/* ----------------------------------------------------------------------------------------------------------- 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. *******************************************************************************/ #include #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____ */ 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) { ALOGE("b/23876444"); 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; }