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author | Xin Li <delphij@google.com> | 2018-08-07 16:51:25 +0000 |
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committer | Gerrit Code Review <noreply-gerritcodereview@google.com> | 2018-08-07 16:51:25 +0000 |
commit | 7027cd87488c2a60becbae7a139d18dbc0370459 (patch) | |
tree | 41c65cebd836ff3f949f1134512985e4a1288593 /libPCMutils/src/pcmutils_lib.cpp | |
parent | a3e0aa5f25908d92535e045bbde73c9a3d19adc7 (diff) | |
parent | 0757f38b01d703b355eb5e5acc1f344a949e74e1 (diff) | |
download | fdk-aac-7027cd87488c2a60becbae7a139d18dbc0370459.tar.gz fdk-aac-7027cd87488c2a60becbae7a139d18dbc0370459.tar.bz2 fdk-aac-7027cd87488c2a60becbae7a139d18dbc0370459.zip |
Merge "Merge Android Pie into master"
Diffstat (limited to 'libPCMutils/src/pcmutils_lib.cpp')
-rw-r--r-- | libPCMutils/src/pcmutils_lib.cpp | 2510 |
1 files changed, 0 insertions, 2510 deletions
diff --git a/libPCMutils/src/pcmutils_lib.cpp b/libPCMutils/src/pcmutils_lib.cpp deleted file mode 100644 index 9303d16..0000000 --- a/libPCMutils/src/pcmutils_lib.cpp +++ /dev/null @@ -1,2510 +0,0 @@ - -/* ----------------------------------------------------------------------------------------------------------- -Software License for The Fraunhofer FDK AAC Codec Library for Android - -© Copyright 1995 - 2013 Fraunhofer-Gesellschaft zur Förderung der angewandten Forschung e.V. - All rights reserved. - - 1. INTRODUCTION -The Fraunhofer FDK AAC Codec Library for Android ("FDK AAC Codec") is software that implements -the MPEG Advanced Audio Coding ("AAC") encoding and decoding scheme for digital audio. -This FDK AAC Codec software is intended to be used on a wide variety of Android devices. - -AAC's HE-AAC and HE-AAC v2 versions are regarded as today's most efficient general perceptual -audio codecs. AAC-ELD is considered the best-performing full-bandwidth communications codec by -independent studies and is widely deployed. AAC has been standardized by ISO and IEC as part -of the MPEG specifications. - -Patent licenses for necessary patent claims for the FDK AAC Codec (including those of Fraunhofer) -may be obtained through Via Licensing (www.vialicensing.com) or through the respective patent owners -individually for the purpose of encoding or decoding bit streams in products that are compliant with -the ISO/IEC MPEG audio standards. Please note that most manufacturers of Android devices already license -these patent claims through Via Licensing or directly from the patent owners, and therefore FDK AAC Codec -software may already be covered under those patent licenses when it is used for those licensed purposes only. - -Commercially-licensed AAC software libraries, including floating-point versions with enhanced sound quality, -are also available from Fraunhofer. Users are encouraged to check the Fraunhofer website for additional -applications information and documentation. - -2. COPYRIGHT LICENSE - -Redistribution and use in source and binary forms, with or without modification, are permitted without -payment of copyright license fees provided that you satisfy the following conditions: - -You must retain the complete text of this software license in redistributions of the FDK AAC Codec or -your modifications thereto in source code form. - -You must retain the complete text of this software license in the documentation and/or other materials -provided with redistributions of the FDK AAC Codec or your modifications thereto in binary form. -You must make available free of charge copies of the complete source code of the FDK AAC Codec and your -modifications thereto to recipients of copies in binary form. - -The name of Fraunhofer may not be used to endorse or promote products derived from this library without -prior written permission. - -You may not charge copyright license fees for anyone to use, copy or distribute the FDK AAC Codec -software or your modifications thereto. - -Your modified versions of the FDK AAC Codec must carry prominent notices stating that you changed the software -and the date of any change. For modified versions of the FDK AAC Codec, the term -"Fraunhofer FDK AAC Codec Library for Android" must be replaced by the term -"Third-Party Modified Version of the Fraunhofer FDK AAC Codec Library for Android." - -3. NO PATENT LICENSE - -NO EXPRESS OR IMPLIED LICENSES TO ANY PATENT CLAIMS, including without limitation the patents of Fraunhofer, -ARE GRANTED BY THIS SOFTWARE LICENSE. Fraunhofer provides no warranty of patent non-infringement with -respect to this software. - -You may use this FDK AAC Codec software or modifications thereto only for purposes that are authorized -by appropriate patent licenses. - -4. DISCLAIMER - -This FDK AAC Codec software is provided by Fraunhofer on behalf of the copyright holders and contributors -"AS IS" and WITHOUT ANY EXPRESS OR IMPLIED WARRANTIES, including but not limited to the implied warranties -of merchantability and fitness for a particular purpose. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR -CONTRIBUTORS BE LIABLE for any direct, indirect, incidental, special, exemplary, or consequential damages, -including but not limited to procurement of substitute goods or services; loss of use, data, or profits, -or business interruption, however caused and on any theory of liability, whether in contract, strict -liability, or tort (including negligence), arising in any way out of the use of this software, even if -advised of the possibility of such damage. - -5. CONTACT INFORMATION - -Fraunhofer Institute for Integrated Circuits IIS -Attention: Audio and Multimedia Departments - FDK AAC LL -Am Wolfsmantel 33 -91058 Erlangen, Germany - -www.iis.fraunhofer.de/amm -amm-info@iis.fraunhofer.de ------------------------------------------------------------------------------------------------------------ */ - -/**************************** FDK PCM utils module ************************** - - Author(s): Christian Griebel - Description: Defines functions that perform downmixing or a simple channel - expansion in the PCM time domain. - -*******************************************************************************/ -#ifndef __linux__ -#include <log/log.h> -#endif -#include "pcmutils_lib.h" - -#include "genericStds.h" -#include "fixpoint_math.h" -#include "FDK_core.h" - - -/* ------------------------ * - * GLOBAL SETTINGS (GFR): * - * ------------------------ */ -#define DSE_METADATA_ENABLE /*!< Enable this to support MPEG/ETSI DVB ancillary data for - encoder assisted downmixing of MPEG-4 AAC and - MPEG-1/2 layer 2 streams. */ -#define PCE_METADATA_ENABLE /*!< Enable this to support MPEG matrix mixdown with a - coefficient carried in the PCE. */ - -#define PCM_DMX_MAX_IN_CHANNELS ( 8 ) /* Neither the maximum number of input nor the maximum number of output channels ... */ -#define PCM_DMX_MAX_OUT_CHANNELS ( 8 ) /* ... must exceed the maximum number of channels that the framework can handle. */ - -/* ------------------------ * - * SPECIFIC SETTINGS: * - * ------------------------ */ -#define PCM_CHANNEL_EXTENSION_ENABLE /*!< Allow module to duplicate mono signals or add zero channels to achieve the - desired number of output channels. */ - -#define PCM_DMX_DFLT_MAX_OUT_CHANNELS ( 6 ) /*!< The maximum number of output channels. If the value is greater than 0 the module - will automatically create a mixdown for all input signals with more channels - than specified. */ -#define PCM_DMX_DFLT_MIN_OUT_CHANNELS ( 0 ) /*!< The minimum number of output channels. If the value is greater than 0 the module - will do channel extension automatically for all input signals with less channels - than specified. */ -#define PCM_DMX_MAX_DELAY_FRAMES ( 1 ) /*!< The maximum delay frames to align the bitstreams payload with the PCM output. */ -#define PCM_DMX_DFLT_EXPIRY_FRAME ( 50 ) /*!< If value is greater than 0 the mixdown coefficients will expire by default after the - given number of frames. The value 50 corresponds to at least 500ms (FL 960 @ 96kHz) */ -/* #define PCMDMX_DEBUG */ - -/* Derived setting: - * No need to edit beyond this line. */ -#if defined(DSE_METADATA_ENABLE) || defined(PCE_METADATA_ENABLE) || defined(ARIB_MIXDOWN_ENABLE) - #define PCM_DOWNMIX_ENABLE /*!< Generally enable down mixing. */ -#endif -#if (PCM_DMX_MAX_IN_CHANNELS > 2) || (PCM_DMX_MAX_OUT_CHANNELS > 2) - #define PCM_DMX_MAX_CHANNELS ( 8 ) - #define PCM_DMX_MAX_CHANNEL_GROUPS ( 4 ) - #define PCM_DMX_MAX_CHANNELS_PER_GROUP PCM_DMX_MAX_CHANNELS /* All channels can be in one group */ -#else - #define PCM_DMX_MAX_CHANNELS ( 3 ) /* Need to add 1 because there are three channel positions in first channel group. */ - #define PCM_DMX_MAX_CHANNEL_GROUPS ( 1 ) /* Only front channels supported. */ - #define PCM_DMX_MAX_CHANNELS_PER_GROUP ( 2 ) /* The maximum over all channel groups */ -#endif -#if (PCM_DMX_MAX_IN_CHANNELS > PCM_DMX_MAX_OUT_CHANNELS) - #define PCM_DMX_MAX_IO_CHANNELS PCM_DMX_MAX_IN_CHANNELS -#else - #define PCM_DMX_MAX_IO_CHANNELS PCM_DMX_MAX_OUT_CHANNELS -#endif - -/* Decoder library info */ -#define PCMDMX_LIB_VL0 2 -#define PCMDMX_LIB_VL1 4 -#define PCMDMX_LIB_VL2 2 -#define PCMDMX_LIB_TITLE "PCM Downmix Lib" -#ifdef __ANDROID__ -#define PCMDMX_LIB_BUILD_DATE "" -#define PCMDMX_LIB_BUILD_TIME "" -#else -#define PCMDMX_LIB_BUILD_DATE __DATE__ -#define PCMDMX_LIB_BUILD_TIME __TIME__ -#endif - - -/* Fixed and unique channel group indices. - * The last group index has to be smaller than PCM_DMX_MAX_CHANNEL_GROUPS. */ -#define CH_GROUP_FRONT ( 0 ) -#define CH_GROUP_SIDE ( 1 ) -#define CH_GROUP_REAR ( 2 ) -#define CH_GROUP_LFE ( 3 ) - -/* The ordering of the following fixed channel labels has to be in MPEG-4 style. - * From the center to the back with left and right channel interleaved (starting with left). - * The last channel label index has to be smaller than PCM_DMX_MAX_CHANNELS. */ -#define CENTER_FRONT_CHANNEL ( 0 ) /* C */ -#define LEFT_FRONT_CHANNEL ( 1 ) /* L */ -#define RIGHT_FRONT_CHANNEL ( 2 ) /* R */ -#define LEFT_REAR_CHANNEL ( 3 ) /* Lr (aka left back channel) or center back channel */ -#define RIGHT_REAR_CHANNEL ( 4 ) /* Rr (aka right back channel) */ -#define LOW_FREQUENCY_CHANNEL ( 5 ) /* Lf */ -#define LEFT_MULTIPRPS_CHANNEL ( 6 ) /* Left multipurpose channel */ -#define RIGHT_MULTIPRPS_CHANNEL ( 7 ) /* Right multipurpose channel */ - -/* More constants */ -#define ONE_CHANNEL ( 1 ) -#define TWO_CHANNEL ( 2 ) -#define SIX_CHANNEL ( 6 ) -#define EIGHT_CHANNEL ( 8 ) - -#define PCMDMX_A_IDX_DEFAULT ( 2 ) -#define PCMDMX_B_IDX_DEFAULT ( 2 ) -#define PCMDMX_LFE_IDX_DEFAULT ( 15 ) -#define PCMDMX_GAIN_5_DEFAULT ( 0 ) -#define PCMDMX_GAIN_2_DEFAULT ( 0 ) - -#define PCMDMX_MAX_HEADROOM ( 3 ) /* Defines the maximum PCM scaling headroom that can be done by a - postprocessing step. This value must be greater or equal to 0. */ - -#define FALSE 0 -#define TRUE 1 -#define IN 0 -#define OUT 1 - -/* Type definitions: */ -#ifndef DMX_HIGH_PRECISION_ENABLE - #define FIXP_DMX FIXP_SGL - #define FX_DMX2FX_DBL(x) FX_SGL2FX_DBL((FIXP_SGL)(x)) - #define FX_DBL2FX_DMX(x) FX_DBL2FX_SGL(x) - #define FL2FXCONST_DMX(x) FL2FXCONST_SGL(x) - #define MAXVAL_DMX MAXVAL_SGL - #define FX_DMX2SHRT(x) ((SHORT)(x)) - #define FX_DMX2FL(x) FX_DBL2FL(FX_DMX2FX_DBL(x)) -#else - #define FIXP_DMX FIXP_DBL - #define FX_DMX2FX_DBL(x) ((FIXP_DBL)(x)) - #define FX_DBL2FX_DMX(x) ((FIXP_DBL)(x) - #define FL2FXCONST_DMX(x) FL2FXCONST_DBL(x) - #define MAXVAL_DMX MAXVAL_DBL - #define FX_DMX2SHRT(x) ((SHORT)((x)>>FRACT_BITS)) - #define FX_DMX2FL(x) FX_DBL2FL(x) -#endif - -/* The number of channels positions for each group in the internal representation. - * See the channel labels above. */ -static const UCHAR maxChInGrp[PCM_DMX_MAX_CHANNEL_GROUPS] = { -#if (PCM_DMX_MAX_CHANNELS > 3) - 3, 0, 2, 1 -#else - PCM_DMX_MAX_CHANNELS_PER_GROUP -#endif -}; - -/* List of packed channel modes */ -typedef enum -{ /* CH_MODE_<numFrontCh>_<numSideCh>_<numBackCh>_<numLfCh> */ - CH_MODE_UNDEFINED = 0x0000, - /* 1 channel */ - CH_MODE_1_0_0_0 = 0x0001, /* chCfg 1 */ - /* 2 channels */ - CH_MODE_2_0_0_0 = 0x0002, /* chCfg 2 */ - /* 3 channels */ - CH_MODE_3_0_0_0 = 0x0003, /* chCfg 3 */ - CH_MODE_2_0_1_0 = 0x0102, - CH_MODE_2_0_0_1 = 0x1002, - /* 4 channels */ - CH_MODE_3_0_1_0 = 0x0103, /* chCfg 4 */ - CH_MODE_2_0_2_0 = 0x0202, - CH_MODE_2_0_1_1 = 0x1102, - CH_MODE_4_0_0_0 = 0x0004, - /* 5 channels */ - CH_MODE_3_0_2_0 = 0x0203, /* chCfg 5 */ - CH_MODE_2_0_2_1 = 0x1202, - CH_MODE_3_0_1_1 = 0x1103, - CH_MODE_3_2_0_0 = 0x0023, - CH_MODE_5_0_0_0 = 0x0005, - /* 6 channels */ - CH_MODE_3_0_2_1 = 0x1203, /* chCfg 6 */ - CH_MODE_3_2_0_1 = 0x1023, - CH_MODE_3_2_1_0 = 0x0123, - CH_MODE_5_0_1_0 = 0x0105, - CH_MODE_6_0_0_0 = 0x0006, - /* 7 channels */ - CH_MODE_2_2_2_1 = 0x1222, - CH_MODE_3_0_3_1 = 0x1303, /* chCfg 11 */ - CH_MODE_3_2_1_1 = 0x1123, - CH_MODE_3_2_2_0 = 0x0223, - CH_MODE_3_0_2_2 = 0x2203, - CH_MODE_5_0_2_0 = 0x0205, - CH_MODE_5_0_1_1 = 0x1105, - CH_MODE_7_0_0_0 = 0x0007, - /* 8 channels */ - CH_MODE_3_2_2_1 = 0x1223, - CH_MODE_3_0_4_1 = 0x1403, /* chCfg 12 */ - CH_MODE_5_0_2_1 = 0x1205, /* chCfg 7 + 14 */ - CH_MODE_5_2_1_0 = 0x0125, - CH_MODE_3_2_1_2 = 0x2123, - CH_MODE_2_2_2_2 = 0x2222, - CH_MODE_3_0_3_2 = 0x2303, - CH_MODE_8_0_0_0 = 0x0008 - -} PCM_DMX_CHANNEL_MODE; - - -/* These are the channel configurations linked to - the number of output channels give by the user: */ -static const PCM_DMX_CHANNEL_MODE outChModeTable[PCM_DMX_MAX_CHANNELS+1] = -{ - CH_MODE_UNDEFINED, - CH_MODE_1_0_0_0, /* 1 channel */ - CH_MODE_2_0_0_0, /* 2 channels */ - CH_MODE_3_0_0_0 /* 3 channels */ -#if (PCM_DMX_MAX_CHANNELS > 3) - ,CH_MODE_3_0_1_0, /* 4 channels */ - CH_MODE_3_0_2_0, /* 5 channels */ - CH_MODE_3_0_2_1, /* 6 channels */ - CH_MODE_3_0_3_1, /* 7 channels */ - CH_MODE_3_0_4_1 /* 8 channels */ -#endif -}; - -static const FIXP_DMX abMixLvlValueTab[8] = -{ - FL2FXCONST_DMX(0.500f), /* scaled by 1 */ - FL2FXCONST_DMX(0.841f), - FL2FXCONST_DMX(0.707f), - FL2FXCONST_DMX(0.596f), - FL2FXCONST_DMX(0.500f), - FL2FXCONST_DMX(0.422f), - FL2FXCONST_DMX(0.355f), - FL2FXCONST_DMX(0.0f) -}; - -static const FIXP_DMX lfeMixLvlValueTab[16] = -{ /* value, scale */ - FL2FXCONST_DMX(0.7905f), /* 2 */ - FL2FXCONST_DMX(0.5000f), /* 2 */ - FL2FXCONST_DMX(0.8395f), /* 1 */ - FL2FXCONST_DMX(0.7065f), /* 1 */ - FL2FXCONST_DMX(0.5945f), /* 1 */ - FL2FXCONST_DMX(0.500f), /* 1 */ - FL2FXCONST_DMX(0.841f), /* 0 */ - FL2FXCONST_DMX(0.707f), /* 0 */ - FL2FXCONST_DMX(0.596f), /* 0 */ - FL2FXCONST_DMX(0.500f), /* 0 */ - FL2FXCONST_DMX(0.316f), /* 0 */ - FL2FXCONST_DMX(0.178f), /* 0 */ - FL2FXCONST_DMX(0.100f), /* 0 */ - FL2FXCONST_DMX(0.032f), /* 0 */ - FL2FXCONST_DMX(0.010f), /* 0 */ - FL2FXCONST_DMX(0.000f) /* 0 */ -}; - - - -#ifdef PCE_METADATA_ENABLE - /* MPEG matrix mixdown: - Set 1: L' = (1 + 2^-0.5 + A )^-1 * [L + C * 2^-0.5 + A * Ls]; - R' = (1 + 2^-0.5 + A )^-1 * [R + C * 2^-0.5 + A * Rs]; - - Set 2: L' = (1 + 2^-0.5 + 2A )^-1 * [L + C * 2^-0.5 - A * (Ls + Rs)]; - R' = (1 + 2^-0.5 + 2A )^-1 * [R + C * 2^-0.5 + A * (Ls + Rs)]; - - M = (3 + 2A)^-1 * [L + C + R + A*(Ls + Rs)]; - */ - static const FIXP_DMX mpegMixDownIdx2Coef[4] = - { - FL2FXCONST_DMX(0.70710678f), - FL2FXCONST_DMX(0.5f), - FL2FXCONST_DMX(0.35355339f), - FL2FXCONST_DMX(0.0f) - }; - - static const FIXP_SGL mpegMixDownIdx2PreFact[3][4] = - { { /* Set 1: */ - FL2FXCONST_DMX(0.4142135623730950f), - FL2FXCONST_DMX(0.4530818393219728f), - FL2FXCONST_DMX(0.4852813742385703f), - FL2FXCONST_DMX(0.5857864376269050f) - },{ /* Set 2: */ - FL2FXCONST_DMX(0.3203772410170407f), - FL2FXCONST_DMX(0.3693980625181293f), - FL2FXCONST_DMX(0.4142135623730950f), - FL2FXCONST_DMX(0.5857864376269050f) - },{ /* Mono DMX set: */ - FL2FXCONST_DMX(0.2265409196609864f), - FL2FXCONST_DMX(0.25f), - FL2FXCONST_DMX(0.2697521433898179f), - FL2FXCONST_DMX(0.3333333333333333f) } - }; -#endif /* PCE_METADATA_ENABLE */ - - -#define TYPE_NONE ( 0x0 ) -#define TYPE_DSE_DATA ( 0x1 ) -#define TYPE_PCE_DATA ( 0x2 ) - -typedef struct -{ - UINT typeFlags; - /* From DSE */ - UCHAR cLevIdx; - UCHAR sLevIdx; - UCHAR dmixIdxA; - UCHAR dmixIdxB; - UCHAR dmixIdxLfe; - UCHAR dmxGainIdx2; - UCHAR dmxGainIdx5; -#ifdef PCE_METADATA_ENABLE - /* From PCE */ - UCHAR matrixMixdownIdx; -#endif - /* Attributes: */ - SCHAR pseudoSurround; /*!< If set to 1 the signal is pseudo surround compatible. The value 0 tells - that it is not. If the value is -1 the information is not available. */ - UINT expiryCount; /*!< Counter to monitor the life time of a meta data set. */ - -} DMX_BS_META_DATA; - -/* Default metadata */ -static const DMX_BS_META_DATA dfltMetaData = { - 0, 2, 2, 2, 2, 15, 0, 0, -#ifdef PCE_METADATA_ENABLE - 0, -#endif - -1, 0 -}; - -/* Dynamic (user) params: - See the definition of PCMDMX_PARAM for details on the specific fields. */ -typedef struct -{ - UINT expiryFrame; /*!< Linked to DMX_BS_DATA_EXPIRY_FRAME */ - DUAL_CHANNEL_MODE dualChannelMode; /*!< Linked to DMX_DUAL_CHANNEL_MODE */ - PSEUDO_SURROUND_MODE pseudoSurrMode; /*!< Linked to DMX_PSEUDO_SURROUND_MODE */ - SHORT numOutChannelsMin; /*!< Linked to MIN_NUMBER_OF_OUTPUT_CHANNELS */ - SHORT numOutChannelsMax; /*!< Linked to MAX_NUMBER_OF_OUTPUT_CHANNELS */ - UCHAR frameDelay; /*!< Linked to DMX_BS_DATA_DELAY */ - -} PCM_DMX_USER_PARAMS; - -/* Modules main data structure: */ -struct PCM_DMX_INSTANCE -{ - /* Metadata */ - DMX_BS_META_DATA bsMetaData[PCM_DMX_MAX_DELAY_FRAMES+1]; - PCM_DMX_USER_PARAMS userParams; - - UCHAR applyProcessing; /*!< Flag to en-/disable modules processing. - The max channel limiting is done independently. */ -}; - -/* Memory allocation macro */ -C_ALLOC_MEM_STATIC(PcmDmxInstance, struct PCM_DMX_INSTANCE, 1) - - -/** Evaluate a given channel configuration and extract a packed channel mode. In addition the - * function generates a channel offset table for the mapping to the internal representation. - * This function is the inverse to the getChannelDescription() routine. - * @param [in] The total number of channels of the given configuration. - * @param [in] Array holding the corresponding channel types for each channel. - * @param [in] Array holding the corresponding channel type indices for each channel. - * @param [out] Array where the buffer offsets for each channel are stored into. - * @param [out] The generated packed channel mode that represents the given input configuration. - * @returns Returns an error code. - **/ -static -PCMDMX_ERROR getChannelMode ( - const INT numChannels, /* in */ - const AUDIO_CHANNEL_TYPE channelType[], /* in */ - const UCHAR channelIndices[], /* in */ - UCHAR offsetTable[PCM_DMX_MAX_CHANNELS], /* out */ - PCM_DMX_CHANNEL_MODE *chMode /* out */ - ) -{ - UCHAR chIdx[PCM_DMX_MAX_CHANNEL_GROUPS][PCM_DMX_MAX_CHANNELS_PER_GROUP]; - UCHAR numChInGrp[PCM_DMX_MAX_CHANNEL_GROUPS]; /* Total num of channels per group of the input config */ - UCHAR numChFree[PCM_DMX_MAX_CHANNEL_GROUPS]; /* Number of free slots per group in the internal repr. */ - UCHAR hardToPlace[PCM_DMX_MAX_CHANNELS]; /* List of channels not matching the internal repr. */ - UCHAR h2pSortIdx[PCM_DMX_MAX_CHANNELS]; - PCMDMX_ERROR err = PCMDMX_OK; - int ch, grpIdx; - int numChToPlace = 0; - - FDK_ASSERT(channelType != NULL); - FDK_ASSERT(channelIndices != NULL); - FDK_ASSERT(offsetTable != NULL); - FDK_ASSERT(chMode != NULL); - - /* For details see ISO/IEC 13818-7:2005(E), 8.5.3 Channel configuration */ - FDKmemclear(numChInGrp, PCM_DMX_MAX_CHANNEL_GROUPS*sizeof(UCHAR)); - FDKmemset(offsetTable, 255, PCM_DMX_MAX_CHANNELS*sizeof(UCHAR)); - FDKmemset(chIdx, 255, PCM_DMX_MAX_CHANNEL_GROUPS*PCM_DMX_MAX_CHANNELS_PER_GROUP*sizeof(UCHAR)); - FDKmemset(hardToPlace, 255, PCM_DMX_MAX_CHANNELS*sizeof(UCHAR)); - FDKmemset(h2pSortIdx, 255, PCM_DMX_MAX_CHANNELS*sizeof(UCHAR)); - /* Get the restrictions of the internal representation */ - FDKmemcpy(numChFree, maxChInGrp, PCM_DMX_MAX_CHANNEL_GROUPS*sizeof(UCHAR)); - - *chMode = CH_MODE_UNDEFINED; - - /* Categorize channels */ - for (ch = 0; ch < numChannels; ch += 1) { - UCHAR chGrpIdx = channelIndices[ch]; - int i = 0, j; - - switch (channelType[ch]) { - case ACT_FRONT_TOP: - chGrpIdx += numChInGrp[CH_GROUP_FRONT]; /* Append after normal plain */ - case ACT_FRONT: - grpIdx = CH_GROUP_FRONT; - break; -#if (PCM_DMX_MAX_CHANNEL_GROUPS > 1) - case ACT_SIDE_TOP: - chGrpIdx += numChInGrp[CH_GROUP_SIDE]; /* Append after normal plain */ - case ACT_SIDE: - grpIdx = CH_GROUP_SIDE; - break; - case ACT_BACK_TOP: - chGrpIdx += numChInGrp[CH_GROUP_REAR]; /* Append after normal plain */ - case ACT_BACK: - grpIdx = CH_GROUP_REAR; - break; - case ACT_LFE: - grpIdx = CH_GROUP_LFE; - break; -#endif - default: - /* Found a channel that can not be categorized! Most likely due to corrupt input signalling. - The rescue strategy is to append it to the front channels (=> ignore index). - This could cause strange behaviour so return an error to signal it. */ - err = PCMDMX_INVALID_MODE; - grpIdx = CH_GROUP_FRONT; - chGrpIdx = numChannels + numChToPlace; - numChToPlace += 1; - break; - } - - if (numChInGrp[grpIdx] < PCM_DMX_MAX_CHANNELS_PER_GROUP) { - /* Sort channels by index */ - while ( (i < numChInGrp[grpIdx]) && (chGrpIdx > channelIndices[chIdx[grpIdx][i]]) ) { - i += 1; - } - for (j = numChInGrp[grpIdx]; j > i; j -= 1) { - chIdx[grpIdx][j] = chIdx[grpIdx][j-1]; - } - chIdx[grpIdx][i] = ch; - numChInGrp[grpIdx] += 1; - } - } - -#if (PCM_DMX_MAX_CHANNEL_GROUPS > 1) - FDK_ASSERT( (numChInGrp[CH_GROUP_FRONT]+numChInGrp[CH_GROUP_SIDE] - +numChInGrp[CH_GROUP_REAR]+numChInGrp[CH_GROUP_LFE]) == numChannels); -#else - FDK_ASSERT( numChInGrp[CH_GROUP_FRONT] == numChannels ); -#endif - - /* Compose channel offset table: - * Map all channels to the internal representation. */ - numChToPlace = 0; - - /* Non-symmetric channels */ - if (numChInGrp[CH_GROUP_FRONT] & 0x1) { - /* Odd number of front channels -> we have a center channel. - In MPEG-4 the center has the index 0. */ - offsetTable[CENTER_FRONT_CHANNEL] = chIdx[CH_GROUP_FRONT][0]; - numChFree[CH_GROUP_FRONT] -= 1; - } - - for (grpIdx = 0; grpIdx < PCM_DMX_MAX_CHANNEL_GROUPS; grpIdx += 1) { - int chMapPos = 0; - ch = 0; /* Index of channel within the specific group */ - - switch (grpIdx) { - case CH_GROUP_FRONT: - chMapPos = LEFT_FRONT_CHANNEL; - ch = numChInGrp[grpIdx] & 0x1; - break; -#if (PCM_DMX_MAX_CHANNEL_GROUPS > 1) - case CH_GROUP_SIDE: - break; - case CH_GROUP_REAR: - chMapPos = LEFT_REAR_CHANNEL; - break; - case CH_GROUP_LFE: - chMapPos = LOW_FREQUENCY_CHANNEL; - break; -#endif - default: - FDK_ASSERT(0); - continue; - } - - /* Map all channels of the group */ - for ( ; ch < numChInGrp[grpIdx]; ch += 1) { - if (numChFree[grpIdx] > 0) { - offsetTable[chMapPos] = chIdx[grpIdx][ch]; - chMapPos += 1; - numChFree[grpIdx] -= 1; - } else { - /* Add to the list of hardship cases considering a MPEG-like sorting order: */ - int pos, sortIdx = grpIdx*PCM_DMX_MAX_CHANNELS_PER_GROUP + channelIndices[chIdx[grpIdx][ch]]; - for (pos = numChToPlace; pos > 0; pos -= 1) { - if (h2pSortIdx[pos-1] > sortIdx) { - hardToPlace[pos] = hardToPlace[pos-1]; - h2pSortIdx[pos] = h2pSortIdx[pos-1]; - } else { - /* Insert channel at the current index/position */ - break; - } - } - hardToPlace[pos] = chIdx[grpIdx][ch]; - h2pSortIdx[pos] = sortIdx; - numChToPlace += 1; - } - } - } - - { /* Assign the hardship cases */ - int chMapPos = 0; - int mappingHeat = 0; - for (ch = 0; ch < numChToPlace; ch+=1) { - int chAssigned = 0; - - /* Just assigning the channels to the next best slot can lead to undesired results (especially for x/x/1.x - configurations). Thus use the MPEG-like sorting index to find the best fitting slot for each channel. - If this is not possible the sorting index will be ignored (mappingHeat >= 2). */ - for ( ; chMapPos < PCM_DMX_MAX_CHANNELS; chMapPos+=1) { - if (offsetTable[chMapPos] == 255) { - int prvSortIdx = 0; - int nxtSortIdx = (CH_GROUP_LFE+1)*PCM_DMX_MAX_CHANNELS_PER_GROUP; - - if (mappingHeat < 2) { - if (chMapPos < LEFT_REAR_CHANNEL) { - /* Got front channel slot */ - prvSortIdx = CH_GROUP_FRONT*PCM_DMX_MAX_CHANNELS_PER_GROUP + chMapPos - CENTER_FRONT_CHANNEL; - nxtSortIdx = CH_GROUP_SIDE *PCM_DMX_MAX_CHANNELS_PER_GROUP; - } - else if (chMapPos < LOW_FREQUENCY_CHANNEL) { - /* Got back channel slot */ - prvSortIdx = CH_GROUP_REAR*PCM_DMX_MAX_CHANNELS_PER_GROUP + chMapPos - LEFT_REAR_CHANNEL; - nxtSortIdx = CH_GROUP_LFE *PCM_DMX_MAX_CHANNELS_PER_GROUP; - } - else if (chMapPos < LEFT_MULTIPRPS_CHANNEL) { - /* Got lfe channel slot */ - prvSortIdx = CH_GROUP_LFE *PCM_DMX_MAX_CHANNELS_PER_GROUP + chMapPos - LOW_FREQUENCY_CHANNEL; - nxtSortIdx = (CH_GROUP_LFE+1)*PCM_DMX_MAX_CHANNELS_PER_GROUP; - } - } - - /* Assign the channel only if its sort index is within the range */ - if ( (h2pSortIdx[ch] >= prvSortIdx) - && (h2pSortIdx[ch] < nxtSortIdx) ) { - offsetTable[chMapPos++] = hardToPlace[ch]; - chAssigned = 1; - break; - } - } - } - if (chAssigned == 0) { - chMapPos = 0; - ch -= 1; - mappingHeat += 1; - continue; - } - } - } - - /* Compose the channel mode */ - *chMode = (PCM_DMX_CHANNEL_MODE)( (numChInGrp[CH_GROUP_FRONT] & 0xF) -#if (PCM_DMX_MAX_CHANNEL_GROUPS > 1) - | (numChInGrp[CH_GROUP_SIDE] & 0xF) << 4 - | (numChInGrp[CH_GROUP_REAR] & 0xF) << 8 - | (numChInGrp[CH_GROUP_LFE] & 0xF) << 12 -#endif - ); - - return err; -} - - -/** Generate a channel offset table and complete channel description for a given (packed) channel mode. - * This function is the inverse to the getChannelMode() routine but does not support weird channel - * configurations. All channels have to be in the normal height layer and there must not be more - * channels in each group than given by maxChInGrp. - * @param [in] The packed channel mode of the configuration to be processed. - * @param [in] Array containing the channel mapping to be used (From MPEG PCE ordering to whatever is required). - * @param [out] Array where corresponding channel types for each channels are stored into. - * @param [out] Array where corresponding channel type indices for each output channel are stored into. - * @param [out] Array where the buffer offsets for each channel are stored into. - * @returns None. - **/ -static -void getChannelDescription ( - const PCM_DMX_CHANNEL_MODE chMode, /* in */ - const UCHAR channelMapping[][8], /* in */ - AUDIO_CHANNEL_TYPE channelType[], /* out */ - UCHAR channelIndices[], /* out */ - UCHAR offsetTable[PCM_DMX_MAX_CHANNELS] /* out */ - ) -{ - const UCHAR *pChannelMap; - int grpIdx, ch = 0, numChannels = 0; - UCHAR numChInGrp[PCM_DMX_MAX_CHANNEL_GROUPS]; - - FDK_ASSERT(channelType != NULL); - FDK_ASSERT(channelIndices != NULL); - FDK_ASSERT(channelMapping != NULL); - FDK_ASSERT(offsetTable != NULL); - - /* Init output arrays */ - FDKmemclear(channelType, PCM_DMX_MAX_IO_CHANNELS*sizeof(AUDIO_CHANNEL_TYPE)); - FDKmemclear(channelIndices, PCM_DMX_MAX_IO_CHANNELS*sizeof(UCHAR)); - FDKmemset(offsetTable, 255, PCM_DMX_MAX_CHANNELS*sizeof(UCHAR)); - - /* Extract the number of channels per group */ - numChInGrp[CH_GROUP_FRONT] = chMode & 0xF; -#if (PCM_DMX_MAX_CHANNEL_GROUPS > 1) - numChInGrp[CH_GROUP_SIDE] = (chMode >> 4) & 0xF; - numChInGrp[CH_GROUP_REAR] = (chMode >> 8) & 0xF; - numChInGrp[CH_GROUP_LFE] = (chMode >> 12) & 0xF; -#endif - - /* Summerize to get the total number of channels */ - for (grpIdx = 0; grpIdx < PCM_DMX_MAX_CHANNEL_GROUPS; grpIdx += 1) { - numChannels += numChInGrp[grpIdx]; - } - - /* Get the appropriate channel map */ - switch (chMode) { - case CH_MODE_1_0_0_0: - case CH_MODE_2_0_0_0: - case CH_MODE_3_0_0_0: - case CH_MODE_3_0_1_0: - case CH_MODE_3_0_2_0: - case CH_MODE_3_0_2_1: - pChannelMap = channelMapping[numChannels]; - break; - case CH_MODE_3_0_3_1: - pChannelMap = channelMapping[11]; - break; - case CH_MODE_3_0_4_1: - pChannelMap = channelMapping[12]; - break; - case CH_MODE_5_0_2_1: - pChannelMap = channelMapping[7]; - break; - default: - /* fallback */ - pChannelMap = channelMapping[0]; - break; - } - - /* Compose channel offset table */ - - /* Non-symmetric channels */ - if (numChInGrp[CH_GROUP_FRONT] & 0x1) { - /* Odd number of front channels -> we have a center channel. - In MPEG-4 the center has the index 0. */ - int mappedIdx = pChannelMap[ch]; - offsetTable[CENTER_FRONT_CHANNEL] = mappedIdx; - channelType[mappedIdx] = ACT_FRONT; - channelIndices[mappedIdx] = 0; - ch += 1; - } - - for (grpIdx = 0; grpIdx < PCM_DMX_MAX_CHANNEL_GROUPS; grpIdx += 1) { - AUDIO_CHANNEL_TYPE type = ACT_NONE; - int chMapPos = 0, maxChannels = 0; - int chIdx = 0; /* Index of channel within the specific group */ - - switch (grpIdx) { - case CH_GROUP_FRONT: - type = ACT_FRONT; - chMapPos = LEFT_FRONT_CHANNEL; - maxChannels = 3; - chIdx = numChInGrp[grpIdx] & 0x1; - break; -#if (PCM_DMX_MAX_CHANNEL_GROUPS > 1) - case CH_GROUP_SIDE: - /* Always map side channels to the multipurpose group. */ - type = ACT_SIDE; - chMapPos = LEFT_MULTIPRPS_CHANNEL; - break; - case CH_GROUP_REAR: - type = ACT_BACK; - chMapPos = LEFT_REAR_CHANNEL; - maxChannels = 2; - break; - case CH_GROUP_LFE: - type = ACT_LFE; - chMapPos = LOW_FREQUENCY_CHANNEL; - maxChannels = 1; - break; -#endif - default: - break; - } - - /* Map all channels in this group */ - for ( ; chIdx < numChInGrp[grpIdx]; chIdx += 1) { - int mappedIdx = pChannelMap[ch]; - if (chIdx == maxChannels) { - /* No space left in this channel group! - Use the multipurpose group instead: */ - chMapPos = LEFT_MULTIPRPS_CHANNEL; - } - offsetTable[chMapPos] = mappedIdx; - channelType[mappedIdx] = type; - channelIndices[mappedIdx] = chIdx; - chMapPos += 1; - ch += 1; - } - } -} - -/** Private helper function for downmix matrix manipulation that initializes - * one row in a given downmix matrix (corresponding to one output channel). - * @param [inout] Pointer to fixed-point parts of the downmix matrix. - * @param [inout] Pointer to scale factor matrix associated to the downmix factors. - * @param [in] Index of channel (row) to be initialized. - * @returns Nothing to return. - **/ -static -void dmxInitChannel( - FIXP_DMX mixFactors[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - INT mixScales[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - const unsigned int outCh - ) -{ - unsigned int inCh; - for (inCh=0; inCh < PCM_DMX_MAX_CHANNELS; inCh+=1) { - if (inCh == outCh) { - mixFactors[outCh][inCh] = FL2FXCONST_DMX(0.5f); - mixScales[outCh][inCh] = 1; - } else { - mixFactors[outCh][inCh] = FL2FXCONST_DMX(0.0f); - mixScales[outCh][inCh] = 0; - } - } -} - -/** Private helper function for downmix matrix manipulation that does a reset - * of one row in a given downmix matrix (corresponding to one output channel). - * @param [inout] Pointer to fixed-point parts of the downmix matrix. - * @param [inout] Pointer to scale factor matrix associated to the downmix factors. - * @param [in] Index of channel (row) to be cleared/reset. - * @returns Nothing to return. - **/ -static -void dmxClearChannel( - FIXP_DMX mixFactors[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - INT mixScales[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - const unsigned int outCh - ) -{ - FDKmemclear(&mixFactors[outCh], PCM_DMX_MAX_CHANNELS*sizeof(FIXP_DMX)); - FDKmemclear(&mixScales[outCh], PCM_DMX_MAX_CHANNELS*sizeof(INT)); -} - -/** Private helper function for downmix matrix manipulation that applies a source channel (row) - * scaled by a given mix factor to a destination channel (row) in a given downmix matrix. - * Existing mix factors of the destination channel (row) will get overwritten. - * @param [inout] Pointer to fixed-point parts of the downmix matrix. - * @param [inout] Pointer to scale factor matrix associated to the downmix factors. - * @param [in] Index of source channel (row). - * @param [in] Index of destination channel (row). - * @param [in] Fixed-point part of mix factor to be applied. - * @param [in] Scale factor of mix factor to be applied. - * @returns Nothing to return. - **/ -static -void dmxSetChannel( - FIXP_DMX mixFactors[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - INT mixScales[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - const unsigned int dstCh, - const unsigned int srcCh, - const FIXP_DMX factor, - const INT scale - ) -{ - int ch; - for (ch=0; ch < PCM_DMX_MAX_CHANNELS; ch+=1) { - if (mixFactors[srcCh][ch] != (FIXP_DMX)0) { - mixFactors[dstCh][ch] = FX_DBL2FX_DMX(fMult(mixFactors[srcCh][ch], factor)); - mixScales[dstCh][ch] = mixScales[srcCh][ch] + scale; - } - } -} - -/** Private helper function for downmix matrix manipulation that adds a source channel (row) - * scaled by a given mix factor to a destination channel (row) in a given downmix matrix. - * @param [inout] Pointer to fixed-point parts of the downmix matrix. - * @param [inout] Pointer to scale factor matrix associated to the downmix factors. - * @param [in] Index of source channel (row). - * @param [in] Index of destination channel (row). - * @param [in] Fixed-point part of mix factor to be applied. - * @param [in] Scale factor of mix factor to be applied. - * @returns Nothing to return. - **/ -static -void dmxAddChannel( - FIXP_DMX mixFactors[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - INT mixScales[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - const unsigned int dstCh, - const unsigned int srcCh, - const FIXP_DMX factor, - const INT scale - ) -{ - int ch; - for (ch=0; ch < PCM_DMX_MAX_CHANNELS; ch+=1) { - FIXP_DBL addFact = fMult(mixFactors[srcCh][ch], factor); - if (addFact != (FIXP_DMX)0) { - INT newScale = mixScales[srcCh][ch] + scale; - if (mixFactors[dstCh][ch] != (FIXP_DMX)0) { - if (newScale > mixScales[dstCh][ch]) { - mixFactors[dstCh][ch] >>= newScale - mixScales[dstCh][ch]; - } else { - addFact >>= mixScales[dstCh][ch] - newScale; - newScale = mixScales[dstCh][ch]; - } - } - mixFactors[dstCh][ch] += FX_DBL2FX_DMX(addFact); - mixScales[dstCh][ch] = newScale; - } - } -} - - -/** Private function that creates a downmix factor matrix depending on the input and output - * configuration, the user parameters as well as the given metadata. This function is the modules - * brain and hold all downmix algorithms. - * @param [in] Flag that indicates if inChMode holds a real (packed) channel mode or has been - converted to a MPEG-4 channel configuration index. - * @param [in] Dependent on the inModeIsCfg flag this field hands in a (packed) channel mode or - the corresponding MPEG-4 channel configuration index.of the input configuration. - * @param [in] The (packed) channel mode of the output configuration. - * @param [in] Pointer to structure holding all current user parameter. - * @param [in] Pointer to field holding all current meta data. - * @param [out] Pointer to fixed-point parts of the downmix matrix. Normalized to one scale factor. - * @param [out] The common scale factor of the downmix matrix. - * @returns An error code. - **/ -static -PCMDMX_ERROR getMixFactors ( - const UCHAR inModeIsCfg, - PCM_DMX_CHANNEL_MODE inChMode, - const PCM_DMX_CHANNEL_MODE outChMode, - const PCM_DMX_USER_PARAMS *pParams, - const DMX_BS_META_DATA *pMetaData, - FIXP_DMX mixFactors[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS], - INT *pOutScale - ) -{ - PCMDMX_ERROR err = PCMDMX_OK; - INT mixScales[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS]; - INT maxScale = 0; - int numInChannel, numOutChannel; - unsigned int outCh, inCh, inChCfg = 0; - unsigned int valid[PCM_DMX_MAX_CHANNELS] = { 0 }; - - FDK_ASSERT(pMetaData != NULL); - FDK_ASSERT(mixFactors != NULL); - /* Check on a supported output configuration */ - FDK_ASSERT( (outChMode == CH_MODE_1_0_0_0) - || (outChMode == CH_MODE_2_0_0_0) - || (outChMode == CH_MODE_3_0_2_1) ); - - if (inModeIsCfg) { - /* Workaround for the ambiguity of the internal channel modes. - Convert channel config to channel mode: */ - inChCfg = (unsigned int)inChMode; - switch (inChCfg) { - case 1: case 2: case 3: -#if (PCM_DMX_MAX_CHANNELS > 3) - case 4: case 5: case 6: -#endif - inChMode = outChModeTable[inChCfg]; - break; - case 11: - inChMode = CH_MODE_3_0_3_1; - break; - case 12: - inChMode = CH_MODE_3_0_4_1; - break; - case 7: case 14: - inChMode = CH_MODE_5_0_2_1; - break; - default: - FDK_ASSERT(0); - } - } - - /* Extract the total number of input channels */ - numInChannel = (inChMode&0xF) - + ((inChMode>> 4)&0xF) - + ((inChMode>> 8)&0xF) - + ((inChMode>>12)&0xF); - /* Extract the total number of output channels */ - numOutChannel = (outChMode&0xF) - + ((outChMode>> 4)&0xF) - + ((outChMode>> 8)&0xF) - + ((outChMode>>12)&0xF); - - /* MPEG ammendment 4 aka ETSI metadata and fallback mode: */ - - - /* Create identity DMX matrix: */ - for (outCh=0; outCh < PCM_DMX_MAX_CHANNELS; outCh+=1) { - dmxInitChannel( mixFactors, mixScales, outCh ); - } - if (((inChMode>>12)&0xF) == 0) { - /* Clear empty or wrongly mapped input channel */ - dmxClearChannel( mixFactors, mixScales, LOW_FREQUENCY_CHANNEL ); - } - - /* FIRST STAGE: */ - if (numInChannel > SIX_CHANNEL) - { /* Always use MPEG equations either with meta data or with default values. */ - FIXP_DMX dMixFactA, dMixFactB; - INT dMixScaleA, dMixScaleB; - int isValidCfg = TRUE; - - /* Get factors from meta data */ - dMixFactA = abMixLvlValueTab[pMetaData->dmixIdxA]; - dMixScaleA = (pMetaData->dmixIdxA==0) ? 1 : 0; - dMixFactB = abMixLvlValueTab[pMetaData->dmixIdxB]; - dMixScaleB = (pMetaData->dmixIdxB==0) ? 1 : 0; - - /* Check if input is in the list of supported configurations */ - switch (inChMode) { - case CH_MODE_3_0_3_1: /* chCfg 11 */ - /* 6.1ch: C' = C; L' = L; R' = R; LFE' = LFE; - Ls' = Ls*dmix_a_idx + Cs*dmix_b_idx; - Rs' = Rs*dmix_a_idx + Cs*dmix_b_idx; */ - dmxClearChannel( mixFactors, mixScales, RIGHT_MULTIPRPS_CHANNEL ); /* clear empty input channel */ - dmxSetChannel( mixFactors, mixScales, LEFT_REAR_CHANNEL, LEFT_REAR_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, LEFT_REAR_CHANNEL, LEFT_MULTIPRPS_CHANNEL, dMixFactB, dMixScaleB ); - dmxSetChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL, RIGHT_REAR_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL, LEFT_MULTIPRPS_CHANNEL, dMixFactB, dMixScaleB ); - break; - case CH_MODE_3_2_1_0: - case CH_MODE_3_2_1_1: /* chCfg 11 but with side channels */ - /* 6.1ch: C' = C; L' = L; R' = R; LFE' = LFE; - Ls' = Ls*dmix_a_idx + Cs*dmix_b_idx; - Rs' = Rs*dmix_a_idx + Cs*dmix_b_idx; */ - dmxClearChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL ); /* clear empty input channel */ - dmxSetChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL, LEFT_REAR_CHANNEL, dMixFactB, dMixScaleB ); - dmxSetChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL, RIGHT_MULTIPRPS_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, LEFT_REAR_CHANNEL, LEFT_REAR_CHANNEL, dMixFactB, dMixScaleB ); - dmxSetChannel( mixFactors, mixScales, LEFT_REAR_CHANNEL, LEFT_MULTIPRPS_CHANNEL, dMixFactA, dMixScaleA ); - isValidCfg = FALSE; - err = PCMDMX_INVALID_MODE; - break; - case CH_MODE_5_2_1_0: - case CH_MODE_5_0_1_0: - case CH_MODE_5_0_1_1: - /* Ls' = Cs*dmix_a_idx; - Rs' = Cs*dmix_a_idx; */ - dmxClearChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL ); /* clear empty input channel */ - dmxSetChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL, LEFT_REAR_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, LEFT_REAR_CHANNEL, LEFT_REAR_CHANNEL, dMixFactA, dMixScaleA ); - isValidCfg = FALSE; - err = PCMDMX_INVALID_MODE; - break; - case CH_MODE_3_0_4_1: /* chCfg 12 */ - /* 7.1ch Surround Back: C' = C; L' = L; R' = R; LFE' = LFE; - Ls' = Ls*dmix_a_idx + Lsr*dmix_b_idx; - Rs' = Rs*dmix_a_idx + Rsr*dmix_b_idx; */ - dmxSetChannel( mixFactors, mixScales, LEFT_REAR_CHANNEL, LEFT_REAR_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, LEFT_REAR_CHANNEL, LEFT_MULTIPRPS_CHANNEL, dMixFactB, dMixScaleB ); - dmxSetChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL, RIGHT_REAR_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL, RIGHT_MULTIPRPS_CHANNEL, dMixFactB, dMixScaleB ); - break; - case CH_MODE_5_0_2_1: /* chCfg 7 || 14 */ - if (inChCfg == 14) { - /* 7.1ch Front Height: C' = C; Ls' = Ls; Rs' = Rs; LFE' = LFE; - L' = L*dmix_a_idx + Lv*dmix_b_idx; - R' = R*dmix_a_idx + Rv*dmix_b_idx; */ - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_MULTIPRPS_CHANNEL, dMixFactB, dMixScaleB ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_MULTIPRPS_CHANNEL, dMixFactB, dMixScaleB ); - } else { - /* 7.1ch Front: Ls' = Ls; Rs' = Rs; LFE' = LFE; - C' = C + (Lc+Rc)*dmix_a_idx; - L' = L + Lc*dmix_b_idx; - R' = R + Rc*dmix_b_idx; - CAUTION: L+R are not at (MPEG) index 1+2. */ - dmxSetChannel( mixFactors, mixScales, CENTER_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, CENTER_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, dMixFactA, dMixScaleA ); - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, dMixFactB, dMixScaleB ); - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_MULTIPRPS_CHANNEL, FL2FXCONST_DMX(0.5f), 1 ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, dMixFactB, dMixScaleB ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_MULTIPRPS_CHANNEL, FL2FXCONST_DMX(0.5f), 1 ); - } - break; - default: - /* Nothing to do. Just use the identity matrix. */ - isValidCfg = FALSE; - err = PCMDMX_INVALID_MODE; - break; - } - - /* Add additional DMX gain */ - if ( (isValidCfg == TRUE) - && (pMetaData->dmxGainIdx5 != 0)) - { /* Apply DMX gain 5 */ - FIXP_DMX dmxGain; - INT dmxScale; - INT sign = (pMetaData->dmxGainIdx5 & 0x40) ? -1 : 1; - INT val = pMetaData->dmxGainIdx5 & 0x3F; - - /* 10^(dmx_gain_5/80) */ - dmxGain = FX_DBL2FX_DMX( fLdPow( - FL2FXCONST_DBL(0.830482023721841f), 2, /* log2(10) */ - (FIXP_DBL)(sign*val*(LONG)FL2FXCONST_DBL(0.0125f)), 0, - &dmxScale ) - ); - /* Currently only positive scale factors supported! */ - if (dmxScale < 0) { - dmxGain >>= -dmxScale; - dmxScale = 0; - } - - dmxSetChannel( mixFactors, mixScales, CENTER_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, dmxGain, dmxScale ); - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, dmxGain, dmxScale ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, dmxGain, dmxScale ); - dmxSetChannel( mixFactors, mixScales, LEFT_REAR_CHANNEL, LEFT_REAR_CHANNEL, dmxGain, dmxScale ); - dmxSetChannel( mixFactors, mixScales, RIGHT_REAR_CHANNEL, RIGHT_REAR_CHANNEL, dmxGain, dmxScale ); - dmxSetChannel( mixFactors, mixScales, LOW_FREQUENCY_CHANNEL, LOW_FREQUENCY_CHANNEL, dmxGain, dmxScale ); - } - - /* Mark the output channels */ - valid[CENTER_FRONT_CHANNEL] = 1; - valid[LEFT_FRONT_CHANNEL] = 1; - valid[RIGHT_FRONT_CHANNEL] = 1; - valid[LEFT_REAR_CHANNEL] = 1; - valid[RIGHT_REAR_CHANNEL] = 1; - valid[LOW_FREQUENCY_CHANNEL] = 1; - - /* Update channel mode for the next stage */ - inChMode = CH_MODE_3_0_2_1; - } - - /* SECOND STAGE: */ - if (numOutChannel <= TWO_CHANNEL) { - /* Create DMX matrix according to input configuration */ - switch (inChMode) { - case CH_MODE_2_0_0_0: /* chCfg 2 */ - /* Apply the dual channel mode. */ - switch (pParams->dualChannelMode) { - case CH1_MODE: /* L' = 0.707 * Ch1; - R' = 0.707 * Ch1; */ - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - break; - case CH2_MODE: /* L' = 0.707 * Ch2; - R' = 0.707 * Ch2; */ - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - break; - case MIXED_MODE: /* L' = 0.5*Ch1 + 0.5*Ch2; - R' = 0.5*Ch1 + 0.5*Ch2; */ - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, FL2FXCONST_DMX(0.5f), 0 ); - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, FL2FXCONST_DMX(0.5f), 0 ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, FL2FXCONST_DMX(0.5f), 0 ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, FL2FXCONST_DMX(0.5f), 0 ); - break; - default: - case STEREO_MODE: - /* Nothing to do */ - break; - } - break; - case CH_MODE_2_0_1_0: - /* L' = L + 0.707*S; - R' = R + 0.707*S; */ - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - break; - case CH_MODE_3_0_0_0: /* chCfg 3 */ - /* L' = L + 0.707*C; - R' = R + 0.707*C; */ - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - break; - case CH_MODE_3_0_1_0: /* chCfg 4 */ - /* L' = L + 0.707*C + 0.707*S; - R' = R + 0.707*C + 0.707*S; */ - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, FL2FXCONST_DMX(0.707f), 0 ); - break; - case CH_MODE_3_0_2_0: /* chCfg 5 */ - case CH_MODE_3_0_2_1: /* chCfg 6 */ - /* MPEG + ITU + DLB - But because the default downmix equations and coefficients are equal we stick to MPEG. */ - if ( (pMetaData->typeFlags & TYPE_DSE_DATA) - || !(pMetaData->typeFlags & TYPE_PCE_DATA) ) - { - FIXP_DMX cMixLvl, sMixLvl, lMixLvl; - INT cMixScale, sMixScale, lMixScale; - - /* Get factors from meta data */ - cMixLvl = abMixLvlValueTab[pMetaData->cLevIdx]; - cMixScale = (pMetaData->cLevIdx==0) ? 1 : 0; - sMixLvl = abMixLvlValueTab[pMetaData->sLevIdx]; - sMixScale = (pMetaData->sLevIdx==0) ? 1 : 0; - lMixLvl = lfeMixLvlValueTab[pMetaData->dmixIdxLfe]; - if (pMetaData->dmixIdxLfe <= 1) { - lMixScale = 2; - } else if (pMetaData->dmixIdxLfe <= 5) { - lMixScale = 1; - } else { - lMixScale = 0; - } - /* Setup the DMX matrix */ - if ( (pParams->pseudoSurrMode == FORCE_PS_DMX) - || ((pParams->pseudoSurrMode == AUTO_PS_DMX) && (pMetaData->pseudoSurround==1))) - { /* L' = L + C*clev - (Ls+Rs)*slev + LFE*lflev; - R' = R + C*clev + (Ls+Rs)*slev + LFE*lflev; */ - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, cMixLvl, cMixScale ); - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, -sMixLvl, sMixScale ); - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, RIGHT_REAR_CHANNEL, -sMixLvl, sMixScale ); - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LOW_FREQUENCY_CHANNEL, lMixLvl, lMixScale ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, cMixLvl, cMixScale ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, sMixLvl, sMixScale ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_REAR_CHANNEL, sMixLvl, sMixScale ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, LOW_FREQUENCY_CHANNEL, lMixLvl, lMixScale ); - } - else - { /* L' = L + C*clev + Ls*slev + LFE*llev; - R' = R + C*clev + Rs*slev + LFE*llev; */ - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, cMixLvl, cMixScale ); - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, sMixLvl, sMixScale ); - dmxAddChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LOW_FREQUENCY_CHANNEL, lMixLvl, lMixScale ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, cMixLvl, cMixScale ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_REAR_CHANNEL, sMixLvl, sMixScale ); - dmxAddChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, LOW_FREQUENCY_CHANNEL, lMixLvl, lMixScale ); - } - - /* Add additional DMX gain */ - if ( pMetaData->dmxGainIdx2 != 0 ) - { /* Apply DMX gain 2 */ - FIXP_DMX dmxGain; - INT dmxScale; - INT sign = (pMetaData->dmxGainIdx2 & 0x40) ? -1 : 1; - INT val = pMetaData->dmxGainIdx2 & 0x3F; - - /* 10^(dmx_gain_2/80) */ - dmxGain = FX_DBL2FX_DMX( fLdPow( - FL2FXCONST_DBL(0.830482023721841f), 2, /* log2(10) */ - (FIXP_DBL)(sign*val*(LONG)FL2FXCONST_DBL(0.0125f)), 0, - &dmxScale ) - ); - /* Currently only positive scale factors supported! */ - if (dmxScale < 0) { - dmxGain >>= -dmxScale; - dmxScale = 0; - } - - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, dmxGain, dmxScale ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, dmxGain, dmxScale ); - } - } -#ifdef PCE_METADATA_ENABLE - else { - FIXP_DMX flev, clev, slevLL, slevLR, slevRL, slevRR; - FIXP_DMX mtrxMixDwnCoef = mpegMixDownIdx2Coef[pMetaData->matrixMixdownIdx]; - - if ( (pParams->pseudoSurrMode == FORCE_PS_DMX) - || ((pParams->pseudoSurrMode == AUTO_PS_DMX) && (pMetaData->pseudoSurround==1))) - { /* 3/2 input: L' = (1.707+2*A)^-1 * [L+0.707*C-A*Ls-A*Rs]; - R' = (1.707+2*A)^-1 * [R+0.707*C+A*Ls+A*Rs]; */ - flev = mpegMixDownIdx2PreFact[1][pMetaData->matrixMixdownIdx]; - slevRR = slevRL = FX_DBL2FX_DMX(fMult(flev, mtrxMixDwnCoef)); - slevLL = slevLR = -slevRL; - } - else { - /* 3/2 input: L' = (1.707+A)^-1 * [L+0.707*C+A*Ls]; - R' = (1.707+A)^-1 * [R+0.707*C+A*Rs]; */ - flev = mpegMixDownIdx2PreFact[0][pMetaData->matrixMixdownIdx]; - slevRR = slevLL = FX_DBL2FX_DMX(fMult(flev, mtrxMixDwnCoef)); - slevLR = slevRL = (FIXP_SGL)0; - } - /* common factor */ - clev = FX_DBL2FX_DMX(fMult(flev, mpegMixDownIdx2Coef[0] /* 0.707 */)); - - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, flev, 0 ); - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, clev, 0 ); - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, slevLL, 0 ); - dmxSetChannel( mixFactors, mixScales, LEFT_FRONT_CHANNEL, RIGHT_REAR_CHANNEL, slevLR, 0 ); - - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, flev, 0 ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, CENTER_FRONT_CHANNEL, clev, 0 ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, LEFT_REAR_CHANNEL, slevRL, 0 ); - dmxSetChannel( mixFactors, mixScales, RIGHT_FRONT_CHANNEL, RIGHT_REAR_CHANNEL, slevRR, 0 ); - } -#endif /* PCE_METADATA_ENABLE */ - break; - default: - /* This configuration does not fit to any known downmix equation! */ - err = PCMDMX_INVALID_MODE; - break; - } - /* Mark the output channels */ - FDKmemclear(valid, PCM_DMX_MAX_CHANNELS*sizeof(unsigned int)); - valid[LEFT_FRONT_CHANNEL] = 1; - valid[RIGHT_FRONT_CHANNEL] = 1; - /* Update channel mode for the next stage */ - inChMode = CH_MODE_2_0_0_0; - } - - if (numOutChannel == ONE_CHANNEL) { - FIXP_DMX monoMixLevel; - INT monoMixScale; - -#ifdef PCE_METADATA_ENABLE - if ( (pMetaData->typeFlags & TYPE_PCE_DATA) - && !(pMetaData->typeFlags & TYPE_DSE_DATA) ) - { /* C' = (3+2*A)^-1 * [C+L+R+A*Ls+A+Rs]; */ - monoMixLevel = mpegMixDownIdx2PreFact[2][pMetaData->matrixMixdownIdx]; - monoMixScale = 0; - - dmxClearChannel( mixFactors, mixScales, CENTER_FRONT_CHANNEL ); - mixFactors[CENTER_FRONT_CHANNEL][CENTER_FRONT_CHANNEL] = monoMixLevel; - mixFactors[CENTER_FRONT_CHANNEL][LEFT_FRONT_CHANNEL] = monoMixLevel; - mixFactors[CENTER_FRONT_CHANNEL][RIGHT_FRONT_CHANNEL] = monoMixLevel; - monoMixLevel = FX_DBL2FX_DMX(fMult(monoMixLevel, mpegMixDownIdx2Coef[pMetaData->matrixMixdownIdx])); - mixFactors[CENTER_FRONT_CHANNEL][LEFT_REAR_CHANNEL] = monoMixLevel; - mixFactors[CENTER_FRONT_CHANNEL][RIGHT_REAR_CHANNEL] = monoMixLevel; - } - else -#endif - { /* C' = L + R; [default] */ - monoMixLevel = FL2FXCONST_DMX(0.5f); - monoMixScale = 1; - dmxClearChannel( mixFactors, mixScales, CENTER_FRONT_CHANNEL ); /* C is not in the mix */ - dmxSetChannel( mixFactors, mixScales, CENTER_FRONT_CHANNEL, LEFT_FRONT_CHANNEL, monoMixLevel, monoMixScale ); - dmxAddChannel( mixFactors, mixScales, CENTER_FRONT_CHANNEL, RIGHT_FRONT_CHANNEL, monoMixLevel, monoMixScale ); - } - - /* Mark the output channel */ - FDKmemclear(valid, PCM_DMX_MAX_CHANNELS*sizeof(unsigned int)); - valid[CENTER_FRONT_CHANNEL] = 1; - } - -#define MAX_SEARCH_START_VAL ( -7 ) - - { - LONG chSum[PCM_DMX_MAX_CHANNELS]; - INT chSumMax = MAX_SEARCH_START_VAL; - - /* Determine the current maximum scale factor */ - for (outCh=0; outCh < PCM_DMX_MAX_CHANNELS; outCh+=1) { - if (valid[outCh]!=0) { - for (inCh=0; inCh < PCM_DMX_MAX_CHANNELS; inCh+=1) { - if (mixScales[outCh][inCh] > maxScale) - { /* Store the new maximum */ - maxScale = mixScales[outCh][inCh]; - } - } - } - } - - /* Individualy analyse output chanal levels */ - for (outCh=0; outCh < PCM_DMX_MAX_CHANNELS; outCh+=1) { - chSum[outCh] = MAX_SEARCH_START_VAL; - if (valid[outCh]!=0) { - int ovrflwProtScale = 0; - - /* Accumulate all factors for each output channel */ - chSum[outCh] = 0; - for (inCh=0; inCh < PCM_DMX_MAX_CHANNELS; inCh+=1) { - SHORT addFact = FX_DMX2SHRT(mixFactors[outCh][inCh]); - if ( mixScales[outCh][inCh] <= maxScale ) { - addFact >>= maxScale - mixScales[outCh][inCh]; - } else { - addFact <<= mixScales[outCh][inCh] - maxScale; - } - chSum[outCh] += addFact; - } - if (chSum[outCh] > (LONG)MAXVAL_SGL) { - while (chSum[outCh] > (LONG)MAXVAL_SGL) { - ovrflwProtScale += 1; - chSum[outCh] >>= 1; - } - } else if (chSum[outCh] > 0) { - while ((chSum[outCh]<<1) <= (LONG)MAXVAL_SGL) { - ovrflwProtScale -= 1; - chSum[outCh] <<= 1; - } - } - /* Store the differential scaling in the same array */ - chSum[outCh] = ovrflwProtScale; - } - } - - for (outCh=0; outCh < PCM_DMX_MAX_CHANNELS; outCh+=1) { - if ( (valid[outCh] != 0) - && (chSum[outCh] > chSumMax) ) - { /* Store the new maximum */ - chSumMax = chSum[outCh]; - } - } - maxScale = FDKmax(maxScale+chSumMax, 0); - - /* Normalize all factors */ - for (outCh=0; outCh < PCM_DMX_MAX_CHANNELS; outCh+=1) { - if (valid[outCh]!=0) { - for (inCh=0; inCh < PCM_DMX_MAX_CHANNELS; inCh+=1) { - if (mixFactors[outCh][inCh] != (FIXP_DMX)0) { - if ( mixScales[outCh][inCh] <= maxScale ) { - mixFactors[outCh][inCh] >>= maxScale - mixScales[outCh][inCh]; - } else { - mixFactors[outCh][inCh] <<= mixScales[outCh][inCh] - maxScale; - } - mixScales[outCh][inCh] = maxScale; - } - } - } - } - } - - - /* return the scale factor */ - *pOutScale = maxScale; - - return (err); -} - - -/** Open and initialize an instance of the PCM downmix module - * @param [out] Pointer to a buffer receiving the handle of the new instance. - * @returns Returns an error code. - **/ -PCMDMX_ERROR pcmDmx_Open ( - HANDLE_PCM_DOWNMIX *pSelf - ) -{ - HANDLE_PCM_DOWNMIX self; - - if (pSelf == NULL) { - return (PCMDMX_INVALID_HANDLE); - } - - *pSelf = NULL; - - self = (HANDLE_PCM_DOWNMIX) GetPcmDmxInstance( 0 ); - if (self == NULL) { - return (PCMDMX_OUT_OF_MEMORY); - } - - /* Reset the full instance */ - pcmDmx_Reset( self, PCMDMX_RESET_FULL ); - - *pSelf = self; - - return (PCMDMX_OK); -} - - -/** Reset all static values like e.g. mixdown coefficients. - * @param [in] Handle of PCM downmix module instance. - * @param [in] Flags telling which parts of the module shall be reset. - * @returns Returns an error code. - **/ -PCMDMX_ERROR pcmDmx_Reset ( - HANDLE_PCM_DOWNMIX self, - UINT flags - ) -{ - if (self == NULL) { return (PCMDMX_INVALID_HANDLE); } - - if (flags & PCMDMX_RESET_PARAMS) { - PCM_DMX_USER_PARAMS *pParams = &self->userParams; - - pParams->dualChannelMode = STEREO_MODE; - pParams->pseudoSurrMode = NEVER_DO_PS_DMX; - pParams->numOutChannelsMax = PCM_DMX_DFLT_MAX_OUT_CHANNELS; - pParams->numOutChannelsMin = PCM_DMX_DFLT_MIN_OUT_CHANNELS; - pParams->frameDelay = 0; - pParams->expiryFrame = PCM_DMX_DFLT_EXPIRY_FRAME; - - self->applyProcessing = 0; - } - - if (flags & PCMDMX_RESET_BS_DATA) { - int slot; - /* Init all slots with a default set */ - for (slot = 0; slot <= PCM_DMX_MAX_DELAY_FRAMES; slot += 1) { - FDKmemcpy(&self->bsMetaData[slot], &dfltMetaData, sizeof(DMX_BS_META_DATA)); - } - } - - return (PCMDMX_OK); -} - - -/** Set one parameter for one instance of the PCM downmix module. - * @param [in] Handle of PCM downmix module instance. - * @param [in] Parameter to be set. - * @param [in] Parameter value. - * @returns Returns an error code. - **/ -PCMDMX_ERROR pcmDmx_SetParam ( - HANDLE_PCM_DOWNMIX self, - const PCMDMX_PARAM param, - const INT value - ) -{ - switch (param) - { - case DMX_BS_DATA_EXPIRY_FRAME: - if (self == NULL) - return (PCMDMX_INVALID_HANDLE); - self->userParams.expiryFrame = (value > 0) ? (UINT)value : 0; - break; - - case DMX_BS_DATA_DELAY: - if ( (value > PCM_DMX_MAX_DELAY_FRAMES) - || (value < 0) ) { - return (PCMDMX_UNABLE_TO_SET_PARAM); - } - if (self == NULL) { - return (PCMDMX_INVALID_HANDLE); - } - self->userParams.frameDelay = (UCHAR)value; - break; - - case MIN_NUMBER_OF_OUTPUT_CHANNELS: - switch (value) { /* supported output channels */ - case -1: case 0: case ONE_CHANNEL: case TWO_CHANNEL: -#if (PCM_DMX_MAX_OUT_CHANNELS >= 6) - case SIX_CHANNEL: -#endif -#if (PCM_DMX_MAX_OUT_CHANNELS >= 8) - case EIGHT_CHANNEL: -#endif - break; - default: - return (PCMDMX_UNABLE_TO_SET_PARAM); - } - if (self == NULL) - return (PCMDMX_INVALID_HANDLE); - /* Store the new value */ - self->userParams.numOutChannelsMin = (value > 0) ? value : -1; - if ( (value > 0) - && (self->userParams.numOutChannelsMax > 0) - && (value > self->userParams.numOutChannelsMax) ) - { /* MIN > MAX would be an invalid state. Thus set MAX = MIN in this case. */ - self->userParams.numOutChannelsMax = self->userParams.numOutChannelsMin; - } - break; - - case MAX_NUMBER_OF_OUTPUT_CHANNELS: - switch (value) { /* supported output channels */ - case -1: case 0: case ONE_CHANNEL: case TWO_CHANNEL: -#if (PCM_DMX_MAX_OUT_CHANNELS >= 6) - case SIX_CHANNEL: -#endif -#if (PCM_DMX_MAX_OUT_CHANNELS >= 8) - case EIGHT_CHANNEL: -#endif - break; - default: - return (PCMDMX_UNABLE_TO_SET_PARAM); - } - if (self == NULL) - return (PCMDMX_INVALID_HANDLE); - /* Store the new value */ - self->userParams.numOutChannelsMax = (value > 0) ? value : -1; - if ( (value > 0) - && (value < self->userParams.numOutChannelsMin) ) - { /* MAX < MIN would be an invalid state. Thus set MIN = MAX in this case. */ - self->userParams.numOutChannelsMin = self->userParams.numOutChannelsMax; - } - break; - - case DMX_DUAL_CHANNEL_MODE: - switch ((DUAL_CHANNEL_MODE)value) { - case STEREO_MODE: - case CH1_MODE: - case CH2_MODE: - case MIXED_MODE: - break; - default: - return (PCMDMX_UNABLE_TO_SET_PARAM); - } - if (self == NULL) - return (PCMDMX_INVALID_HANDLE); - self->userParams.dualChannelMode = (DUAL_CHANNEL_MODE)value; - self->applyProcessing = 1; /* Force processing */ - break; - - case DMX_PSEUDO_SURROUND_MODE: - switch ((PSEUDO_SURROUND_MODE)value) { - case NEVER_DO_PS_DMX: - case AUTO_PS_DMX: - case FORCE_PS_DMX: - break; - default: - return (PCMDMX_UNABLE_TO_SET_PARAM); - } - if (self == NULL) - return (PCMDMX_INVALID_HANDLE); - self->userParams.pseudoSurrMode = (PSEUDO_SURROUND_MODE)value; - break; - - default: - return (PCMDMX_UNKNOWN_PARAM); - } - - return (PCMDMX_OK); -} - -/** Get one parameter value of one PCM downmix module instance. - * @param [in] Handle of PCM downmix module instance. - * @param [in] Parameter to be set. - * @param [out] Pointer to buffer receiving the parameter value. - * @returns Returns an error code. - **/ -PCMDMX_ERROR pcmDmx_GetParam ( - HANDLE_PCM_DOWNMIX self, - const PCMDMX_PARAM param, - INT * const pValue - ) -{ - PCM_DMX_USER_PARAMS *pUsrParams; - - if ( (self == NULL) - || (pValue == NULL) ) { - return (PCMDMX_INVALID_HANDLE); - } - pUsrParams = &self->userParams; - - switch (param) - { - case DMX_BS_DATA_EXPIRY_FRAME: - *pValue = (INT)pUsrParams->expiryFrame; - break; - case DMX_BS_DATA_DELAY: - *pValue = (INT)pUsrParams->frameDelay; - break; - case MIN_NUMBER_OF_OUTPUT_CHANNELS: - *pValue = (INT)pUsrParams->numOutChannelsMin; - break; - case MAX_NUMBER_OF_OUTPUT_CHANNELS: - *pValue = (INT)pUsrParams->numOutChannelsMax; - break; - case DMX_DUAL_CHANNEL_MODE: - *pValue = (INT)pUsrParams->dualChannelMode; - break; - case DMX_PSEUDO_SURROUND_MODE: - *pValue = (INT)pUsrParams->pseudoSurrMode; - break; - default: - return (PCMDMX_UNKNOWN_PARAM); - } - - return (PCMDMX_OK); -} - - -#ifdef DSE_METADATA_ENABLE - -#define MAX_DSE_ANC_BYTES ( 16 ) /* 15 bytes */ -#define ANC_DATA_SYNC_BYTE ( 0xBC ) /* ancillary data sync byte. */ - -/* - * Read DMX meta-data from a data stream element. - */ -PCMDMX_ERROR pcmDmx_Parse ( - HANDLE_PCM_DOWNMIX self, - HANDLE_FDK_BITSTREAM hBs, - UINT ancDataBits, - int isMpeg2 - ) -{ - PCMDMX_ERROR errorStatus = PCMDMX_OK; - DMX_BS_META_DATA *pBsMetaData = &self->bsMetaData[0]; - - int skip4Dmx = 0, skip4Ext = 0; - int dmxLvlAvail = 0, extDataAvail = 0; - int foundNewData = 0; - UINT minAncBits = ((isMpeg2) ? 5 : 3)*8; - - if ( (self == NULL) - || (hBs == NULL) ) { return (PCMDMX_INVALID_HANDLE); } - - ancDataBits = FDKgetValidBits(hBs); - - /* sanity checks */ - if ( (ancDataBits < minAncBits) - || (ancDataBits > FDKgetValidBits(hBs)) ) { - return (PCMDMX_CORRUPT_ANC_DATA); - } - - pBsMetaData = &self->bsMetaData[0]; - - if (isMpeg2) { - /* skip DVD ancillary data */ - FDKpushFor(hBs, 16); - } - - /* check sync word */ - if (FDKreadBits(hBs,8) != ANC_DATA_SYNC_BYTE) { - return (PCMDMX_CORRUPT_ANC_DATA); - } - - /* skip MPEG audio type and Dolby surround mode */ - FDKpushFor(hBs, 4); - - if (isMpeg2) { - /* int numAncBytes = */ FDKreadBits(hBs, 4); - /* advanced dynamic range control */ - if (FDKreadBit(hBs)) skip4Dmx += 24; - /* dialog normalization */ - if (FDKreadBit(hBs)) skip4Dmx += 8; - /* reproduction_level */ - if (FDKreadBit(hBs)) skip4Dmx += 8; - } else { - FDKpushFor(hBs, 2); /* drc presentation mode */ - pBsMetaData->pseudoSurround = FDKreadBit(hBs); - FDKpushFor(hBs, 4); /* reserved bits */ - } - - /* downmixing levels MPEGx status */ - dmxLvlAvail = FDKreadBit(hBs); - - if (isMpeg2) { - /* scale factor CRC status */ - if (FDKreadBit(hBs)) skip4Ext += 16; - } else { - /* ancillary data extension status */ - extDataAvail = FDKreadBit(hBs); - } - - /* audio coding and compression status */ - if (FDKreadBit(hBs)) skip4Ext += 16; - /* coarse grain timecode status */ - if (FDKreadBit(hBs)) skip4Ext += 16; - /* fine grain timecode status */ - if (FDKreadBit(hBs)) skip4Ext += 16; - - /* skip the useless data to get to the DMX levels */ - FDKpushFor(hBs, skip4Dmx); - - /* downmix_levels_MPEGX */ - if (dmxLvlAvail) - { - if (FDKreadBit(hBs)) { /* center_mix_level_on */ - pBsMetaData->cLevIdx = FDKreadBits(hBs, 3); - foundNewData = 1; - } else { - FDKreadBits(hBs, 3); - } - if (FDKreadBit(hBs)) { /* surround_mix_level_on */ - pBsMetaData->sLevIdx = FDKreadBits(hBs, 3); - foundNewData = 1; - } else { - FDKreadBits(hBs, 3); - } - } - - /* skip the useless data to get to the ancillary data extension */ - FDKpushFor(hBs, skip4Ext); - - /* anc data extension (MPEG-4 only) */ - if (extDataAvail) { - int extDmxLvlSt, extDmxGainSt, extDmxLfeSt; - - FDKreadBit(hBs); /* reserved bit */ - extDmxLvlSt = FDKreadBit(hBs); - extDmxGainSt = FDKreadBit(hBs); - extDmxLfeSt = FDKreadBit(hBs); - FDKreadBits(hBs, 4); /* reserved bits */ - - if (extDmxLvlSt) { - pBsMetaData->dmixIdxA = FDKreadBits(hBs, 3); - pBsMetaData->dmixIdxB = FDKreadBits(hBs, 3); - FDKreadBits(hBs, 2); /* reserved bits */ - foundNewData = 1; - } - if (extDmxGainSt) { - pBsMetaData->dmxGainIdx5 = FDKreadBits(hBs, 7); - FDKreadBit(hBs); /* reserved bit */ - pBsMetaData->dmxGainIdx2 = FDKreadBits(hBs, 7); - FDKreadBit(hBs); /* reserved bit */ - foundNewData = 1; - } - if (extDmxLfeSt) { - pBsMetaData->dmixIdxLfe = FDKreadBits(hBs, 4); - FDKreadBits(hBs, 4); /* reserved bits */ - foundNewData = 1; - } - } - - /* final sanity check on the amount of read data */ - if ((INT)FDKgetValidBits(hBs) < 0) { - errorStatus = PCMDMX_CORRUPT_ANC_DATA; - } - - if ( (errorStatus == PCMDMX_OK) - && (foundNewData == 1) ) { - /* announce new data */ - pBsMetaData->typeFlags |= TYPE_DSE_DATA; - /* reset expiry counter */ - pBsMetaData->expiryCount = 0; - } - - return (errorStatus); -} - -/* - * Read DMX meta-data from a data stream element. - */ -PCMDMX_ERROR pcmDmx_ReadDvbAncData ( - HANDLE_PCM_DOWNMIX self, - UCHAR *pAncDataBuf, - UINT ancDataBytes, - int isMpeg2 - ) -{ - FDK_BITSTREAM bs; - HANDLE_FDK_BITSTREAM hBs = &bs; - PCMDMX_ERROR errorStatus = PCMDMX_OK; - - if (self == NULL) { return (PCMDMX_INVALID_HANDLE); } - - /* sanity checks */ - if ( (pAncDataBuf == NULL) - || (ancDataBytes == 0) ) { - return (PCMDMX_CORRUPT_ANC_DATA); - } - - FDKinitBitStream (hBs, pAncDataBuf, MAX_DSE_ANC_BYTES, ancDataBytes*8, BS_READER); - - errorStatus = pcmDmx_Parse ( - self, - hBs, - ancDataBytes*8, - isMpeg2 ); - - return (errorStatus); -} -#endif /* DSE_METADATA_ENABLE */ - -#ifdef PCE_METADATA_ENABLE -/** Set the matrix mixdown information extracted from the PCE of an AAC bitstream. - * Note: Call only if matrix_mixdown_idx_present is true. - * @param [in] Handle of PCM downmix module instance. - * @param [in] The 2 bit matrix mixdown index extracted from PCE. - * @param [in] The pseudo surround enable flag extracted from PCE. - * @returns Returns an error code. - **/ -PCMDMX_ERROR pcmDmx_SetMatrixMixdownFromPce ( - HANDLE_PCM_DOWNMIX self, - int matrixMixdownPresent, - int matrixMixdownIdx, - int pseudoSurroundEnable - ) -{ - DMX_BS_META_DATA *pBsMetaData = &self->bsMetaData[0]; - - if (self == NULL) { - return (PCMDMX_INVALID_HANDLE); - } - - if (matrixMixdownPresent) { - pBsMetaData->pseudoSurround = pseudoSurroundEnable; - pBsMetaData->matrixMixdownIdx = matrixMixdownIdx & 0x03; - pBsMetaData->typeFlags |= TYPE_PCE_DATA; - /* Reset expiry counter */ - pBsMetaData->expiryCount = 0; - } - - return (PCMDMX_OK); -} -#endif /* PCE_METADATA_ENABLE */ - - -/** Apply down or up mixing. - * @param [in] Handle of PCM downmix module instance. - * @param [inout] Pointer to buffer that hold the time domain signal. - * @param [in] Pointer where the amount of output samples is returned into. - * @param [inout] Pointer where the amount of output channels is returned into. - * @param [in] Flag which indicates if output time data are writtern interleaved or as subsequent blocks. - * @param [inout] Array where the corresponding channel type for each output audio channel is stored into. - * @param [inout] Array where the corresponding channel type index for each output audio channel is stored into. - * @param [in] Array containing the out channel mapping to be used (From MPEG PCE ordering to whatever is required). - * @param [out] Pointer on a field receiving the scale factor that has to be applied on all samples afterwards. - * If the handed pointer is NULL scaling is done internally. - * @returns Returns an error code. - **/ -PCMDMX_ERROR pcmDmx_ApplyFrame ( - HANDLE_PCM_DOWNMIX self, - INT_PCM *pPcmBuf, - UINT frameSize, - INT *nChannels, - int fInterleaved, - AUDIO_CHANNEL_TYPE channelType[], - UCHAR channelIndices[], - const UCHAR channelMapping[][8], - INT *pDmxOutScale - ) -{ - PCM_DMX_USER_PARAMS *pParam = NULL; - PCMDMX_ERROR errorStatus = PCMDMX_OK; - DUAL_CHANNEL_MODE dualChannelMode; - PCM_DMX_CHANNEL_MODE inChMode; - PCM_DMX_CHANNEL_MODE outChMode; - INT devNull; /* Just a dummy to avoid a lot of branches in the code */ - int numOutChannels, numInChannels; - int inStride, outStride, offset; - int dmxMaxScale, dmxScale; - int ch, slot; - UCHAR inOffsetTable[PCM_DMX_MAX_CHANNELS]; - - DMX_BS_META_DATA bsMetaData; - - if ( (self == NULL) - || (nChannels == NULL) - || (channelType == NULL) - || (channelIndices == NULL) - || (channelMapping == NULL) ) { - return (PCMDMX_INVALID_HANDLE); - } - - /* Init the output scaling */ - dmxScale = 0; - if (pDmxOutScale != NULL) { - /* Avoid final scaling internally and hand it to the outside world. */ - *pDmxOutScale = 0; - dmxMaxScale = PCMDMX_MAX_HEADROOM; - } else { - /* Apply the scaling internally. */ - pDmxOutScale = &devNull; /* redirect to temporal stack memory */ - dmxMaxScale = 0; - } - - pParam = &self->userParams; - numInChannels = *nChannels; - - /* Perform some input sanity checks */ - if (pPcmBuf == NULL) { return (PCMDMX_INVALID_ARGUMENT); } - if (frameSize == 0) { return (PCMDMX_INVALID_ARGUMENT); } - if ( (numInChannels == 0) - || (numInChannels > PCM_DMX_MAX_IN_CHANNELS) ) - { return (PCMDMX_INVALID_ARGUMENT); } - - /* Check on misconfiguration */ - FDK_ASSERT( (pParam->numOutChannelsMax <= 0) \ - || (pParam->numOutChannelsMax >= pParam->numOutChannelsMin)); - - /* Determine if the module has to do processing */ - if ( (self->applyProcessing == 0) - && ((pParam->numOutChannelsMax <= 0) - || (pParam->numOutChannelsMax >= numInChannels)) - && (pParam->numOutChannelsMin <= numInChannels) ) { - /* Nothing to do */ - return (errorStatus); - } - - /* Determine the number of output channels */ - if ( (pParam->numOutChannelsMax > 0) - && (numInChannels > pParam->numOutChannelsMax) ) { - numOutChannels = pParam->numOutChannelsMax; - } - else if (numInChannels < pParam->numOutChannelsMin) { - numOutChannels = pParam->numOutChannelsMin; - } - else { - numOutChannels = numInChannels; - } - - dualChannelMode = pParam->dualChannelMode; - - /* Analyse input channel configuration and get channel offset - * table that can be accessed with the fixed channel labels. */ - errorStatus = getChannelMode( - numInChannels, - channelType, - channelIndices, - inOffsetTable, - &inChMode - ); - if ( PCMDMX_IS_FATAL_ERROR(errorStatus) - || (inChMode == CH_MODE_UNDEFINED) ) { - /* We don't need to restore because the channel - configuration has not been changed. Just exit. */ - return (PCMDMX_INVALID_CH_CONFIG); - } - - /* Set input stride and offset */ - if (fInterleaved) { - inStride = numInChannels; - offset = 1; /* Channel specific offset factor */ - } else { - inStride = 1; - offset = frameSize; /* Channel specific offset factor */ - } - - /* Reset downmix meta data if necessary */ - if ( (pParam->expiryFrame > 0) - && (++self->bsMetaData[0].expiryCount > pParam->expiryFrame) ) - { /* The metadata read from bitstream is too old. */ - PCMDMX_ERROR err = pcmDmx_Reset(self, PCMDMX_RESET_BS_DATA); - FDK_ASSERT(err == PCMDMX_OK); - } - FDKmemcpy(&bsMetaData, &self->bsMetaData[pParam->frameDelay], sizeof(DMX_BS_META_DATA)); - /* Maintain delay line */ - for (slot = pParam->frameDelay; slot > 0; slot -= 1) { - FDKmemcpy(&self->bsMetaData[slot], &self->bsMetaData[slot-1], sizeof(DMX_BS_META_DATA)); - } - - /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ -#ifdef PCM_DOWNMIX_ENABLE - if ( numInChannels > numOutChannels ) - { /* Apply downmix */ - INT_PCM *pInPcm[PCM_DMX_MAX_IN_CHANNELS] = { NULL }; - INT_PCM *pOutPcm[PCM_DMX_MAX_OUT_CHANNELS] = { NULL }; - FIXP_DMX mixFactors[PCM_DMX_MAX_CHANNELS][PCM_DMX_MAX_CHANNELS]; - UCHAR outOffsetTable[PCM_DMX_MAX_CHANNELS]; - UINT sample; - int chCfg = 0; - int bypScale = 0; - -#if (PCM_DMX_MAX_IN_CHANNELS >= 7) - if (numInChannels > SIX_CHANNEL) { - AUDIO_CHANNEL_TYPE multiPurposeChType[2]; - - /* Get the type of the multipurpose channels */ - multiPurposeChType[0] = channelType[inOffsetTable[LEFT_MULTIPRPS_CHANNEL]]; - multiPurposeChType[1] = channelType[inOffsetTable[RIGHT_MULTIPRPS_CHANNEL]]; - - /* Check if the input configuration is one defined in the standard. */ - switch (inChMode) { - case CH_MODE_5_0_2_1: /* chCfg 7 || 14 */ - /* Further analyse the input config to distinguish the two CH_MODE_5_0_2_1 configs. */ - if ( (multiPurposeChType[0] == ACT_FRONT_TOP) - && (multiPurposeChType[1] == ACT_FRONT_TOP) ) { - chCfg = 14; - } else { - chCfg = 7; - } - break; - case CH_MODE_3_0_3_1: /* chCfg 11 */ - chCfg = 11; - break; - case CH_MODE_3_0_4_1: /* chCfg 12 */ - chCfg = 12; - break; - default: - chCfg = 0; /* Not a known config */ - break; - } - } -#endif - - /* Set this stages output stride and channel mode: */ - outStride = (fInterleaved) ? numOutChannels : 1; - outChMode = outChModeTable[numOutChannels]; - - /* Get channel description and channel mapping for the desired output configuration. */ - getChannelDescription( - outChMode, - channelMapping, - channelType, - channelIndices, - outOffsetTable - ); - /* Now there is no way back because we modified the channel configuration! */ - - /* Create the DMX matrix */ - errorStatus = getMixFactors ( - (chCfg>0) ? 1 : 0, - (chCfg>0) ? (PCM_DMX_CHANNEL_MODE)chCfg : inChMode, - outChMode, - pParam, - &bsMetaData, - mixFactors, - &dmxScale - ); - /* No fatal errors can occur here. The function is designed to always return a valid matrix. - The error code is used to signal configurations and matrices that are not conform to any standard. */ - - /* Determine the final scaling */ - bypScale = FDKmin(dmxMaxScale, dmxScale); - *pDmxOutScale += bypScale; - dmxScale -= bypScale; - - { /* Set channel pointer for input. Remove empty cols. */ - int inCh, outCh, map[PCM_DMX_MAX_CHANNELS]; - ch = 0; - for (inCh=0; inCh < PCM_DMX_MAX_CHANNELS; inCh+=1) { - if (inOffsetTable[inCh] != 255) { - pInPcm[ch] = &pPcmBuf[inOffsetTable[inCh]*offset]; - map[ch++] = inCh; - } - } - if (ch != numInChannels) { -#ifndef __linux__ - ALOGE("b/23876444"); -#endif - return PCMDMX_INVALID_ARGUMENT; - } - - /* Remove unused cols from factor matrix */ - for (inCh=0; inCh < numInChannels; inCh+=1) { - if (inCh != map[inCh]) { - int outCh; - for (outCh=0; outCh < PCM_DMX_MAX_CHANNELS; outCh+=1) { - mixFactors[outCh][inCh] = mixFactors[outCh][map[inCh]]; - } - } - } - - /* Set channel pointer for output. Remove empty cols. */ - ch = 0; - for (outCh=0; outCh < PCM_DMX_MAX_CHANNELS; outCh+=1) { - if (outOffsetTable[outCh] != 255) { - pOutPcm[ch] = &pPcmBuf[outOffsetTable[outCh]*offset]; - map[ch++] = outCh; - } - } - FDK_ASSERT(ch == numOutChannels); - - /* Remove unused rows from factor matrix */ - for (outCh=0; outCh < numOutChannels; outCh+=1) { - if (outCh != map[outCh]) { - FDKmemcpy(&mixFactors[outCh], &mixFactors[map[outCh]], PCM_DMX_MAX_CHANNELS*sizeof(FIXP_DMX)); - } - } - } - - /* Sample processing loop */ - for (sample = 0; sample < frameSize; sample++) - { - FIXP_PCM tIn[PCM_DMX_MAX_IN_CHANNELS]; - FIXP_DBL tOut[PCM_DMX_MAX_OUT_CHANNELS] = { (FIXP_DBL)0 }; - int inCh, outCh; - - /* Preload all input samples */ - for (inCh=0; inCh < numInChannels; inCh+=1) { - tIn[inCh] = (FIXP_PCM)*pInPcm[inCh]; - pInPcm[inCh] += inStride; - } - /* Apply downmix coefficients to input samples and accumulate for output */ - for (outCh=0; outCh < numOutChannels; outCh+=1) { - for (inCh=0; inCh < numInChannels; inCh+=1) { - tOut[outCh] += fMult(tIn[inCh], mixFactors[outCh][inCh]); - } - /* Write sample */ -#if (SAMPLE_BITS == DFRACT_BITS) - *pOutPcm[outCh] = (INT_PCM)SATURATE_LEFT_SHIFT(tOut[outCh], dmxScale, SAMPLE_BITS); -#else - *pOutPcm[outCh] = (INT_PCM)SATURATE_RIGHT_SHIFT(tOut[outCh], DFRACT_BITS-SAMPLE_BITS-dmxScale, SAMPLE_BITS); -#endif - pOutPcm[outCh] += outStride; - } - } - - /* Update the number of output channels */ - *nChannels = numOutChannels; - - } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ - else -#endif /* PCM_DOWNMIX_ENABLE */ -#ifdef PCM_CHANNEL_EXTENSION_ENABLE - if ( numInChannels < numOutChannels ) - { /* Apply rudimentary upmix */ - /* Set up channel pointer */ - UINT sample; - UCHAR outOffsetTable[PCM_DMX_MAX_CHANNELS]; - - /* FIRST STAGE - Create a stereo/dual channel signal */ - if (numInChannels == ONE_CHANNEL) - { - INT_PCM *pInPcm[PCM_DMX_MAX_CHANNELS]; - INT_PCM *pOutLF, *pOutRF; - - /* Set this stages output stride and channel mode: */ - outStride = (fInterleaved) ? TWO_CHANNEL : 1; - outChMode = outChModeTable[TWO_CHANNEL]; - - /* Get channel description and channel mapping for this - * stages number of output channels (always STEREO). */ - getChannelDescription( - outChMode, - channelMapping, - channelType, - channelIndices, - outOffsetTable - ); - /* Now there is no way back because we modified the channel configuration! */ - - /* Set input channel pointer. The first channel is always at index 0. */ - pInPcm[CENTER_FRONT_CHANNEL] = &pPcmBuf[(frameSize-1)*inStride]; /* Considering input mapping could lead to a invalid pointer - here if the channel is not declared to be a front channel. */ - - /* Set output channel pointer (for this stage). */ - pOutLF = &pPcmBuf[outOffsetTable[LEFT_FRONT_CHANNEL]*offset+(frameSize-1)*outStride]; - pOutRF = &pPcmBuf[outOffsetTable[RIGHT_FRONT_CHANNEL]*offset+(frameSize-1)*outStride]; - - /* 1/0 input: */ - for (sample = 0; sample < frameSize; sample++) { - /* L' = C; R' = C; */ - *pOutLF = *pOutRF = *pInPcm[CENTER_FRONT_CHANNEL]; - - pInPcm[CENTER_FRONT_CHANNEL] -= inStride; - pOutLF -= outStride; pOutRF -= outStride; - } - - /* Prepare for next stage: */ - inStride = outStride; - inChMode = outChMode; - FDKmemcpy(inOffsetTable, outOffsetTable, PCM_DMX_MAX_CHANNELS*sizeof(UCHAR)); - } - -#if (PCM_DMX_MAX_OUT_CHANNELS > 2) - /* SECOND STAGE - Extend with zero channels to achieved the desired number of output channels. */ - if (numOutChannels > TWO_CHANNEL) - { - INT_PCM *pIn[PCM_DMX_MAX_CHANNELS] = { NULL }; - INT_PCM *pOut[PCM_DMX_MAX_CHANNELS] = { NULL }; - AUDIO_CHANNEL_TYPE inChTypes[PCM_DMX_MAX_CHANNELS]; - UCHAR inChIndices[PCM_DMX_MAX_CHANNELS]; - UCHAR numChPerGrp[2][PCM_DMX_MAX_CHANNEL_GROUPS]; - int nContentCh = 0; /* Number of channels with content */ - int nEmptyCh = 0; /* Number of channels with content */ - int ch, chGrp, isCompatible = 1; - - /* Do not change the signalling which is the channel types and indices. - Just reorder and add channels. So first save the input signalling. */ - FDKmemcpy(inChTypes, channelType, PCM_DMX_MAX_CHANNELS*sizeof(AUDIO_CHANNEL_TYPE)); - FDKmemcpy(inChIndices, channelIndices, PCM_DMX_MAX_CHANNELS*sizeof(UCHAR)); - - /* Set this stages output stride and channel mode: */ - outStride = (fInterleaved) ? numOutChannels : 1; - outChMode = outChModeTable[numOutChannels]; - - /* Check if input channel config can be easily mapped to the desired output config. */ - for (chGrp = 0; chGrp < PCM_DMX_MAX_CHANNEL_GROUPS; chGrp += 1) { - numChPerGrp[IN][chGrp] = (inChMode >> (chGrp*4)) & 0xF; - numChPerGrp[OUT][chGrp] = (outChMode >> (chGrp*4)) & 0xF; - - if (numChPerGrp[IN][chGrp] > numChPerGrp[OUT][chGrp]) { - isCompatible = 0; - break; - } - } - - if ( isCompatible ) { - /* Get new channel description and channel - * mapping for the desired output channel mode. */ - getChannelDescription( - outChMode, - channelMapping, - channelType, - channelIndices, - outOffsetTable - ); - /* If the input config has a back center channel but the output - config has not, copy it to left and right (if available). */ - if ( (numChPerGrp[IN][CH_GROUP_REAR]%2) - && !(numChPerGrp[OUT][CH_GROUP_REAR]%2) ) { - if (numChPerGrp[IN][CH_GROUP_REAR] == 1) { - inOffsetTable[RIGHT_REAR_CHANNEL] = inOffsetTable[LEFT_REAR_CHANNEL]; - } else if (numChPerGrp[IN][CH_GROUP_REAR] == 3) { - inOffsetTable[RIGHT_MULTIPRPS_CHANNEL] = inOffsetTable[LEFT_MULTIPRPS_CHANNEL]; - } - } - } - else { - /* Just copy and extend the original config */ - FDKmemcpy(outOffsetTable, inOffsetTable, PCM_DMX_MAX_CHANNELS*sizeof(UCHAR)); - } - - /* Set I/O channel pointer. - Note: The following assignment algorithm clears the channel offset tables. - Thus they can not be used afterwards. */ - for (ch = 0; ch < PCM_DMX_MAX_CHANNELS; ch+=1) { - if ( (outOffsetTable[ch] < 255) - && (inOffsetTable[ch] < 255) ) - { /* Set I/O pointer: */ - pIn[nContentCh] = &pPcmBuf[inOffsetTable[ch]*offset+(frameSize-1)*inStride]; - pOut[nContentCh] = &pPcmBuf[outOffsetTable[ch]*offset+(frameSize-1)*outStride]; - /* Update signalling */ - channelType[outOffsetTable[ch]] = inChTypes[inOffsetTable[ch]]; - channelIndices[outOffsetTable[ch]] = inChIndices[inOffsetTable[ch]]; - inOffsetTable[ch] = 255; - outOffsetTable[ch] = 255; - nContentCh += 1; - } - } - if ( isCompatible ) { - /* Assign the remaining input channels. - This is just a safety appliance. We should never need it. */ - for (ch = 0; ch < PCM_DMX_MAX_CHANNELS; ch+=1) { - if (inOffsetTable[ch] < 255) { - int outCh; - for (outCh = 0 ; outCh < PCM_DMX_MAX_CHANNELS; outCh += 1) { - if (outOffsetTable[outCh] < 255) { - break; - } - } - /* Set I/O pointer: */ - pIn[nContentCh] = &pPcmBuf[inOffsetTable[ch]*offset+(frameSize-1)*inStride]; - pOut[nContentCh] = &pPcmBuf[outOffsetTable[outCh]*offset+(frameSize-1)*outStride]; - /* Update signalling */ - channelType[outOffsetTable[outCh]] = inChTypes[inOffsetTable[ch]]; - channelIndices[outOffsetTable[outCh]] = inChIndices[inOffsetTable[ch]]; - inOffsetTable[ch] = 255; - outOffsetTable[outCh] = 255; - nContentCh += 1; - } - } - /* Set the remaining output channel pointer */ - for (ch = 0; ch < PCM_DMX_MAX_CHANNELS; ch+=1) { - if (outOffsetTable[ch] < 255) { - pOut[nContentCh+nEmptyCh] = &pPcmBuf[outOffsetTable[ch]*offset+(frameSize-1)*outStride]; - /* Expand output signalling */ - channelType[outOffsetTable[ch]] = ACT_NONE; - channelIndices[outOffsetTable[ch]] = nEmptyCh; - outOffsetTable[ch] = 255; - nEmptyCh += 1; - } - } - } - else { - /* Set the remaining output channel pointer */ - for (ch = nContentCh; ch < numOutChannels; ch+=1) { - pOut[ch] = &pPcmBuf[ch*offset+(frameSize-1)*outStride]; - /* Expand output signalling */ - channelType[ch] = ACT_NONE; - channelIndices[ch] = nEmptyCh; - nEmptyCh += 1; - } - } - - /* First copy the channels that have signal */ - for (sample = 0; sample < frameSize; sample+=1) { - INT_PCM tIn[PCM_DMX_MAX_CHANNELS]; - /* Read all channel samples */ - for (ch = 0; ch < nContentCh; ch+=1) { - tIn[ch] = *pIn[ch]; - pIn[ch] -= inStride; - } - /* Write all channel samples */ - for (ch = 0; ch < nContentCh; ch+=1) { - *pOut[ch] = tIn[ch]; - pOut[ch] -= outStride; - } - } - - /* Clear all the other channels */ - for (sample = 0; sample < frameSize; sample++) { - for (ch = nContentCh; ch < numOutChannels; ch+=1) { - *pOut[ch] = (INT_PCM)0; - pOut[ch] -= outStride; - } - } - } -#endif /* if (PCM_DMX_MAX_OUT_CHANNELS > 2) */ - - /* update the number of output channels */ - *nChannels = numOutChannels; - } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ - else -#endif /* PCM_CHANNEL_EXTENSION_ENABLE */ - if ( numInChannels == numOutChannels ) - { - /* Don't need to change the channel description here */ - - switch (numInChannels) - { - case 2: - { /* Set up channel pointer */ - INT_PCM *pInPcm[PCM_DMX_MAX_CHANNELS]; - INT_PCM *pOutL, *pOutR; - FIXP_DMX flev; - - UINT sample; - int inStride, outStride, offset; - - if (fInterleaved) { - inStride = numInChannels; - outStride = 2; /* fixed !!! (below stereo is donwmixed to mono if required */ - offset = 1; /* Channel specific offset factor */ - } else { - inStride = 1; - outStride = 1; - offset = frameSize; /* Channel specific offset factor */ - } - - /* Set input channel pointer */ - pInPcm[LEFT_FRONT_CHANNEL] = &pPcmBuf[inOffsetTable[LEFT_FRONT_CHANNEL]*offset]; - pInPcm[RIGHT_FRONT_CHANNEL] = &pPcmBuf[inOffsetTable[RIGHT_FRONT_CHANNEL]*offset]; - - /* Set output channel pointer (same as input) */ - pOutL = pInPcm[LEFT_FRONT_CHANNEL]; - pOutR = pInPcm[RIGHT_FRONT_CHANNEL]; - - /* Set downmix levels: */ - flev = FL2FXCONST_DMX(0.70710678f); - /* 2/0 input: */ - switch (dualChannelMode) - { - case CH1_MODE: /* L' = 0.707 * Ch1; R' = 0.707 * Ch1 */ - for (sample = 0; sample < frameSize; sample++) { - *pOutL = *pOutR = - (INT_PCM)SATURATE_RIGHT_SHIFT(fMult((FIXP_PCM)*pInPcm[LEFT_FRONT_CHANNEL], flev), DFRACT_BITS-SAMPLE_BITS, SAMPLE_BITS); - - pInPcm[LEFT_FRONT_CHANNEL] += inStride; - pOutL += outStride; pOutR += outStride; - } - break; - case CH2_MODE: /* L' = 0.707 * Ch2; R' = 0.707 * Ch2 */ - for (sample = 0; sample < frameSize; sample++) { - *pOutL = *pOutR = - (INT_PCM)SATURATE_RIGHT_SHIFT(fMult((FIXP_PCM)*pInPcm[RIGHT_FRONT_CHANNEL], flev), DFRACT_BITS-SAMPLE_BITS, SAMPLE_BITS); - - pInPcm[RIGHT_FRONT_CHANNEL] += inStride; - pOutL += outStride; pOutR += outStride; - } - break; - case MIXED_MODE: /* L' = 0.5*Ch1 + 0.5*Ch2; R' = 0.5*Ch1 + 0.5*Ch2 */ - for (sample = 0; sample < frameSize; sample++) { - *pOutL = *pOutR = (*pInPcm[LEFT_FRONT_CHANNEL] >> 1) + (*pInPcm[RIGHT_FRONT_CHANNEL] >> 1); - - pInPcm[LEFT_FRONT_CHANNEL] += inStride; pInPcm[RIGHT_FRONT_CHANNEL] += inStride; - pOutL += outStride; pOutR += outStride; - } - break; - default: - case STEREO_MODE: - /* nothing to do */ - break; - } - } - break; - - default: - /* nothing to do */ - break; - } - } - - return (errorStatus); -} - - -/** Close an instance of the PCM downmix module. - * @param [inout] Pointer to a buffer containing the handle of the instance. - * @returns Returns an error code. - **/ -PCMDMX_ERROR pcmDmx_Close ( - HANDLE_PCM_DOWNMIX *pSelf - ) -{ - if (pSelf == NULL) { - return (PCMDMX_INVALID_HANDLE); - } - - FreePcmDmxInstance( pSelf ); - *pSelf = NULL; - - return (PCMDMX_OK); -} - - -/** Get library info for this module. - * @param [out] Pointer to an allocated LIB_INFO structure. - * @returns Returns an error code. - */ -PCMDMX_ERROR pcmDmx_GetLibInfo( LIB_INFO *info ) -{ - int i; - - if (info == NULL) { - return PCMDMX_INVALID_ARGUMENT; - } - - /* Search for next free tab */ - for (i = 0; i < FDK_MODULE_LAST; i++) { - if (info[i].module_id == FDK_NONE) break; - } - if (i == FDK_MODULE_LAST) { - return PCMDMX_UNKNOWN; - } - - /* Add the library info */ - info[i].module_id = FDK_PCMDMX; - info[i].version = LIB_VERSION(PCMDMX_LIB_VL0, PCMDMX_LIB_VL1, PCMDMX_LIB_VL2); - LIB_VERSION_STRING(info+i); - info[i].build_date = PCMDMX_LIB_BUILD_DATE; - info[i].build_time = PCMDMX_LIB_BUILD_TIME; - info[i].title = PCMDMX_LIB_TITLE; - - /* Set flags */ - info[i].flags = 0 -#ifdef PCM_DOWNMIX_ENABLE - | CAPF_DMX_BLIND /* At least blind downmixing is possible */ - #ifdef PCE_METADATA_ENABLE - | CAPF_DMX_PCE /* Guided downmix with data from MPEG-2/4 Program Config Elements (PCE). */ - #ifdef ARIB_MIXDOWN_ENABLE - | CAPF_DMX_ARIB /* PCE guided downmix with slightly different equations and levels. */ - #endif - #endif /* PCE_METADATA_ENABLE */ - #ifdef DSE_METADATA_ENABLE - | CAPF_DMX_DVB /* Guided downmix with data from DVB ancillary data fields. */ - #endif -#endif /* PCM_DOWNMIX_ENABLE */ -#ifdef PCM_CHANNEL_EXTENSION_ENABLE - | CAPF_DMX_CH_EXP /* Simple upmixing by dublicating channels or adding zero channels. */ -#endif - ; - - /* Add lib info for FDK tools (if not yet done). */ - FDK_toolsGetLibInfo(info); - - return PCMDMX_OK; -} - - - |