev->hw_lower->attach(dev->hw_lower, vs1053_dreq_isr, dev);
/* Do some initialization of the codec */
vs1053_shutdown(&dev->lower); /* Go to shutdown state */
}
return &dev->lower;
}