1 /* SPDX-License-Identifier: GPL-2.0-only */ 2 /****************************************************************************** 3 4 AudioScience HPI driver 5 Copyright (C) 1997-2011 AudioScience Inc. <support@audioscience.com> 6 7 8 */ 9 /** \file hpi.h 10 11 AudioScience Hardware Programming Interface (HPI) 12 public API definition. 13 14 The HPI is a low-level hardware abstraction layer to all 15 AudioScience digital audio adapters 16 17 (C) Copyright AudioScience Inc. 1998-2010 18 */ 19 20 #ifndef _HPI_H_ 21 #define _HPI_H_ 22 23 #include <linux/types.h> 24 #define HPI_BUILD_KERNEL_MODE 25 26 /******************************************************************************/ 27 /******** HPI API DEFINITIONS *****/ 28 /******************************************************************************/ 29 30 /*******************************************/ 31 /** Audio format types 32 \ingroup stream 33 */ 34 enum HPI_FORMATS { 35 /** Used internally on adapter. */ 36 HPI_FORMAT_MIXER_NATIVE = 0, 37 /** 8-bit unsigned PCM. Windows equivalent is WAVE_FORMAT_PCM. */ 38 HPI_FORMAT_PCM8_UNSIGNED = 1, 39 /** 16-bit signed PCM. Windows equivalent is WAVE_FORMAT_PCM. */ 40 HPI_FORMAT_PCM16_SIGNED = 2, 41 /** MPEG-1 Layer-1. */ 42 HPI_FORMAT_MPEG_L1 = 3, 43 /** MPEG-1 Layer-2. 44 45 Windows equivalent is WAVE_FORMAT_MPEG. 46 47 The following table shows what combinations of mode and bitrate are possible: 48 49 <table border=1 cellspacing=0 cellpadding=5> 50 <tr> 51 <td><p><b>Bitrate (kbs)</b></p> 52 <td><p><b>Mono</b></p> 53 <td><p><b>Stereo,<br>Joint Stereo or<br>Dual Channel</b></p> 54 55 <tr><td>32<td>X<td>_ 56 <tr><td>40<td>_<td>_ 57 <tr><td>48<td>X<td>_ 58 <tr><td>56<td>X<td>_ 59 <tr><td>64<td>X<td>X 60 <tr><td>80<td>X<td>_ 61 <tr><td>96<td>X<td>X 62 <tr><td>112<td>X<td>X 63 <tr><td>128<td>X<td>X 64 <tr><td>160<td>X<td>X 65 <tr><td>192<td>X<td>X 66 <tr><td>224<td>_<td>X 67 <tr><td>256<td>-<td>X 68 <tr><td>320<td>-<td>X 69 <tr><td>384<td>_<td>X 70 </table> 71 */ 72 HPI_FORMAT_MPEG_L2 = 4, 73 /** MPEG-1 Layer-3. 74 Windows equivalent is WAVE_FORMAT_MPEG. 75 76 The following table shows what combinations of mode and bitrate are possible: 77 78 <table border=1 cellspacing=0 cellpadding=5> 79 <tr> 80 <td><p><b>Bitrate (kbs)</b></p> 81 <td><p><b>Mono<br>Stereo @ 8,<br>11.025 and<br>12kHz*</b></p> 82 <td><p><b>Mono<br>Stereo @ 16,<br>22.050 and<br>24kHz*</b></p> 83 <td><p><b>Mono<br>Stereo @ 32,<br>44.1 and<br>48kHz</b></p> 84 85 <tr><td>16<td>X<td>X<td>_ 86 <tr><td>24<td>X<td>X<td>_ 87 <tr><td>32<td>X<td>X<td>X 88 <tr><td>40<td>X<td>X<td>X 89 <tr><td>48<td>X<td>X<td>X 90 <tr><td>56<td>X<td>X<td>X 91 <tr><td>64<td>X<td>X<td>X 92 <tr><td>80<td>_<td>X<td>X 93 <tr><td>96<td>_<td>X<td>X 94 <tr><td>112<td>_<td>X<td>X 95 <tr><td>128<td>_<td>X<td>X 96 <tr><td>144<td>_<td>X<td>_ 97 <tr><td>160<td>_<td>X<td>X 98 <tr><td>192<td>_<td>_<td>X 99 <tr><td>224<td>_<td>_<td>X 100 <tr><td>256<td>-<td>_<td>X 101 <tr><td>320<td>-<td>_<td>X 102 </table> 103 \b * Available on the ASI6000 series only 104 */ 105 HPI_FORMAT_MPEG_L3 = 5, 106 /** Dolby AC-2. */ 107 HPI_FORMAT_DOLBY_AC2 = 6, 108 /** Dolbt AC-3. */ 109 HPI_FORMAT_DOLBY_AC3 = 7, 110 /** 16-bit PCM big-endian. */ 111 HPI_FORMAT_PCM16_BIGENDIAN = 8, 112 /** TAGIT-1 algorithm - hits. */ 113 HPI_FORMAT_AA_TAGIT1_HITS = 9, 114 /** TAGIT-1 algorithm - inserts. */ 115 HPI_FORMAT_AA_TAGIT1_INSERTS = 10, 116 /** 32-bit signed PCM. Windows equivalent is WAVE_FORMAT_PCM. 117 Each sample is a 32bit word. The most significant 24 bits contain a 24-bit 118 sample and the least significant 8 bits are set to 0. 119 */ 120 HPI_FORMAT_PCM32_SIGNED = 11, 121 /** Raw bitstream - unknown format. */ 122 HPI_FORMAT_RAW_BITSTREAM = 12, 123 /** TAGIT-1 algorithm hits - extended. */ 124 HPI_FORMAT_AA_TAGIT1_HITS_EX1 = 13, 125 /** 32-bit PCM as an IEEE float. Windows equivalent is WAVE_FORMAT_IEEE_FLOAT. 126 Each sample is a 32bit word in IEEE754 floating point format. 127 The range is +1.0 to -1.0, which corresponds to digital fullscale. 128 */ 129 HPI_FORMAT_PCM32_FLOAT = 14, 130 /** 24-bit PCM signed. Windows equivalent is WAVE_FORMAT_PCM. */ 131 HPI_FORMAT_PCM24_SIGNED = 15, 132 /** OEM format 1 - private. */ 133 HPI_FORMAT_OEM1 = 16, 134 /** OEM format 2 - private. */ 135 HPI_FORMAT_OEM2 = 17, 136 /** Undefined format. */ 137 HPI_FORMAT_UNDEFINED = 0xffff 138 }; 139 140 /*******************************************/ 141 /** Stream States 142 \ingroup stream 143 */ 144 enum HPI_STREAM_STATES { 145 /** State stopped - stream is stopped. */ 146 HPI_STATE_STOPPED = 1, 147 /** State playing - stream is playing audio. */ 148 HPI_STATE_PLAYING = 2, 149 /** State recording - stream is recording. */ 150 HPI_STATE_RECORDING = 3, 151 /** State drained - playing stream ran out of data to play. */ 152 HPI_STATE_DRAINED = 4, 153 /** State generate sine - to be implemented. */ 154 HPI_STATE_SINEGEN = 5, 155 /** State wait - used for inter-card sync to mean waiting for all 156 cards to be ready. */ 157 HPI_STATE_WAIT = 6 158 }; 159 /*******************************************/ 160 /** Source node types 161 \ingroup mixer 162 */ 163 enum HPI_SOURCENODES { 164 /** This define can be used instead of 0 to indicate 165 that there is no valid source node. A control that 166 exists on a destination node can be searched for using a source 167 node value of either 0, or HPI_SOURCENODE_NONE */ 168 HPI_SOURCENODE_NONE = 100, 169 /** Out Stream (Play) node. */ 170 HPI_SOURCENODE_OSTREAM = 101, 171 /** Line in node - could be analog, AES/EBU or network. */ 172 HPI_SOURCENODE_LINEIN = 102, 173 HPI_SOURCENODE_AESEBU_IN = 103, /**< AES/EBU input node. */ 174 HPI_SOURCENODE_TUNER = 104, /**< tuner node. */ 175 HPI_SOURCENODE_RF = 105, /**< RF input node. */ 176 HPI_SOURCENODE_CLOCK_SOURCE = 106, /**< clock source node. */ 177 HPI_SOURCENODE_RAW_BITSTREAM = 107, /**< raw bitstream node. */ 178 HPI_SOURCENODE_MICROPHONE = 108, /**< microphone node. */ 179 /** Cobranet input node - 180 Audio samples come from the Cobranet network and into the device. */ 181 HPI_SOURCENODE_COBRANET = 109, 182 HPI_SOURCENODE_ANALOG = 110, /**< analog input node. */ 183 HPI_SOURCENODE_ADAPTER = 111, /**< adapter node. */ 184 /** RTP stream input node - This node is a destination for 185 packets of RTP audio samples from other devices. */ 186 HPI_SOURCENODE_RTP_DESTINATION = 112, 187 HPI_SOURCENODE_INTERNAL = 113, /**< node internal to the device. */ 188 HPI_SOURCENODE_AVB = 114, /**< AVB input stream */ 189 HPI_SOURCENODE_BLULINK = 115, /**< BLU-link input channel */ 190 /* !!!Update this AND hpidebug.h if you add a new sourcenode type!!! */ 191 HPI_SOURCENODE_LAST_INDEX = 115 /**< largest ID */ 192 /* AX6 max sourcenode types = 15 */ 193 }; 194 195 /*******************************************/ 196 /** Destination node types 197 \ingroup mixer 198 */ 199 enum HPI_DESTNODES { 200 /** This define can be used instead of 0 to indicate 201 that there is no valid destination node. A control that 202 exists on a source node can be searched for using a destination 203 node value of either 0, or HPI_DESTNODE_NONE */ 204 HPI_DESTNODE_NONE = 200, 205 /** In Stream (Record) node. */ 206 HPI_DESTNODE_ISTREAM = 201, 207 HPI_DESTNODE_LINEOUT = 202, /**< line out node. */ 208 HPI_DESTNODE_AESEBU_OUT = 203, /**< AES/EBU output node. */ 209 HPI_DESTNODE_RF = 204, /**< RF output node. */ 210 HPI_DESTNODE_SPEAKER = 205, /**< speaker output node. */ 211 /** Cobranet output node - 212 Audio samples from the device are sent out on the Cobranet network.*/ 213 HPI_DESTNODE_COBRANET = 206, 214 HPI_DESTNODE_ANALOG = 207, /**< analog output node. */ 215 /** RTP stream output node - This node is a source for 216 packets of RTP audio samples that are sent to other devices. */ 217 HPI_DESTNODE_RTP_SOURCE = 208, 218 HPI_DESTNODE_AVB = 209, /**< AVB output stream */ 219 HPI_DESTNODE_INTERNAL = 210, /**< node internal to the device. */ 220 HPI_DESTNODE_BLULINK = 211, /**< BLU-link output channel. */ 221 /* !!!Update this AND hpidebug.h if you add a new destnode type!!! */ 222 HPI_DESTNODE_LAST_INDEX = 211 /**< largest ID */ 223 /* AX6 max destnode types = 15 */ 224 }; 225 226 /*******************************************/ 227 /** Mixer control types 228 \ingroup mixer 229 */ 230 enum HPI_CONTROLS { 231 HPI_CONTROL_GENERIC = 0, /**< generic control. */ 232 HPI_CONTROL_CONNECTION = 1, /**< A connection between nodes. */ 233 HPI_CONTROL_VOLUME = 2, /**< volume control - works in dB_fs. */ 234 HPI_CONTROL_METER = 3, /**< peak meter control. */ 235 HPI_CONTROL_MUTE = 4, /*mute control - not used at present. */ 236 HPI_CONTROL_MULTIPLEXER = 5, /**< multiplexer control. */ 237 238 HPI_CONTROL_AESEBU_TRANSMITTER = 6, /**< AES/EBU transmitter control */ 239 HPI_CONTROL_AESEBUTX = 6, /* HPI_CONTROL_AESEBU_TRANSMITTER */ 240 241 HPI_CONTROL_AESEBU_RECEIVER = 7, /**< AES/EBU receiver control. */ 242 HPI_CONTROL_AESEBURX = 7, /* HPI_CONTROL_AESEBU_RECEIVER */ 243 244 HPI_CONTROL_LEVEL = 8, /**< level/trim control - works in d_bu. */ 245 HPI_CONTROL_TUNER = 9, /**< tuner control. */ 246 /* HPI_CONTROL_ONOFFSWITCH = 10 */ 247 HPI_CONTROL_VOX = 11, /**< vox control. */ 248 /* HPI_CONTROL_AES18_TRANSMITTER = 12 */ 249 /* HPI_CONTROL_AES18_RECEIVER = 13 */ 250 /* HPI_CONTROL_AES18_BLOCKGENERATOR = 14 */ 251 HPI_CONTROL_CHANNEL_MODE = 15, /**< channel mode control. */ 252 253 HPI_CONTROL_BITSTREAM = 16, /**< bitstream control. */ 254 HPI_CONTROL_SAMPLECLOCK = 17, /**< sample clock control. */ 255 HPI_CONTROL_MICROPHONE = 18, /**< microphone control. */ 256 HPI_CONTROL_PARAMETRIC_EQ = 19, /**< parametric EQ control. */ 257 HPI_CONTROL_EQUALIZER = 19, /*HPI_CONTROL_PARAMETRIC_EQ */ 258 259 HPI_CONTROL_COMPANDER = 20, /**< compander control. */ 260 HPI_CONTROL_COBRANET = 21, /**< cobranet control. */ 261 HPI_CONTROL_TONEDETECTOR = 22, /**< tone detector control. */ 262 HPI_CONTROL_SILENCEDETECTOR = 23, /**< silence detector control. */ 263 HPI_CONTROL_PAD = 24, /**< tuner PAD control. */ 264 HPI_CONTROL_SRC = 25, /**< samplerate converter control. */ 265 HPI_CONTROL_UNIVERSAL = 26, /**< universal control. */ 266 267 /* !!! Update this AND hpidebug.h if you add a new control type!!!*/ 268 HPI_CONTROL_LAST_INDEX = 26 /**<highest control type ID */ 269 /* WARNING types 256 or greater impact bit packing in all AX6 DSP code */ 270 }; 271 272 /*******************************************/ 273 /** Adapter properties 274 These are used in HPI_AdapterSetProperty() and HPI_AdapterGetProperty() 275 \ingroup adapter 276 */ 277 enum HPI_ADAPTER_PROPERTIES { 278 /** \internal Used in dwProperty field of HPI_AdapterSetProperty() and 279 HPI_AdapterGetProperty(). This errata applies to all ASI6000 cards with both 280 analog and digital outputs. The CS4224 A/D+D/A has a one sample delay between 281 left and right channels on both its input (ADC) and output (DAC). 282 More details are available in Cirrus Logic errata ER284B2. 283 PDF available from www.cirrus.com, released by Cirrus in 2001. 284 */ 285 HPI_ADAPTER_PROPERTY_ERRATA_1 = 1, 286 287 /** Adapter grouping property 288 Indicates whether the adapter supports the grouping API (for ASIO and SSX2) 289 */ 290 HPI_ADAPTER_PROPERTY_GROUPING = 2, 291 292 /** Driver SSX2 property 293 Tells the kernel driver to turn on SSX2 stream mapping. 294 This feature is not used by the DSP. In fact the call is completely processed 295 by the driver and is not passed on to the DSP at all. 296 */ 297 HPI_ADAPTER_PROPERTY_ENABLE_SSX2 = 3, 298 299 /** Adapter SSX2 property 300 Indicates the state of the adapter's SSX2 setting. This setting is stored in 301 non-volatile memory on the adapter. A typical call sequence would be to use 302 HPI_ADAPTER_PROPERTY_SSX2_SETTING to set SSX2 on the adapter and then to reload 303 the driver. The driver would query HPI_ADAPTER_PROPERTY_SSX2_SETTING during 304 startup and if SSX2 is set, it would then call HPI_ADAPTER_PROPERTY_ENABLE_SSX2 305 to enable SSX2 stream mapping within the kernel level of the driver. 306 */ 307 HPI_ADAPTER_PROPERTY_SSX2_SETTING = 4, 308 309 /** Enables/disables PCI(e) IRQ. 310 A setting of 0 indicates that no interrupts are being generated. A DSP boot 311 this property is set to 0. Setting to a non-zero value specifies the number 312 of frames of audio that should be processed between interrupts. This property 313 should be set to multiple of the mixer interval as read back from the 314 HPI_ADAPTER_PROPERTY_INTERVAL property. 315 */ 316 HPI_ADAPTER_PROPERTY_IRQ_RATE = 5, 317 318 /** Base number for readonly properties */ 319 HPI_ADAPTER_PROPERTY_READONLYBASE = 256, 320 321 /** Readonly adapter latency property. 322 This property returns in the input and output latency in samples. 323 Property 1 is the estimated input latency 324 in samples, while Property 2 is that output latency in samples. 325 */ 326 HPI_ADAPTER_PROPERTY_LATENCY = 256, 327 328 /** Readonly adapter granularity property. 329 The granulariy is the smallest size chunk of stereo samples that is processed by 330 the adapter. 331 This property returns the record granularity in samples in Property 1. 332 Property 2 returns the play granularity. 333 */ 334 HPI_ADAPTER_PROPERTY_GRANULARITY = 257, 335 336 /** Readonly adapter number of current channels property. 337 Property 1 is the number of record channels per record device. 338 Property 2 is the number of play channels per playback device.*/ 339 HPI_ADAPTER_PROPERTY_CURCHANNELS = 258, 340 341 /** Readonly adapter software version. 342 The SOFTWARE_VERSION property returns the version of the software running 343 on the adapter as Major.Minor.Release. 344 Property 1 contains Major in bits 15..8 and Minor in bits 7..0. 345 Property 2 contains Release in bits 7..0. */ 346 HPI_ADAPTER_PROPERTY_SOFTWARE_VERSION = 259, 347 348 /** Readonly adapter MAC address MSBs. 349 The MAC_ADDRESS_MSB property returns 350 the most significant 32 bits of the MAC address. 351 Property 1 contains bits 47..32 of the MAC address. 352 Property 2 contains bits 31..16 of the MAC address. */ 353 HPI_ADAPTER_PROPERTY_MAC_ADDRESS_MSB = 260, 354 355 /** Readonly adapter MAC address LSBs 356 The MAC_ADDRESS_LSB property returns 357 the least significant 16 bits of the MAC address. 358 Property 1 contains bits 15..0 of the MAC address. */ 359 HPI_ADAPTER_PROPERTY_MAC_ADDRESS_LSB = 261, 360 361 /** Readonly extended adapter type number 362 The EXTENDED_ADAPTER_TYPE property returns the 4 digits of an extended 363 adapter type, i.e ASI8920-0022, 0022 is the extended type. 364 The digits are returned as ASCII characters rather than the hex digits that 365 are returned for the main type 366 Property 1 returns the 1st two (left most) digits, i.e "00" 367 in the example above, the upper byte being the left most digit. 368 Property 2 returns the 2nd two digits, i.e "22" in the example above*/ 369 HPI_ADAPTER_PROPERTY_EXTENDED_ADAPTER_TYPE = 262, 370 371 /** Readonly debug log buffer information */ 372 HPI_ADAPTER_PROPERTY_LOGTABLEN = 263, 373 HPI_ADAPTER_PROPERTY_LOGTABBEG = 264, 374 375 /** Readonly adapter IP address 376 For 192.168.1.101 377 Property 1 returns the 1st two (left most) digits, i.e 192*256 + 168 378 in the example above, the upper byte being the left most digit. 379 Property 2 returns the 2nd two digits, i.e 1*256 + 101 in the example above, */ 380 HPI_ADAPTER_PROPERTY_IP_ADDRESS = 265, 381 382 /** Readonly adapter buffer processed count. Returns a buffer processed count 383 that is incremented every time all buffers for all streams are updated. This 384 is useful for checking completion of all stream operations across the adapter 385 when using grouped streams. 386 */ 387 HPI_ADAPTER_PROPERTY_BUFFER_UPDATE_COUNT = 266, 388 389 /** Readonly mixer and stream intervals 390 391 These intervals are measured in mixer frames. 392 To convert to time, divide by the adapter samplerate. 393 394 The mixer interval is the number of frames processed in one mixer iteration. 395 The stream update interval is the interval at which streams check for and 396 process data, and BBM host buffer counters are updated. 397 398 Property 1 is the mixer interval in mixer frames. 399 Property 2 is the stream update interval in mixer frames. 400 */ 401 HPI_ADAPTER_PROPERTY_INTERVAL = 267, 402 /** Adapter capabilities 1 403 Property 1 - adapter can do multichannel (SSX1) 404 Property 2 - adapter can do stream grouping (supports SSX2) 405 */ 406 HPI_ADAPTER_PROPERTY_CAPS1 = 268, 407 /** Adapter capabilities 2 408 Property 1 - adapter can do samplerate conversion (MRX) 409 Property 2 - adapter can do timestretch (TSX) 410 */ 411 HPI_ADAPTER_PROPERTY_CAPS2 = 269, 412 413 /** Readonly adapter sync header connection count. 414 */ 415 HPI_ADAPTER_PROPERTY_SYNC_HEADER_CONNECTIONS = 270, 416 /** Readonly supports SSX2 property. 417 Indicates the adapter supports SSX2 in some mode setting. The 418 return value is true (1) or false (0). If the current adapter 419 mode is MONO SSX2 is disabled, even though this property will 420 return true. 421 */ 422 HPI_ADAPTER_PROPERTY_SUPPORTS_SSX2 = 271, 423 /** Readonly supports PCI(e) IRQ. 424 Indicates that the adapter in it's current mode supports interrupts 425 across the host bus. Note, this does not imply that interrupts are 426 enabled. Instead it indicates that they can be enabled. 427 */ 428 HPI_ADAPTER_PROPERTY_SUPPORTS_IRQ = 272, 429 /** Readonly supports firmware updating. 430 Indicates that the adapter implements an interface to update firmware 431 on the adapter. 432 */ 433 HPI_ADAPTER_PROPERTY_SUPPORTS_FW_UPDATE = 273, 434 /** Readonly Firmware IDs 435 Identifiy firmware independent of individual adapter type. 436 May be used as a filter for firmware update images. 437 Property 1 = Bootloader ID 438 Property 2 = Main program ID 439 */ 440 HPI_ADAPTER_PROPERTY_FIRMWARE_ID = 274 441 }; 442 443 /** Adapter mode commands 444 445 Used in wQueryOrSet parameter of HPI_AdapterSetModeEx(). 446 \ingroup adapter 447 */ 448 enum HPI_ADAPTER_MODE_CMDS { 449 /** Set the mode to the given parameter */ 450 HPI_ADAPTER_MODE_SET = 0, 451 /** Return 0 or error depending whether mode is valid, 452 but don't set the mode */ 453 HPI_ADAPTER_MODE_QUERY = 1 454 }; 455 456 /** Adapter Modes 457 These are used by HPI_AdapterSetModeEx() 458 459 \warning - more than 16 possible modes breaks 460 a bitmask in the Windows WAVE DLL 461 \ingroup adapter 462 */ 463 enum HPI_ADAPTER_MODES { 464 /** 4 outstream mode. 465 - ASI6114: 1 instream 466 - ASI6044: 4 instreams 467 - ASI6012: 1 instream 468 - ASI6102: no instreams 469 - ASI6022, ASI6122: 2 instreams 470 - ASI5111, ASI5101: 2 instreams 471 - ASI652x, ASI662x: 2 instreams 472 - ASI654x, ASI664x: 4 instreams 473 */ 474 HPI_ADAPTER_MODE_4OSTREAM = 1, 475 476 /** 6 outstream mode. 477 - ASI6012: 1 instream, 478 - ASI6022, ASI6122: 2 instreams 479 - ASI652x, ASI662x: 4 instreams 480 */ 481 HPI_ADAPTER_MODE_6OSTREAM = 2, 482 483 /** 8 outstream mode. 484 - ASI6114: 8 instreams 485 - ASI6118: 8 instreams 486 - ASI6585: 8 instreams 487 */ 488 HPI_ADAPTER_MODE_8OSTREAM = 3, 489 490 /** 16 outstream mode. 491 - ASI6416 16 instreams 492 - ASI6518, ASI6618 16 instreams 493 - ASI6118 16 mono out and in streams 494 */ 495 HPI_ADAPTER_MODE_16OSTREAM = 4, 496 497 /** one outstream mode. 498 - ASI5111 1 outstream, 1 instream 499 */ 500 HPI_ADAPTER_MODE_1OSTREAM = 5, 501 502 /** ASI504X mode 1. 12 outstream, 4 instream 0 to 48kHz sample rates 503 (see ASI504X datasheet for more info). 504 */ 505 HPI_ADAPTER_MODE_1 = 6, 506 507 /** ASI504X mode 2. 4 outstreams, 4 instreams at 0 to 192kHz sample rates 508 (see ASI504X datasheet for more info). 509 */ 510 HPI_ADAPTER_MODE_2 = 7, 511 512 /** ASI504X mode 3. 4 outstreams, 4 instreams at 0 to 192kHz sample rates 513 (see ASI504X datasheet for more info). 514 */ 515 HPI_ADAPTER_MODE_3 = 8, 516 517 /** ASI504X multichannel mode. 518 2 outstreams -> 4 line outs = 1 to 8 channel streams), 519 4 lineins -> 1 instream (1 to 8 channel streams) at 0-48kHz. 520 For more info see the SSX Specification. 521 */ 522 HPI_ADAPTER_MODE_MULTICHANNEL = 9, 523 524 /** 12 outstream mode. 525 - ASI6514, ASI6614: 2 instreams 526 - ASI6540,ASI6544: 8 instreams 527 - ASI6640,ASI6644: 8 instreams 528 */ 529 HPI_ADAPTER_MODE_12OSTREAM = 10, 530 531 /** 9 outstream mode. 532 - ASI6044: 8 instreams 533 */ 534 HPI_ADAPTER_MODE_9OSTREAM = 11, 535 536 /** mono mode. 537 - ASI6416: 16 outstreams/instreams 538 - ASI5402: 2 outstreams/instreams 539 */ 540 HPI_ADAPTER_MODE_MONO = 12, 541 542 /** Low latency mode. 543 - ASI6416/ASI6316: 1 16 channel outstream and instream 544 */ 545 HPI_ADAPTER_MODE_LOW_LATENCY = 13 546 }; 547 548 /* Note, adapters can have more than one capability - 549 encoding as bitfield is recommended. */ 550 #define HPI_CAPABILITY_NONE (0) 551 #define HPI_CAPABILITY_MPEG_LAYER3 (1) 552 553 /* Set this equal to maximum capability index, 554 Must not be greater than 32 - see axnvdef.h */ 555 #define HPI_CAPABILITY_MAX 1 556 /* #define HPI_CAPABILITY_AAC 2 */ 557 558 /******************************************* STREAM ATTRIBUTES ****/ 559 560 /** MPEG Ancillary Data modes 561 562 The mode for the ancillary data insertion or extraction to operate in. 563 \ingroup stream 564 */ 565 enum HPI_MPEG_ANC_MODES { 566 /** the MPEG frames have energy information stored in them (5 bytes per stereo frame, 3 per mono) */ 567 HPI_MPEG_ANC_HASENERGY = 0, 568 /** the entire ancillary data field is taken up by data from the Anc data buffer 569 On encode, the encoder will insert the energy bytes before filling the remainder 570 of the ancillary data space with data from the ancillary data buffer. 571 */ 572 HPI_MPEG_ANC_RAW = 1 573 }; 574 575 /** Ancillary Data Alignment 576 \ingroup instream 577 */ 578 enum HPI_ISTREAM_MPEG_ANC_ALIGNS { 579 /** data is packed against the end of data, then padded to the end of frame */ 580 HPI_MPEG_ANC_ALIGN_LEFT = 0, 581 /** data is packed against the end of the frame */ 582 HPI_MPEG_ANC_ALIGN_RIGHT = 1 583 }; 584 585 /** MPEG modes 586 MPEG modes - can be used optionally for HPI_FormatCreate() 587 parameter dwAttributes. 588 589 Using any mode setting other than HPI_MPEG_MODE_DEFAULT 590 with single channel format will return an error. 591 \ingroup stream 592 */ 593 enum HPI_MPEG_MODES { 594 /** Causes the MPEG-1 Layer II bitstream to be recorded 595 in single_channel mode when the number of channels is 1 and in stereo when the 596 number of channels is 2. */ 597 HPI_MPEG_MODE_DEFAULT = 0, 598 /** Standard stereo without joint-stereo compression */ 599 HPI_MPEG_MODE_STEREO = 1, 600 /** Joint stereo */ 601 HPI_MPEG_MODE_JOINTSTEREO = 2, 602 /** Left and Right channels are completely independent */ 603 HPI_MPEG_MODE_DUALCHANNEL = 3 604 }; 605 /******************************************* MIXER ATTRIBUTES ****/ 606 607 /* \defgroup mixer_flags Mixer flags for HPI_MIXER_GET_CONTROL_MULTIPLE_VALUES 608 { 609 */ 610 #define HPI_MIXER_GET_CONTROL_MULTIPLE_CHANGED (0) 611 #define HPI_MIXER_GET_CONTROL_MULTIPLE_RESET (1) 612 /*}*/ 613 614 /** Commands used by HPI_MixerStore() 615 \ingroup mixer 616 */ 617 enum HPI_MIXER_STORE_COMMAND { 618 /** Save all mixer control settings. */ 619 HPI_MIXER_STORE_SAVE = 1, 620 /** Restore all controls from saved. */ 621 HPI_MIXER_STORE_RESTORE = 2, 622 /** Delete saved control settings. */ 623 HPI_MIXER_STORE_DELETE = 3, 624 /** Enable auto storage of some control settings. */ 625 HPI_MIXER_STORE_ENABLE = 4, 626 /** Disable auto storage of some control settings. */ 627 HPI_MIXER_STORE_DISABLE = 5, 628 /** Unimplemented - save the attributes of a single control. */ 629 HPI_MIXER_STORE_SAVE_SINGLE = 6 630 }; 631 632 /****************************/ 633 /* CONTROL ATTRIBUTE VALUES */ 634 /****************************/ 635 636 /** Used by mixer plugin enable functions 637 638 E.g. HPI_ParametricEq_SetState() 639 \ingroup mixer 640 */ 641 enum HPI_SWITCH_STATES { 642 HPI_SWITCH_OFF = 0, /**< turn the mixer plugin on. */ 643 HPI_SWITCH_ON = 1 /**< turn the mixer plugin off. */ 644 }; 645 646 /* Volume control special gain values */ 647 648 /** volumes units are 100ths of a dB 649 \ingroup volume 650 */ 651 #define HPI_UNITS_PER_dB 100 652 /** turns volume control OFF or MUTE 653 \ingroup volume 654 */ 655 #define HPI_GAIN_OFF (-100 * HPI_UNITS_PER_dB) 656 657 /** channel mask specifying all channels 658 \ingroup volume 659 */ 660 #define HPI_BITMASK_ALL_CHANNELS (0xFFFFFFFF) 661 662 /** value returned for no signal 663 \ingroup meter 664 */ 665 #define HPI_METER_MINIMUM (-150 * HPI_UNITS_PER_dB) 666 667 /** autofade profiles 668 \ingroup volume 669 */ 670 enum HPI_VOLUME_AUTOFADES { 671 /** log fade - dB attenuation changes linearly over time */ 672 HPI_VOLUME_AUTOFADE_LOG = 2, 673 /** linear fade - amplitude changes linearly */ 674 HPI_VOLUME_AUTOFADE_LINEAR = 3 675 }; 676 677 /** The physical encoding format of the AESEBU I/O. 678 679 Used in HPI_Aesebu_Transmitter_SetFormat(), HPI_Aesebu_Receiver_SetFormat() 680 along with related Get and Query functions 681 \ingroup aestx 682 */ 683 enum HPI_AESEBU_FORMATS { 684 /** AES/EBU physical format - AES/EBU balanced "professional" */ 685 HPI_AESEBU_FORMAT_AESEBU = 1, 686 /** AES/EBU physical format - S/PDIF unbalanced "consumer" */ 687 HPI_AESEBU_FORMAT_SPDIF = 2 688 }; 689 690 /** AES/EBU error status bits 691 692 Returned by HPI_Aesebu_Receiver_GetErrorStatus() 693 \ingroup aesrx 694 */ 695 enum HPI_AESEBU_ERRORS { 696 /** bit0: 1 when PLL is not locked */ 697 HPI_AESEBU_ERROR_NOT_LOCKED = 0x01, 698 /** bit1: 1 when signal quality is poor */ 699 HPI_AESEBU_ERROR_POOR_QUALITY = 0x02, 700 /** bit2: 1 when there is a parity error */ 701 HPI_AESEBU_ERROR_PARITY_ERROR = 0x04, 702 /** bit3: 1 when there is a bi-phase coding violation */ 703 HPI_AESEBU_ERROR_BIPHASE_VIOLATION = 0x08, 704 /** bit4: 1 when the validity bit is high */ 705 HPI_AESEBU_ERROR_VALIDITY = 0x10, 706 /** bit5: 1 when the CRC error bit is high */ 707 HPI_AESEBU_ERROR_CRC = 0x20 708 }; 709 710 /** \addtogroup pad 711 \{ 712 */ 713 /** The text string containing the station/channel combination. */ 714 #define HPI_PAD_CHANNEL_NAME_LEN 16 715 /** The text string containing the artist. */ 716 #define HPI_PAD_ARTIST_LEN 64 717 /** The text string containing the title. */ 718 #define HPI_PAD_TITLE_LEN 64 719 /** The text string containing the comment. */ 720 #define HPI_PAD_COMMENT_LEN 256 721 /** The PTY when the tuner has not received any PTY. */ 722 #define HPI_PAD_PROGRAM_TYPE_INVALID 0xffff 723 /** \} */ 724 725 /** Data types for PTY string translation. 726 \ingroup rds 727 */ 728 enum eHPI_RDS_type { 729 HPI_RDS_DATATYPE_RDS = 0, /**< RDS bitstream.*/ 730 HPI_RDS_DATATYPE_RBDS = 1 /**< RBDS bitstream.*/ 731 }; 732 733 /** Tuner bands 734 735 Used for HPI_Tuner_SetBand(),HPI_Tuner_GetBand() 736 \ingroup tuner 737 */ 738 enum HPI_TUNER_BAND { 739 HPI_TUNER_BAND_AM = 1, /**< AM band */ 740 HPI_TUNER_BAND_FM = 2, /**< FM band (mono) */ 741 HPI_TUNER_BAND_TV_NTSC_M = 3, /**< NTSC-M TV band*/ 742 HPI_TUNER_BAND_TV = 3, /* use TV_NTSC_M */ 743 HPI_TUNER_BAND_FM_STEREO = 4, /**< FM band (stereo) */ 744 HPI_TUNER_BAND_AUX = 5, /**< auxiliary input */ 745 HPI_TUNER_BAND_TV_PAL_BG = 6, /**< PAL-B/G TV band*/ 746 HPI_TUNER_BAND_TV_PAL_I = 7, /**< PAL-I TV band*/ 747 HPI_TUNER_BAND_TV_PAL_DK = 8, /**< PAL-D/K TV band*/ 748 HPI_TUNER_BAND_TV_SECAM_L = 9, /**< SECAM-L TV band*/ 749 HPI_TUNER_BAND_DAB = 10, 750 HPI_TUNER_BAND_LAST = 10 /**< the index of the last tuner band. */ 751 }; 752 753 /** Tuner mode attributes 754 755 Used by HPI_Tuner_SetMode(), HPI_Tuner_GetMode() 756 \ingroup tuner 757 758 */ 759 enum HPI_TUNER_MODES { 760 HPI_TUNER_MODE_RSS = 1, /**< control RSS */ 761 HPI_TUNER_MODE_RDS = 2 /**< control RBDS/RDS */ 762 }; 763 764 /** Tuner mode attribute values 765 766 Used by HPI_Tuner_SetMode(), HPI_Tuner_GetMode() 767 \ingroup tuner 768 */ 769 enum HPI_TUNER_MODE_VALUES { 770 /* RSS attribute values */ 771 HPI_TUNER_MODE_RSS_DISABLE = 0, /**< RSS disable */ 772 HPI_TUNER_MODE_RSS_ENABLE = 1, /**< RSS enable */ 773 774 /* RDS mode attributes */ 775 HPI_TUNER_MODE_RDS_DISABLE = 0, /**< RDS - disabled */ 776 HPI_TUNER_MODE_RDS_RDS = 1, /**< RDS - RDS mode */ 777 HPI_TUNER_MODE_RDS_RBDS = 2 /**< RDS - RBDS mode */ 778 }; 779 780 /** Tuner Status Bits 781 782 These bitfield values are returned by a call to HPI_Tuner_GetStatus(). 783 Multiple fields are returned from a single call. 784 \ingroup tuner 785 */ 786 enum HPI_TUNER_STATUS_BITS { 787 HPI_TUNER_VIDEO_COLOR_PRESENT = 0x0001, /**< video color is present. */ 788 HPI_TUNER_VIDEO_IS_60HZ = 0x0020, /**< 60 hz video detected. */ 789 HPI_TUNER_VIDEO_HORZ_SYNC_MISSING = 0x0040, /**< video HSYNC is missing. */ 790 HPI_TUNER_VIDEO_STATUS_VALID = 0x0100, /**< video status is valid. */ 791 HPI_TUNER_DIGITAL = 0x0200, /**< tuner reports digital programming. */ 792 HPI_TUNER_MULTIPROGRAM = 0x0400, /**< tuner reports multiple programs. */ 793 HPI_TUNER_PLL_LOCKED = 0x1000, /**< the tuner's PLL is locked. */ 794 HPI_TUNER_FM_STEREO = 0x2000 /**< tuner reports back FM stereo. */ 795 }; 796 797 /** Channel Modes 798 Used for HPI_ChannelModeSet/Get() 799 \ingroup channelmode 800 */ 801 enum HPI_CHANNEL_MODES { 802 /** Left channel out = left channel in, Right channel out = right channel in. */ 803 HPI_CHANNEL_MODE_NORMAL = 1, 804 /** Left channel out = right channel in, Right channel out = left channel in. */ 805 HPI_CHANNEL_MODE_SWAP = 2, 806 /** Left channel out = left channel in, Right channel out = left channel in. */ 807 HPI_CHANNEL_MODE_LEFT_TO_STEREO = 3, 808 /** Left channel out = right channel in, Right channel out = right channel in.*/ 809 HPI_CHANNEL_MODE_RIGHT_TO_STEREO = 4, 810 /** Left channel out = (left channel in + right channel in)/2, 811 Right channel out = mute. */ 812 HPI_CHANNEL_MODE_STEREO_TO_LEFT = 5, 813 /** Left channel out = mute, 814 Right channel out = (right channel in + left channel in)/2. */ 815 HPI_CHANNEL_MODE_STEREO_TO_RIGHT = 6, 816 HPI_CHANNEL_MODE_LAST = 6 817 }; 818 819 /** SampleClock source values 820 \ingroup sampleclock 821 */ 822 enum HPI_SAMPLECLOCK_SOURCES { 823 /** The sampleclock output is derived from its local samplerate generator. 824 The local samplerate may be set using HPI_SampleClock_SetLocalRate(). */ 825 HPI_SAMPLECLOCK_SOURCE_LOCAL = 1, 826 /** The adapter is clocked from a dedicated AES/EBU SampleClock input.*/ 827 HPI_SAMPLECLOCK_SOURCE_AESEBU_SYNC = 2, 828 /** From external wordclock connector */ 829 HPI_SAMPLECLOCK_SOURCE_WORD = 3, 830 /** Board-to-board header */ 831 HPI_SAMPLECLOCK_SOURCE_WORD_HEADER = 4, 832 /** FUTURE - SMPTE clock. */ 833 HPI_SAMPLECLOCK_SOURCE_SMPTE = 5, 834 /** One of the aesebu inputs */ 835 HPI_SAMPLECLOCK_SOURCE_AESEBU_INPUT = 6, 836 /** From a network interface e.g. Cobranet or Livewire at either 48 or 96kHz */ 837 HPI_SAMPLECLOCK_SOURCE_NETWORK = 8, 838 /** From previous adjacent module (ASI2416 only)*/ 839 HPI_SAMPLECLOCK_SOURCE_PREV_MODULE = 10, 840 /** Blu link sample clock*/ 841 HPI_SAMPLECLOCK_SOURCE_BLULINK = 11, 842 /*! Update this if you add a new clock source.*/ 843 HPI_SAMPLECLOCK_SOURCE_LAST = 11 844 }; 845 846 /** Equalizer filter types. Used by HPI_ParametricEq_SetBand() 847 \ingroup parmeq 848 */ 849 enum HPI_FILTER_TYPE { 850 HPI_FILTER_TYPE_BYPASS = 0, /**< filter is turned off */ 851 852 HPI_FILTER_TYPE_LOWSHELF = 1, /**< EQ low shelf */ 853 HPI_FILTER_TYPE_HIGHSHELF = 2, /**< EQ high shelf */ 854 HPI_FILTER_TYPE_EQ_BAND = 3, /**< EQ gain */ 855 856 HPI_FILTER_TYPE_LOWPASS = 4, /**< standard low pass */ 857 HPI_FILTER_TYPE_HIGHPASS = 5, /**< standard high pass */ 858 HPI_FILTER_TYPE_BANDPASS = 6, /**< standard band pass */ 859 HPI_FILTER_TYPE_BANDSTOP = 7 /**< standard band stop/notch */ 860 }; 861 862 /** Async Event sources 863 \ingroup async 864 */ 865 enum ASYNC_EVENT_SOURCES { 866 HPI_ASYNC_EVENT_GPIO = 1, /**< GPIO event. */ 867 HPI_ASYNC_EVENT_SILENCE = 2, /**< silence event detected. */ 868 HPI_ASYNC_EVENT_TONE = 3 /**< tone event detected. */ 869 }; 870 /*******************************************/ 871 /** HPI Error codes 872 873 Almost all HPI functions return an error code 874 A return value of zero means there was no error. 875 Otherwise one of these error codes is returned. 876 Error codes can be converted to a descriptive string using HPI_GetErrorText() 877 878 \note When a new error code is added HPI_GetErrorText() MUST be updated. 879 \note Codes 1-100 are reserved for driver use 880 \ingroup utility 881 */ 882 enum HPI_ERROR_CODES { 883 /** Message type does not exist. */ 884 HPI_ERROR_INVALID_TYPE = 100, 885 /** Object type does not exist. */ 886 HPI_ERROR_INVALID_OBJ = 101, 887 /** Function does not exist. */ 888 HPI_ERROR_INVALID_FUNC = 102, 889 /** The specified object does not exist. */ 890 HPI_ERROR_INVALID_OBJ_INDEX = 103, 891 /** Trying to access an object that has not been opened yet. */ 892 HPI_ERROR_OBJ_NOT_OPEN = 104, 893 /** Trying to open an already open object. */ 894 HPI_ERROR_OBJ_ALREADY_OPEN = 105, 895 /** PCI, ISA resource not valid. */ 896 HPI_ERROR_INVALID_RESOURCE = 106, 897 /* HPI_ERROR_SUBSYSFINDADAPTERS_GETINFO= 107 */ 898 /** Default response was never updated with actual error code. */ 899 HPI_ERROR_INVALID_RESPONSE = 108, 900 /** wSize field of response was not updated, 901 indicating that the message was not processed. */ 902 HPI_ERROR_PROCESSING_MESSAGE = 109, 903 /** The network did not respond in a timely manner. */ 904 HPI_ERROR_NETWORK_TIMEOUT = 110, 905 /* An HPI handle is invalid (uninitialised?). */ 906 HPI_ERROR_INVALID_HANDLE = 111, 907 /** A function or attribute has not been implemented yet. */ 908 HPI_ERROR_UNIMPLEMENTED = 112, 909 /** There are too many clients attempting 910 to access a network resource. */ 911 HPI_ERROR_NETWORK_TOO_MANY_CLIENTS = 113, 912 /** Response buffer passed to HPI_Message 913 was smaller than returned response. 914 wSpecificError field of hpi response contains the required size. 915 */ 916 HPI_ERROR_RESPONSE_BUFFER_TOO_SMALL = 114, 917 /** The returned response did not match the sent message */ 918 HPI_ERROR_RESPONSE_MISMATCH = 115, 919 /** A control setting that should have been cached was not. */ 920 HPI_ERROR_CONTROL_CACHING = 116, 921 /** A message buffer in the path to the adapter was smaller 922 than the message size. 923 wSpecificError field of hpi response contains the actual size. 924 */ 925 HPI_ERROR_MESSAGE_BUFFER_TOO_SMALL = 117, 926 927 /* HPI_ERROR_TOO_MANY_ADAPTERS= 200 */ 928 /** Bad adpater. */ 929 HPI_ERROR_BAD_ADAPTER = 201, 930 /** Adapter number out of range or not set properly. */ 931 HPI_ERROR_BAD_ADAPTER_NUMBER = 202, 932 /** 2 adapters with the same adapter number. */ 933 HPI_ERROR_DUPLICATE_ADAPTER_NUMBER = 203, 934 /** DSP code failed to bootload. Usually a DSP memory test failure. */ 935 HPI_ERROR_DSP_BOOTLOAD = 204, 936 /** Couldn't find or open the DSP code file. */ 937 HPI_ERROR_DSP_FILE_NOT_FOUND = 206, 938 /** Internal DSP hardware error. */ 939 HPI_ERROR_DSP_HARDWARE = 207, 940 /** Could not allocate memory */ 941 HPI_ERROR_MEMORY_ALLOC = 208, 942 /** Failed to correctly load/config PLD. (unused) */ 943 HPI_ERROR_PLD_LOAD = 209, 944 /** Unexpected end of file, block length too big etc. */ 945 HPI_ERROR_DSP_FILE_FORMAT = 210, 946 947 /** Found but could not open DSP code file. */ 948 HPI_ERROR_DSP_FILE_ACCESS_DENIED = 211, 949 /** First DSP code section header not found in DSP file. */ 950 HPI_ERROR_DSP_FILE_NO_HEADER = 212, 951 /* HPI_ERROR_DSP_FILE_READ_ERROR= 213, */ 952 /** DSP code for adapter family not found. */ 953 HPI_ERROR_DSP_SECTION_NOT_FOUND = 214, 954 /** Other OS specific error opening DSP file. */ 955 HPI_ERROR_DSP_FILE_OTHER_ERROR = 215, 956 /** Sharing violation opening DSP code file. */ 957 HPI_ERROR_DSP_FILE_SHARING_VIOLATION = 216, 958 /** DSP code section header had size == 0. */ 959 HPI_ERROR_DSP_FILE_NULL_HEADER = 217, 960 961 /* HPI_ERROR_FLASH = 220, */ 962 963 /** Flash has bad checksum */ 964 HPI_ERROR_BAD_CHECKSUM = 221, 965 HPI_ERROR_BAD_SEQUENCE = 222, 966 HPI_ERROR_FLASH_ERASE = 223, 967 HPI_ERROR_FLASH_PROGRAM = 224, 968 HPI_ERROR_FLASH_VERIFY = 225, 969 HPI_ERROR_FLASH_TYPE = 226, 970 HPI_ERROR_FLASH_START = 227, 971 HPI_ERROR_FLASH_READ = 228, 972 HPI_ERROR_FLASH_READ_NO_FILE = 229, 973 HPI_ERROR_FLASH_SIZE = 230, 974 975 /** Reserved for OEMs. */ 976 HPI_ERROR_RESERVED_1 = 290, 977 978 /* HPI_ERROR_INVALID_STREAM = 300 use HPI_ERROR_INVALID_OBJ_INDEX */ 979 /** Invalid compression format. */ 980 HPI_ERROR_INVALID_FORMAT = 301, 981 /** Invalid format samplerate */ 982 HPI_ERROR_INVALID_SAMPLERATE = 302, 983 /** Invalid format number of channels. */ 984 HPI_ERROR_INVALID_CHANNELS = 303, 985 /** Invalid format bitrate. */ 986 HPI_ERROR_INVALID_BITRATE = 304, 987 /** Invalid datasize used for stream read/write. */ 988 HPI_ERROR_INVALID_DATASIZE = 305, 989 /* HPI_ERROR_BUFFER_FULL = 306 use HPI_ERROR_INVALID_DATASIZE */ 990 /* HPI_ERROR_BUFFER_EMPTY = 307 use HPI_ERROR_INVALID_DATASIZE */ 991 /** Null data pointer used for stream read/write. */ 992 HPI_ERROR_INVALID_DATA_POINTER = 308, 993 /** Packet ordering error for stream read/write. */ 994 HPI_ERROR_INVALID_PACKET_ORDER = 309, 995 996 /** Object can't do requested operation in its current 997 state, eg set format, change rec mux state while recording.*/ 998 HPI_ERROR_INVALID_OPERATION = 310, 999 1000 /** Where a SRG is shared amongst streams, an incompatible samplerate 1001 is one that is different to any currently active stream. */ 1002 HPI_ERROR_INCOMPATIBLE_SAMPLERATE = 311, 1003 /** Adapter mode is illegal.*/ 1004 HPI_ERROR_BAD_ADAPTER_MODE = 312, 1005 1006 /** There have been too many attempts to set the adapter's 1007 capabilities (using bad keys), the card should be returned 1008 to ASI if further capabilities updates are required */ 1009 HPI_ERROR_TOO_MANY_CAPABILITY_CHANGE_ATTEMPTS = 313, 1010 /** Streams on different adapters cannot be grouped. */ 1011 HPI_ERROR_NO_INTERADAPTER_GROUPS = 314, 1012 /** Streams on different DSPs cannot be grouped. */ 1013 HPI_ERROR_NO_INTERDSP_GROUPS = 315, 1014 /** Stream wait cancelled before threshold reached. */ 1015 HPI_ERROR_WAIT_CANCELLED = 316, 1016 /** A character string is invalid. */ 1017 HPI_ERROR_INVALID_STRING = 317, 1018 1019 /** Invalid mixer node for this adapter. */ 1020 HPI_ERROR_INVALID_NODE = 400, 1021 /** Invalid control. */ 1022 HPI_ERROR_INVALID_CONTROL = 401, 1023 /** Invalid control value was passed. */ 1024 HPI_ERROR_INVALID_CONTROL_VALUE = 402, 1025 /** Control attribute not supported by this control. */ 1026 HPI_ERROR_INVALID_CONTROL_ATTRIBUTE = 403, 1027 /** Control is disabled. */ 1028 HPI_ERROR_CONTROL_DISABLED = 404, 1029 /** I2C transaction failed due to a missing ACK. */ 1030 HPI_ERROR_CONTROL_I2C_MISSING_ACK = 405, 1031 HPI_ERROR_I2C_MISSING_ACK = 405, 1032 /** Control is busy, or coming out of 1033 reset and cannot be accessed at this time. */ 1034 HPI_ERROR_CONTROL_NOT_READY = 407, 1035 1036 /** Non volatile memory */ 1037 HPI_ERROR_NVMEM_BUSY = 450, 1038 HPI_ERROR_NVMEM_FULL = 451, 1039 HPI_ERROR_NVMEM_FAIL = 452, 1040 1041 /** I2C */ 1042 HPI_ERROR_I2C_BAD_ADR = 460, 1043 1044 /** Entity type did not match requested type */ 1045 HPI_ERROR_ENTITY_TYPE_MISMATCH = 470, 1046 /** Entity item count did not match requested count */ 1047 HPI_ERROR_ENTITY_ITEM_COUNT = 471, 1048 /** Entity type is not one of the valid types */ 1049 HPI_ERROR_ENTITY_TYPE_INVALID = 472, 1050 /** Entity role is not one of the valid roles */ 1051 HPI_ERROR_ENTITY_ROLE_INVALID = 473, 1052 /** Entity size doesn't match target size */ 1053 HPI_ERROR_ENTITY_SIZE_MISMATCH = 474, 1054 1055 /* AES18 specific errors were 500..507 */ 1056 1057 /** custom error to use for debugging */ 1058 HPI_ERROR_CUSTOM = 600, 1059 1060 /** hpioct32.c can't obtain mutex */ 1061 HPI_ERROR_MUTEX_TIMEOUT = 700, 1062 1063 /** Backend errors used to be greater than this. 1064 \deprecated Now, all backends return only errors defined here in hpi.h 1065 */ 1066 HPI_ERROR_BACKEND_BASE = 900, 1067 1068 /** Communication with DSP failed */ 1069 HPI_ERROR_DSP_COMMUNICATION = 900 1070 /* Note that the dsp communication error is set to this value so that 1071 it remains compatible with any software that expects such errors 1072 to be backend errors i.e. >= 900. 1073 Do not define any new error codes with values > 900. 1074 */ 1075 }; 1076 1077 /** \defgroup maximums HPI maximum values 1078 \{ 1079 */ 1080 /** Maximum number of PCI HPI adapters */ 1081 #define HPI_MAX_ADAPTERS 20 1082 /** Maximum number of in or out streams per adapter */ 1083 #define HPI_MAX_STREAMS 16 1084 #define HPI_MAX_CHANNELS 2 /* per stream */ 1085 #define HPI_MAX_NODES 8 /* per mixer ? */ 1086 #define HPI_MAX_CONTROLS 4 /* per node ? */ 1087 /** maximum number of ancillary bytes per MPEG frame */ 1088 #define HPI_MAX_ANC_BYTES_PER_FRAME (64) 1089 #define HPI_STRING_LEN 16 1090 1091 /** Networked adapters have index >= 100 */ 1092 #define HPI_MIN_NETWORK_ADAPTER_IDX 100 1093 1094 /** Velocity units */ 1095 #define HPI_OSTREAM_VELOCITY_UNITS 4096 1096 /** OutStream timescale units */ 1097 #define HPI_OSTREAM_TIMESCALE_UNITS 10000 1098 /** OutStream timescale passthrough - turns timescaling on in passthough mode */ 1099 #define HPI_OSTREAM_TIMESCALE_PASSTHROUGH 99999 1100 1101 /**\}*/ 1102 1103 /**************/ 1104 /* STRUCTURES */ 1105 #ifndef DISABLE_PRAGMA_PACK1 1106 #pragma pack(push, 1) 1107 #endif 1108 1109 /** Structure containing sample format information. 1110 See also HPI_FormatCreate(). 1111 */ 1112 struct hpi_format { 1113 u32 sample_rate; 1114 /**< 11025, 32000, 44100 ... */ 1115 u32 bit_rate; /**< for MPEG */ 1116 u32 attributes; 1117 /**< Stereo/JointStereo/Mono */ 1118 u16 mode_legacy; 1119 /**< Legacy ancillary mode or idle bit */ 1120 u16 unused; /**< Unused */ 1121 u16 channels; /**< 1,2..., (or ancillary mode or idle bit */ 1122 u16 format; /**< HPI_FORMAT_PCM16, _MPEG etc. see #HPI_FORMATS. */ 1123 }; 1124 1125 struct hpi_anc_frame { 1126 u32 valid_bits_in_this_frame; 1127 u8 b_data[HPI_MAX_ANC_BYTES_PER_FRAME]; 1128 }; 1129 1130 /** An object for containing a single async event. 1131 */ 1132 struct hpi_async_event { 1133 u16 event_type; /**< type of event. \sa async_event */ 1134 u16 sequence; /**< Sequence number, allows lost event detection */ 1135 u32 state; /**< New state */ 1136 u32 h_object; /**< handle to the object returning the event. */ 1137 union { 1138 struct { 1139 u16 index; /**< GPIO bit index. */ 1140 } gpio; 1141 struct { 1142 u16 node_index; /**< what node is the control on ? */ 1143 u16 node_type; /**< what type of node is the control on ? */ 1144 } control; 1145 } u; 1146 }; 1147 1148 #ifndef DISABLE_PRAGMA_PACK1 1149 #pragma pack(pop) 1150 #endif 1151 1152 /*****************/ 1153 /* HPI FUNCTIONS */ 1154 /*****************/ 1155 1156 /* Stream */ 1157 u16 hpi_stream_estimate_buffer_size(struct hpi_format *pF, 1158 u32 host_polling_rate_in_milli_seconds, u32 *recommended_buffer_size); 1159 1160 /*************/ 1161 /* SubSystem */ 1162 /*************/ 1163 1164 u16 hpi_subsys_get_version_ex(u32 *pversion_ex); 1165 1166 u16 hpi_subsys_get_num_adapters(int *pn_num_adapters); 1167 1168 u16 hpi_subsys_get_adapter(int iterator, u32 *padapter_index, 1169 u16 *pw_adapter_type); 1170 1171 /***********/ 1172 /* Adapter */ 1173 /***********/ 1174 1175 u16 hpi_adapter_open(u16 adapter_index); 1176 1177 u16 hpi_adapter_close(u16 adapter_index); 1178 1179 u16 hpi_adapter_get_info(u16 adapter_index, u16 *pw_num_outstreams, 1180 u16 *pw_num_instreams, u16 *pw_version, u32 *pserial_number, 1181 u16 *pw_adapter_type); 1182 1183 u16 hpi_adapter_get_module_by_index(u16 adapter_index, u16 module_index, 1184 u16 *pw_num_outputs, u16 *pw_num_inputs, u16 *pw_version, 1185 u32 *pserial_number, u16 *pw_module_type, u32 *ph_module); 1186 1187 u16 hpi_adapter_set_mode(u16 adapter_index, u32 adapter_mode); 1188 1189 u16 hpi_adapter_set_mode_ex(u16 adapter_index, u32 adapter_mode, 1190 u16 query_or_set); 1191 1192 u16 hpi_adapter_get_mode(u16 adapter_index, u32 *padapter_mode); 1193 1194 u16 hpi_adapter_set_property(u16 adapter_index, u16 property, u16 paramter1, 1195 u16 paramter2); 1196 1197 u16 hpi_adapter_get_property(u16 adapter_index, u16 property, 1198 u16 *pw_paramter1, u16 *pw_paramter2); 1199 1200 u16 hpi_adapter_enumerate_property(u16 adapter_index, u16 index, 1201 u16 what_to_enumerate, u16 property_index, u32 *psetting); 1202 /*************/ 1203 /* OutStream */ 1204 /*************/ 1205 u16 hpi_outstream_open(u16 adapter_index, u16 outstream_index, 1206 u32 *ph_outstream); 1207 1208 u16 hpi_outstream_close(u32 h_outstream); 1209 1210 u16 hpi_outstream_get_info_ex(u32 h_outstream, u16 *pw_state, 1211 u32 *pbuffer_size, u32 *pdata_to_play, u32 *psamples_played, 1212 u32 *pauxiliary_data_to_play); 1213 1214 u16 hpi_outstream_write_buf(u32 h_outstream, const u8 *pb_write_buf, 1215 u32 bytes_to_write, const struct hpi_format *p_format); 1216 1217 u16 hpi_outstream_start(u32 h_outstream); 1218 1219 u16 hpi_outstream_wait_start(u32 h_outstream); 1220 1221 u16 hpi_outstream_stop(u32 h_outstream); 1222 1223 u16 hpi_outstream_sinegen(u32 h_outstream); 1224 1225 u16 hpi_outstream_reset(u32 h_outstream); 1226 1227 u16 hpi_outstream_query_format(u32 h_outstream, struct hpi_format *p_format); 1228 1229 u16 hpi_outstream_set_format(u32 h_outstream, struct hpi_format *p_format); 1230 1231 u16 hpi_outstream_set_punch_in_out(u32 h_outstream, u32 punch_in_sample, 1232 u32 punch_out_sample); 1233 1234 u16 hpi_outstream_set_velocity(u32 h_outstream, short velocity); 1235 1236 u16 hpi_outstream_ancillary_reset(u32 h_outstream, u16 mode); 1237 1238 u16 hpi_outstream_ancillary_get_info(u32 h_outstream, u32 *pframes_available); 1239 1240 u16 hpi_outstream_ancillary_read(u32 h_outstream, 1241 struct hpi_anc_frame *p_anc_frame_buffer, 1242 u32 anc_frame_buffer_size_in_bytes, 1243 u32 number_of_ancillary_frames_to_read); 1244 1245 u16 hpi_outstream_set_time_scale(u32 h_outstream, u32 time_scaleX10000); 1246 1247 u16 hpi_outstream_host_buffer_allocate(u32 h_outstream, u32 size_in_bytes); 1248 1249 u16 hpi_outstream_host_buffer_free(u32 h_outstream); 1250 1251 u16 hpi_outstream_group_add(u32 h_outstream, u32 h_stream); 1252 1253 u16 hpi_outstream_group_get_map(u32 h_outstream, u32 *poutstream_map, 1254 u32 *pinstream_map); 1255 1256 u16 hpi_outstream_group_reset(u32 h_outstream); 1257 1258 /************/ 1259 /* InStream */ 1260 /************/ 1261 u16 hpi_instream_open(u16 adapter_index, u16 instream_index, 1262 u32 *ph_instream); 1263 1264 u16 hpi_instream_close(u32 h_instream); 1265 1266 u16 hpi_instream_query_format(u32 h_instream, 1267 const struct hpi_format *p_format); 1268 1269 u16 hpi_instream_set_format(u32 h_instream, 1270 const struct hpi_format *p_format); 1271 1272 u16 hpi_instream_read_buf(u32 h_instream, u8 *pb_read_buf, u32 bytes_to_read); 1273 1274 u16 hpi_instream_start(u32 h_instream); 1275 1276 u16 hpi_instream_wait_start(u32 h_instream); 1277 1278 u16 hpi_instream_stop(u32 h_instream); 1279 1280 u16 hpi_instream_reset(u32 h_instream); 1281 1282 u16 hpi_instream_get_info_ex(u32 h_instream, u16 *pw_state, u32 *pbuffer_size, 1283 u32 *pdata_recorded, u32 *psamples_recorded, 1284 u32 *pauxiliary_data_recorded); 1285 1286 u16 hpi_instream_ancillary_reset(u32 h_instream, u16 bytes_per_frame, 1287 u16 mode, u16 alignment, u16 idle_bit); 1288 1289 u16 hpi_instream_ancillary_get_info(u32 h_instream, u32 *pframe_space); 1290 1291 u16 hpi_instream_ancillary_write(u32 h_instream, 1292 const struct hpi_anc_frame *p_anc_frame_buffer, 1293 u32 anc_frame_buffer_size_in_bytes, 1294 u32 number_of_ancillary_frames_to_write); 1295 1296 u16 hpi_instream_host_buffer_allocate(u32 h_instream, u32 size_in_bytes); 1297 1298 u16 hpi_instream_host_buffer_free(u32 h_instream); 1299 1300 u16 hpi_instream_group_add(u32 h_instream, u32 h_stream); 1301 1302 u16 hpi_instream_group_get_map(u32 h_instream, u32 *poutstream_map, 1303 u32 *pinstream_map); 1304 1305 u16 hpi_instream_group_reset(u32 h_instream); 1306 1307 /*********/ 1308 /* Mixer */ 1309 /*********/ 1310 u16 hpi_mixer_open(u16 adapter_index, u32 *ph_mixer); 1311 1312 u16 hpi_mixer_close(u32 h_mixer); 1313 1314 u16 hpi_mixer_get_control(u32 h_mixer, u16 src_node_type, 1315 u16 src_node_type_index, u16 dst_node_type, u16 dst_node_type_index, 1316 u16 control_type, u32 *ph_control); 1317 1318 u16 hpi_mixer_get_control_by_index(u32 h_mixer, u16 control_index, 1319 u16 *pw_src_node_type, u16 *pw_src_node_index, u16 *pw_dst_node_type, 1320 u16 *pw_dst_node_index, u16 *pw_control_type, u32 *ph_control); 1321 1322 u16 hpi_mixer_store(u32 h_mixer, enum HPI_MIXER_STORE_COMMAND command, 1323 u16 index); 1324 /************/ 1325 /* Controls */ 1326 /************/ 1327 /******************/ 1328 /* Volume control */ 1329 /******************/ 1330 u16 hpi_volume_set_gain(u32 h_control, short an_gain0_01dB[HPI_MAX_CHANNELS] 1331 ); 1332 1333 u16 hpi_volume_get_gain(u32 h_control, 1334 short an_gain0_01dB_out[HPI_MAX_CHANNELS] 1335 ); 1336 1337 u16 hpi_volume_set_mute(u32 h_control, u32 mute); 1338 1339 u16 hpi_volume_get_mute(u32 h_control, u32 *mute); 1340 1341 #define hpi_volume_get_range hpi_volume_query_range 1342 u16 hpi_volume_query_range(u32 h_control, short *min_gain_01dB, 1343 short *max_gain_01dB, short *step_gain_01dB); 1344 1345 u16 hpi_volume_query_channels(const u32 h_control, u32 *p_channels); 1346 1347 u16 hpi_volume_auto_fade(u32 h_control, 1348 short an_stop_gain0_01dB[HPI_MAX_CHANNELS], u32 duration_ms); 1349 1350 u16 hpi_volume_auto_fade_profile(u32 h_control, 1351 short an_stop_gain0_01dB[HPI_MAX_CHANNELS], u32 duration_ms, 1352 u16 profile); 1353 1354 u16 hpi_volume_query_auto_fade_profile(const u32 h_control, const u32 i, 1355 u16 *profile); 1356 1357 /*****************/ 1358 /* Level control */ 1359 /*****************/ 1360 u16 hpi_level_query_range(u32 h_control, short *min_gain_01dB, 1361 short *max_gain_01dB, short *step_gain_01dB); 1362 1363 u16 hpi_level_set_gain(u32 h_control, short an_gain0_01dB[HPI_MAX_CHANNELS] 1364 ); 1365 1366 u16 hpi_level_get_gain(u32 h_control, 1367 short an_gain0_01dB_out[HPI_MAX_CHANNELS] 1368 ); 1369 1370 /*****************/ 1371 /* Meter control */ 1372 /*****************/ 1373 u16 hpi_meter_query_channels(const u32 h_meter, u32 *p_channels); 1374 1375 u16 hpi_meter_get_peak(u32 h_control, 1376 short an_peak0_01dB_out[HPI_MAX_CHANNELS] 1377 ); 1378 1379 u16 hpi_meter_get_rms(u32 h_control, short an_peak0_01dB_out[HPI_MAX_CHANNELS] 1380 ); 1381 1382 u16 hpi_meter_set_peak_ballistics(u32 h_control, u16 attack, u16 decay); 1383 1384 u16 hpi_meter_set_rms_ballistics(u32 h_control, u16 attack, u16 decay); 1385 1386 u16 hpi_meter_get_peak_ballistics(u32 h_control, u16 *attack, u16 *decay); 1387 1388 u16 hpi_meter_get_rms_ballistics(u32 h_control, u16 *attack, u16 *decay); 1389 1390 /************************/ 1391 /* ChannelMode control */ 1392 /************************/ 1393 u16 hpi_channel_mode_query_mode(const u32 h_mode, const u32 index, 1394 u16 *pw_mode); 1395 1396 u16 hpi_channel_mode_set(u32 h_control, u16 mode); 1397 1398 u16 hpi_channel_mode_get(u32 h_control, u16 *mode); 1399 1400 /*****************/ 1401 /* Tuner control */ 1402 /*****************/ 1403 u16 hpi_tuner_query_band(const u32 h_tuner, const u32 index, u16 *pw_band); 1404 1405 u16 hpi_tuner_set_band(u32 h_control, u16 band); 1406 1407 u16 hpi_tuner_get_band(u32 h_control, u16 *pw_band); 1408 1409 u16 hpi_tuner_query_frequency(const u32 h_tuner, const u32 index, 1410 const u16 band, u32 *pfreq); 1411 1412 u16 hpi_tuner_set_frequency(u32 h_control, u32 freq_ink_hz); 1413 1414 u16 hpi_tuner_get_frequency(u32 h_control, u32 *pw_freq_ink_hz); 1415 1416 u16 hpi_tuner_get_rf_level(u32 h_control, short *pw_level); 1417 1418 u16 hpi_tuner_get_raw_rf_level(u32 h_control, short *pw_level); 1419 1420 u16 hpi_tuner_query_gain(const u32 h_tuner, const u32 index, u16 *pw_gain); 1421 1422 u16 hpi_tuner_set_gain(u32 h_control, short gain); 1423 1424 u16 hpi_tuner_get_gain(u32 h_control, short *pn_gain); 1425 1426 u16 hpi_tuner_get_status(u32 h_control, u16 *pw_status_mask, u16 *pw_status); 1427 1428 u16 hpi_tuner_set_mode(u32 h_control, u32 mode, u32 value); 1429 1430 u16 hpi_tuner_get_mode(u32 h_control, u32 mode, u32 *pn_value); 1431 1432 u16 hpi_tuner_get_rds(u32 h_control, char *p_rds_data); 1433 1434 u16 hpi_tuner_query_deemphasis(const u32 h_tuner, const u32 index, 1435 const u16 band, u32 *pdeemphasis); 1436 1437 u16 hpi_tuner_set_deemphasis(u32 h_control, u32 deemphasis); 1438 u16 hpi_tuner_get_deemphasis(u32 h_control, u32 *pdeemphasis); 1439 1440 u16 hpi_tuner_query_program(const u32 h_tuner, u32 *pbitmap_program); 1441 1442 u16 hpi_tuner_set_program(u32 h_control, u32 program); 1443 1444 u16 hpi_tuner_get_program(u32 h_control, u32 *pprogram); 1445 1446 u16 hpi_tuner_get_hd_radio_dsp_version(u32 h_control, char *psz_dsp_version, 1447 const u32 string_size); 1448 1449 u16 hpi_tuner_get_hd_radio_sdk_version(u32 h_control, char *psz_sdk_version, 1450 const u32 string_size); 1451 1452 u16 hpi_tuner_get_hd_radio_signal_quality(u32 h_control, u32 *pquality); 1453 1454 u16 hpi_tuner_get_hd_radio_signal_blend(u32 h_control, u32 *pblend); 1455 1456 u16 hpi_tuner_set_hd_radio_signal_blend(u32 h_control, const u32 blend); 1457 1458 /***************/ 1459 /* PAD control */ 1460 /***************/ 1461 1462 u16 hpi_pad_get_channel_name(u32 h_control, char *psz_string, 1463 const u32 string_length); 1464 1465 u16 hpi_pad_get_artist(u32 h_control, char *psz_string, 1466 const u32 string_length); 1467 1468 u16 hpi_pad_get_title(u32 h_control, char *psz_string, 1469 const u32 string_length); 1470 1471 u16 hpi_pad_get_comment(u32 h_control, char *psz_string, 1472 const u32 string_length); 1473 1474 u16 hpi_pad_get_program_type(u32 h_control, u32 *ppTY); 1475 1476 u16 hpi_pad_get_rdsPI(u32 h_control, u32 *ppI); 1477 1478 /****************************/ 1479 /* AES/EBU Receiver control */ 1480 /****************************/ 1481 u16 hpi_aesebu_receiver_query_format(const u32 h_aes_rx, const u32 index, 1482 u16 *pw_format); 1483 1484 u16 hpi_aesebu_receiver_set_format(u32 h_control, u16 source); 1485 1486 u16 hpi_aesebu_receiver_get_format(u32 h_control, u16 *pw_source); 1487 1488 u16 hpi_aesebu_receiver_get_sample_rate(u32 h_control, u32 *psample_rate); 1489 1490 u16 hpi_aesebu_receiver_get_user_data(u32 h_control, u16 index, u16 *pw_data); 1491 1492 u16 hpi_aesebu_receiver_get_channel_status(u32 h_control, u16 index, 1493 u16 *pw_data); 1494 1495 u16 hpi_aesebu_receiver_get_error_status(u32 h_control, u16 *pw_error_data); 1496 1497 /*******************************/ 1498 /* AES/EBU Transmitter control */ 1499 /*******************************/ 1500 u16 hpi_aesebu_transmitter_set_sample_rate(u32 h_control, u32 sample_rate); 1501 1502 u16 hpi_aesebu_transmitter_set_user_data(u32 h_control, u16 index, u16 data); 1503 1504 u16 hpi_aesebu_transmitter_set_channel_status(u32 h_control, u16 index, 1505 u16 data); 1506 1507 u16 hpi_aesebu_transmitter_get_channel_status(u32 h_control, u16 index, 1508 u16 *pw_data); 1509 1510 u16 hpi_aesebu_transmitter_query_format(const u32 h_aes_tx, const u32 index, 1511 u16 *pw_format); 1512 1513 u16 hpi_aesebu_transmitter_set_format(u32 h_control, u16 output_format); 1514 1515 u16 hpi_aesebu_transmitter_get_format(u32 h_control, u16 *pw_output_format); 1516 1517 /***********************/ 1518 /* Multiplexer control */ 1519 /***********************/ 1520 u16 hpi_multiplexer_set_source(u32 h_control, u16 source_node_type, 1521 u16 source_node_index); 1522 1523 u16 hpi_multiplexer_get_source(u32 h_control, u16 *source_node_type, 1524 u16 *source_node_index); 1525 1526 u16 hpi_multiplexer_query_source(u32 h_control, u16 index, 1527 u16 *source_node_type, u16 *source_node_index); 1528 1529 /***************/ 1530 /* Vox control */ 1531 /***************/ 1532 u16 hpi_vox_set_threshold(u32 h_control, short an_gain0_01dB); 1533 1534 u16 hpi_vox_get_threshold(u32 h_control, short *an_gain0_01dB); 1535 1536 /*********************/ 1537 /* Bitstream control */ 1538 /*********************/ 1539 u16 hpi_bitstream_set_clock_edge(u32 h_control, u16 edge_type); 1540 1541 u16 hpi_bitstream_set_data_polarity(u32 h_control, u16 polarity); 1542 1543 u16 hpi_bitstream_get_activity(u32 h_control, u16 *pw_clk_activity, 1544 u16 *pw_data_activity); 1545 1546 /***********************/ 1547 /* SampleClock control */ 1548 /***********************/ 1549 1550 u16 hpi_sample_clock_query_source(const u32 h_clock, const u32 index, 1551 u16 *pw_source); 1552 1553 u16 hpi_sample_clock_set_source(u32 h_control, u16 source); 1554 1555 u16 hpi_sample_clock_get_source(u32 h_control, u16 *pw_source); 1556 1557 u16 hpi_sample_clock_query_source_index(const u32 h_clock, const u32 index, 1558 const u32 source, u16 *pw_source_index); 1559 1560 u16 hpi_sample_clock_set_source_index(u32 h_control, u16 source_index); 1561 1562 u16 hpi_sample_clock_get_source_index(u32 h_control, u16 *pw_source_index); 1563 1564 u16 hpi_sample_clock_get_sample_rate(u32 h_control, u32 *psample_rate); 1565 1566 u16 hpi_sample_clock_query_local_rate(const u32 h_clock, const u32 index, 1567 u32 *psource); 1568 1569 u16 hpi_sample_clock_set_local_rate(u32 h_control, u32 sample_rate); 1570 1571 u16 hpi_sample_clock_get_local_rate(u32 h_control, u32 *psample_rate); 1572 1573 u16 hpi_sample_clock_set_auto(u32 h_control, u32 enable); 1574 1575 u16 hpi_sample_clock_get_auto(u32 h_control, u32 *penable); 1576 1577 u16 hpi_sample_clock_set_local_rate_lock(u32 h_control, u32 lock); 1578 1579 u16 hpi_sample_clock_get_local_rate_lock(u32 h_control, u32 *plock); 1580 1581 /***********************/ 1582 /* Microphone control */ 1583 /***********************/ 1584 u16 hpi_microphone_set_phantom_power(u32 h_control, u16 on_off); 1585 1586 u16 hpi_microphone_get_phantom_power(u32 h_control, u16 *pw_on_off); 1587 1588 /********************************/ 1589 /* Parametric Equalizer control */ 1590 /********************************/ 1591 u16 hpi_parametric_eq_get_info(u32 h_control, u16 *pw_number_of_bands, 1592 u16 *pw_enabled); 1593 1594 u16 hpi_parametric_eq_set_state(u32 h_control, u16 on_off); 1595 1596 u16 hpi_parametric_eq_set_band(u32 h_control, u16 index, u16 type, 1597 u32 frequency_hz, short q100, short gain0_01dB); 1598 1599 u16 hpi_parametric_eq_get_band(u32 h_control, u16 index, u16 *pn_type, 1600 u32 *pfrequency_hz, short *pnQ100, short *pn_gain0_01dB); 1601 1602 u16 hpi_parametric_eq_get_coeffs(u32 h_control, u16 index, short coeffs[5] 1603 ); 1604 1605 /*******************************/ 1606 /* Compressor Expander control */ 1607 /*******************************/ 1608 1609 u16 hpi_compander_set_enable(u32 h_control, u32 on); 1610 1611 u16 hpi_compander_get_enable(u32 h_control, u32 *pon); 1612 1613 u16 hpi_compander_set_makeup_gain(u32 h_control, short makeup_gain0_01dB); 1614 1615 u16 hpi_compander_get_makeup_gain(u32 h_control, short *pn_makeup_gain0_01dB); 1616 1617 u16 hpi_compander_set_attack_time_constant(u32 h_control, u32 index, 1618 u32 attack); 1619 1620 u16 hpi_compander_get_attack_time_constant(u32 h_control, u32 index, 1621 u32 *pw_attack); 1622 1623 u16 hpi_compander_set_decay_time_constant(u32 h_control, u32 index, 1624 u32 decay); 1625 1626 u16 hpi_compander_get_decay_time_constant(u32 h_control, u32 index, 1627 u32 *pw_decay); 1628 1629 u16 hpi_compander_set_threshold(u32 h_control, u32 index, 1630 short threshold0_01dB); 1631 1632 u16 hpi_compander_get_threshold(u32 h_control, u32 index, 1633 short *pn_threshold0_01dB); 1634 1635 u16 hpi_compander_set_ratio(u32 h_control, u32 index, u32 ratio100); 1636 1637 u16 hpi_compander_get_ratio(u32 h_control, u32 index, u32 *pw_ratio100); 1638 1639 /********************/ 1640 /* Cobranet control */ 1641 /********************/ 1642 u16 hpi_cobranet_hmi_write(u32 h_control, u32 hmi_address, u32 byte_count, 1643 u8 *pb_data); 1644 1645 u16 hpi_cobranet_hmi_read(u32 h_control, u32 hmi_address, u32 max_byte_count, 1646 u32 *pbyte_count, u8 *pb_data); 1647 1648 u16 hpi_cobranet_hmi_get_status(u32 h_control, u32 *pstatus, 1649 u32 *preadable_size, u32 *pwriteable_size); 1650 1651 u16 hpi_cobranet_get_ip_address(u32 h_control, u32 *pdw_ip_address); 1652 1653 u16 hpi_cobranet_set_ip_address(u32 h_control, u32 dw_ip_address); 1654 1655 u16 hpi_cobranet_get_static_ip_address(u32 h_control, u32 *pdw_ip_address); 1656 1657 u16 hpi_cobranet_set_static_ip_address(u32 h_control, u32 dw_ip_address); 1658 1659 u16 hpi_cobranet_get_macaddress(u32 h_control, u32 *p_mac_msbs, 1660 u32 *p_mac_lsbs); 1661 1662 /*************************/ 1663 /* Tone Detector control */ 1664 /*************************/ 1665 u16 hpi_tone_detector_get_state(u32 hC, u32 *state); 1666 1667 u16 hpi_tone_detector_set_enable(u32 hC, u32 enable); 1668 1669 u16 hpi_tone_detector_get_enable(u32 hC, u32 *enable); 1670 1671 u16 hpi_tone_detector_set_event_enable(u32 hC, u32 event_enable); 1672 1673 u16 hpi_tone_detector_get_event_enable(u32 hC, u32 *event_enable); 1674 1675 u16 hpi_tone_detector_set_threshold(u32 hC, int threshold); 1676 1677 u16 hpi_tone_detector_get_threshold(u32 hC, int *threshold); 1678 1679 u16 hpi_tone_detector_get_frequency(u32 hC, u32 index, u32 *frequency); 1680 1681 /****************************/ 1682 /* Silence Detector control */ 1683 /****************************/ 1684 u16 hpi_silence_detector_get_state(u32 hC, u32 *state); 1685 1686 u16 hpi_silence_detector_set_enable(u32 hC, u32 enable); 1687 1688 u16 hpi_silence_detector_get_enable(u32 hC, u32 *enable); 1689 1690 u16 hpi_silence_detector_set_event_enable(u32 hC, u32 event_enable); 1691 1692 u16 hpi_silence_detector_get_event_enable(u32 hC, u32 *event_enable); 1693 1694 u16 hpi_silence_detector_set_delay(u32 hC, u32 delay); 1695 1696 u16 hpi_silence_detector_get_delay(u32 hC, u32 *delay); 1697 1698 u16 hpi_silence_detector_set_threshold(u32 hC, int threshold); 1699 1700 u16 hpi_silence_detector_get_threshold(u32 hC, int *threshold); 1701 /*********************/ 1702 /* Utility functions */ 1703 /*********************/ 1704 1705 u16 hpi_format_create(struct hpi_format *p_format, u16 channels, u16 format, 1706 u32 sample_rate, u32 bit_rate, u32 attributes); 1707 1708 #endif /*_HPI_H_ */ 1709
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