1 /*
2  * Copyright (C) 2011 The Android Open Source Project
3  *
4  * Licensed under the Apache License, Version 2.0 (the "License");
5  * you may not use this file except in compliance with the License.
6  * You may obtain a copy of the License at
7  *
8  *      http://www.apache.org/licenses/LICENSE-2.0
9  *
10  * Unless required by applicable law or agreed to in writing, software
11  * distributed under the License is distributed on an "AS IS" BASIS,
12  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
13  * See the License for the specific language governing permissions and
14  * limitations under the License.
15  */
16 
17 
18 #ifndef ANDROID_AUDIO_CORE_H
19 #define ANDROID_AUDIO_CORE_H
20 
21 #include <stdbool.h>
22 #include <stdint.h>
23 #include <stdio.h>
24 #include <string.h>
25 #include <sys/cdefs.h>
26 #include <sys/types.h>
27 
28 #include "audio-base-utils.h"
29 #include "audio-base.h"
30 #include "audio-hal-enums.h"
31 #include "audio_common-base.h"
32 
33 /*
34  * Annotation to tell clang that we intend to fall through from one case to
35  * another in a switch. Sourced from android-base/macros.h.
36  */
37 #ifndef FALLTHROUGH_INTENDED
38 #ifdef __cplusplus
39 #define FALLTHROUGH_INTENDED [[fallthrough]]
40 #elif __has_attribute(fallthrough)
41 #define FALLTHROUGH_INTENDED __attribute__((__fallthrough__))
42 #else
43 #define FALLTHROUGH_INTENDED
44 #endif // __cplusplus
45 #endif // FALLTHROUGH_INTENDED
46 
47 __BEGIN_DECLS
48 
49 /* The enums were moved here mostly from
50  * frameworks/base/include/media/AudioSystem.h
51  */
52 
53 /* represents an invalid uid for tracks; the calling or client uid is often substituted. */
54 #define AUDIO_UID_INVALID ((uid_t)-1)
55 
56 /* device address used to refer to the standard remote submix */
57 #define AUDIO_REMOTE_SUBMIX_DEVICE_ADDRESS "0"
58 
59 /* AudioFlinger and AudioPolicy services use I/O handles to identify audio sources and sinks */
60 typedef int audio_io_handle_t;
61 
62 /* Null values for handles. */
63 enum {
64     AUDIO_IO_HANDLE_NONE = 0,
65     AUDIO_MODULE_HANDLE_NONE = 0,
66     AUDIO_PORT_HANDLE_NONE = 0,
67     AUDIO_PATCH_HANDLE_NONE = 0,
68 };
69 
70 typedef enum {
71 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
72     AUDIO_MODE_INVALID = -2, // (-2)
73     AUDIO_MODE_CURRENT = -1, // (-1)
74 #endif // AUDIO_NO_SYSTEM_DECLARATIONS
75     AUDIO_MODE_NORMAL = HAL_AUDIO_MODE_NORMAL,
76     AUDIO_MODE_RINGTONE = HAL_AUDIO_MODE_RINGTONE,
77     AUDIO_MODE_IN_CALL = HAL_AUDIO_MODE_IN_CALL,
78     AUDIO_MODE_IN_COMMUNICATION = HAL_AUDIO_MODE_IN_COMMUNICATION,
79     AUDIO_MODE_CALL_SCREEN = HAL_AUDIO_MODE_CALL_SCREEN,
80 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
81     AUDIO_MODE_MAX            = AUDIO_MODE_CALL_SCREEN,
82     AUDIO_MODE_CNT            = AUDIO_MODE_MAX + 1,
83 #endif // AUDIO_NO_SYSTEM_DECLARATIONS
84 } audio_mode_t;
85 
86 /* Do not change these values without updating their counterparts
87  * in frameworks/base/media/java/android/media/AudioAttributes.java
88  */
89 typedef enum {
90     AUDIO_FLAG_NONE                       = 0x0,
91     AUDIO_FLAG_AUDIBILITY_ENFORCED        = 0x1,
92     AUDIO_FLAG_SECURE                     = 0x2,
93     AUDIO_FLAG_SCO                        = 0x4,
94     AUDIO_FLAG_BEACON                     = 0x8,
95     AUDIO_FLAG_HW_AV_SYNC                 = 0x10,
96     AUDIO_FLAG_HW_HOTWORD                 = 0x20,
97     AUDIO_FLAG_BYPASS_INTERRUPTION_POLICY = 0x40,
98     AUDIO_FLAG_BYPASS_MUTE                = 0x80,
99     AUDIO_FLAG_LOW_LATENCY                = 0x100,
100     AUDIO_FLAG_DEEP_BUFFER                = 0x200,
101     AUDIO_FLAG_NO_MEDIA_PROJECTION        = 0X400,
102     AUDIO_FLAG_MUTE_HAPTIC                = 0x800,
103     AUDIO_FLAG_NO_SYSTEM_CAPTURE          = 0X1000,
104     AUDIO_FLAG_CAPTURE_PRIVATE            = 0X2000,
105 } audio_flags_mask_t;
106 
107 /* Audio attributes */
108 #define AUDIO_ATTRIBUTES_TAGS_MAX_SIZE 256
109 typedef struct {
110     audio_content_type_t content_type;
111     audio_usage_t        usage;
112     audio_source_t       source;
113     audio_flags_mask_t   flags;
114     char                 tags[AUDIO_ATTRIBUTES_TAGS_MAX_SIZE]; /* UTF8 */
115 } __attribute__((packed)) audio_attributes_t; // sent through Binder;
116 
117 static const audio_attributes_t AUDIO_ATTRIBUTES_INITIALIZER = {
118     /* .content_type = */ AUDIO_CONTENT_TYPE_UNKNOWN,
119     /* .usage = */ AUDIO_USAGE_UNKNOWN,
120     /* .source = */ AUDIO_SOURCE_DEFAULT,
121     /* .flags = */ AUDIO_FLAG_NONE,
122     /* .tags = */ ""
123 };
124 
attributes_initializer(audio_usage_t usage)125 static inline audio_attributes_t attributes_initializer(audio_usage_t usage)
126 {
127     audio_attributes_t attributes = AUDIO_ATTRIBUTES_INITIALIZER;
128     attributes.usage = usage;
129     return attributes;
130 }
131 
attributes_initializer_flags(audio_flags_mask_t flags)132 static inline audio_attributes_t attributes_initializer_flags(audio_flags_mask_t flags)
133 {
134     audio_attributes_t attributes = AUDIO_ATTRIBUTES_INITIALIZER;
135     attributes.flags = flags;
136     return attributes;
137 }
138 
audio_flags_to_audio_output_flags(const audio_flags_mask_t audio_flags,audio_output_flags_t * flags)139 static inline void audio_flags_to_audio_output_flags(
140                                            const audio_flags_mask_t audio_flags,
141                                            audio_output_flags_t *flags)
142 {
143     if ((audio_flags & AUDIO_FLAG_HW_AV_SYNC) != 0) {
144         *flags = (audio_output_flags_t)(*flags |
145             AUDIO_OUTPUT_FLAG_HW_AV_SYNC | AUDIO_OUTPUT_FLAG_DIRECT);
146     }
147     if ((audio_flags & AUDIO_FLAG_LOW_LATENCY) != 0) {
148         *flags = (audio_output_flags_t)(*flags | AUDIO_OUTPUT_FLAG_FAST);
149     }
150     // check deep buffer after flags have been modified above
151     if (*flags == AUDIO_OUTPUT_FLAG_NONE && (audio_flags & AUDIO_FLAG_DEEP_BUFFER) != 0) {
152         *flags = AUDIO_OUTPUT_FLAG_DEEP_BUFFER;
153     }
154 }
155 
156 
157 /* A unique ID allocated by AudioFlinger for use as an audio_io_handle_t, audio_session_t,
158  * audio_effect_handle_t, audio_module_handle_t, and audio_patch_handle_t.
159  * Audio port IDs (audio_port_handle_t) are allocated by AudioPolicy
160  * in a different namespace than AudioFlinger unique IDs.
161  */
162 typedef int audio_unique_id_t;
163 
164 /* A unique ID with use AUDIO_UNIQUE_ID_USE_EFFECT */
165 typedef int audio_effect_handle_t;
166 
167 /* Possible uses for an audio_unique_id_t */
168 typedef enum {
169     AUDIO_UNIQUE_ID_USE_UNSPECIFIED = 0,
170     AUDIO_UNIQUE_ID_USE_SESSION = 1, // audio_session_t
171                                      // for allocated sessions, not special AUDIO_SESSION_*
172     AUDIO_UNIQUE_ID_USE_MODULE = 2,  // audio_module_handle_t
173     AUDIO_UNIQUE_ID_USE_EFFECT = 3,  // audio_effect_handle_t
174     AUDIO_UNIQUE_ID_USE_PATCH = 4,   // audio_patch_handle_t
175     AUDIO_UNIQUE_ID_USE_OUTPUT = 5,  // audio_io_handle_t
176     AUDIO_UNIQUE_ID_USE_INPUT = 6,   // audio_io_handle_t
177     AUDIO_UNIQUE_ID_USE_CLIENT = 7,  // client-side players and recorders
178                                      // FIXME should move to a separate namespace;
179                                      // these IDs are allocated by AudioFlinger on client request,
180                                      // but are never used by AudioFlinger
181     AUDIO_UNIQUE_ID_USE_MAX = 8,     // must be a power-of-two
182     AUDIO_UNIQUE_ID_USE_MASK = AUDIO_UNIQUE_ID_USE_MAX - 1
183 } audio_unique_id_use_t;
184 
185 /* Return the use of an audio_unique_id_t */
audio_unique_id_get_use(audio_unique_id_t id)186 static inline audio_unique_id_use_t audio_unique_id_get_use(audio_unique_id_t id)
187 {
188     return (audio_unique_id_use_t) (id & AUDIO_UNIQUE_ID_USE_MASK);
189 }
190 
191 typedef enum {
192     AUDIO_SESSION_DEVICE = HAL_AUDIO_SESSION_DEVICE,
193     AUDIO_SESSION_OUTPUT_STAGE = HAL_AUDIO_SESSION_OUTPUT_STAGE,
194     AUDIO_SESSION_OUTPUT_MIX = HAL_AUDIO_SESSION_OUTPUT_MIX,
195 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
196     AUDIO_SESSION_ALLOCATE = 0,
197     AUDIO_SESSION_NONE = 0,
198 #endif
199 } audio_session_t;
200 
201 /* Reserved audio_unique_id_t values.  FIXME: not a complete list. */
202 #define AUDIO_UNIQUE_ID_ALLOCATE AUDIO_SESSION_ALLOCATE
203 
204 /* returns true if the audio session ID corresponds to a global
205  * effect sessions (e.g. OUTPUT_MIX, OUTPUT_STAGE, or DEVICE).
206  */
audio_is_global_session(audio_session_t session)207 static inline bool audio_is_global_session(audio_session_t session) {
208     return session <= AUDIO_SESSION_OUTPUT_MIX;
209 }
210 
211 /* These constants are used instead of "magic numbers" for
212  * channel counts.
213  */
214 enum {
215     FCC_1 = 1,
216     FCC_2 = 2,
217     FCC_8 = 8,
218     FCC_12 = 12,
219     FCC_24 = 24,
220     // FCC_LIMIT is the maximum PCM channel count supported through
221     // the mixing pipeline to the audio HAL.
222     //
223     // This can be adjusted onto a value such as FCC_12 or FCC_24
224     // if the device HAL can support it.  Do not reduce below FCC_8.
225     FCC_LIMIT = FCC_12,
226 };
227 
228 /* A channel mask per se only defines the presence or absence of a channel, not the order.
229  * But see AUDIO_INTERLEAVE_* below for the platform convention of order.
230  *
231  * audio_channel_mask_t is an opaque type and its internal layout should not
232  * be assumed as it may change in the future.
233  * Instead, always use the functions declared in this header to examine.
234  *
235  * These are the current representations:
236  *
237  *   AUDIO_CHANNEL_REPRESENTATION_POSITION
238  *     is a channel mask representation for position assignment.
239  *     Each low-order bit corresponds to the spatial position of a transducer (output),
240  *     or interpretation of channel (input).
241  *     The user of a channel mask needs to know the context of whether it is for output or input.
242  *     The constants AUDIO_CHANNEL_OUT_* or AUDIO_CHANNEL_IN_* apply to the bits portion.
243  *     It is not permitted for no bits to be set.
244  *
245  *   AUDIO_CHANNEL_REPRESENTATION_INDEX
246  *     is a channel mask representation for index assignment.
247  *     Each low-order bit corresponds to a selected channel.
248  *     There is no platform interpretation of the various bits.
249  *     There is no concept of output or input.
250  *     It is not permitted for no bits to be set.
251  *
252  * All other representations are reserved for future use.
253  *
254  * Warning: current representation distinguishes between input and output, but this will not the be
255  * case in future revisions of the platform. Wherever there is an ambiguity between input and output
256  * that is currently resolved by checking the channel mask, the implementer should look for ways to
257  * fix it with additional information outside of the mask.
258  */
259 
260 /* log(2) of maximum number of representations, not part of public API */
261 #define AUDIO_CHANNEL_REPRESENTATION_LOG2   2
262 
263 /* The return value is undefined if the channel mask is invalid. */
audio_channel_mask_get_bits(audio_channel_mask_t channel)264 static inline uint32_t audio_channel_mask_get_bits(audio_channel_mask_t channel)
265 {
266     return channel & ((1 << AUDIO_CHANNEL_COUNT_MAX) - 1);
267 }
268 
269 typedef enum {
270     AUDIO_CHANNEL_REPRESENTATION_POSITION   = 0x0u,
271     AUDIO_CHANNEL_REPRESENTATION_INDEX      = 0x2u,
272 } audio_channel_representation_t;
273 
274 /* The return value is undefined if the channel mask is invalid. */
audio_channel_mask_get_representation(audio_channel_mask_t channel)275 static inline audio_channel_representation_t audio_channel_mask_get_representation(
276         audio_channel_mask_t channel)
277 {
278     // The right shift should be sufficient, but also "and" for safety in case mask is not 32 bits
279     return (audio_channel_representation_t)
280             ((channel >> AUDIO_CHANNEL_COUNT_MAX) & ((1 << AUDIO_CHANNEL_REPRESENTATION_LOG2) - 1));
281 }
282 
283 #ifdef __cplusplus
284 // Some effects use `int32_t` directly for channel mask.
audio_channel_mask_get_representation(int32_t mask)285 static inline uint32_t audio_channel_mask_get_representation(int32_t mask) {
286     return audio_channel_mask_get_representation(static_cast<audio_channel_mask_t>(mask));
287 }
288 #endif
289 
290 /* Returns true if the channel mask is valid,
291  * or returns false for AUDIO_CHANNEL_NONE, AUDIO_CHANNEL_INVALID, and other invalid values.
292  * This function is unable to determine whether a channel mask for position assignment
293  * is invalid because an output mask has an invalid output bit set,
294  * or because an input mask has an invalid input bit set.
295  * All other APIs that take a channel mask assume that it is valid.
296  */
audio_channel_mask_is_valid(audio_channel_mask_t channel)297 static inline bool audio_channel_mask_is_valid(audio_channel_mask_t channel)
298 {
299     uint32_t bits = audio_channel_mask_get_bits(channel);
300     audio_channel_representation_t representation = audio_channel_mask_get_representation(channel);
301     switch (representation) {
302     case AUDIO_CHANNEL_REPRESENTATION_POSITION:
303     case AUDIO_CHANNEL_REPRESENTATION_INDEX:
304         break;
305     default:
306         bits = 0;
307         break;
308     }
309     return bits != 0;
310 }
311 
312 /* Not part of public API */
audio_channel_mask_from_representation_and_bits(audio_channel_representation_t representation,uint32_t bits)313 static inline audio_channel_mask_t audio_channel_mask_from_representation_and_bits(
314         audio_channel_representation_t representation, uint32_t bits)
315 {
316     return (audio_channel_mask_t) ((representation << AUDIO_CHANNEL_COUNT_MAX) | bits);
317 }
318 
319 /**
320  * Expresses the convention when stereo audio samples are stored interleaved
321  * in an array.  This should improve readability by allowing code to use
322  * symbolic indices instead of hard-coded [0] and [1].
323  *
324  * For multi-channel beyond stereo, the platform convention is that channels
325  * are interleaved in order from least significant channel mask bit to most
326  * significant channel mask bit, with unused bits skipped.  Any exceptions
327  * to this convention will be noted at the appropriate API.
328  */
329 enum {
330     AUDIO_INTERLEAVE_LEFT = 0,
331     AUDIO_INTERLEAVE_RIGHT = 1,
332 };
333 
334 /* This enum is deprecated */
335 typedef enum {
336     AUDIO_IN_ACOUSTICS_NONE          = 0,
337     AUDIO_IN_ACOUSTICS_AGC_ENABLE    = 0x0001,
338     AUDIO_IN_ACOUSTICS_AGC_DISABLE   = 0,
339     AUDIO_IN_ACOUSTICS_NS_ENABLE     = 0x0002,
340     AUDIO_IN_ACOUSTICS_NS_DISABLE    = 0,
341     AUDIO_IN_ACOUSTICS_TX_IIR_ENABLE = 0x0004,
342     AUDIO_IN_ACOUSTICS_TX_DISABLE    = 0,
343 } audio_in_acoustics_t;
344 
345 /* Additional information about compressed streams offloaded to
346  * hardware playback
347  * The version and size fields must be initialized by the caller by using
348  * one of the constants defined here.
349  * Must be aligned to transmit as raw memory through Binder.
350  */
351 typedef struct {
352     uint16_t version;                   // version of the info structure
353     uint16_t size;                      // total size of the structure including version and size
354     uint32_t sample_rate;               // sample rate in Hz
355     audio_channel_mask_t channel_mask;  // channel mask
356     audio_format_t format;              // audio format
357     audio_stream_type_t stream_type;    // stream type
358     uint32_t bit_rate;                  // bit rate in bits per second
359     int64_t duration_us;                // duration in microseconds, -1 if unknown
360     bool has_video;                     // true if stream is tied to a video stream
361     bool is_streaming;                  // true if streaming, false if local playback
362     uint32_t bit_width;
363     uint32_t offload_buffer_size;       // offload fragment size
364     audio_usage_t usage;
365     audio_encapsulation_mode_t encapsulation_mode;  // version 0.2:
366     int32_t content_id;                 // version 0.2: content id from tuner hal (0 if none)
367     int32_t sync_id;                    // version 0.2: sync id from tuner hal (0 if none)
368 } __attribute__((aligned(8))) audio_offload_info_t;
369 
370 #define AUDIO_MAKE_OFFLOAD_INFO_VERSION(maj,min) \
371             ((((maj) & 0xff) << 8) | ((min) & 0xff))
372 
373 #define AUDIO_OFFLOAD_INFO_VERSION_0_2 AUDIO_MAKE_OFFLOAD_INFO_VERSION(0, 2)
374 #define AUDIO_OFFLOAD_INFO_VERSION_CURRENT AUDIO_OFFLOAD_INFO_VERSION_0_2
375 
376 static const audio_offload_info_t AUDIO_INFO_INITIALIZER = {
377     /* .version = */ AUDIO_OFFLOAD_INFO_VERSION_CURRENT,
378     /* .size = */ sizeof(audio_offload_info_t),
379     /* .sample_rate = */ 0,
380     /* .channel_mask = */ AUDIO_CHANNEL_NONE,
381     /* .format = */ AUDIO_FORMAT_DEFAULT,
382     /* .stream_type = */ AUDIO_STREAM_VOICE_CALL,
383     /* .bit_rate = */ 0,
384     /* .duration_us = */ 0,
385     /* .has_video = */ false,
386     /* .is_streaming = */ false,
387     /* .bit_width = */ 16,
388     /* .offload_buffer_size = */ 0,
389     /* .usage = */ AUDIO_USAGE_UNKNOWN,
390     /* .encapsulation_mode = */ AUDIO_ENCAPSULATION_MODE_NONE,
391     /* .content_id = */ 0,
392     /* .sync_id = */ 0,
393 };
394 
395 /* common audio stream configuration parameters
396  * You should memset() the entire structure to zero before use to
397  * ensure forward compatibility
398  * Must be aligned to transmit as raw memory through Binder.
399  */
400 struct __attribute__((aligned(8))) audio_config {
401     uint32_t sample_rate;
402     audio_channel_mask_t channel_mask;
403     audio_format_t  format;
404     audio_offload_info_t offload_info;
405     uint32_t frame_count;
406 };
407 typedef struct audio_config audio_config_t;
408 
409 static const audio_config_t AUDIO_CONFIG_INITIALIZER = {
410     /* .sample_rate = */ 0,
411     /* .channel_mask = */ AUDIO_CHANNEL_NONE,
412     /* .format = */ AUDIO_FORMAT_DEFAULT,
413     /* .offload_info = */ {
414         /* .version = */ AUDIO_OFFLOAD_INFO_VERSION_CURRENT,
415         /* .size = */ sizeof(audio_offload_info_t),
416         /* .sample_rate = */ 0,
417         /* .channel_mask = */ AUDIO_CHANNEL_NONE,
418         /* .format = */ AUDIO_FORMAT_DEFAULT,
419         /* .stream_type = */ AUDIO_STREAM_VOICE_CALL,
420         /* .bit_rate = */ 0,
421         /* .duration_us = */ 0,
422         /* .has_video = */ false,
423         /* .is_streaming = */ false,
424         /* .bit_width = */ 16,
425         /* .offload_buffer_size = */ 0,
426         /* .usage = */ AUDIO_USAGE_UNKNOWN,
427         /* .encapsulation_mode = */ AUDIO_ENCAPSULATION_MODE_NONE,
428         /* .content_id = */ 0,
429         /* .sync_id = */ 0,
430     },
431     /* .frame_count = */ 0,
432 };
433 
434 struct audio_config_base {
435     uint32_t sample_rate;
436     audio_channel_mask_t channel_mask;
437     audio_format_t  format;
438 };
439 
440 typedef struct audio_config_base audio_config_base_t;
441 
442 static const audio_config_base_t AUDIO_CONFIG_BASE_INITIALIZER = {
443     /* .sample_rate = */ 0,
444     /* .channel_mask = */ AUDIO_CHANNEL_NONE,
445     /* .format = */ AUDIO_FORMAT_DEFAULT
446 };
447 
448 /* audio hw module handle functions or structures referencing a module */
449 typedef int audio_module_handle_t;
450 
451 /******************************
452  *  Volume control
453  *****************************/
454 
455 /** 3 dB headroom are allowed on float samples (3db = 10^(3/20) = 1.412538).
456 * See: https://developer.android.com/reference/android/media/AudioTrack.html#write(float[], int, int, int)
457 */
458 #define FLOAT_NOMINAL_RANGE_HEADROOM 1.412538
459 
460 /* If the audio hardware supports gain control on some audio paths,
461  * the platform can expose them in the audio_policy_configuration.xml file. The audio HAL
462  * will then implement gain control functions that will use the following data
463  * structures. */
464 
465 /* An audio_gain struct is a representation of a gain stage.
466  * A gain stage is always attached to an audio port. */
467 struct audio_gain  {
468     audio_gain_mode_t    mode;          /* e.g. AUDIO_GAIN_MODE_JOINT */
469     audio_channel_mask_t channel_mask;  /* channels which gain an be controlled.
470                                            N/A if AUDIO_GAIN_MODE_CHANNELS is not supported */
471     int                  min_value;     /* minimum gain value in millibels */
472     int                  max_value;     /* maximum gain value in millibels */
473     int                  default_value; /* default gain value in millibels */
474     unsigned int         step_value;    /* gain step in millibels */
475     unsigned int         min_ramp_ms;   /* minimum ramp duration in ms */
476     unsigned int         max_ramp_ms;   /* maximum ramp duration in ms */
477 };
478 
479 /* The gain configuration structure is used to get or set the gain values of a
480  * given port */
481 struct audio_gain_config  {
482     int                  index;             /* index of the corresponding audio_gain in the
483                                                audio_port gains[] table */
484     audio_gain_mode_t    mode;              /* mode requested for this command */
485     audio_channel_mask_t channel_mask;      /* channels which gain value follows.
486                                                N/A in joint mode */
487 
488     // note this "8" is not FCC_8, so it won't need to be changed for > 8 channels
489     int                  values[sizeof(audio_channel_mask_t) * 8]; /* gain values in millibels
490                                                for each channel ordered from LSb to MSb in
491                                                channel mask. The number of values is 1 in joint
492                                                mode or __builtin_popcount(channel_mask) */
493     unsigned int         ramp_duration_ms; /* ramp duration in ms */
494 };
495 
496 /******************************
497  *  Routing control
498  *****************************/
499 
500 /* Types defined here are used to describe an audio source or sink at internal
501  * framework interfaces (audio policy, patch panel) or at the audio HAL.
502  * Sink and sources are grouped in a concept of “audio port” representing an
503  * audio end point at the edge of the system managed by the module exposing
504  * the interface. */
505 
506 /* Each port has a unique ID or handle allocated by policy manager */
507 typedef int audio_port_handle_t;
508 
509 /* the maximum length for the human-readable device name */
510 #define AUDIO_PORT_MAX_NAME_LEN 128
511 
512 /* a union to store port configuration flags. Declared as a type so can be reused
513    in framework code */
514 union audio_io_flags {
515     audio_input_flags_t  input;
516     audio_output_flags_t output;
517 };
518 
519 /* maximum audio device address length */
520 #define AUDIO_DEVICE_MAX_ADDRESS_LEN 32
521 
522 /* extension for audio port configuration structure when the audio port is a
523  * hardware device */
524 struct audio_port_config_device_ext {
525     audio_module_handle_t hw_module;                /* module the device is attached to */
526     audio_devices_t       type;                     /* device type (e.g AUDIO_DEVICE_OUT_SPEAKER) */
527     char                  address[AUDIO_DEVICE_MAX_ADDRESS_LEN]; /* device address. "" if N/A */
528 };
529 
530 /* extension for audio port configuration structure when the audio port is a
531  * sub mix */
532 struct audio_port_config_mix_ext {
533     audio_module_handle_t hw_module;    /* module the stream is attached to */
534     audio_io_handle_t handle;           /* I/O handle of the input/output stream */
535     union {
536         //TODO: change use case for output streams: use strategy and mixer attributes
537         audio_stream_type_t stream;
538         audio_source_t      source;
539     } usecase;
540 };
541 
542 /* extension for audio port configuration structure when the audio port is an
543  * audio session */
544 struct audio_port_config_session_ext {
545     audio_session_t   session; /* audio session */
546 };
547 
548 typedef enum {
549     AUDIO_PORT_ROLE_NONE = 0,
550     AUDIO_PORT_ROLE_SOURCE = 1,
551     AUDIO_PORT_ROLE_SINK = 2,
552 } audio_port_role_t;
553 
554 typedef enum {
555     AUDIO_PORT_TYPE_NONE = 0,
556     AUDIO_PORT_TYPE_DEVICE = 1,
557     AUDIO_PORT_TYPE_MIX = 2,
558     AUDIO_PORT_TYPE_SESSION = 3,
559 } audio_port_type_t;
560 
561 enum {
562     AUDIO_PORT_CONFIG_SAMPLE_RATE  = 0x1u,
563     AUDIO_PORT_CONFIG_CHANNEL_MASK = 0x2u,
564     AUDIO_PORT_CONFIG_FORMAT       = 0x4u,
565     AUDIO_PORT_CONFIG_GAIN         = 0x8u,
566 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
567     AUDIO_PORT_CONFIG_FLAGS        = 0x10u,
568 #endif
569     AUDIO_PORT_CONFIG_ALL          = AUDIO_PORT_CONFIG_SAMPLE_RATE |
570                                      AUDIO_PORT_CONFIG_CHANNEL_MASK |
571                                      AUDIO_PORT_CONFIG_FORMAT |
572                                      AUDIO_PORT_CONFIG_GAIN,
573 };
574 
575 typedef enum {
576     AUDIO_LATENCY_LOW = 0,
577     AUDIO_LATENCY_NORMAL = 1,
578 } audio_mix_latency_class_t;
579 
580 /* audio port configuration structure used to specify a particular configuration of
581  * an audio port */
582 struct audio_port_config {
583     audio_port_handle_t      id;           /* port unique ID */
584     audio_port_role_t        role;         /* sink or source */
585     audio_port_type_t        type;         /* device, mix ... */
586     unsigned int             config_mask;  /* e.g AUDIO_PORT_CONFIG_ALL */
587     unsigned int             sample_rate;  /* sampling rate in Hz */
588     audio_channel_mask_t     channel_mask; /* channel mask if applicable */
589     audio_format_t           format;       /* format if applicable */
590     struct audio_gain_config gain;         /* gain to apply if applicable */
591 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
592     union audio_io_flags     flags;        /* framework only: HW_AV_SYNC, DIRECT, ... */
593 #endif
594     union {
595         struct audio_port_config_device_ext  device;  /* device specific info */
596         struct audio_port_config_mix_ext     mix;     /* mix specific info */
597         struct audio_port_config_session_ext session; /* session specific info */
598     } ext;
599 };
600 
601 
602 /* max number of sampling rates in audio port */
603 #define AUDIO_PORT_MAX_SAMPLING_RATES 32
604 /* max number of channel masks in audio port */
605 #define AUDIO_PORT_MAX_CHANNEL_MASKS 32
606 /* max number of audio formats in audio port */
607 #define AUDIO_PORT_MAX_FORMATS 32
608 /* max number of audio profiles in audio port. The audio profiles are used in
609  * `struct audio_port_v7`. When converting between `struct audio_port` and
610  * `struct audio_port_v7`, the number of audio profiles in `struct audio_port_v7`
611  * must be the same as the number of formats in `struct audio_port`. Therefore,
612  * the maximum number of audio profiles must be the same as the maximum number
613  * of formats. */
614 #define AUDIO_PORT_MAX_AUDIO_PROFILES AUDIO_PORT_MAX_FORMATS
615 /* max number of extra audio descriptors in audio port. */
616 #define AUDIO_PORT_MAX_EXTRA_AUDIO_DESCRIPTORS AUDIO_PORT_MAX_FORMATS
617 /* max number of gain controls in audio port */
618 #define AUDIO_PORT_MAX_GAINS 16
619 /* max bytes of extra audio descriptor */
620 #define EXTRA_AUDIO_DESCRIPTOR_SIZE 32
621 
622 /* extension for audio port structure when the audio port is a hardware device */
623 struct audio_port_device_ext {
624     audio_module_handle_t hw_module;    /* module the device is attached to */
625     audio_devices_t       type;         /* device type (e.g AUDIO_DEVICE_OUT_SPEAKER) */
626     char                  address[AUDIO_DEVICE_MAX_ADDRESS_LEN];
627 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
628     uint32_t              encapsulation_modes;
629     uint32_t              encapsulation_metadata_types;
630 #endif
631 };
632 
633 /* extension for audio port structure when the audio port is a sub mix */
634 struct audio_port_mix_ext {
635     audio_module_handle_t     hw_module;     /* module the stream is attached to */
636     audio_io_handle_t         handle;        /* I/O handle of the input.output stream */
637     audio_mix_latency_class_t latency_class; /* latency class */
638     // other attributes: routing strategies
639 };
640 
641 /* extension for audio port structure when the audio port is an audio session */
642 struct audio_port_session_ext {
643     audio_session_t   session; /* audio session */
644 };
645 
646 struct audio_port {
647     audio_port_handle_t      id;                 /* port unique ID */
648     audio_port_role_t        role;               /* sink or source */
649     audio_port_type_t        type;               /* device, mix ... */
650     char                     name[AUDIO_PORT_MAX_NAME_LEN];
651     unsigned int             num_sample_rates;   /* number of sampling rates in following array */
652     unsigned int             sample_rates[AUDIO_PORT_MAX_SAMPLING_RATES];
653     unsigned int             num_channel_masks;  /* number of channel masks in following array */
654     audio_channel_mask_t     channel_masks[AUDIO_PORT_MAX_CHANNEL_MASKS];
655     unsigned int             num_formats;        /* number of formats in following array */
656     audio_format_t           formats[AUDIO_PORT_MAX_FORMATS];
657     unsigned int             num_gains;          /* number of gains in following array */
658     struct audio_gain        gains[AUDIO_PORT_MAX_GAINS];
659     struct audio_port_config active_config;      /* current audio port configuration */
660     union {
661         struct audio_port_device_ext  device;
662         struct audio_port_mix_ext     mix;
663         struct audio_port_session_ext session;
664     } ext;
665 };
666 
667 typedef enum {
668     AUDIO_STANDARD_NONE = 0,
669     AUDIO_STANDARD_EDID = 1,
670 } audio_standard_t;
671 
672 /**
673  * Configuration described by hardware descriptor for a format that is unrecognized
674  * by the platform.
675  */
676 struct audio_extra_audio_descriptor {
677     audio_standard_t standard;
678     unsigned int descriptor_length;
679     uint8_t descriptor[EXTRA_AUDIO_DESCRIPTOR_SIZE];
680     audio_encapsulation_type_t encapsulation_type;
681 };
682 
683 /* configurations supported for a certain format */
684 struct audio_profile {
685     audio_format_t format;
686     unsigned int num_sample_rates;  /* number of sampling rates in following array */
687     unsigned int sample_rates[AUDIO_PORT_MAX_SAMPLING_RATES];
688     unsigned int num_channel_masks; /* number of channel masks in following array */
689     audio_channel_mask_t channel_masks[AUDIO_PORT_MAX_CHANNEL_MASKS];
690     audio_encapsulation_type_t encapsulation_type;
691 };
692 
693 struct audio_port_v7 {
694     audio_port_handle_t      id;                 /* port unique ID */
695     audio_port_role_t        role;               /* sink or source */
696     audio_port_type_t        type;               /* device, mix ... */
697     char                     name[AUDIO_PORT_MAX_NAME_LEN];
698     unsigned int             num_audio_profiles; /* number of audio profiles in the following
699                                                     array */
700     struct audio_profile     audio_profiles[AUDIO_PORT_MAX_AUDIO_PROFILES];
701     unsigned int             num_extra_audio_descriptors; /* number of extra audio descriptors in
702                                                              the following array */
703     struct audio_extra_audio_descriptor
704             extra_audio_descriptors[AUDIO_PORT_MAX_EXTRA_AUDIO_DESCRIPTORS];
705     unsigned int             num_gains;          /* number of gains in following array */
706     struct audio_gain        gains[AUDIO_PORT_MAX_GAINS];
707     struct audio_port_config active_config;      /* current audio port configuration */
708     union {
709         struct audio_port_device_ext  device;
710         struct audio_port_mix_ext     mix;
711         struct audio_port_session_ext session;
712     } ext;
713 };
714 
715 /* Return true when a given uint8_t array is a valid short audio descriptor. This function just
716  * does basic validation by checking if the first value is not zero.
717  */
audio_is_valid_short_audio_descriptor(const uint8_t * shortAudioDescriptor,size_t length)718 static inline bool audio_is_valid_short_audio_descriptor(const uint8_t *shortAudioDescriptor,
719                                                          size_t length) {
720     return length != 0 && *shortAudioDescriptor != 0;
721 }
722 
audio_populate_audio_port_v7(const struct audio_port * port,struct audio_port_v7 * portV7)723 static inline void audio_populate_audio_port_v7(
724         const struct audio_port *port, struct audio_port_v7 *portV7) {
725     portV7->id = port->id;
726     portV7->role = port->role;
727     portV7->type = port->type;
728     strncpy(portV7->name, port->name, AUDIO_PORT_MAX_NAME_LEN);
729     portV7->name[AUDIO_PORT_MAX_NAME_LEN-1] = '\0';
730     portV7->num_audio_profiles =
731             port->num_formats > AUDIO_PORT_MAX_AUDIO_PROFILES ?
732             AUDIO_PORT_MAX_AUDIO_PROFILES : port->num_formats;
733     for (size_t i = 0; i < portV7->num_audio_profiles; ++i) {
734         portV7->audio_profiles[i].format = port->formats[i];
735         portV7->audio_profiles[i].num_sample_rates = port->num_sample_rates;
736         memcpy(portV7->audio_profiles[i].sample_rates, port->sample_rates,
737                 port->num_sample_rates * sizeof(unsigned int));
738         portV7->audio_profiles[i].num_channel_masks = port->num_channel_masks;
739         memcpy(portV7->audio_profiles[i].channel_masks, port->channel_masks,
740                 port->num_channel_masks * sizeof(audio_channel_mask_t));
741     }
742     portV7->num_gains = port->num_gains;
743     memcpy(portV7->gains, port->gains, port->num_gains * sizeof(struct audio_gain));
744     memcpy(&portV7->active_config, &port->active_config, sizeof(struct audio_port_config));
745     memcpy(&portV7->ext, &port->ext, sizeof(port->ext));
746 }
747 
748 /* Populate the data in `struct audio_port` using data from `struct audio_port_v7`. As the
749  * `struct audio_port_v7` use audio profiles to describe its capabilities, it may contain more
750  * data for sample rates or channel masks than the data that can be held by `struct audio_port`.
751  * Return true if all the data from `struct audio_port_v7` are converted to `struct audio_port`.
752  * Otherwise, return false.
753  */
audio_populate_audio_port(const struct audio_port_v7 * portV7,struct audio_port * port)754 static inline bool audio_populate_audio_port(
755         const struct audio_port_v7 *portV7, struct audio_port *port) {
756     bool allDataConverted = true;
757     port->id = portV7->id;
758     port->role = portV7->role;
759     port->type = portV7->type;
760     strncpy(port->name, portV7->name, AUDIO_PORT_MAX_NAME_LEN);
761     port->name[AUDIO_PORT_MAX_NAME_LEN-1] = '\0';
762     port->num_formats =
763             portV7->num_audio_profiles > AUDIO_PORT_MAX_FORMATS ?
764             AUDIO_PORT_MAX_FORMATS : portV7->num_audio_profiles;
765     port->num_sample_rates = 0;
766     port->num_channel_masks = 0;
767     for (size_t i = 0; i < port->num_formats; ++i) {
768         port->formats[i] = portV7->audio_profiles[i].format;
769         for (size_t j = 0; j < portV7->audio_profiles[i].num_sample_rates; ++j) {
770             size_t k = 0;
771             for (; k < port->num_sample_rates; ++k) {
772                 if (port->sample_rates[k] == portV7->audio_profiles[i].sample_rates[j]) {
773                     break;
774                 }
775             }
776             if (k == port->num_sample_rates) {
777                 if (port->num_sample_rates >= AUDIO_PORT_MAX_SAMPLING_RATES) {
778                     allDataConverted = false;
779                     break;
780                 }
781                 port->sample_rates[port->num_sample_rates++] =
782                         portV7->audio_profiles[i].sample_rates[j];
783             }
784         }
785         for (size_t j = 0; j < portV7->audio_profiles[i].num_channel_masks; ++j) {
786             size_t k = 0;
787             for (; k < port->num_channel_masks; ++k) {
788                 if (port->channel_masks[k] == portV7->audio_profiles[i].channel_masks[j]) {
789                     break;
790                 }
791             }
792             if (k == port->num_channel_masks) {
793                 if (port->num_channel_masks >= AUDIO_PORT_MAX_CHANNEL_MASKS) {
794                     allDataConverted = false;
795                     break;
796                 }
797                 port->channel_masks[port->num_channel_masks++] =
798                         portV7->audio_profiles[i].channel_masks[j];
799             }
800         }
801     }
802     port->num_gains = portV7->num_gains;
803     memcpy(port->gains, portV7->gains, port->num_gains * sizeof(struct audio_gain));
804     memcpy(&port->active_config, &portV7->active_config, sizeof(struct audio_port_config));
805     memcpy(&port->ext, &portV7->ext, sizeof(port->ext));
806     return allDataConverted && portV7->num_extra_audio_descriptors == 0;
807 }
808 
audio_gain_config_are_equal(const struct audio_gain_config * lhs,const struct audio_gain_config * rhs)809 static inline bool audio_gain_config_are_equal(
810         const struct audio_gain_config *lhs, const struct audio_gain_config *rhs) {
811     if (lhs->mode != rhs->mode) return false;
812     if (lhs->mode & AUDIO_GAIN_MODE_JOINT) {
813         if (lhs->values[0] != rhs->values[0]) return false;
814     }
815     if (lhs->mode & (AUDIO_GAIN_MODE_CHANNELS | AUDIO_GAIN_MODE_RAMP)) {
816         if (lhs->channel_mask != rhs->channel_mask) return false;
817         for (int i = 0; i < __builtin_popcount(lhs->channel_mask); ++i) {
818             if (lhs->values[i] != rhs->values[i]) return false;
819         }
820     }
821     return lhs->ramp_duration_ms == rhs->ramp_duration_ms;
822 }
823 
audio_has_input_direction(audio_port_type_t type,audio_port_role_t role)824 static inline bool audio_has_input_direction(audio_port_type_t type, audio_port_role_t role) {
825     switch (type) {
826     case AUDIO_PORT_TYPE_DEVICE:
827         switch (role) {
828         case AUDIO_PORT_ROLE_SOURCE: return true;
829         case AUDIO_PORT_ROLE_SINK: return false;
830         default: return false;
831         }
832     case AUDIO_PORT_TYPE_MIX:
833         switch (role) {
834         case AUDIO_PORT_ROLE_SOURCE: return false;
835         case AUDIO_PORT_ROLE_SINK: return true;
836         default: return false;
837         }
838     default: return false;
839     }
840 }
841 
audio_port_config_has_input_direction(const struct audio_port_config * port_cfg)842 static inline bool audio_port_config_has_input_direction(const struct audio_port_config *port_cfg) {
843     return audio_has_input_direction(port_cfg->type, port_cfg->role);
844 }
845 
audio_port_configs_are_equal(const struct audio_port_config * lhs,const struct audio_port_config * rhs)846 static inline bool audio_port_configs_are_equal(
847         const struct audio_port_config *lhs, const struct audio_port_config *rhs) {
848     if (lhs->role != rhs->role || lhs->type != rhs->type) return false;
849     switch (lhs->type) {
850     case AUDIO_PORT_TYPE_NONE: break;
851     case AUDIO_PORT_TYPE_DEVICE:
852         if (lhs->ext.device.hw_module != rhs->ext.device.hw_module ||
853                 lhs->ext.device.type != rhs->ext.device.type ||
854                 strncmp(lhs->ext.device.address, rhs->ext.device.address,
855                         AUDIO_DEVICE_MAX_ADDRESS_LEN) != 0) {
856             return false;
857         }
858         break;
859     case AUDIO_PORT_TYPE_MIX:
860         if (lhs->ext.mix.hw_module != rhs->ext.mix.hw_module ||
861                 lhs->ext.mix.handle != rhs->ext.mix.handle) return false;
862         if (lhs->role == AUDIO_PORT_ROLE_SOURCE &&
863                 lhs->ext.mix.usecase.stream != rhs->ext.mix.usecase.stream) return false;
864         else if (lhs->role == AUDIO_PORT_ROLE_SINK &&
865                 lhs->ext.mix.usecase.source != rhs->ext.mix.usecase.source) return false;
866         break;
867     case AUDIO_PORT_TYPE_SESSION:
868         if (lhs->ext.session.session != rhs->ext.session.session) return false;
869         break;
870     default: return false;
871     }
872     return
873             lhs->config_mask == rhs->config_mask &&
874 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
875             ((lhs->config_mask & AUDIO_PORT_CONFIG_FLAGS) == 0 ||
876                     (audio_port_config_has_input_direction(lhs) ?
877                             lhs->flags.input == rhs->flags.input :
878                             lhs->flags.output == rhs->flags.output)) &&
879 #endif
880             ((lhs->config_mask & AUDIO_PORT_CONFIG_SAMPLE_RATE) == 0 ||
881                     lhs->sample_rate == rhs->sample_rate) &&
882             ((lhs->config_mask & AUDIO_PORT_CONFIG_CHANNEL_MASK) == 0 ||
883                     lhs->channel_mask == rhs->channel_mask) &&
884             ((lhs->config_mask & AUDIO_PORT_CONFIG_FORMAT) == 0 ||
885                     lhs->format == rhs->format) &&
886             ((lhs->config_mask & AUDIO_PORT_CONFIG_GAIN) == 0 ||
887                     audio_gain_config_are_equal(&lhs->gain, &rhs->gain));
888 }
889 
audio_gains_are_equal(const struct audio_gain * lhs,const struct audio_gain * rhs)890 static inline bool audio_gains_are_equal(const struct audio_gain* lhs, const struct audio_gain* rhs) {
891     return lhs->mode == rhs->mode &&
892             ((lhs->mode & AUDIO_GAIN_MODE_CHANNELS) != AUDIO_GAIN_MODE_CHANNELS ||
893                     lhs->channel_mask == rhs->channel_mask) &&
894             lhs->min_value == rhs->min_value &&
895             lhs->max_value == rhs->max_value &&
896             lhs->default_value == rhs->default_value &&
897             lhs->step_value == rhs->step_value &&
898             lhs->min_ramp_ms == rhs->min_ramp_ms &&
899             lhs->max_ramp_ms == rhs->max_ramp_ms;
900 }
901 
902 // Define the helper functions of compare two audio_port/audio_port_v7 only in
903 // C++ as it is easier to compare the device capabilities.
904 #ifdef __cplusplus
905 extern "C++" {
906 #include <map>
907 #include <set>
908 #include <type_traits>
909 #include <utility>
910 #include <vector>
911 
912 namespace {
913 
audio_gain_array_contains_all_elements_from(const struct audio_gain gains[],const size_t numGains,const struct audio_gain from[],size_t numFromGains)914 static inline bool audio_gain_array_contains_all_elements_from(
915         const struct audio_gain gains[], const size_t numGains,
916         const struct audio_gain from[], size_t numFromGains) {
917     for (size_t i = 0; i < numFromGains; ++i) {
918         size_t j = 0;
919         for (;j < numGains; ++j) {
920             if (audio_gains_are_equal(&from[i], &gains[j])) {
921                 break;
922             }
923         }
924         if (j == numGains) {
925             return false;
926         }
927     }
928     return true;
929 }
930 
931 template <typename T, std::enable_if_t<std::is_same<T, struct audio_port>::value
932                                     || std::is_same<T, struct audio_port_v7>::value, int> = 0>
audio_ports_base_are_equal(const T * lhs,const T * rhs)933 static inline bool audio_ports_base_are_equal(const T* lhs, const T* rhs) {
934     if (lhs->id != rhs->id || lhs->role != rhs->role || lhs->type != rhs->type ||
935             strncmp(lhs->name, rhs->name, AUDIO_PORT_MAX_NAME_LEN) != 0 ||
936             lhs->num_gains != rhs->num_gains) {
937         return false;
938     }
939     switch (lhs->type) {
940     case AUDIO_PORT_TYPE_NONE: break;
941     case AUDIO_PORT_TYPE_DEVICE:
942         if (
943 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
944                 lhs->ext.device.encapsulation_modes != rhs->ext.device.encapsulation_modes ||
945                 lhs->ext.device.encapsulation_metadata_types !=
946                         rhs->ext.device.encapsulation_metadata_types ||
947 #endif
948                 lhs->ext.device.hw_module != rhs->ext.device.hw_module ||
949                 lhs->ext.device.type != rhs->ext.device.type ||
950                 strncmp(lhs->ext.device.address, rhs->ext.device.address,
951                         AUDIO_DEVICE_MAX_ADDRESS_LEN) != 0) {
952             return false;
953         }
954         break;
955     case AUDIO_PORT_TYPE_MIX:
956         if (lhs->ext.mix.hw_module != rhs->ext.mix.hw_module ||
957                 lhs->ext.mix.handle != rhs->ext.mix.handle ||
958                 lhs->ext.mix.latency_class != rhs->ext.mix.latency_class) {
959             return false;
960         }
961         break;
962     case AUDIO_PORT_TYPE_SESSION:
963         if (lhs->ext.session.session != rhs->ext.session.session) {
964             return false;
965         }
966         break;
967     default:
968         return false;
969     }
970     if (!audio_gain_array_contains_all_elements_from(
971             lhs->gains, lhs->num_gains, rhs->gains, rhs->num_gains) ||
972             !audio_gain_array_contains_all_elements_from(
973                     rhs->gains, rhs->num_gains, lhs->gains, lhs->num_gains)) {
974         return false;
975     }
976     return audio_port_configs_are_equal(&lhs->active_config, &rhs->active_config);
977 }
978 
979 template <typename T, std::enable_if_t<std::is_same<T, audio_format_t>::value
980                                     || std::is_same<T, unsigned int>::value
981                                     || std::is_same<T, audio_channel_mask_t>::value, int> = 0>
audio_capability_arrays_are_equal(const T lhs[],unsigned int lsize,const T rhs[],unsigned int rsize)982 static inline bool audio_capability_arrays_are_equal(
983         const T lhs[], unsigned int lsize, const T rhs[], unsigned int rsize) {
984     std::set<T> lhsSet(lhs, lhs + lsize);
985     std::set<T> rhsSet(rhs, rhs + rsize);
986     return lhsSet == rhsSet;
987 }
988 
989 using AudioProfileMap =
990         std::map<audio_format_t,
991                  std::pair<std::set<unsigned int>, std::set<audio_channel_mask_t>>>;
getAudioProfileMap(const struct audio_profile profiles[],unsigned int size)992 static inline AudioProfileMap getAudioProfileMap(
993         const struct audio_profile profiles[], unsigned int size) {
994     AudioProfileMap audioProfiles;
995     for (size_t i = 0; i < size; ++i) {
996         std::set<unsigned int> sampleRates(
997                 profiles[i].sample_rates, profiles[i].sample_rates + profiles[i].num_sample_rates);
998         std::set<audio_channel_mask_t> channelMasks(
999                 profiles[i].channel_masks,
1000                 profiles[i].channel_masks + profiles[i].num_channel_masks);
1001         audioProfiles.emplace(profiles[i].format, std::make_pair(sampleRates, channelMasks));
1002     }
1003     return audioProfiles;
1004 }
1005 
audio_profile_arrays_are_equal(const struct audio_profile lhs[],unsigned int lsize,const struct audio_profile rhs[],unsigned int rsize)1006 static inline bool audio_profile_arrays_are_equal(
1007         const struct audio_profile lhs[], unsigned int lsize,
1008         const struct audio_profile rhs[], unsigned int rsize) {
1009     return getAudioProfileMap(lhs, lsize) == getAudioProfileMap(rhs, rsize);
1010 }
1011 
1012 using ExtraAudioDescriptorMap =std::map<audio_standard_t,
1013                                         std::map<audio_encapsulation_type_t,
1014                                                  std::set<std::vector<uint8_t>>>>;
1015 
getExtraAudioDescriptorMap(const struct audio_extra_audio_descriptor extraAudioDescriptors[],unsigned int numExtraAudioDescriptors)1016 static inline ExtraAudioDescriptorMap getExtraAudioDescriptorMap(
1017         const struct audio_extra_audio_descriptor extraAudioDescriptors[],
1018         unsigned int numExtraAudioDescriptors) {
1019     ExtraAudioDescriptorMap extraAudioDescriptorMap;
1020     for (unsigned int i = 0; i < numExtraAudioDescriptors; ++i) {
1021         extraAudioDescriptorMap[extraAudioDescriptors[i].standard]
1022                 [extraAudioDescriptors[i].encapsulation_type].insert(
1023                 std::vector<uint8_t>(
1024                         extraAudioDescriptors[i].descriptor,
1025                         extraAudioDescriptors[i].descriptor
1026                                 + extraAudioDescriptors[i].descriptor_length));
1027     }
1028     return extraAudioDescriptorMap;
1029 }
1030 
audio_extra_audio_descriptor_are_equal(const struct audio_extra_audio_descriptor lhs[],unsigned int lsize,const struct audio_extra_audio_descriptor rhs[],unsigned int rsize)1031 static inline bool audio_extra_audio_descriptor_are_equal(
1032         const struct audio_extra_audio_descriptor lhs[], unsigned int lsize,
1033         const struct audio_extra_audio_descriptor rhs[], unsigned int rsize) {
1034     return getExtraAudioDescriptorMap(lhs, lsize) == getExtraAudioDescriptorMap(rhs, rsize);
1035 }
1036 
1037 } // namespace
1038 
audio_ports_are_equal(const struct audio_port * lhs,const struct audio_port * rhs)1039 static inline bool audio_ports_are_equal(
1040         const struct audio_port* lhs, const struct audio_port* rhs) {
1041     if (!audio_ports_base_are_equal(lhs, rhs)) {
1042         return false;
1043     }
1044     return audio_capability_arrays_are_equal(
1045             lhs->formats, lhs->num_formats, rhs->formats, rhs->num_formats) &&
1046             audio_capability_arrays_are_equal(
1047                     lhs->sample_rates, lhs->num_sample_rates,
1048                     rhs->sample_rates, rhs->num_sample_rates) &&
1049             audio_capability_arrays_are_equal(
1050                     lhs->channel_masks, lhs->num_channel_masks,
1051                     rhs->channel_masks, rhs->num_channel_masks);
1052 }
1053 
audio_ports_v7_are_equal(const struct audio_port_v7 * lhs,const struct audio_port_v7 * rhs)1054 static inline bool audio_ports_v7_are_equal(
1055         const struct audio_port_v7* lhs, const struct audio_port_v7* rhs) {
1056     if (!audio_ports_base_are_equal(lhs, rhs)) {
1057         return false;
1058     }
1059     return audio_profile_arrays_are_equal(
1060             lhs->audio_profiles, lhs->num_audio_profiles,
1061             rhs->audio_profiles, rhs->num_audio_profiles) &&
1062            audio_extra_audio_descriptor_are_equal(
1063                    lhs->extra_audio_descriptors, lhs->num_extra_audio_descriptors,
1064                    rhs->extra_audio_descriptors, rhs->num_extra_audio_descriptors);
1065 }
1066 
1067 } // extern "C++"
1068 #endif // __cplusplus
1069 
1070 /* An audio patch represents a connection between one or more source ports and
1071  * one or more sink ports. Patches are connected and disconnected by audio policy manager or by
1072  * applications via framework APIs.
1073  * Each patch is identified by a handle at the interface used to create that patch. For instance,
1074  * when a patch is created by the audio HAL, the HAL allocates and returns a handle.
1075  * This handle is unique to a given audio HAL hardware module.
1076  * But the same patch receives another system wide unique handle allocated by the framework.
1077  * This unique handle is used for all transactions inside the framework.
1078  */
1079 typedef int audio_patch_handle_t;
1080 
1081 #define AUDIO_PATCH_PORTS_MAX   16
1082 
1083 struct audio_patch {
1084     audio_patch_handle_t id;            /* patch unique ID */
1085     unsigned int      num_sources;      /* number of sources in following array */
1086     struct audio_port_config sources[AUDIO_PATCH_PORTS_MAX];
1087     unsigned int      num_sinks;        /* number of sinks in following array */
1088     struct audio_port_config sinks[AUDIO_PATCH_PORTS_MAX];
1089 };
1090 
1091 
1092 
1093 /* a HW synchronization source returned by the audio HAL */
1094 typedef uint32_t audio_hw_sync_t;
1095 
1096 /* an invalid HW synchronization source indicating an error */
1097 #define AUDIO_HW_SYNC_INVALID 0
1098 
1099 /** @TODO export from .hal */
1100 typedef enum {
1101     NONE    = 0x0,
1102     /**
1103      * Only set this flag if applications can access the audio buffer memory
1104      * shared with the backend (usually DSP) _without_ security issue.
1105      *
1106      * Setting this flag also implies that Binder will allow passing the shared memory FD
1107      * to applications.
1108      *
1109      * That usually implies that the kernel will prevent any access to the
1110      * memory surrounding the audio buffer as it could lead to a security breach.
1111      *
1112      * For example, a "/dev/snd/" file descriptor generally is not shareable,
1113      * but an "anon_inode:dmabuffer" file descriptor is shareable.
1114      * See also Linux kernel's dma_buf.
1115      *
1116      * This flag is required to support AAudio exclusive mode:
1117      * See: https://source.android.com/devices/audio/aaudio
1118      */
1119     AUDIO_MMAP_APPLICATION_SHAREABLE    = 0x1,
1120 } audio_mmap_buffer_flag;
1121 
1122 /**
1123  * Mmap buffer descriptor returned by audio_stream->create_mmap_buffer().
1124  * note\ Used by streams opened in mmap mode.
1125  */
1126 struct audio_mmap_buffer_info {
1127     void*   shared_memory_address;  /**< base address of mmap memory buffer.
1128                                          For use by local process only */
1129     int32_t shared_memory_fd;       /**< FD for mmap memory buffer */
1130     int32_t buffer_size_frames;     /**< total buffer size in frames */
1131     int32_t burst_size_frames;      /**< transfer size granularity in frames */
1132     audio_mmap_buffer_flag flags;   /**< Attributes describing the buffer. */
1133 };
1134 
1135 /**
1136  * Mmap buffer read/write position returned by audio_stream->get_mmap_position().
1137  * note\ Used by streams opened in mmap mode.
1138  */
1139 struct audio_mmap_position {
1140     int64_t  time_nanoseconds; /**< timestamp in ns, CLOCK_MONOTONIC */
1141     int32_t  position_frames;  /**< increasing 32 bit frame count reset when stream->stop()
1142                                     is called */
1143 };
1144 
1145 /** Metadata of a playback track for an in stream. */
1146 typedef struct playback_track_metadata {
1147     audio_usage_t usage;
1148     audio_content_type_t content_type;
1149     float gain; // Normalized linear volume. 0=silence, 1=0dbfs...
1150 } playback_track_metadata_t;
1151 
1152 /** Metadata of a record track for an out stream. */
1153 typedef struct record_track_metadata {
1154     audio_source_t source;
1155     float gain; // Normalized linear volume. 0=silence, 1=0dbfs...
1156     // For record tracks originating from a software patch, the dest_device
1157     // fields provide information about the downstream device.
1158     audio_devices_t dest_device;
1159     char dest_device_address[AUDIO_DEVICE_MAX_ADDRESS_LEN];
1160 } record_track_metadata_t;
1161 
1162 /** Metadata of a playback track for an in stream. */
1163 typedef struct playback_track_metadata_v7 {
1164     struct playback_track_metadata base;
1165     audio_channel_mask_t channel_mask;
1166     char tags[AUDIO_ATTRIBUTES_TAGS_MAX_SIZE]; /* UTF8 */
1167 } playback_track_metadata_v7_t;
1168 
1169 /** Metadata of a record track for an out stream. */
1170 typedef struct record_track_metadata_v7 {
1171     struct record_track_metadata base;
1172     audio_channel_mask_t channel_mask;
1173     char tags[AUDIO_ATTRIBUTES_TAGS_MAX_SIZE]; /* UTF8 */
1174 } record_track_metadata_v7_t;
1175 
playback_track_metadata_to_v7(struct playback_track_metadata_v7 * dst,const struct playback_track_metadata * src)1176 static inline void playback_track_metadata_to_v7(struct playback_track_metadata_v7 *dst,
1177                                                  const struct playback_track_metadata *src) {
1178     dst->base = *src;
1179     dst->channel_mask = AUDIO_CHANNEL_NONE;
1180     dst->tags[0] = '\0';
1181 }
1182 
playback_track_metadata_from_v7(struct playback_track_metadata * dst,const struct playback_track_metadata_v7 * src)1183 static inline void playback_track_metadata_from_v7(struct playback_track_metadata *dst,
1184                                                    const struct playback_track_metadata_v7 *src) {
1185     *dst = src->base;
1186 }
1187 
record_track_metadata_to_v7(struct record_track_metadata_v7 * dst,const struct record_track_metadata * src)1188 static inline void record_track_metadata_to_v7(struct record_track_metadata_v7 *dst,
1189                                                const struct record_track_metadata *src) {
1190     dst->base = *src;
1191     dst->channel_mask = AUDIO_CHANNEL_NONE;
1192     dst->tags[0] = '\0';
1193 }
1194 
record_track_metadata_from_v7(struct record_track_metadata * dst,const struct record_track_metadata_v7 * src)1195 static inline void record_track_metadata_from_v7(struct record_track_metadata *dst,
1196                                                  const struct record_track_metadata_v7 *src) {
1197     *dst = src->base;
1198 }
1199 
1200 /******************************
1201  *  Helper functions
1202  *****************************/
1203 
1204 // see also: std::binary_search
1205 // search range [left, right)
audio_binary_search_device_array(const audio_devices_t audio_array[],size_t left,size_t right,audio_devices_t target)1206 static inline bool audio_binary_search_device_array(const audio_devices_t audio_array[],
1207                                                     size_t left, size_t right,
1208                                                     audio_devices_t target)
1209 {
1210     if (right <= left || target < audio_array[left] || target > audio_array[right - 1]) {
1211         return false;
1212     }
1213 
1214     while (left < right) {
1215         const size_t mid = left + (right - left) / 2;
1216         if (audio_array[mid] == target) {
1217             return true;
1218         } else if (audio_array[mid] < target) {
1219             left = mid + 1;
1220         } else {
1221             right = mid;
1222         }
1223     }
1224     return false;
1225 }
1226 
audio_is_output_device(audio_devices_t device)1227 static inline bool audio_is_output_device(audio_devices_t device)
1228 {
1229     switch (device) {
1230     case AUDIO_DEVICE_OUT_SPEAKER_SAFE:
1231     case AUDIO_DEVICE_OUT_SPEAKER:
1232     case AUDIO_DEVICE_OUT_BLUETOOTH_A2DP:
1233     case AUDIO_DEVICE_OUT_WIRED_HEADSET:
1234     case AUDIO_DEVICE_OUT_USB_HEADSET:
1235     case AUDIO_DEVICE_OUT_BLUETOOTH_SCO:
1236     case AUDIO_DEVICE_OUT_EARPIECE:
1237     case AUDIO_DEVICE_OUT_REMOTE_SUBMIX:
1238     case AUDIO_DEVICE_OUT_TELEPHONY_TX:
1239         // Search the most common devices first as these devices are most likely
1240         // to be used. Put the most common devices in the order of the likelihood
1241         // of usage to get a quick return.
1242         return true;
1243     default:
1244         // Binary seach all devices if the device is not a most common device.
1245         return audio_binary_search_device_array(
1246                 AUDIO_DEVICE_OUT_ALL_ARRAY, 0 /*left*/, AUDIO_DEVICE_OUT_CNT, device);
1247     }
1248 }
1249 
audio_is_input_device(audio_devices_t device)1250 static inline bool audio_is_input_device(audio_devices_t device)
1251 {
1252     switch (device) {
1253     case AUDIO_DEVICE_IN_BUILTIN_MIC:
1254     case AUDIO_DEVICE_IN_BACK_MIC:
1255     case AUDIO_DEVICE_IN_BLUETOOTH_SCO_HEADSET:
1256     case AUDIO_DEVICE_IN_WIRED_HEADSET:
1257     case AUDIO_DEVICE_IN_USB_HEADSET:
1258     case AUDIO_DEVICE_IN_REMOTE_SUBMIX:
1259     case AUDIO_DEVICE_IN_TELEPHONY_RX:
1260         // Search the most common devices first as these devices are most likely
1261         // to be used. Put the most common devices in the order of the likelihood
1262         // of usage to get a quick return.
1263         return true;
1264     default:
1265         // Binary seach all devices if the device is not a most common device.
1266         return audio_binary_search_device_array(
1267                 AUDIO_DEVICE_IN_ALL_ARRAY, 0 /*left*/, AUDIO_DEVICE_IN_CNT, device);
1268     }
1269 }
1270 
1271 #ifdef __cplusplus
1272 // Some effects use `uint32_t` directly for device.
audio_is_input_device(uint32_t device)1273 static inline bool audio_is_input_device(uint32_t device) {
1274     return audio_is_input_device(static_cast<audio_devices_t>(device));
1275 }
1276 // This needs to be used when `audio_is_input_device` is passed
1277 // to an STL algorithm, as otherwise the compiler can't resolve
1278 // the overload at that point--the type of the container elements
1279 // doesn't appear in the predicate parameter type definition.
1280 const auto audio_call_is_input_device = [](auto x) { return audio_is_input_device(x); };
1281 #endif
1282 
1283 
1284 // TODO: this function expects a combination of audio device types as parameter. It should
1285 // be deprecated as audio device types should not be use as bit mask any more since R.
audio_is_output_devices(audio_devices_t device)1286 static inline bool audio_is_output_devices(audio_devices_t device)
1287 {
1288     return (device & AUDIO_DEVICE_BIT_IN) == 0;
1289 }
1290 
audio_is_a2dp_in_device(audio_devices_t device)1291 static inline bool audio_is_a2dp_in_device(audio_devices_t device)
1292 {
1293     return device == AUDIO_DEVICE_IN_BLUETOOTH_A2DP;
1294 }
1295 
audio_is_a2dp_out_device(audio_devices_t device)1296 static inline bool audio_is_a2dp_out_device(audio_devices_t device)
1297 {
1298     return audio_binary_search_device_array(
1299             AUDIO_DEVICE_OUT_ALL_A2DP_ARRAY, 0 /*left*/, AUDIO_DEVICE_OUT_A2DP_CNT, device);
1300 }
1301 
1302 // Deprecated - use audio_is_a2dp_out_device() instead
audio_is_a2dp_device(audio_devices_t device)1303 static inline bool audio_is_a2dp_device(audio_devices_t device)
1304 {
1305     return audio_is_a2dp_out_device(device);
1306 }
1307 
audio_is_bluetooth_out_sco_device(audio_devices_t device)1308 static inline bool audio_is_bluetooth_out_sco_device(audio_devices_t device)
1309 {
1310     return audio_binary_search_device_array(
1311             AUDIO_DEVICE_OUT_ALL_SCO_ARRAY, 0 /*left*/, AUDIO_DEVICE_OUT_SCO_CNT, device);
1312 }
1313 
audio_is_bluetooth_in_sco_device(audio_devices_t device)1314 static inline bool audio_is_bluetooth_in_sco_device(audio_devices_t device)
1315 {
1316     return audio_binary_search_device_array(
1317             AUDIO_DEVICE_IN_ALL_SCO_ARRAY, 0 /*left*/, AUDIO_DEVICE_IN_SCO_CNT, device);
1318 }
1319 
audio_is_bluetooth_sco_device(audio_devices_t device)1320 static inline bool audio_is_bluetooth_sco_device(audio_devices_t device)
1321 {
1322     return audio_is_bluetooth_out_sco_device(device) ||
1323             audio_is_bluetooth_in_sco_device(device);
1324 }
1325 
audio_is_hearing_aid_out_device(audio_devices_t device)1326 static inline bool audio_is_hearing_aid_out_device(audio_devices_t device)
1327 {
1328     return device == AUDIO_DEVICE_OUT_HEARING_AID;
1329 }
1330 
audio_is_usb_out_device(audio_devices_t device)1331 static inline bool audio_is_usb_out_device(audio_devices_t device)
1332 {
1333     return audio_binary_search_device_array(
1334             AUDIO_DEVICE_OUT_ALL_USB_ARRAY, 0 /*left*/, AUDIO_DEVICE_OUT_USB_CNT, device);
1335 }
1336 
audio_is_usb_in_device(audio_devices_t device)1337 static inline bool audio_is_usb_in_device(audio_devices_t device)
1338 {
1339     return audio_binary_search_device_array(
1340             AUDIO_DEVICE_IN_ALL_USB_ARRAY, 0 /*left*/, AUDIO_DEVICE_IN_USB_CNT, device);
1341 }
1342 
1343 /* OBSOLETE - use audio_is_usb_out_device() instead. */
audio_is_usb_device(audio_devices_t device)1344 static inline bool audio_is_usb_device(audio_devices_t device)
1345 {
1346     return audio_is_usb_out_device(device);
1347 }
1348 
audio_is_remote_submix_device(audio_devices_t device)1349 static inline bool audio_is_remote_submix_device(audio_devices_t device)
1350 {
1351     return device == AUDIO_DEVICE_OUT_REMOTE_SUBMIX ||
1352            device == AUDIO_DEVICE_IN_REMOTE_SUBMIX;
1353 }
1354 
audio_is_digital_out_device(audio_devices_t device)1355 static inline bool audio_is_digital_out_device(audio_devices_t device)
1356 {
1357     return audio_binary_search_device_array(
1358             AUDIO_DEVICE_OUT_ALL_DIGITAL_ARRAY, 0 /*left*/, AUDIO_DEVICE_OUT_DIGITAL_CNT, device);
1359 }
1360 
audio_is_digital_in_device(audio_devices_t device)1361 static inline bool audio_is_digital_in_device(audio_devices_t device)
1362 {
1363     return audio_binary_search_device_array(
1364             AUDIO_DEVICE_IN_ALL_DIGITAL_ARRAY, 0 /*left*/, AUDIO_DEVICE_IN_DIGITAL_CNT, device);
1365 }
1366 
audio_device_is_digital(audio_devices_t device)1367 static inline bool audio_device_is_digital(audio_devices_t device) {
1368     return audio_is_digital_in_device(device) ||
1369            audio_is_digital_out_device(device);
1370 }
1371 
audio_is_ble_out_device(audio_devices_t device)1372 static inline bool audio_is_ble_out_device(audio_devices_t device)
1373 {
1374     return audio_binary_search_device_array(
1375             AUDIO_DEVICE_OUT_ALL_BLE_ARRAY, 0 /*left*/, AUDIO_DEVICE_OUT_BLE_CNT, device);
1376 }
1377 
audio_is_ble_in_device(audio_devices_t device)1378 static inline bool audio_is_ble_in_device(audio_devices_t device)
1379 {
1380     return audio_binary_search_device_array(
1381             AUDIO_DEVICE_IN_ALL_BLE_ARRAY, 0 /*left*/, AUDIO_DEVICE_IN_BLE_CNT, device);
1382 }
1383 
audio_is_ble_device(audio_devices_t device)1384 static inline bool audio_is_ble_device(audio_devices_t device) {
1385     return audio_is_ble_in_device(device) ||
1386            audio_is_ble_out_device(device);
1387 }
1388 
1389 /* Returns true if:
1390  *  representation is valid, and
1391  *  there is at least one channel bit set which _could_ correspond to an input channel, and
1392  *  there are no channel bits set which could _not_ correspond to an input channel.
1393  * Otherwise returns false.
1394  */
audio_is_input_channel(audio_channel_mask_t channel)1395 static inline bool audio_is_input_channel(audio_channel_mask_t channel)
1396 {
1397     uint32_t bits = audio_channel_mask_get_bits(channel);
1398     switch (audio_channel_mask_get_representation(channel)) {
1399     case AUDIO_CHANNEL_REPRESENTATION_POSITION:
1400         if (bits & ~AUDIO_CHANNEL_IN_ALL) {
1401             bits = 0;
1402         }
1403         FALLTHROUGH_INTENDED;
1404     case AUDIO_CHANNEL_REPRESENTATION_INDEX:
1405         return bits != 0;
1406     default:
1407         return false;
1408     }
1409 }
1410 
1411 /* Returns true if:
1412  *  representation is valid, and
1413  *  there is at least one channel bit set which _could_ correspond to an output channel, and
1414  *  there are no channel bits set which could _not_ correspond to an output channel.
1415  * Otherwise returns false.
1416  */
audio_is_output_channel(audio_channel_mask_t channel)1417 static inline bool audio_is_output_channel(audio_channel_mask_t channel)
1418 {
1419     uint32_t bits = audio_channel_mask_get_bits(channel);
1420     switch (audio_channel_mask_get_representation(channel)) {
1421     case AUDIO_CHANNEL_REPRESENTATION_POSITION:
1422         if (bits & ~AUDIO_CHANNEL_OUT_ALL) {
1423             bits = 0;
1424         }
1425         FALLTHROUGH_INTENDED;
1426     case AUDIO_CHANNEL_REPRESENTATION_INDEX:
1427         return bits != 0;
1428     default:
1429         return false;
1430     }
1431 }
1432 
1433 /* Returns the number of channels from an input channel mask,
1434  * used in the context of audio input or recording.
1435  * If a channel bit is set which could _not_ correspond to an input channel,
1436  * it is excluded from the count.
1437  * Returns zero if the representation is invalid.
1438  */
audio_channel_count_from_in_mask(audio_channel_mask_t channel)1439 static inline uint32_t audio_channel_count_from_in_mask(audio_channel_mask_t channel)
1440 {
1441     uint32_t bits = audio_channel_mask_get_bits(channel);
1442     switch (audio_channel_mask_get_representation(channel)) {
1443     case AUDIO_CHANNEL_REPRESENTATION_POSITION:
1444         // TODO: We can now merge with from_out_mask and remove anding
1445         bits &= AUDIO_CHANNEL_IN_ALL;
1446         FALLTHROUGH_INTENDED;
1447     case AUDIO_CHANNEL_REPRESENTATION_INDEX:
1448         return __builtin_popcount(bits);
1449     default:
1450         return 0;
1451     }
1452 }
1453 
1454 #ifdef __cplusplus
1455 // FIXME(b/169889714): buffer_config_t uses `uint32_t` for the mask.
1456 // A lot of effects code thus use `uint32_t` directly.
audio_channel_count_from_in_mask(uint32_t mask)1457 static inline uint32_t audio_channel_count_from_in_mask(uint32_t mask) {
1458     return audio_channel_count_from_in_mask(static_cast<audio_channel_mask_t>(mask));
1459 }
1460 #endif
1461 
1462 /* Returns the number of channels from an output channel mask,
1463  * used in the context of audio output or playback.
1464  * If a channel bit is set which could _not_ correspond to an output channel,
1465  * it is excluded from the count.
1466  * Returns zero if the representation is invalid.
1467  */
audio_channel_count_from_out_mask(audio_channel_mask_t channel)1468 static inline uint32_t audio_channel_count_from_out_mask(audio_channel_mask_t channel)
1469 {
1470     uint32_t bits = audio_channel_mask_get_bits(channel);
1471     switch (audio_channel_mask_get_representation(channel)) {
1472     case AUDIO_CHANNEL_REPRESENTATION_POSITION:
1473         // TODO: We can now merge with from_in_mask and remove anding
1474         bits &= AUDIO_CHANNEL_OUT_ALL;
1475         FALLTHROUGH_INTENDED;
1476     case AUDIO_CHANNEL_REPRESENTATION_INDEX:
1477         return __builtin_popcount(bits);
1478     default:
1479         return 0;
1480     }
1481 }
1482 
1483 #ifdef __cplusplus
1484 // FIXME(b/169889714): buffer_config_t uses `uint32_t` for the mask.
1485 // A lot of effects code thus use `uint32_t` directly.
audio_channel_count_from_out_mask(uint32_t mask)1486 static inline uint32_t audio_channel_count_from_out_mask(uint32_t mask) {
1487     return audio_channel_count_from_out_mask(static_cast<audio_channel_mask_t>(mask));
1488 }
1489 #endif
1490 
1491 /* Derive a channel mask for index assignment from a channel count.
1492  * Returns the matching channel mask,
1493  * or AUDIO_CHANNEL_NONE if the channel count is zero,
1494  * or AUDIO_CHANNEL_INVALID if the channel count exceeds AUDIO_CHANNEL_COUNT_MAX.
1495  */
audio_channel_mask_for_index_assignment_from_count(uint32_t channel_count)1496 static inline audio_channel_mask_t audio_channel_mask_for_index_assignment_from_count(
1497         uint32_t channel_count)
1498 {
1499     if (channel_count == 0) {
1500         return AUDIO_CHANNEL_NONE;
1501     }
1502     if (channel_count > AUDIO_CHANNEL_COUNT_MAX) {
1503         return AUDIO_CHANNEL_INVALID;
1504     }
1505     uint32_t bits = (1 << channel_count) - 1;
1506     return audio_channel_mask_from_representation_and_bits(
1507             AUDIO_CHANNEL_REPRESENTATION_INDEX, bits);
1508 }
1509 
1510 /* Derive an output channel mask for position assignment from a channel count.
1511  * This is to be used when the content channel mask is unknown. The 1, 2, 4, 5, 6, 7 and 8 channel
1512  * cases are mapped to the standard game/home-theater layouts, but note that 4 is mapped to quad,
1513  * and not stereo + FC + mono surround. A channel count of 3 is arbitrarily mapped to stereo + FC
1514  * for continuity with stereo.
1515  * Returns the matching channel mask,
1516  * or AUDIO_CHANNEL_NONE if the channel count is zero,
1517  * or AUDIO_CHANNEL_INVALID if the channel count exceeds that of the
1518  * configurations for which a default output channel mask is defined.
1519  */
audio_channel_out_mask_from_count(uint32_t channel_count)1520 static inline audio_channel_mask_t audio_channel_out_mask_from_count(uint32_t channel_count)
1521 {
1522     uint32_t bits;
1523     switch (channel_count) {
1524     case 0:
1525         return AUDIO_CHANNEL_NONE;
1526     case 1:
1527         bits = AUDIO_CHANNEL_OUT_MONO;
1528         break;
1529     case 2:
1530         bits = AUDIO_CHANNEL_OUT_STEREO;
1531         break;
1532     case 3: // 2.1
1533         bits = AUDIO_CHANNEL_OUT_STEREO | AUDIO_CHANNEL_OUT_LOW_FREQUENCY;
1534         break;
1535     case 4: // 4.0
1536         bits = AUDIO_CHANNEL_OUT_QUAD;
1537         break;
1538     case 5: // 5.0
1539         bits = AUDIO_CHANNEL_OUT_QUAD | AUDIO_CHANNEL_OUT_FRONT_CENTER;
1540         break;
1541     case 6: // 5.1
1542         bits = AUDIO_CHANNEL_OUT_5POINT1;
1543         break;
1544     case 7: // 6.1
1545         bits = AUDIO_CHANNEL_OUT_5POINT1 | AUDIO_CHANNEL_OUT_BACK_CENTER;
1546         break;
1547     case FCC_8:
1548         bits = AUDIO_CHANNEL_OUT_7POINT1;
1549         break;
1550     case FCC_12:
1551         bits = AUDIO_CHANNEL_OUT_7POINT1POINT4;
1552         break;
1553     case FCC_24:
1554         bits = AUDIO_CHANNEL_OUT_22POINT2;
1555         break;
1556     default:
1557         return AUDIO_CHANNEL_INVALID;
1558     }
1559     return audio_channel_mask_from_representation_and_bits(
1560             AUDIO_CHANNEL_REPRESENTATION_POSITION, bits);
1561 }
1562 
1563 /* Derive a default input channel mask from a channel count.
1564  * Assumes a position mask for mono and stereo, or an index mask for channel counts > 2.
1565  * Returns the matching channel mask,
1566  * or AUDIO_CHANNEL_NONE if the channel count is zero,
1567  * or AUDIO_CHANNEL_INVALID if the channel count exceeds that of the
1568  * configurations for which a default input channel mask is defined.
1569  */
audio_channel_in_mask_from_count(uint32_t channel_count)1570 static inline audio_channel_mask_t audio_channel_in_mask_from_count(uint32_t channel_count)
1571 {
1572     uint32_t bits;
1573     switch (channel_count) {
1574     case 0:
1575         return AUDIO_CHANNEL_NONE;
1576     case 1:
1577         bits = AUDIO_CHANNEL_IN_MONO;
1578         break;
1579     case 2:
1580         bits = AUDIO_CHANNEL_IN_STEREO;
1581         break;
1582     default:
1583         if (channel_count <= FCC_LIMIT) {
1584             return audio_channel_mask_for_index_assignment_from_count(channel_count);
1585         }
1586         return AUDIO_CHANNEL_INVALID;
1587     }
1588     return audio_channel_mask_from_representation_and_bits(
1589             AUDIO_CHANNEL_REPRESENTATION_POSITION, bits);
1590 }
1591 
1592 /* Derive a default haptic channel mask from a channel count.
1593  */
haptic_channel_mask_from_count(uint32_t channel_count)1594 static inline audio_channel_mask_t haptic_channel_mask_from_count(uint32_t channel_count)
1595 {
1596     switch(channel_count) {
1597     case 0:
1598         return AUDIO_CHANNEL_NONE;
1599     case 1:
1600         return AUDIO_CHANNEL_OUT_HAPTIC_A;
1601     case 2:
1602         return AUDIO_CHANNEL_OUT_HAPTIC_AB;
1603     default:
1604         return AUDIO_CHANNEL_INVALID;
1605     }
1606 }
1607 
audio_channel_mask_in_to_out(audio_channel_mask_t in)1608 static inline audio_channel_mask_t audio_channel_mask_in_to_out(audio_channel_mask_t in)
1609 {
1610     switch (in) {
1611     case AUDIO_CHANNEL_IN_MONO:
1612         return AUDIO_CHANNEL_OUT_MONO;
1613     case AUDIO_CHANNEL_IN_STEREO:
1614         return AUDIO_CHANNEL_OUT_STEREO;
1615     case AUDIO_CHANNEL_IN_5POINT1:
1616         return AUDIO_CHANNEL_OUT_5POINT1;
1617     case AUDIO_CHANNEL_IN_3POINT1POINT2:
1618         return AUDIO_CHANNEL_OUT_3POINT1POINT2;
1619     case AUDIO_CHANNEL_IN_3POINT0POINT2:
1620         return AUDIO_CHANNEL_OUT_3POINT0POINT2;
1621     case AUDIO_CHANNEL_IN_2POINT1POINT2:
1622         return AUDIO_CHANNEL_OUT_2POINT1POINT2;
1623     case AUDIO_CHANNEL_IN_2POINT0POINT2:
1624         return AUDIO_CHANNEL_OUT_2POINT0POINT2;
1625     default:
1626         return AUDIO_CHANNEL_INVALID;
1627     }
1628 }
1629 
audio_channel_mask_out_to_in(audio_channel_mask_t out)1630 static inline audio_channel_mask_t audio_channel_mask_out_to_in(audio_channel_mask_t out)
1631 {
1632     switch (out) {
1633     case AUDIO_CHANNEL_OUT_MONO:
1634         return AUDIO_CHANNEL_IN_MONO;
1635     case AUDIO_CHANNEL_OUT_STEREO:
1636         return AUDIO_CHANNEL_IN_STEREO;
1637     case AUDIO_CHANNEL_OUT_5POINT1:
1638         return AUDIO_CHANNEL_IN_5POINT1;
1639     case AUDIO_CHANNEL_OUT_3POINT1POINT2:
1640         return AUDIO_CHANNEL_IN_3POINT1POINT2;
1641     case AUDIO_CHANNEL_OUT_3POINT0POINT2:
1642         return AUDIO_CHANNEL_IN_3POINT0POINT2;
1643     case AUDIO_CHANNEL_OUT_2POINT1POINT2:
1644         return AUDIO_CHANNEL_IN_2POINT1POINT2;
1645     case AUDIO_CHANNEL_OUT_2POINT0POINT2:
1646         return AUDIO_CHANNEL_IN_2POINT0POINT2;
1647     default:
1648         return AUDIO_CHANNEL_INVALID;
1649     }
1650 }
1651 
audio_channel_position_mask_is_out_canonical(audio_channel_mask_t channelMask)1652 static inline bool audio_channel_position_mask_is_out_canonical(audio_channel_mask_t channelMask)
1653 {
1654     if (audio_channel_mask_get_representation(channelMask)
1655             != AUDIO_CHANNEL_REPRESENTATION_POSITION) {
1656         return false;
1657     }
1658     const uint32_t audioChannelCount = audio_channel_count_from_out_mask(
1659             (audio_channel_mask_t)(channelMask & ~AUDIO_CHANNEL_HAPTIC_ALL));
1660     const uint32_t hapticChannelCount = audio_channel_count_from_out_mask(
1661             (audio_channel_mask_t)(channelMask & AUDIO_CHANNEL_HAPTIC_ALL));
1662     return channelMask == (audio_channel_mask_t)(
1663             audio_channel_out_mask_from_count(audioChannelCount) |
1664             haptic_channel_mask_from_count(hapticChannelCount));
1665 }
1666 
audio_is_valid_format(audio_format_t format)1667 static inline bool audio_is_valid_format(audio_format_t format)
1668 {
1669     switch (format & AUDIO_FORMAT_MAIN_MASK) {
1670     case AUDIO_FORMAT_PCM:
1671         switch (format) {
1672         case AUDIO_FORMAT_PCM_16_BIT:
1673         case AUDIO_FORMAT_PCM_8_BIT:
1674         case AUDIO_FORMAT_PCM_32_BIT:
1675         case AUDIO_FORMAT_PCM_8_24_BIT:
1676         case AUDIO_FORMAT_PCM_FLOAT:
1677         case AUDIO_FORMAT_PCM_24_BIT_PACKED:
1678             return true;
1679         default:
1680             return false;
1681         }
1682         /* not reached */
1683     case AUDIO_FORMAT_MP3:
1684     case AUDIO_FORMAT_AMR_NB:
1685     case AUDIO_FORMAT_AMR_WB:
1686         return true;
1687     case AUDIO_FORMAT_AAC:
1688         switch (format) {
1689         case AUDIO_FORMAT_AAC:
1690         case AUDIO_FORMAT_AAC_MAIN:
1691         case AUDIO_FORMAT_AAC_LC:
1692         case AUDIO_FORMAT_AAC_SSR:
1693         case AUDIO_FORMAT_AAC_LTP:
1694         case AUDIO_FORMAT_AAC_HE_V1:
1695         case AUDIO_FORMAT_AAC_SCALABLE:
1696         case AUDIO_FORMAT_AAC_ERLC:
1697         case AUDIO_FORMAT_AAC_LD:
1698         case AUDIO_FORMAT_AAC_HE_V2:
1699         case AUDIO_FORMAT_AAC_ELD:
1700         case AUDIO_FORMAT_AAC_XHE:
1701             return true;
1702         default:
1703             return false;
1704         }
1705         /* not reached */
1706     case AUDIO_FORMAT_HE_AAC_V1:
1707     case AUDIO_FORMAT_HE_AAC_V2:
1708     case AUDIO_FORMAT_VORBIS:
1709     case AUDIO_FORMAT_OPUS:
1710     case AUDIO_FORMAT_AC3:
1711         return true;
1712     case AUDIO_FORMAT_E_AC3:
1713         switch (format) {
1714         case AUDIO_FORMAT_E_AC3:
1715         case AUDIO_FORMAT_E_AC3_JOC:
1716             return true;
1717         default:
1718             return false;
1719         }
1720         /* not reached */
1721     case AUDIO_FORMAT_DTS:
1722     case AUDIO_FORMAT_DTS_HD:
1723     case AUDIO_FORMAT_IEC60958:
1724     case AUDIO_FORMAT_IEC61937:
1725     case AUDIO_FORMAT_DOLBY_TRUEHD:
1726     case AUDIO_FORMAT_EVRC:
1727     case AUDIO_FORMAT_EVRCB:
1728     case AUDIO_FORMAT_EVRCWB:
1729     case AUDIO_FORMAT_EVRCNW:
1730     case AUDIO_FORMAT_AAC_ADIF:
1731     case AUDIO_FORMAT_WMA:
1732     case AUDIO_FORMAT_WMA_PRO:
1733     case AUDIO_FORMAT_AMR_WB_PLUS:
1734     case AUDIO_FORMAT_MP2:
1735     case AUDIO_FORMAT_QCELP:
1736     case AUDIO_FORMAT_DSD:
1737     case AUDIO_FORMAT_FLAC:
1738     case AUDIO_FORMAT_ALAC:
1739     case AUDIO_FORMAT_APE:
1740         return true;
1741     case AUDIO_FORMAT_AAC_ADTS:
1742         switch (format) {
1743         case AUDIO_FORMAT_AAC_ADTS:
1744         case AUDIO_FORMAT_AAC_ADTS_MAIN:
1745         case AUDIO_FORMAT_AAC_ADTS_LC:
1746         case AUDIO_FORMAT_AAC_ADTS_SSR:
1747         case AUDIO_FORMAT_AAC_ADTS_LTP:
1748         case AUDIO_FORMAT_AAC_ADTS_HE_V1:
1749         case AUDIO_FORMAT_AAC_ADTS_SCALABLE:
1750         case AUDIO_FORMAT_AAC_ADTS_ERLC:
1751         case AUDIO_FORMAT_AAC_ADTS_LD:
1752         case AUDIO_FORMAT_AAC_ADTS_HE_V2:
1753         case AUDIO_FORMAT_AAC_ADTS_ELD:
1754         case AUDIO_FORMAT_AAC_ADTS_XHE:
1755             return true;
1756         default:
1757             return false;
1758         }
1759         /* not reached */
1760     case AUDIO_FORMAT_SBC:
1761     case AUDIO_FORMAT_APTX:
1762     case AUDIO_FORMAT_APTX_HD:
1763     case AUDIO_FORMAT_AC4:
1764     case AUDIO_FORMAT_LDAC:
1765         return true;
1766     case AUDIO_FORMAT_MAT:
1767         switch (format) {
1768         case AUDIO_FORMAT_MAT:
1769         case AUDIO_FORMAT_MAT_1_0:
1770         case AUDIO_FORMAT_MAT_2_0:
1771         case AUDIO_FORMAT_MAT_2_1:
1772             return true;
1773         default:
1774             return false;
1775         }
1776         /* not reached */
1777     case AUDIO_FORMAT_AAC_LATM:
1778         switch (format) {
1779         case AUDIO_FORMAT_AAC_LATM:
1780         case AUDIO_FORMAT_AAC_LATM_LC:
1781         case AUDIO_FORMAT_AAC_LATM_HE_V1:
1782         case AUDIO_FORMAT_AAC_LATM_HE_V2:
1783             return true;
1784         default:
1785             return false;
1786         }
1787         /* not reached */
1788     case AUDIO_FORMAT_CELT:
1789     case AUDIO_FORMAT_APTX_ADAPTIVE:
1790     case AUDIO_FORMAT_LHDC:
1791     case AUDIO_FORMAT_LHDC_LL:
1792     case AUDIO_FORMAT_APTX_TWSP:
1793     case AUDIO_FORMAT_LC3:
1794         return true;
1795     case AUDIO_FORMAT_MPEGH:
1796         switch (format) {
1797         case AUDIO_FORMAT_MPEGH_BL_L3:
1798         case AUDIO_FORMAT_MPEGH_BL_L4:
1799         case AUDIO_FORMAT_MPEGH_LC_L3:
1800         case AUDIO_FORMAT_MPEGH_LC_L4:
1801             return true;
1802         default:
1803             return false;
1804         }
1805         /* not reached */
1806     case AUDIO_FORMAT_DTS_UHD:
1807     case AUDIO_FORMAT_DRA:
1808         return true;
1809     default:
1810         return false;
1811     }
1812 }
1813 
audio_is_iec61937_compatible(audio_format_t format)1814 static inline bool audio_is_iec61937_compatible(audio_format_t format)
1815 {
1816     switch (format) {
1817     case AUDIO_FORMAT_AC3:         // IEC 61937-3:2017
1818     case AUDIO_FORMAT_AC4:         // IEC 61937-14:2017
1819     case AUDIO_FORMAT_E_AC3:       // IEC 61937-3:2017
1820     case AUDIO_FORMAT_E_AC3_JOC:   // IEC 61937-3:2017
1821     case AUDIO_FORMAT_MAT:         // IEC 61937-9:2017
1822     case AUDIO_FORMAT_MAT_1_0:     // IEC 61937-9:2017
1823     case AUDIO_FORMAT_MAT_2_0:     // IEC 61937-9:2017
1824     case AUDIO_FORMAT_MAT_2_1:     // IEC 61937-9:2017
1825     case AUDIO_FORMAT_MPEGH_BL_L3: // IEC 61937-13:2018
1826     case AUDIO_FORMAT_MPEGH_BL_L4: // IEC 61937-13:2018
1827     case AUDIO_FORMAT_MPEGH_LC_L3: // IEC 61937-13:2018
1828     case AUDIO_FORMAT_MPEGH_LC_L4: // IEC 61937-13:2018
1829         return true;
1830     default:
1831         return false;
1832     }
1833 }
1834 
1835 /**
1836  * Extract the primary format, eg. PCM, AC3, etc.
1837  */
audio_get_main_format(audio_format_t format)1838 static inline audio_format_t audio_get_main_format(audio_format_t format)
1839 {
1840     return (audio_format_t)(format & AUDIO_FORMAT_MAIN_MASK);
1841 }
1842 
1843 /**
1844  * Is the data plain PCM samples that can be scaled and mixed?
1845  */
audio_is_linear_pcm(audio_format_t format)1846 static inline bool audio_is_linear_pcm(audio_format_t format)
1847 {
1848     return (audio_get_main_format(format) == AUDIO_FORMAT_PCM);
1849 }
1850 
1851 /**
1852  * For this format, is the number of PCM audio frames directly proportional
1853  * to the number of data bytes?
1854  *
1855  * In other words, is the format transported as PCM audio samples,
1856  * but not necessarily scalable or mixable.
1857  * This returns true for real PCM, but also for AUDIO_FORMAT_IEC61937,
1858  * which is transported as 16 bit PCM audio, but where the encoded data
1859  * cannot be mixed or scaled.
1860  */
audio_has_proportional_frames(audio_format_t format)1861 static inline bool audio_has_proportional_frames(audio_format_t format)
1862 {
1863     audio_format_t mainFormat = audio_get_main_format(format);
1864     return (mainFormat == AUDIO_FORMAT_PCM
1865             || mainFormat == AUDIO_FORMAT_IEC61937);
1866 }
1867 
audio_bytes_per_sample(audio_format_t format)1868 static inline size_t audio_bytes_per_sample(audio_format_t format)
1869 {
1870     size_t size = 0;
1871 
1872     switch (format) {
1873     case AUDIO_FORMAT_PCM_32_BIT:
1874     case AUDIO_FORMAT_PCM_8_24_BIT:
1875         size = sizeof(int32_t);
1876         break;
1877     case AUDIO_FORMAT_PCM_24_BIT_PACKED:
1878         size = sizeof(uint8_t) * 3;
1879         break;
1880     case AUDIO_FORMAT_PCM_16_BIT:
1881     case AUDIO_FORMAT_IEC61937:
1882         size = sizeof(int16_t);
1883         break;
1884     case AUDIO_FORMAT_PCM_8_BIT:
1885         size = sizeof(uint8_t);
1886         break;
1887     case AUDIO_FORMAT_PCM_FLOAT:
1888         size = sizeof(float);
1889         break;
1890     default:
1891         break;
1892     }
1893     return size;
1894 }
1895 
audio_bytes_per_frame(uint32_t channel_count,audio_format_t format)1896 static inline size_t audio_bytes_per_frame(uint32_t channel_count, audio_format_t format)
1897 {
1898     // cannot overflow for reasonable channel_count
1899     return channel_count * audio_bytes_per_sample(format);
1900 }
1901 
1902 /* converts device address to string sent to audio HAL via set_parameters */
audio_device_address_to_parameter(audio_devices_t device,const char * address)1903 static inline char *audio_device_address_to_parameter(audio_devices_t device, const char *address)
1904 {
1905     const size_t kSize = AUDIO_DEVICE_MAX_ADDRESS_LEN + sizeof("a2dp_source_address=");
1906     char param[kSize];
1907 
1908     if (device == AUDIO_DEVICE_IN_BLUETOOTH_A2DP) {
1909         snprintf(param, kSize, "%s=%s", "a2dp_source_address", address);
1910     } else if (audio_is_a2dp_out_device(device)) {
1911         snprintf(param, kSize, "%s=%s", "a2dp_sink_address", address);
1912     } else if (audio_is_remote_submix_device(device)) {
1913         snprintf(param, kSize, "%s=%s", "mix", address);
1914     } else {
1915         snprintf(param, kSize, "%s", address);
1916     }
1917     return strdup(param);
1918 }
1919 
audio_is_valid_audio_source(audio_source_t audioSource)1920 static inline bool audio_is_valid_audio_source(audio_source_t audioSource)
1921 {
1922     switch (audioSource) {
1923     case AUDIO_SOURCE_MIC:
1924     case AUDIO_SOURCE_VOICE_UPLINK:
1925     case AUDIO_SOURCE_VOICE_DOWNLINK:
1926     case AUDIO_SOURCE_VOICE_CALL:
1927     case AUDIO_SOURCE_CAMCORDER:
1928     case AUDIO_SOURCE_VOICE_RECOGNITION:
1929     case AUDIO_SOURCE_VOICE_COMMUNICATION:
1930     case AUDIO_SOURCE_REMOTE_SUBMIX:
1931     case AUDIO_SOURCE_UNPROCESSED:
1932     case AUDIO_SOURCE_VOICE_PERFORMANCE:
1933     case AUDIO_SOURCE_ECHO_REFERENCE:
1934     case AUDIO_SOURCE_FM_TUNER:
1935 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
1936     case AUDIO_SOURCE_HOTWORD:
1937 #endif // AUDIO_NO_SYSTEM_DECLARATIONS
1938         return true;
1939     default:
1940         return false;
1941     }
1942 }
1943 
1944 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
1945 
audio_port_config_has_hw_av_sync(const struct audio_port_config * port_cfg)1946 static inline bool audio_port_config_has_hw_av_sync(const struct audio_port_config *port_cfg) {
1947     if (!(port_cfg->config_mask & AUDIO_PORT_CONFIG_FLAGS)) {
1948         return false;
1949     }
1950     return audio_port_config_has_input_direction(port_cfg) ?
1951             port_cfg->flags.input & AUDIO_INPUT_FLAG_HW_AV_SYNC
1952             : port_cfg->flags.output & AUDIO_OUTPUT_FLAG_HW_AV_SYNC;
1953 }
1954 
audio_patch_has_hw_av_sync(const struct audio_patch * patch)1955 static inline bool audio_patch_has_hw_av_sync(const struct audio_patch *patch) {
1956     for (unsigned int i = 0; i < patch->num_sources; ++i) {
1957         if (audio_port_config_has_hw_av_sync(&patch->sources[i])) return true;
1958     }
1959     for (unsigned int i = 0; i < patch->num_sinks; ++i) {
1960         if (audio_port_config_has_hw_av_sync(&patch->sinks[i])) return true;
1961     }
1962     return false;
1963 }
1964 
audio_patch_is_valid(const struct audio_patch * patch)1965 static inline bool audio_patch_is_valid(const struct audio_patch *patch) {
1966     // Note that patch can have no sinks.
1967     return patch->num_sources != 0 && patch->num_sources <= AUDIO_PATCH_PORTS_MAX &&
1968             patch->num_sinks <= AUDIO_PATCH_PORTS_MAX;
1969 }
1970 
1971 // Note that when checking for equality the order of ports must match.
1972 // Patches will not be equivalent if they contain the same ports but they are permuted differently.
audio_patches_are_equal(const struct audio_patch * lhs,const struct audio_patch * rhs)1973 static inline bool audio_patches_are_equal(
1974         const struct audio_patch *lhs, const struct audio_patch *rhs) {
1975     if (!audio_patch_is_valid(lhs) || !audio_patch_is_valid(rhs)) return false;
1976     if (lhs->num_sources != rhs->num_sources || lhs->num_sinks != rhs->num_sinks) return false;
1977     for (unsigned int i = 0; i < lhs->num_sources; ++i) {
1978         if (!audio_port_configs_are_equal(&lhs->sources[i], &rhs->sources[i])) return false;
1979     }
1980     for (unsigned int i = 0; i < lhs->num_sinks; ++i) {
1981         if (!audio_port_configs_are_equal(&lhs->sinks[i], &rhs->sinks[i])) return false;
1982     }
1983     return true;
1984 }
1985 
1986 #endif
1987 
1988 // Unique effect ID (can be generated from the following site:
1989 //  http://www.itu.int/ITU-T/asn1/uuid.html)
1990 // This struct is used for effects identification and in soundtrigger.
1991 typedef struct audio_uuid_s {
1992     uint32_t timeLow;
1993     uint16_t timeMid;
1994     uint16_t timeHiAndVersion;
1995     uint16_t clockSeq;
1996     uint8_t node[6];
1997 } audio_uuid_t;
1998 
1999 /* A 3D point which could be used to represent geometric location
2000  * or orientation of a microphone.
2001  */
2002 struct audio_microphone_coordinate {
2003     float x;
2004     float y;
2005     float z;
2006 };
2007 
2008 /* An number to indicate which group the microphone locate. Main body is
2009  * usually group 0. Developer could use this value to group the microphones
2010  * that locate on the same peripheral or attachments.
2011  */
2012 typedef int audio_microphone_group_t;
2013 
2014 /* the maximum length for the microphone id */
2015 #define AUDIO_MICROPHONE_ID_MAX_LEN 32
2016 /* max number of frequency responses in a frequency response table */
2017 #define AUDIO_MICROPHONE_MAX_FREQUENCY_RESPONSES 256
2018 /* max number of microphone */
2019 #define AUDIO_MICROPHONE_MAX_COUNT 32
2020 /* the value of unknown spl */
2021 #define AUDIO_MICROPHONE_SPL_UNKNOWN -FLT_MAX
2022 /* the value of unknown sensitivity */
2023 #define AUDIO_MICROPHONE_SENSITIVITY_UNKNOWN -FLT_MAX
2024 /* the value of unknown coordinate */
2025 #define AUDIO_MICROPHONE_COORDINATE_UNKNOWN -FLT_MAX
2026 /* the value used as address when the address of bottom microphone is empty */
2027 #define AUDIO_BOTTOM_MICROPHONE_ADDRESS "bottom"
2028 /* the value used as address when the address of back microphone is empty */
2029 #define AUDIO_BACK_MICROPHONE_ADDRESS "back"
2030 
2031 struct audio_microphone_characteristic_t {
2032     char                               device_id[AUDIO_MICROPHONE_ID_MAX_LEN];
2033     audio_port_handle_t                id;
2034     audio_devices_t                    device;
2035     char                               address[AUDIO_DEVICE_MAX_ADDRESS_LEN];
2036     audio_microphone_channel_mapping_t channel_mapping[AUDIO_CHANNEL_COUNT_MAX];
2037     audio_microphone_location_t        location;
2038     audio_microphone_group_t           group;
2039     unsigned int                       index_in_the_group;
2040     float                              sensitivity;
2041     float                              max_spl;
2042     float                              min_spl;
2043     audio_microphone_directionality_t  directionality;
2044     unsigned int                       num_frequency_responses;
2045     float frequency_responses[2][AUDIO_MICROPHONE_MAX_FREQUENCY_RESPONSES];
2046     struct audio_microphone_coordinate geometric_location;
2047     struct audio_microphone_coordinate orientation;
2048 };
2049 
2050 typedef enum {
2051 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
2052     AUDIO_TIMESTRETCH_FALLBACK_CUT_REPEAT = -1, // (framework only) for speed <1.0 will truncate
2053                                                 // frames, for speed > 1.0 will repeat frames
2054     AUDIO_TIMESTRETCH_FALLBACK_DEFAULT    = 0,  // (framework only) system determines behavior
2055 #endif
2056     /* Set all processed frames to zero. */
2057     AUDIO_TIMESTRETCH_FALLBACK_MUTE       = HAL_AUDIO_TIMESTRETCH_FALLBACK_MUTE,
2058     /* Stop processing and indicate an error. */
2059     AUDIO_TIMESTRETCH_FALLBACK_FAIL       = HAL_AUDIO_TIMESTRETCH_FALLBACK_FAIL,
2060 } audio_timestretch_fallback_mode_t;
2061 
2062 // AUDIO_TIMESTRETCH_SPEED_MIN and AUDIO_TIMESTRETCH_SPEED_MAX define the min and max time stretch
2063 // speeds supported by the system. These are enforced by the system and values outside this range
2064 // will result in a runtime error.
2065 // Depending on the AudioPlaybackRate::mStretchMode, the effective limits might be narrower than
2066 // the ones specified here
2067 // AUDIO_TIMESTRETCH_SPEED_MIN_DELTA is the minimum absolute speed difference that might trigger a
2068 // parameter update
2069 #define AUDIO_TIMESTRETCH_SPEED_MIN    0.01f
2070 #define AUDIO_TIMESTRETCH_SPEED_MAX    20.0f
2071 #define AUDIO_TIMESTRETCH_SPEED_NORMAL 1.0f
2072 #define AUDIO_TIMESTRETCH_SPEED_MIN_DELTA 0.0001f
2073 
2074 // AUDIO_TIMESTRETCH_PITCH_MIN and AUDIO_TIMESTRETCH_PITCH_MAX define the min and max time stretch
2075 // pitch shifting supported by the system. These are not enforced by the system and values
2076 // outside this range might result in a pitch different than the one requested.
2077 // Depending on the AudioPlaybackRate::mStretchMode, the effective limits might be narrower than
2078 // the ones specified here.
2079 // AUDIO_TIMESTRETCH_PITCH_MIN_DELTA is the minimum absolute pitch difference that might trigger a
2080 // parameter update
2081 #define AUDIO_TIMESTRETCH_PITCH_MIN    0.25f
2082 #define AUDIO_TIMESTRETCH_PITCH_MAX    4.0f
2083 #define AUDIO_TIMESTRETCH_PITCH_NORMAL 1.0f
2084 #define AUDIO_TIMESTRETCH_PITCH_MIN_DELTA 0.0001f
2085 
2086 //Limits for AUDIO_TIMESTRETCH_STRETCH_VOICE mode
2087 #define TIMESTRETCH_SONIC_SPEED_MIN 0.1f
2088 #define TIMESTRETCH_SONIC_SPEED_MAX 6.0f
2089 
2090 struct audio_playback_rate {
2091     float mSpeed;
2092     float mPitch;
2093     audio_timestretch_stretch_mode_t  mStretchMode;
2094     audio_timestretch_fallback_mode_t mFallbackMode;
2095 };
2096 
2097 typedef struct audio_playback_rate audio_playback_rate_t;
2098 
2099 static const audio_playback_rate_t AUDIO_PLAYBACK_RATE_INITIALIZER = {
2100     /* .mSpeed = */ AUDIO_TIMESTRETCH_SPEED_NORMAL,
2101     /* .mPitch = */ AUDIO_TIMESTRETCH_PITCH_NORMAL,
2102     /* .mStretchMode = */ AUDIO_TIMESTRETCH_STRETCH_DEFAULT,
2103     /* .mFallbackMode = */ AUDIO_TIMESTRETCH_FALLBACK_FAIL
2104 };
2105 
2106 #ifndef AUDIO_NO_SYSTEM_DECLARATIONS
2107 typedef enum {
2108     AUDIO_OFFLOAD_NOT_SUPPORTED = 0,
2109     AUDIO_OFFLOAD_SUPPORTED = 1,
2110     AUDIO_OFFLOAD_GAPLESS_SUPPORTED = 2
2111 } audio_offload_mode_t;
2112 #endif // AUDIO_NO_SYSTEM_DECLARATIONS
2113 
2114 __END_DECLS
2115 
2116 /**
2117  * List of known audio HAL modules. This is the base name of the audio HAL
2118  * library composed of the "audio." prefix, one of the base names below and
2119  * a suffix specific to the device.
2120  * e.g: audio.primary.goldfish.so or audio.a2dp.default.so
2121  *
2122  * The same module names are used in audio policy configuration files.
2123  */
2124 
2125 #define AUDIO_HARDWARE_MODULE_ID_PRIMARY "primary"
2126 #define AUDIO_HARDWARE_MODULE_ID_A2DP "a2dp"
2127 #define AUDIO_HARDWARE_MODULE_ID_USB "usb"
2128 #define AUDIO_HARDWARE_MODULE_ID_REMOTE_SUBMIX "r_submix"
2129 #define AUDIO_HARDWARE_MODULE_ID_CODEC_OFFLOAD "codec_offload"
2130 #define AUDIO_HARDWARE_MODULE_ID_STUB "stub"
2131 #define AUDIO_HARDWARE_MODULE_ID_HEARING_AID "hearing_aid"
2132 #define AUDIO_HARDWARE_MODULE_ID_MSD "msd"
2133 
2134 /**
2135  * Multi-Stream Decoder (MSD) HAL service name. MSD HAL is used to mix
2136  * encoded streams together with PCM streams, producing re-encoded
2137  * streams or PCM streams.
2138  *
2139  * The service must register itself using this name, and audioserver
2140  * tries to instantiate a device factory using this name as well.
2141  * Note that the HIDL implementation library file name *must* have the
2142  * suffix "msd" in order to be picked up by HIDL that is:
2143  *
2144  *   android.hardware.audio@x.x-implmsd.so
2145  */
2146 #define AUDIO_HAL_SERVICE_NAME_MSD "msd"
2147 
2148 /**
2149  * Parameter definitions.
2150  * Note that in the framework code it's recommended to use AudioParameter.h
2151  * instead of these preprocessor defines, and for sure avoid just copying
2152  * the constant values.
2153  */
2154 
2155 #define AUDIO_PARAMETER_VALUE_ON "on"
2156 #define AUDIO_PARAMETER_VALUE_OFF "off"
2157 
2158 /**
2159  *  audio device parameters
2160  */
2161 
2162 /* BT SCO Noise Reduction + Echo Cancellation parameters */
2163 #define AUDIO_PARAMETER_KEY_BT_NREC "bt_headset_nrec"
2164 
2165 /* Get a new HW synchronization source identifier.
2166  * Return a valid source (positive integer) or AUDIO_HW_SYNC_INVALID if an error occurs
2167  * or no HW sync is available. */
2168 #define AUDIO_PARAMETER_HW_AV_SYNC "hw_av_sync"
2169 
2170 /* Screen state */
2171 #define AUDIO_PARAMETER_KEY_SCREEN_STATE "screen_state"
2172 
2173 /* User's preferred audio language setting (in ISO 639-2/T three-letter string code)
2174  * used to select a specific language presentation for next generation audio codecs. */
2175 #define AUDIO_PARAMETER_KEY_AUDIO_LANGUAGE_PREFERRED "audio_language_preferred"
2176 
2177 /**
2178  *  audio stream parameters
2179  */
2180 
2181 #define AUDIO_PARAMETER_STREAM_ROUTING "routing"             /* audio_devices_t */
2182 #define AUDIO_PARAMETER_STREAM_FORMAT "format"               /* audio_format_t */
2183 #define AUDIO_PARAMETER_STREAM_CHANNELS "channels"           /* audio_channel_mask_t */
2184 #define AUDIO_PARAMETER_STREAM_FRAME_COUNT "frame_count"     /* size_t */
2185 #define AUDIO_PARAMETER_STREAM_INPUT_SOURCE "input_source"   /* audio_source_t */
2186 #define AUDIO_PARAMETER_STREAM_SAMPLING_RATE "sampling_rate" /* uint32_t */
2187 
2188 /* Request the presentation id to be decoded by a next gen audio decoder */
2189 #define AUDIO_PARAMETER_STREAM_PRESENTATION_ID "presentation_id" /* int32_t */
2190 
2191 /* Request the program id to be decoded by a next gen audio decoder */
2192 #define AUDIO_PARAMETER_STREAM_PROGRAM_ID "program_id"           /* int32_t */
2193 
2194 #define AUDIO_PARAMETER_DEVICE_CONNECT "connect"            /* audio_devices_t */
2195 #define AUDIO_PARAMETER_DEVICE_DISCONNECT "disconnect"      /* audio_devices_t */
2196 
2197 /* Enable mono audio playback if 1, else should be 0. */
2198 #define AUDIO_PARAMETER_MONO_OUTPUT "mono_output"
2199 
2200 /* Set the HW synchronization source for an output stream. */
2201 #define AUDIO_PARAMETER_STREAM_HW_AV_SYNC "hw_av_sync"
2202 
2203 /* Query supported formats. The response is a '|' separated list of strings from
2204  * audio_format_t enum e.g: "sup_formats=AUDIO_FORMAT_PCM_16_BIT" */
2205 #define AUDIO_PARAMETER_STREAM_SUP_FORMATS "sup_formats"
2206 /* Query supported channel masks. The response is a '|' separated list of strings from
2207  * audio_channel_mask_t enum e.g: "sup_channels=AUDIO_CHANNEL_OUT_STEREO|AUDIO_CHANNEL_OUT_MONO" */
2208 #define AUDIO_PARAMETER_STREAM_SUP_CHANNELS "sup_channels"
2209 /* Query supported sampling rates. The response is a '|' separated list of integer values e.g:
2210  * "sup_sampling_rates=44100|48000" */
2211 #define AUDIO_PARAMETER_STREAM_SUP_SAMPLING_RATES "sup_sampling_rates"
2212 
2213 #define AUDIO_PARAMETER_VALUE_LIST_SEPARATOR "|"
2214 
2215 /* Reconfigure offloaded A2DP codec */
2216 #define AUDIO_PARAMETER_RECONFIG_A2DP "reconfigA2dp"
2217 /* Query if HwModule supports reconfiguration of offloaded A2DP codec */
2218 #define AUDIO_PARAMETER_A2DP_RECONFIG_SUPPORTED "isReconfigA2dpSupported"
2219 
2220 /**
2221  * For querying device supported encapsulation capabilities. All returned values are integer,
2222  * which are bit fields composed from using encapsulation capability values as position bits.
2223  * Encapsulation capability values are defined in audio_encapsulation_mode_t and
2224  * audio_encapsulation_metadata_type_t. For instance, if the supported encapsulation mode is
2225  * AUDIO_ENCAPSULATION_MODE_ELEMENTARY_STREAM, the returned value is
2226  * "supEncapsulationModes=1 << AUDIO_ENCAPSULATION_MODE_ELEMENTARY_STREAM".
2227  * When querying device supported encapsulation capabilities, the key should use device type
2228  * and address so that it is able to identify the device. The device will be a key. The device
2229  * type will be the value of key AUDIO_PARAMETER_STREAM_ROUTING.
2230  */
2231 #define AUDIO_PARAMETER_DEVICE_SUP_ENCAPSULATION_MODES "supEncapsulationModes"
2232 #define AUDIO_PARAMETER_DEVICE_SUP_ENCAPSULATION_METADATA_TYPES "supEncapsulationMetadataTypes"
2233 
2234 /* Query additional delay in millisecond on each output device. */
2235 #define AUDIO_PARAMETER_DEVICE_ADDITIONAL_OUTPUT_DELAY "additional_output_device_delay"
2236 #define AUDIO_PARAMETER_DEVICE_MAX_ADDITIONAL_OUTPUT_DELAY "max_additional_output_device_delay"
2237 
2238 /**
2239  * audio codec parameters
2240  */
2241 
2242 #define AUDIO_OFFLOAD_CODEC_PARAMS "music_offload_codec_param"
2243 #define AUDIO_OFFLOAD_CODEC_BIT_PER_SAMPLE "music_offload_bit_per_sample"
2244 #define AUDIO_OFFLOAD_CODEC_BIT_RATE "music_offload_bit_rate"
2245 #define AUDIO_OFFLOAD_CODEC_AVG_BIT_RATE "music_offload_avg_bit_rate"
2246 #define AUDIO_OFFLOAD_CODEC_ID "music_offload_codec_id"
2247 #define AUDIO_OFFLOAD_CODEC_BLOCK_ALIGN "music_offload_block_align"
2248 #define AUDIO_OFFLOAD_CODEC_SAMPLE_RATE "music_offload_sample_rate"
2249 #define AUDIO_OFFLOAD_CODEC_ENCODE_OPTION "music_offload_encode_option"
2250 #define AUDIO_OFFLOAD_CODEC_NUM_CHANNEL  "music_offload_num_channels"
2251 #define AUDIO_OFFLOAD_CODEC_DOWN_SAMPLING  "music_offload_down_sampling"
2252 #define AUDIO_OFFLOAD_CODEC_DELAY_SAMPLES  "delay_samples"
2253 #define AUDIO_OFFLOAD_CODEC_PADDING_SAMPLES  "padding_samples"
2254 
2255 
2256 #endif  // ANDROID_AUDIO_CORE_H
2257