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LeafOS / LeafOS-Project / android_hardware_qcom_audio / b33b4428e5508a655b3049e839be92fe26b13059 / . / qahw_api / inc / qahw_api.h
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/*
* Copyright (c) 2016-2021, The Linux Foundation. All rights reserved.
* Not a Contribution.
*
* Copyright (C) 2011 The Android Open Source Project *
* Licensed 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.
*/
#ifndef QTI_AUDIO_QAHW_API_H
#define QTI_AUDIO_QAHW_API_H
#include <stdint.h>
#include <strings.h>
#include <sys/cdefs.h>
#include <sys/types.h>
#include <sys/time.h>
#include <cutils/bitops.h>
#include <system/audio.h>
#include "qahw_defs.h"
__BEGIN_DECLS
/*
* Helper macros for module implementors.
*
* The derived modules should provide convenience macros for supported
* versions so that implementations can explicitly specify module
* versions at definition time.
*/
#define QAHW_MAKE_API_VERSION(maj,min) \
((((maj) & 0xff) << 8) | ((min) & 0xff))
/* First generation of audio devices had version hardcoded to 0. all devices with
* versions < 1.0 will be considered of first generation API.
*/
#define QAHW_MODULE_API_VERSION_0_0 QAHW_MAKE_API_VERSION(0, 0)
/* Minimal QTI audio HAL version supported by the audio framework */
#define QAHW_MODULE_API_VERSION_MIN QAHW_MODULE_API_VERSION_0_0
/**
* List of known audio HAL modules. This is the base name of the audio HAL
* library composed of the "audio." prefix, one of the base names below and
* a suffix specific to the device.
* e.g: audio.primary.goldfish.so or audio.a2dp.default.so
*/
#define QAHW_MODULE_ID_PRIMARY "audio.primary"
#define QAHW_MODULE_ID_A2DP "audio.a2dp"
#define QAHW_MODULE_ID_USB "audio.usb"
typedef void qahw_module_handle_t;
typedef void qahw_stream_handle_t;
typedef void (*audio_error_callback)(void* context);
/**************************************/
/* Output stream specific APIs **/
/*
* This method creates and opens the audio hardware output stream.
* The "address" parameter qualifies the "devices" audio device type if needed.
* The format format depends on the device type:
* - Bluetooth devices use the MAC address of the device in the form "00:11:22:AA:BB:CC"
* - USB devices use the ALSA card and device numbers in the form "card=X;device=Y"
* - Other devices may use a number or any other string.
*/
int qahw_open_output_stream(qahw_module_handle_t *hw_module,
audio_io_handle_t handle,
audio_devices_t devices,
audio_output_flags_t flags,
struct audio_config *config,
qahw_stream_handle_t **out_handle,
const char *address);
int qahw_close_output_stream(qahw_stream_handle_t *out_handle);
/*
* Return the sampling rate in Hz - eg. 44100.
*/
uint32_t qahw_out_get_sample_rate(const qahw_stream_handle_t *stream);
/*
* use set_parameters with key QAHW_PARAMETER_STREAM_SAMPLING_RATE
*/
int qahw_out_set_sample_rate(qahw_stream_handle_t *stream, uint32_t rate);
/*
* Return size of input/output buffer in bytes for this stream - eg. 4800.
* It should be a multiple of the frame size. See also get_input_buffer_size.
*/
size_t qahw_out_get_buffer_size(const qahw_stream_handle_t *stream);
/*
* Return the channel mask -
* e.g. AUDIO_CHANNEL_OUT_STEREO or AUDIO_CHANNEL_IN_STEREO
*/
audio_channel_mask_t qahw_out_get_channels(const qahw_stream_handle_t *stream);
/*
* Return the audio format - e.g. AUDIO_FORMAT_PCM_16_BIT
*/
audio_format_t qahw_out_get_format(const qahw_stream_handle_t *stream);
/*
* Put the audio hardware input/output into standby mode.
* Driver should exit from standby mode at the next I/O operation.
* Returns 0 on success and <0 on failure.
*/
int qahw_out_standby(qahw_stream_handle_t *stream);
/*
* set/get audio stream parameters. The function accepts a list of
* parameter key value pairs in the form: key1=value1;key2=value2;...
*
* Some keys are reserved for standard parameters (See AudioParameter class)
*
* If the implementation does not accept a parameter change while
* the output is active but the parameter is acceptable otherwise, it must
* return -ENOSYS.
*
* The audio flinger will put the stream in standby and then change the
* parameter value.
*/
int qahw_out_set_parameters(qahw_stream_handle_t *stream, const char*kv_pairs);
/*
* Returns a pointer to a heap allocated string. The caller is responsible
* for freeing the memory for it using free().
*/
char* qahw_out_get_parameters(const qahw_stream_handle_t *stream,
const char *keys);
/* API to set playback stream specific config parameters */
int qahw_out_set_param_data(qahw_stream_handle_t *out_handle,
qahw_param_id param_id,
qahw_param_payload *payload);
/* API to get playback stream specific config parameters */
int qahw_out_get_param_data(qahw_stream_handle_t *out_handle,
qahw_param_id param_id,
qahw_param_payload *payload);
/*
* Return the audio hardware driver estimated latency in milliseconds.
*/
uint32_t qahw_out_get_latency(const qahw_stream_handle_t *stream);
/*
* Use this method in situations where audio mixing is done in the
* hardware. This method serves as a direct interface with hardware,
* allowing you to directly set the volume as apposed to via the framework.
* This method might produce multiple PCM outputs or hardware accelerated
* codecs, such as MP3 or AAC.
*/
int qahw_out_set_volume(qahw_stream_handle_t *stream, float left, float right);
/*
* Write audio buffer present in meta_data starting from offset
* along with timestamp to driver. Returns number of bytes
* written or a negative status_t. If at least one frame was written successfully
* prior to the error, it is suggested that the driver return that successful
* (short) byte count and then return an error in the subsequent call.
* timestamp is only sent driver is session has been opened with timestamp flag
* otherwise its ignored.
*
* If set_callback() has previously been called to enable non-blocking mode
* the write() is not allowed to block. It must write only the number of
* bytes that currently fit in the driver/hardware buffer and then return
* this byte count. If this is less than the requested write size the
* callback function must be called when more space is available in the
* driver/hardware buffer.
*/
ssize_t qahw_out_write(qahw_stream_handle_t *stream,
qahw_out_buffer_t *out_buf);
/*
* return the number of audio frames written by the audio dsp to DAC since
* the output has exited standby
*/
int qahw_out_get_render_position(const qahw_stream_handle_t *stream,
uint32_t *dsp_frames);
/*
* set the callback function for notifying completion of non-blocking
* write and drain.
* Calling this function implies that all future rite() and drain()
* must be non-blocking and use the callback to signal completion.
*/
int qahw_out_set_callback(qahw_stream_handle_t *stream,
qahw_stream_callback_t callback,
void *cookie);
/*
* Notifies to the audio driver to stop playback however the queued buffers are
* retained by the hardware. Useful for implementing pause/resume. Empty implementation
* if not supported however should be implemented for hardware with non-trivial
* latency. In the pause state audio hardware could still be using power. User may
* consider calling suspend after a timeout.
*
* Implementation of this function is mandatory for offloaded playback.
*/
int qahw_out_pause(qahw_stream_handle_t *out_handle);
/*
* Notifies to the audio driver to resume playback following a pause.
* Returns error if called without matching pause.
*
* Implementation of this function is mandatory for offloaded playback.
*/
int qahw_out_resume(qahw_stream_handle_t *out_handle);
/*
* Requests notification when data buffered by the driver/hardware has
* been played. If set_callback() has previously been called to enable
* non-blocking mode, the drain() must not block, instead it should return
* quickly and completion of the drain is notified through the callback.
* If set_callback() has not been called, the drain() must block until
* completion.
* If type==AUDIO_DRAIN_ALL, the drain completes when all previously written
* data has been played.
* If type==AUDIO_DRAIN_EARLY_NOTIFY, the drain completes shortly before all
* data for the current track has played to allow time for the framework
* to perform a gapless track switch.
*
* Drain must return immediately on stop() and flush() call
*
* Implementation of this function is mandatory for offloaded playback.
*/
int qahw_out_drain(qahw_stream_handle_t *out_handle, qahw_drain_type_t type);
/*
* Notifies to the audio driver to flush the queued data. Stream must already
* be paused before calling flush().
*
* Implementation of this function is mandatory for offloaded playback.
*/
int qahw_out_flush(qahw_stream_handle_t *out_handle);
/*
* Return a recent count of the number of audio frames presented to an external observer.
* This excludes frames which have been written but are still in the pipeline.
* The count is not reset to zero when output enters standby.
* Also returns the value of CLOCK_MONOTONIC as of this presentation count.
* The returned count is expected to be 'recent',
* but does not need to be the most recent possible value.
* However, the associated time should correspond to whatever count is returned.
* Example: assume that N+M frames have been presented, where M is a 'small' number.
* Then it is permissible to return N instead of N+M,
* and the timestamp should correspond to N rather than N+M.
* The terms 'recent' and 'small' are not defined.
* They reflect the quality of the implementation.
*
* 3.0 and higher only.
*/
int qahw_out_get_presentation_position(const qahw_stream_handle_t *out_handle,
uint64_t *frames, struct timespec *timestamp);
/* Input stream specific APIs */
/* This method creates and opens the audio hardware input stream */
int qahw_open_input_stream(qahw_module_handle_t *hw_module,
audio_io_handle_t handle,
audio_devices_t devices,
struct audio_config *config,
qahw_stream_handle_t **stream_in,
audio_input_flags_t flags,
const char *address,
audio_source_t source);
int qahw_close_input_stream(qahw_stream_handle_t *in_handle);
/*
* Return the sampling rate in Hz - eg. 44100.
*/
uint32_t qahw_in_get_sample_rate(const qahw_stream_handle_t *in_handle);
/*
* currently unused - use set_parameters with key
* QAHW_PARAMETER_STREAM_SAMPLING_RATE
*/
int qahw_in_set_sample_rate(qahw_stream_handle_t *in_handle, uint32_t rate);
/*
* Return size of input/output buffer in bytes for this stream - eg. 4800.
* It should be a multiple of the frame size. See also get_input_buffer_size.
*/
size_t qahw_in_get_buffer_size(const qahw_stream_handle_t *in_handle);
/*
* Return the channel mask -
* e.g. AUDIO_CHANNEL_OUT_STEREO or AUDIO_CHANNEL_IN_STEREO
*/
audio_channel_mask_t qahw_in_get_channels(const qahw_stream_handle_t *in_handle);
/*
* Return the audio format - e.g. AUDIO_FORMAT_PCM_16_BIT
*/
audio_format_t qahw_in_get_format(const qahw_stream_handle_t *in_handle);
/*
* currently unused - use set_parameters with key
* QAHW_PARAMETER_STREAM_FORMAT
*/
int qahw_in_set_format(qahw_stream_handle_t *in_handle, audio_format_t format);
/*
* Put the audio hardware input/output into standby mode.
* Driver should exit from standby mode at the next I/O operation.
* Returns 0 on success and <0 on failure.
*/
int qahw_in_standby(qahw_stream_handle_t *in_handle);
/*
* set/get audio stream parameters. The function accepts a list of
* parameter key value pairs in the form: key1=value1;key2=value2;...
*
* Some keys are reserved for standard parameters (See AudioParameter class)
*
* If the implementation does not accept a parameter change while
* the output is active but the parameter is acceptable otherwise, it must
* return -ENOSYS.
*
* The audio flinger will put the stream in standby and then change the
* parameter value.
*/
int qahw_in_set_parameters(qahw_stream_handle_t *in_handle, const char *kv_pairs);
/*
* Returns a pointer to a heap allocated string. The caller is responsible
* for freeing the memory for it using free().
*/
char* qahw_in_get_parameters(const qahw_stream_handle_t *in_handle,
const char *keys);
/*
* Read audio buffer in from audio driver. Returns number of bytes read, or a
* negative status_t. meta_data structure is filled buffer pointer, start
* offset and valid catpure timestamp (if session is opened with timetamp flag)
* and buffer. if at least one frame was read prior to the error,
* read should return that byte count and then return an error in the
* subsequent call.
*/
ssize_t qahw_in_read(qahw_stream_handle_t *in_handle,
qahw_in_buffer_t *in_buf);
/*
* Stop input stream. Returns zero on success.
*/
int qahw_in_stop(qahw_stream_handle_t *in_handle);
/*
* Return the amount of input frames lost in the audio driver since the
* last call of this function.
* Audio driver is expected to reset the value to 0 and restart counting
* upon returning the current value by this function call.
* Such loss typically occurs when the user space process is blocked
* longer than the capacity of audio driver buffers.
*
* Unit: the number of input audio frames
*/
uint32_t qahw_in_get_input_frames_lost(qahw_stream_handle_t *in_handle);
/*
* Return a recent count of the number of audio frames received and
* the clock time associated with that frame count.
*
* frames is the total frame count received. This should be as early in
* the capture pipeline as possible. In general,
* frames should be non-negative and should not go "backwards".
*
* time is the clock MONOTONIC time when frames was measured. In general,
* time should be a positive quantity and should not go "backwards".
*
* The status returned is 0 on success, -ENOSYS if the device is not
* ready/available, or -EINVAL if the arguments are null or otherwise invalid.
*/
int qahw_in_get_capture_position(const qahw_stream_handle_t *in_handle,
int64_t *frames, int64_t *time);
/* API to set capture stream specific config parameters */
int qahw_in_set_param_data(qahw_stream_handle_t *in_handle,
qahw_param_id param_id,
qahw_param_payload *payload);
/* Module specific APIs */
/* convenience API for opening and closing an audio HAL module */
qahw_module_handle_t *qahw_load_module(const char *hw_module_id);
int qahw_unload_module(qahw_module_handle_t *hw_module);
/*
* check to see if the audio hardware interface has been initialized.
* returns 0 on success, -ENODEV on failure.
*/
int qahw_init_check(const qahw_module_handle_t *hw_module);
/* set the audio volume of a voice call. Range is between 0.0 and 1.0 */
int qahw_set_voice_volume(qahw_module_handle_t *hw_module, float volume);
/*
* set_mode is called when the audio mode changes. AUDIO_MODE_NORMAL mode
* is for standard audio playback, AUDIO_MODE_RINGTONE when a ringtone is
* playing, and AUDIO_MODE_IN_CALL when a call is in progress.
*/
int qahw_set_mode(qahw_module_handle_t *hw_module, audio_mode_t mode);
/* Mute/unmute mic during voice/voip/HFP call */
int qahw_set_mic_mute(qahw_module_handle_t *hw_module, bool state);
/* Get mute/unmute status of mic during voice call */
int qahw_get_mic_mute(qahw_module_handle_t *hw_module, bool *state);
/* set/get global audio parameters */
int qahw_set_parameters(qahw_module_handle_t *hw_module, const char *kv_pairs);
/*
* Returns a pointer to a heap allocated string. The caller is responsible
* for freeing the memory for it using free().
*/
char* qahw_get_parameters(const qahw_module_handle_t *hw_module,
const char *keys);
/* Returns audio input buffer size according to parameters passed or
* 0 if one of the parameters is not supported.
* See also get_buffer_size which is for a particular stream.
*/
size_t qahw_get_input_buffer_size(const qahw_module_handle_t *hw_module,
const struct audio_config *config);
/*returns current QTI HAL version */
int qahw_get_version();
/* Api to implement get parameters based on keyword param_id
* and store data in payload.
*/
int qahw_get_param_data(const qahw_module_handle_t *hw_module,
qahw_param_id param_id,
qahw_param_payload *payload);
/* Api to implement set parameters based on keyword param_id
* and data present in payload.
*/
int qahw_set_param_data(const qahw_module_handle_t *hw_module,
qahw_param_id param_id,
qahw_param_payload *payload);
/* Creates an audio patch between several source and sink ports.
* The handle is allocated by the HAL and should be unique for this
* audio HAL module.
*/
int qahw_create_audio_patch(qahw_module_handle_t *hw_module,
unsigned int num_sources,
const struct audio_port_config *sources,
unsigned int num_sinks,
const struct audio_port_config *sinks,
audio_patch_handle_t *handle);
int qahw_create_audio_patch_v2(qahw_module_handle_t *hw_module,
qahw_source_port_config_t *source_port_config,
qahw_sink_port_config_t *sink_port_config,
audio_patch_handle_t *handle);
/* Release an audio patch */
int qahw_release_audio_patch(qahw_module_handle_t *hw_module,
audio_patch_handle_t handle);
/* API to set loopback stream specific config parameters */
int qahw_loopback_set_param_data(qahw_module_handle_t *hw_module,
audio_patch_handle_t handle,
qahw_loopback_param_id param_id,
qahw_loopback_param_payload *payload);
/* Fills the list of supported attributes for a given audio port.
* As input, "port" contains the information (type, role, address etc...)
* needed by the HAL to identify the port.
* As output, "port" contains possible attributes (sampling rates, formats,
* channel masks, gain controllers...) for this port.
*/
int qahw_get_audio_port(qahw_module_handle_t *hw_module,
struct audio_port *port);
/* Set audio port configuration */
int qahw_set_audio_port_config(qahw_module_handle_t *hw_module,
const struct audio_port_config *config);
void qahw_register_qas_death_notify_cb(audio_error_callback cb, void* context);
/* updated new stream APIs to support voice and Audio use cases */
int qahw_stream_open(qahw_module_handle_t *hw_module,
struct qahw_stream_attributes attr,
uint32_t num_of_devices,
qahw_device_t *devices,
uint32_t no_of_modifiers,
struct qahw_modifier_kv *modifiers,
qahw_stream_callback_t cb,
void *cookie,
qahw_stream_handle_t **stream_handle);
int qahw_stream_close(qahw_stream_handle_t *stream_handle);
int qahw_stream_start(qahw_stream_handle_t *stream_handle);
int qahw_stream_stop(qahw_stream_handle_t *stream_handle);
int qahw_stream_set_device(qahw_stream_handle_t *stream_handle,
uint32_t num_of_dev,
qahw_device_t *devices);
int qahw_stream_get_device(qahw_stream_handle_t *stream_handle,
uint32_t *num_of_dev,
qahw_device_t **devices);
int qahw_stream_set_volume(qahw_stream_handle_t *stream_handle,
struct qahw_volume_data vol_data);
int qahw_stream_get_volume(qahw_stream_handle_t *stream_handle,
struct qahw_volume_data **vol_data);
int qahw_stream_set_mute(qahw_stream_handle_t *stream_handle,
struct qahw_mute_data mute_data);
int qahw_stream_get_mute(qahw_stream_handle_t *stream_handle,
struct qahw_mute_data *mute_data);
ssize_t qahw_stream_read(qahw_stream_handle_t *stream_handle,
qahw_buffer_t *in_buf);
ssize_t qahw_stream_write(qahw_stream_handle_t *stream_handle,
qahw_buffer_t *out_buf);
int32_t qahw_stream_pause(qahw_stream_handle_t *stream_handle);
int32_t qahw_stream_standby(qahw_stream_handle_t *stream_handle);
int32_t qahw_stream_resume(qahw_stream_handle_t *stream_handle);
int32_t qahw_stream_flush(qahw_stream_handle_t *stream_handle);
int32_t qahw_stream_drain(qahw_stream_handle_t *stream_handle,
qahw_drain_type_t type);
int32_t qahw_stream_get_buffer_size(const qahw_stream_handle_t *stream_handle,
size_t *in_buffer, size_t *out_buffer);
int32_t qahw_stream_set_buffer_size(const qahw_stream_handle_t *stream_handle,
size_t in_buffer, size_t out_buffer);
int32_t qahw_stream_set_parameters(qahw_stream_handle_t *stream_handle,
uint32_t param_id,
qahw_param_payload *param_payload);
int32_t qahw_stream_get_parameters(qahw_stream_handle_t *stream_handle,
uint32_t param_id,
qahw_param_payload *param_payload);
__END_DECLS
#endif // QTI_AUDIO_QAHW_API_H