2022-04-03 10:27:06 +00:00
/*
FLAC audio decoder . Choice of public domain or MIT - 0. See license statements at the end of this file .
dr_flac - v0 .12 .37 - 2022 - 02 - 12
David Reid - mackron @ gmail . com
GitHub : https : //github.com/mackron/dr_libs
*/
/*
RELEASE NOTES - v0 .12 .0
= = = = = = = = = = = = = = = = = = = = = = =
Version 0.12 .0 has breaking API changes including changes to the existing API and the removal of deprecated APIs .
Improved Client - Defined Memory Allocation
- - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - -
The main change with this release is the addition of a more flexible way of implementing custom memory allocation routines . The
existing system of DRFLAC_MALLOC , DRFLAC_REALLOC and DRFLAC_FREE are still in place and will be used by default when no custom
allocation callbacks are specified .
To use the new system , you pass in a pointer to a drflac_allocation_callbacks object to drflac_open ( ) and family , like this :
void * my_malloc ( size_t sz , void * pUserData )
{
return malloc ( sz ) ;
}
void * my_realloc ( void * p , size_t sz , void * pUserData )
{
return realloc ( p , sz ) ;
}
void my_free ( void * p , void * pUserData )
{
free ( p ) ;
}
. . .
drflac_allocation_callbacks allocationCallbacks ;
allocationCallbacks . pUserData = & myData ;
allocationCallbacks . onMalloc = my_malloc ;
allocationCallbacks . onRealloc = my_realloc ;
allocationCallbacks . onFree = my_free ;
drflac * pFlac = drflac_open_file ( " my_file.flac " , & allocationCallbacks ) ;
The advantage of this new system is that it allows you to specify user data which will be passed in to the allocation routines .
Passing in null for the allocation callbacks object will cause dr_flac to use defaults which is the same as DRFLAC_MALLOC ,
DRFLAC_REALLOC and DRFLAC_FREE and the equivalent of how it worked in previous versions .
Every API that opens a drflac object now takes this extra parameter . These include the following :
drflac_open ( )
drflac_open_relaxed ( )
drflac_open_with_metadata ( )
drflac_open_with_metadata_relaxed ( )
drflac_open_file ( )
drflac_open_file_with_metadata ( )
drflac_open_memory ( )
drflac_open_memory_with_metadata ( )
drflac_open_and_read_pcm_frames_s32 ( )
drflac_open_and_read_pcm_frames_s16 ( )
drflac_open_and_read_pcm_frames_f32 ( )
drflac_open_file_and_read_pcm_frames_s32 ( )
drflac_open_file_and_read_pcm_frames_s16 ( )
drflac_open_file_and_read_pcm_frames_f32 ( )
drflac_open_memory_and_read_pcm_frames_s32 ( )
drflac_open_memory_and_read_pcm_frames_s16 ( )
drflac_open_memory_and_read_pcm_frames_f32 ( )
Optimizations
- - - - - - - - - - - - -
Seeking performance has been greatly improved . A new binary search based seeking algorithm has been introduced which significantly
improves performance over the brute force method which was used when no seek table was present . Seek table based seeking also takes
advantage of the new binary search seeking system to further improve performance there as well . Note that this depends on CRC which
means it will be disabled when DR_FLAC_NO_CRC is used .
The SSE4 .1 pipeline has been cleaned up and optimized . You should see some improvements with decoding speed of 24 - bit files in
particular . 16 - bit streams should also see some improvement .
drflac_read_pcm_frames_s16 ( ) has been optimized . Previously this sat on top of drflac_read_pcm_frames_s32 ( ) and performed it ' s s32
to s16 conversion in a second pass . This is now all done in a single pass . This includes SSE2 and ARM NEON optimized paths .
A minor optimization has been implemented for drflac_read_pcm_frames_s32 ( ) . This will now use an SSE2 optimized pipeline for stereo
channel reconstruction which is the last part of the decoding process .
The ARM build has seen a few improvements . The CLZ ( count leading zeroes ) and REV ( byte swap ) instructions are now used when
compiling with GCC and Clang which is achieved using inline assembly . The CLZ instruction requires ARM architecture version 5 at
compile time and the REV instruction requires ARM architecture version 6.
An ARM NEON optimized pipeline has been implemented . To enable this you ' ll need to add - mfpu = neon to the command line when compiling .
Removed APIs
- - - - - - - - - - - -
The following APIs were deprecated in version 0.11 .0 and have been completely removed in version 0.12 .0 :
drflac_read_s32 ( ) - > drflac_read_pcm_frames_s32 ( )
drflac_read_s16 ( ) - > drflac_read_pcm_frames_s16 ( )
drflac_read_f32 ( ) - > drflac_read_pcm_frames_f32 ( )
drflac_seek_to_sample ( ) - > drflac_seek_to_pcm_frame ( )
drflac_open_and_decode_s32 ( ) - > drflac_open_and_read_pcm_frames_s32 ( )
drflac_open_and_decode_s16 ( ) - > drflac_open_and_read_pcm_frames_s16 ( )
drflac_open_and_decode_f32 ( ) - > drflac_open_and_read_pcm_frames_f32 ( )
drflac_open_and_decode_file_s32 ( ) - > drflac_open_file_and_read_pcm_frames_s32 ( )
drflac_open_and_decode_file_s16 ( ) - > drflac_open_file_and_read_pcm_frames_s16 ( )
drflac_open_and_decode_file_f32 ( ) - > drflac_open_file_and_read_pcm_frames_f32 ( )
drflac_open_and_decode_memory_s32 ( ) - > drflac_open_memory_and_read_pcm_frames_s32 ( )
drflac_open_and_decode_memory_s16 ( ) - > drflac_open_memory_and_read_pcm_frames_s16 ( )
drflac_open_and_decode_memory_f32 ( ) - > drflac_open_memroy_and_read_pcm_frames_f32 ( )
Prior versions of dr_flac operated on a per - sample basis whereas now it operates on PCM frames . The removed APIs all relate
to the old per - sample APIs . You now need to use the " pcm_frame " versions .
*/
/*
Introduction
= = = = = = = = = = = =
dr_flac is a single file library . To use it , do something like the following in one . c file .
` ` ` c
# define DR_FLAC_IMPLEMENTATION
# include "dr_flac.h"
` ` `
You can then # include this file in other parts of the program as you would with any other header file . To decode audio data , do something like the following :
` ` ` c
drflac * pFlac = drflac_open_file ( " MySong.flac " , NULL ) ;
if ( pFlac = = NULL ) {
// Failed to open FLAC file
}
drflac_int32 * pSamples = malloc ( pFlac - > totalPCMFrameCount * pFlac - > channels * sizeof ( drflac_int32 ) ) ;
drflac_uint64 numberOfInterleavedSamplesActuallyRead = drflac_read_pcm_frames_s32 ( pFlac , pFlac - > totalPCMFrameCount , pSamples ) ;
` ` `
The drflac object represents the decoder . It is a transparent type so all the information you need , such as the number of channels and the bits per sample ,
should be directly accessible - just make sure you don ' t change their values . Samples are always output as interleaved signed 32 - bit PCM . In the example above
a native FLAC stream was opened , however dr_flac has seamless support for Ogg encapsulated FLAC streams as well .
You do not need to decode the entire stream in one go - you just specify how many samples you ' d like at any given time and the decoder will give you as many
samples as it can , up to the amount requested . Later on when you need the next batch of samples , just call it again . Example :
` ` ` c
while ( drflac_read_pcm_frames_s32 ( pFlac , chunkSizeInPCMFrames , pChunkSamples ) > 0 ) {
do_something ( ) ;
}
` ` `
You can seek to a specific PCM frame with ` drflac_seek_to_pcm_frame ( ) ` .
If you just want to quickly decode an entire FLAC file in one go you can do something like this :
` ` ` c
unsigned int channels ;
unsigned int sampleRate ;
drflac_uint64 totalPCMFrameCount ;
drflac_int32 * pSampleData = drflac_open_file_and_read_pcm_frames_s32 ( " MySong.flac " , & channels , & sampleRate , & totalPCMFrameCount , NULL ) ;
if ( pSampleData = = NULL ) {
// Failed to open and decode FLAC file.
}
. . .
drflac_free ( pSampleData , NULL ) ;
` ` `
You can read samples as signed 16 - bit integer and 32 - bit floating - point PCM with the * _s16 ( ) and * _f32 ( ) family of APIs respectively , but note that these
should be considered lossy .
If you need access to metadata ( album art , etc . ) , use ` drflac_open_with_metadata ( ) ` , ` drflac_open_file_with_metdata ( ) ` or ` drflac_open_memory_with_metadata ( ) ` .
The rationale for keeping these APIs separate is that they ' re slightly slower than the normal versions and also just a little bit harder to use . dr_flac
reports metadata to the application through the use of a callback , and every metadata block is reported before ` drflac_open_with_metdata ( ) ` returns .
The main opening APIs ( ` drflac_open ( ) ` , etc . ) will fail if the header is not present . The presents a problem in certain scenarios such as broadcast style
streams or internet radio where the header may not be present because the user has started playback mid - stream . To handle this , use the relaxed APIs :
` drflac_open_relaxed ( ) `
` drflac_open_with_metadata_relaxed ( ) `
It is not recommended to use these APIs for file based streams because a missing header would usually indicate a corrupt or perverse file . In addition , these
APIs can take a long time to initialize because they may need to spend a lot of time finding the first frame .
Build Options
= = = = = = = = = = = = =
# define these options before including this file.
# define DR_FLAC_NO_STDIO
Disable ` drflac_open_file ( ) ` and family .
# define DR_FLAC_NO_OGG
Disables support for Ogg / FLAC streams .
# define DR_FLAC_BUFFER_SIZE <number>
Defines the size of the internal buffer to store data from onRead ( ) . This buffer is used to reduce the number of calls back to the client for more data .
Larger values means more memory , but better performance . My tests show diminishing returns after about 4 KB ( which is the default ) . Consider reducing this if
you have a very efficient implementation of onRead ( ) , or increase it if it ' s very inefficient . Must be a multiple of 8.
# define DR_FLAC_NO_CRC
Disables CRC checks . This will offer a performance boost when CRC is unnecessary . This will disable binary search seeking . When seeking , the seek table will
be used if available . Otherwise the seek will be performed using brute force .
# define DR_FLAC_NO_SIMD
Disables SIMD optimizations ( SSE on x86 / x64 architectures , NEON on ARM architectures ) . Use this if you are having compatibility issues with your compiler .
Notes
= = = = =
- dr_flac does not support changing the sample rate nor channel count mid stream .
- dr_flac is not thread - safe , but its APIs can be called from any thread so long as you do your own synchronization .
- When using Ogg encapsulation , a corrupted metadata block will result in ` drflac_open_with_metadata ( ) ` and ` drflac_open ( ) ` returning inconsistent samples due
to differences in corrupted stream recorvery logic between the two APIs .
*/
# ifndef dr_flac_h
# define dr_flac_h
# ifdef __cplusplus
extern " C " {
# endif
# define DRFLAC_STRINGIFY(x) #x
# define DRFLAC_XSTRINGIFY(x) DRFLAC_STRINGIFY(x)
# define DRFLAC_VERSION_MAJOR 0
# define DRFLAC_VERSION_MINOR 12
# define DRFLAC_VERSION_REVISION 37
# define DRFLAC_VERSION_STRING DRFLAC_XSTRINGIFY(DRFLAC_VERSION_MAJOR) "." DRFLAC_XSTRINGIFY(DRFLAC_VERSION_MINOR) "." DRFLAC_XSTRINGIFY(DRFLAC_VERSION_REVISION)
# include <stddef.h> /* For size_t. */
/* Sized types. */
typedef signed char drflac_int8 ;
typedef unsigned char drflac_uint8 ;
typedef signed short drflac_int16 ;
typedef unsigned short drflac_uint16 ;
typedef signed int drflac_int32 ;
typedef unsigned int drflac_uint32 ;
# if defined(_MSC_VER) && !defined(__clang__)
typedef signed __int64 drflac_int64 ;
typedef unsigned __int64 drflac_uint64 ;
# else
# if defined(__clang__) || (defined(__GNUC__) && (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 6)))
# pragma GCC diagnostic push
# pragma GCC diagnostic ignored "-Wlong-long"
# if defined(__clang__)
# pragma GCC diagnostic ignored "-Wc++11-long-long"
# endif
# endif
typedef signed long long drflac_int64 ;
typedef unsigned long long drflac_uint64 ;
# if defined(__clang__) || (defined(__GNUC__) && (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 6)))
# pragma GCC diagnostic pop
# endif
# endif
# if defined(__LP64__) || defined(_WIN64) || (defined(__x86_64__) && !defined(__ILP32__)) || defined(_M_X64) || defined(__ia64) || defined(_M_IA64) || defined(__aarch64__) || defined(_M_ARM64) || defined(__powerpc64__)
typedef drflac_uint64 drflac_uintptr ;
# else
typedef drflac_uint32 drflac_uintptr ;
# endif
typedef drflac_uint8 drflac_bool8 ;
typedef drflac_uint32 drflac_bool32 ;
# define DRFLAC_TRUE 1
# define DRFLAC_FALSE 0
# if !defined(DRFLAC_API)
# if defined(DRFLAC_DLL)
# if defined(_WIN32)
# define DRFLAC_DLL_IMPORT __declspec(dllimport)
# define DRFLAC_DLL_EXPORT __declspec(dllexport)
# define DRFLAC_DLL_PRIVATE static
# else
# if defined(__GNUC__) && __GNUC__ >= 4
# define DRFLAC_DLL_IMPORT __attribute__((visibility("default")))
# define DRFLAC_DLL_EXPORT __attribute__((visibility("default")))
# define DRFLAC_DLL_PRIVATE __attribute__((visibility("hidden")))
# else
# define DRFLAC_DLL_IMPORT
# define DRFLAC_DLL_EXPORT
# define DRFLAC_DLL_PRIVATE static
# endif
# endif
# if defined(DR_FLAC_IMPLEMENTATION) || defined(DRFLAC_IMPLEMENTATION)
# define DRFLAC_API DRFLAC_DLL_EXPORT
# else
# define DRFLAC_API DRFLAC_DLL_IMPORT
# endif
# define DRFLAC_PRIVATE DRFLAC_DLL_PRIVATE
# else
# define DRFLAC_API extern
# define DRFLAC_PRIVATE static
# endif
# endif
# if defined(_MSC_VER) && _MSC_VER >= 1700 /* Visual Studio 2012 */
# define DRFLAC_DEPRECATED __declspec(deprecated)
# elif (defined(__GNUC__) && __GNUC__ >= 4) /* GCC 4 */
# define DRFLAC_DEPRECATED __attribute__((deprecated))
# elif defined(__has_feature) /* Clang */
# if __has_feature(attribute_deprecated)
# define DRFLAC_DEPRECATED __attribute__((deprecated))
# else
# define DRFLAC_DEPRECATED
# endif
# else
# define DRFLAC_DEPRECATED
# endif
DRFLAC_API void drflac_version ( drflac_uint32 * pMajor , drflac_uint32 * pMinor , drflac_uint32 * pRevision ) ;
DRFLAC_API const char * drflac_version_string ( void ) ;
/*
As data is read from the client it is placed into an internal buffer for fast access . This controls the size of that buffer . Larger values means more speed ,
but also more memory . In my testing there is diminishing returns after about 4 KB , but you can fiddle with this to suit your own needs . Must be a multiple of 8.
*/
# ifndef DR_FLAC_BUFFER_SIZE
# define DR_FLAC_BUFFER_SIZE 4096
# endif
/* Check if we can enable 64-bit optimizations. */
# if defined(_WIN64) || defined(_LP64) || defined(__LP64__)
# define DRFLAC_64BIT
# endif
# ifdef DRFLAC_64BIT
typedef drflac_uint64 drflac_cache_t ;
# else
typedef drflac_uint32 drflac_cache_t ;
# endif
/* The various metadata block types. */
# define DRFLAC_METADATA_BLOCK_TYPE_STREAMINFO 0
# define DRFLAC_METADATA_BLOCK_TYPE_PADDING 1
# define DRFLAC_METADATA_BLOCK_TYPE_APPLICATION 2
# define DRFLAC_METADATA_BLOCK_TYPE_SEEKTABLE 3
# define DRFLAC_METADATA_BLOCK_TYPE_VORBIS_COMMENT 4
# define DRFLAC_METADATA_BLOCK_TYPE_CUESHEET 5
# define DRFLAC_METADATA_BLOCK_TYPE_PICTURE 6
# define DRFLAC_METADATA_BLOCK_TYPE_INVALID 127
/* The various picture types specified in the PICTURE block. */
# define DRFLAC_PICTURE_TYPE_OTHER 0
# define DRFLAC_PICTURE_TYPE_FILE_ICON 1
# define DRFLAC_PICTURE_TYPE_OTHER_FILE_ICON 2
# define DRFLAC_PICTURE_TYPE_COVER_FRONT 3
# define DRFLAC_PICTURE_TYPE_COVER_BACK 4
# define DRFLAC_PICTURE_TYPE_LEAFLET_PAGE 5
# define DRFLAC_PICTURE_TYPE_MEDIA 6
# define DRFLAC_PICTURE_TYPE_LEAD_ARTIST 7
# define DRFLAC_PICTURE_TYPE_ARTIST 8
# define DRFLAC_PICTURE_TYPE_CONDUCTOR 9
# define DRFLAC_PICTURE_TYPE_BAND 10
# define DRFLAC_PICTURE_TYPE_COMPOSER 11
# define DRFLAC_PICTURE_TYPE_LYRICIST 12
# define DRFLAC_PICTURE_TYPE_RECORDING_LOCATION 13
# define DRFLAC_PICTURE_TYPE_DURING_RECORDING 14
# define DRFLAC_PICTURE_TYPE_DURING_PERFORMANCE 15
# define DRFLAC_PICTURE_TYPE_SCREEN_CAPTURE 16
# define DRFLAC_PICTURE_TYPE_BRIGHT_COLORED_FISH 17
# define DRFLAC_PICTURE_TYPE_ILLUSTRATION 18
# define DRFLAC_PICTURE_TYPE_BAND_LOGOTYPE 19
# define DRFLAC_PICTURE_TYPE_PUBLISHER_LOGOTYPE 20
typedef enum
{
drflac_container_native ,
drflac_container_ogg ,
drflac_container_unknown
} drflac_container ;
typedef enum
{
drflac_seek_origin_start ,
drflac_seek_origin_current
} drflac_seek_origin ;
/* Packing is important on this structure because we map this directly to the raw data within the SEEKTABLE metadata block. */
# pragma pack(2)
typedef struct
{
drflac_uint64 firstPCMFrame ;
drflac_uint64 flacFrameOffset ; /* The offset from the first byte of the header of the first frame. */
drflac_uint16 pcmFrameCount ;
} drflac_seekpoint ;
# pragma pack()
typedef struct
{
drflac_uint16 minBlockSizeInPCMFrames ;
drflac_uint16 maxBlockSizeInPCMFrames ;
drflac_uint32 minFrameSizeInPCMFrames ;
drflac_uint32 maxFrameSizeInPCMFrames ;
drflac_uint32 sampleRate ;
drflac_uint8 channels ;
drflac_uint8 bitsPerSample ;
drflac_uint64 totalPCMFrameCount ;
drflac_uint8 md5 [ 16 ] ;
} drflac_streaminfo ;
typedef struct
{
/*
The metadata type . Use this to know how to interpret the data below . Will be set to one of the
DRFLAC_METADATA_BLOCK_TYPE_ * tokens .
*/
drflac_uint32 type ;
/*
A pointer to the raw data . This points to a temporary buffer so don ' t hold on to it . It ' s best to
not modify the contents of this buffer . Use the structures below for more meaningful and structured
information about the metadata . It ' s possible for this to be null .
*/
const void * pRawData ;
/* The size in bytes of the block and the buffer pointed to by pRawData if it's non-NULL. */
drflac_uint32 rawDataSize ;
union
{
drflac_streaminfo streaminfo ;
struct
{
int unused ;
} padding ;
struct
{
drflac_uint32 id ;
const void * pData ;
drflac_uint32 dataSize ;
} application ;
struct
{
drflac_uint32 seekpointCount ;
const drflac_seekpoint * pSeekpoints ;
} seektable ;
struct
{
drflac_uint32 vendorLength ;
const char * vendor ;
drflac_uint32 commentCount ;
const void * pComments ;
} vorbis_comment ;
struct
{
char catalog [ 128 ] ;
drflac_uint64 leadInSampleCount ;
drflac_bool32 isCD ;
drflac_uint8 trackCount ;
const void * pTrackData ;
} cuesheet ;
struct
{
drflac_uint32 type ;
drflac_uint32 mimeLength ;
const char * mime ;
drflac_uint32 descriptionLength ;
const char * description ;
drflac_uint32 width ;
drflac_uint32 height ;
drflac_uint32 colorDepth ;
drflac_uint32 indexColorCount ;
drflac_uint32 pictureDataSize ;
const drflac_uint8 * pPictureData ;
} picture ;
} data ;
} drflac_metadata ;
/*
Callback for when data needs to be read from the client .
Parameters
- - - - - - - - - -
pUserData ( in )
The user data that was passed to drflac_open ( ) and family .
pBufferOut ( out )
The output buffer .
bytesToRead ( in )
The number of bytes to read .
Return Value
- - - - - - - - - - - -
The number of bytes actually read .
Remarks
- - - - - - -
A return value of less than bytesToRead indicates the end of the stream . Do _not_ return from this callback until either the entire bytesToRead is filled or
you have reached the end of the stream .
*/
typedef size_t ( * drflac_read_proc ) ( void * pUserData , void * pBufferOut , size_t bytesToRead ) ;
/*
Callback for when data needs to be seeked .
Parameters
- - - - - - - - - -
pUserData ( in )
The user data that was passed to drflac_open ( ) and family .
offset ( in )
The number of bytes to move , relative to the origin . Will never be negative .
origin ( in )
The origin of the seek - the current position or the start of the stream .
Return Value
- - - - - - - - - - - -
Whether or not the seek was successful .
Remarks
- - - - - - -
The offset will never be negative . Whether or not it is relative to the beginning or current position is determined by the " origin " parameter which will be
either drflac_seek_origin_start or drflac_seek_origin_current .
When seeking to a PCM frame using drflac_seek_to_pcm_frame ( ) , dr_flac may call this with an offset beyond the end of the FLAC stream . This needs to be detected
and handled by returning DRFLAC_FALSE .
*/
typedef drflac_bool32 ( * drflac_seek_proc ) ( void * pUserData , int offset , drflac_seek_origin origin ) ;
/*
Callback for when a metadata block is read .
Parameters
- - - - - - - - - -
pUserData ( in )
The user data that was passed to drflac_open ( ) and family .
pMetadata ( in )
A pointer to a structure containing the data of the metadata block .
Remarks
- - - - - - -
Use pMetadata - > type to determine which metadata block is being handled and how to read the data . This
will be set to one of the DRFLAC_METADATA_BLOCK_TYPE_ * tokens .
*/
typedef void ( * drflac_meta_proc ) ( void * pUserData , drflac_metadata * pMetadata ) ;
typedef struct
{
void * pUserData ;
void * ( * onMalloc ) ( size_t sz , void * pUserData ) ;
void * ( * onRealloc ) ( void * p , size_t sz , void * pUserData ) ;
void ( * onFree ) ( void * p , void * pUserData ) ;
} drflac_allocation_callbacks ;
/* Structure for internal use. Only used for decoders opened with drflac_open_memory. */
typedef struct
{
const drflac_uint8 * data ;
size_t dataSize ;
size_t currentReadPos ;
} drflac__memory_stream ;
/* Structure for internal use. Used for bit streaming. */
typedef struct
{
/* The function to call when more data needs to be read. */
drflac_read_proc onRead ;
/* The function to call when the current read position needs to be moved. */
drflac_seek_proc onSeek ;
/* The user data to pass around to onRead and onSeek. */
void * pUserData ;
/*
The number of unaligned bytes in the L2 cache . This will always be 0 until the end of the stream is hit . At the end of the
stream there will be a number of bytes that don ' t cleanly fit in an L1 cache line , so we use this variable to know whether
or not the bistreamer needs to run on a slower path to read those last bytes . This will never be more than sizeof ( drflac_cache_t ) .
*/
size_t unalignedByteCount ;
/* The content of the unaligned bytes. */
drflac_cache_t unalignedCache ;
/* The index of the next valid cache line in the "L2" cache. */
drflac_uint32 nextL2Line ;
/* The number of bits that have been consumed by the cache. This is used to determine how many valid bits are remaining. */
drflac_uint32 consumedBits ;
/*
The cached data which was most recently read from the client . There are two levels of cache . Data flows as such :
Client - > L2 - > L1 . The L2 - > L1 movement is aligned and runs on a fast path in just a few instructions .
*/
drflac_cache_t cacheL2 [ DR_FLAC_BUFFER_SIZE / sizeof ( drflac_cache_t ) ] ;
drflac_cache_t cache ;
/*
CRC - 16. This is updated whenever bits are read from the bit stream . Manually set this to 0 to reset the CRC . For FLAC , this
is reset to 0 at the beginning of each frame .
*/
drflac_uint16 crc16 ;
drflac_cache_t crc16Cache ; /* A cache for optimizing CRC calculations. This is filled when when the L1 cache is reloaded. */
drflac_uint32 crc16CacheIgnoredBytes ; /* The number of bytes to ignore when updating the CRC-16 from the CRC-16 cache. */
} drflac_bs ;
typedef struct
{
/* The type of the subframe: SUBFRAME_CONSTANT, SUBFRAME_VERBATIM, SUBFRAME_FIXED or SUBFRAME_LPC. */
drflac_uint8 subframeType ;
/* The number of wasted bits per sample as specified by the sub-frame header. */
drflac_uint8 wastedBitsPerSample ;
/* The order to use for the prediction stage for SUBFRAME_FIXED and SUBFRAME_LPC. */
drflac_uint8 lpcOrder ;
/* A pointer to the buffer containing the decoded samples in the subframe. This pointer is an offset from drflac::pExtraData. */
drflac_int32 * pSamplesS32 ;
} drflac_subframe ;
typedef struct
{
/*
If the stream uses variable block sizes , this will be set to the index of the first PCM frame . If fixed block sizes are used , this will
always be set to 0. This is 64 - bit because the decoded PCM frame number will be 36 bits .
*/
drflac_uint64 pcmFrameNumber ;
/*
If the stream uses fixed block sizes , this will be set to the frame number . If variable block sizes are used , this will always be 0. This
is 32 - bit because in fixed block sizes , the maximum frame number will be 31 bits .
*/
drflac_uint32 flacFrameNumber ;
/* The sample rate of this frame. */
drflac_uint32 sampleRate ;
/* The number of PCM frames in each sub-frame within this frame. */
drflac_uint16 blockSizeInPCMFrames ;
/*
The channel assignment of this frame . This is not always set to the channel count . If interchannel decorrelation is being used this
will be set to DRFLAC_CHANNEL_ASSIGNMENT_LEFT_SIDE , DRFLAC_CHANNEL_ASSIGNMENT_RIGHT_SIDE or DRFLAC_CHANNEL_ASSIGNMENT_MID_SIDE .
*/
drflac_uint8 channelAssignment ;
/* The number of bits per sample within this frame. */
drflac_uint8 bitsPerSample ;
/* The frame's CRC. */
drflac_uint8 crc8 ;
} drflac_frame_header ;
typedef struct
{
/* The header. */
drflac_frame_header header ;
/*
The number of PCM frames left to be read in this FLAC frame . This is initially set to the block size . As PCM frames are read ,
this will be decremented . When it reaches 0 , the decoder will see this frame as fully consumed and load the next frame .
*/
drflac_uint32 pcmFramesRemaining ;
/* The list of sub-frames within the frame. There is one sub-frame for each channel, and there's a maximum of 8 channels. */
drflac_subframe subframes [ 8 ] ;
} drflac_frame ;
typedef struct
{
/* The function to call when a metadata block is read. */
drflac_meta_proc onMeta ;
/* The user data posted to the metadata callback function. */
void * pUserDataMD ;
/* Memory allocation callbacks. */
drflac_allocation_callbacks allocationCallbacks ;
/* The sample rate. Will be set to something like 44100. */
drflac_uint32 sampleRate ;
/*
The number of channels . This will be set to 1 for monaural streams , 2 for stereo , etc . Maximum 8. This is set based on the
value specified in the STREAMINFO block .
*/
drflac_uint8 channels ;
/* The bits per sample. Will be set to something like 16, 24, etc. */
drflac_uint8 bitsPerSample ;
/* The maximum block size, in samples. This number represents the number of samples in each channel (not combined). */
drflac_uint16 maxBlockSizeInPCMFrames ;
/*
The total number of PCM Frames making up the stream . Can be 0 in which case it ' s still a valid stream , but just means
the total PCM frame count is unknown . Likely the case with streams like internet radio .
*/
drflac_uint64 totalPCMFrameCount ;
/* The container type. This is set based on whether or not the decoder was opened from a native or Ogg stream. */
drflac_container container ;
/* The number of seekpoints in the seektable. */
drflac_uint32 seekpointCount ;
/* Information about the frame the decoder is currently sitting on. */
drflac_frame currentFLACFrame ;
/* The index of the PCM frame the decoder is currently sitting on. This is only used for seeking. */
drflac_uint64 currentPCMFrame ;
/* The position of the first FLAC frame in the stream. This is only ever used for seeking. */
drflac_uint64 firstFLACFramePosInBytes ;
/* A hack to avoid a malloc() when opening a decoder with drflac_open_memory(). */
drflac__memory_stream memoryStream ;
/* A pointer to the decoded sample data. This is an offset of pExtraData. */
drflac_int32 * pDecodedSamples ;
/* A pointer to the seek table. This is an offset of pExtraData, or NULL if there is no seek table. */
drflac_seekpoint * pSeekpoints ;
/* Internal use only. Only used with Ogg containers. Points to a drflac_oggbs object. This is an offset of pExtraData. */
void * _oggbs ;
/* Internal use only. Used for profiling and testing different seeking modes. */
drflac_bool32 _noSeekTableSeek : 1 ;
drflac_bool32 _noBinarySearchSeek : 1 ;
drflac_bool32 _noBruteForceSeek : 1 ;
/* The bit streamer. The raw FLAC data is fed through this object. */
drflac_bs bs ;
/* Variable length extra data. We attach this to the end of the object so we can avoid unnecessary mallocs. */
drflac_uint8 pExtraData [ 1 ] ;
} drflac ;
/*
Opens a FLAC decoder .
Parameters
- - - - - - - - - -
onRead ( in )
The function to call when data needs to be read from the client .
onSeek ( in )
The function to call when the read position of the client data needs to move .
pUserData ( in , optional )
A pointer to application defined data that will be passed to onRead and onSeek .
pAllocationCallbacks ( in , optional )
A pointer to application defined callbacks for managing memory allocations .
Return Value
- - - - - - - - - - - -
Returns a pointer to an object representing the decoder .
Remarks
- - - - - - -
Close the decoder with ` drflac_close ( ) ` .
` pAllocationCallbacks ` can be NULL in which case it will use ` DRFLAC_MALLOC ` , ` DRFLAC_REALLOC ` and ` DRFLAC_FREE ` .
This function will automatically detect whether or not you are attempting to open a native or Ogg encapsulated FLAC , both of which should work seamlessly
without any manual intervention . Ogg encapsulation also works with multiplexed streams which basically means it can play FLAC encoded audio tracks in videos .
This is the lowest level function for opening a FLAC stream . You can also use ` drflac_open_file ( ) ` and ` drflac_open_memory ( ) ` to open the stream from a file or
from a block of memory respectively .
The STREAMINFO block must be present for this to succeed . Use ` drflac_open_relaxed ( ) ` to open a FLAC stream where the header may not be present .
Use ` drflac_open_with_metadata ( ) ` if you need access to metadata .
Seek Also
- - - - - - - - -
drflac_open_file ( )
drflac_open_memory ( )
drflac_open_with_metadata ( )
drflac_close ( )
*/
DRFLAC_API drflac * drflac_open ( drflac_read_proc onRead , drflac_seek_proc onSeek , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/*
Opens a FLAC stream with relaxed validation of the header block .
Parameters
- - - - - - - - - -
onRead ( in )
The function to call when data needs to be read from the client .
onSeek ( in )
The function to call when the read position of the client data needs to move .
container ( in )
Whether or not the FLAC stream is encapsulated using standard FLAC encapsulation or Ogg encapsulation .
pUserData ( in , optional )
A pointer to application defined data that will be passed to onRead and onSeek .
pAllocationCallbacks ( in , optional )
A pointer to application defined callbacks for managing memory allocations .
Return Value
- - - - - - - - - - - -
A pointer to an object representing the decoder .
Remarks
- - - - - - -
The same as drflac_open ( ) , except attempts to open the stream even when a header block is not present .
Because the header is not necessarily available , the caller must explicitly define the container ( Native or Ogg ) . Do not set this to ` drflac_container_unknown `
as that is for internal use only .
Opening in relaxed mode will continue reading data from onRead until it finds a valid frame . If a frame is never found it will continue forever . To abort ,
force your ` onRead ` callback to return 0 , which dr_flac will use as an indicator that the end of the stream was found .
Use ` drflac_open_with_metadata_relaxed ( ) ` if you need access to metadata .
*/
DRFLAC_API drflac * drflac_open_relaxed ( drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_container container , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/*
Opens a FLAC decoder and notifies the caller of the metadata chunks ( album art , etc . ) .
Parameters
- - - - - - - - - -
onRead ( in )
The function to call when data needs to be read from the client .
onSeek ( in )
The function to call when the read position of the client data needs to move .
onMeta ( in )
The function to call for every metadata block .
pUserData ( in , optional )
A pointer to application defined data that will be passed to onRead , onSeek and onMeta .
pAllocationCallbacks ( in , optional )
A pointer to application defined callbacks for managing memory allocations .
Return Value
- - - - - - - - - - - -
A pointer to an object representing the decoder .
Remarks
- - - - - - -
Close the decoder with ` drflac_close ( ) ` .
` pAllocationCallbacks ` can be NULL in which case it will use ` DRFLAC_MALLOC ` , ` DRFLAC_REALLOC ` and ` DRFLAC_FREE ` .
This is slower than ` drflac_open ( ) ` , so avoid this one if you don ' t need metadata . Internally , this will allocate and free memory on the heap for every
metadata block except for STREAMINFO and PADDING blocks .
The caller is notified of the metadata via the ` onMeta ` callback . All metadata blocks will be handled before the function returns . This callback takes a
pointer to a ` drflac_metadata ` object which is a union containing the data of all relevant metadata blocks . Use the ` type ` member to discriminate against
the different metadata types .
The STREAMINFO block must be present for this to succeed . Use ` drflac_open_with_metadata_relaxed ( ) ` to open a FLAC stream where the header may not be present .
Note that this will behave inconsistently with ` drflac_open ( ) ` if the stream is an Ogg encapsulated stream and a metadata block is corrupted . This is due to
the way the Ogg stream recovers from corrupted pages . When ` drflac_open_with_metadata ( ) ` is being used , the open routine will try to read the contents of the
metadata block , whereas ` drflac_open ( ) ` will simply seek past it ( for the sake of efficiency ) . This inconsistency can result in different samples being
returned depending on whether or not the stream is being opened with metadata .
Seek Also
- - - - - - - - -
drflac_open_file_with_metadata ( )
drflac_open_memory_with_metadata ( )
drflac_open ( )
drflac_close ( )
*/
DRFLAC_API drflac * drflac_open_with_metadata ( drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/*
The same as drflac_open_with_metadata ( ) , except attempts to open the stream even when a header block is not present .
See Also
- - - - - - - -
drflac_open_with_metadata ( )
drflac_open_relaxed ( )
*/
DRFLAC_API drflac * drflac_open_with_metadata_relaxed ( drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , drflac_container container , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/*
Closes the given FLAC decoder .
Parameters
- - - - - - - - - -
pFlac ( in )
The decoder to close .
Remarks
- - - - - - -
This will destroy the decoder object .
See Also
- - - - - - - -
drflac_open ( )
drflac_open_with_metadata ( )
drflac_open_file ( )
drflac_open_file_w ( )
drflac_open_file_with_metadata ( )
drflac_open_file_with_metadata_w ( )
drflac_open_memory ( )
drflac_open_memory_with_metadata ( )
*/
DRFLAC_API void drflac_close ( drflac * pFlac ) ;
/*
Reads sample data from the given FLAC decoder , output as interleaved signed 32 - bit PCM .
Parameters
- - - - - - - - - -
pFlac ( in )
The decoder .
framesToRead ( in )
The number of PCM frames to read .
pBufferOut ( out , optional )
A pointer to the buffer that will receive the decoded samples .
Return Value
- - - - - - - - - - - -
Returns the number of PCM frames actually read . If the return value is less than ` framesToRead ` it has reached the end .
Remarks
- - - - - - -
pBufferOut can be null , in which case the call will act as a seek , and the return value will be the number of frames seeked .
*/
DRFLAC_API drflac_uint64 drflac_read_pcm_frames_s32 ( drflac * pFlac , drflac_uint64 framesToRead , drflac_int32 * pBufferOut ) ;
/*
Reads sample data from the given FLAC decoder , output as interleaved signed 16 - bit PCM .
Parameters
- - - - - - - - - -
pFlac ( in )
The decoder .
framesToRead ( in )
The number of PCM frames to read .
pBufferOut ( out , optional )
A pointer to the buffer that will receive the decoded samples .
Return Value
- - - - - - - - - - - -
Returns the number of PCM frames actually read . If the return value is less than ` framesToRead ` it has reached the end .
Remarks
- - - - - - -
pBufferOut can be null , in which case the call will act as a seek , and the return value will be the number of frames seeked .
Note that this is lossy for streams where the bits per sample is larger than 16.
*/
DRFLAC_API drflac_uint64 drflac_read_pcm_frames_s16 ( drflac * pFlac , drflac_uint64 framesToRead , drflac_int16 * pBufferOut ) ;
/*
Reads sample data from the given FLAC decoder , output as interleaved 32 - bit floating point PCM .
Parameters
- - - - - - - - - -
pFlac ( in )
The decoder .
framesToRead ( in )
The number of PCM frames to read .
pBufferOut ( out , optional )
A pointer to the buffer that will receive the decoded samples .
Return Value
- - - - - - - - - - - -
Returns the number of PCM frames actually read . If the return value is less than ` framesToRead ` it has reached the end .
Remarks
- - - - - - -
pBufferOut can be null , in which case the call will act as a seek , and the return value will be the number of frames seeked .
Note that this should be considered lossy due to the nature of floating point numbers not being able to exactly represent every possible number .
*/
DRFLAC_API drflac_uint64 drflac_read_pcm_frames_f32 ( drflac * pFlac , drflac_uint64 framesToRead , float * pBufferOut ) ;
/*
Seeks to the PCM frame at the given index .
Parameters
- - - - - - - - - -
pFlac ( in )
The decoder .
pcmFrameIndex ( in )
The index of the PCM frame to seek to . See notes below .
Return Value
- - - - - - - - - - - - -
` DRFLAC_TRUE ` if successful ; ` DRFLAC_FALSE ` otherwise .
*/
DRFLAC_API drflac_bool32 drflac_seek_to_pcm_frame ( drflac * pFlac , drflac_uint64 pcmFrameIndex ) ;
# ifndef DR_FLAC_NO_STDIO
/*
Opens a FLAC decoder from the file at the given path .
Parameters
- - - - - - - - - -
pFileName ( in )
The path of the file to open , either absolute or relative to the current directory .
pAllocationCallbacks ( in , optional )
A pointer to application defined callbacks for managing memory allocations .
Return Value
- - - - - - - - - - - -
A pointer to an object representing the decoder .
Remarks
- - - - - - -
Close the decoder with drflac_close ( ) .
Remarks
- - - - - - -
This will hold a handle to the file until the decoder is closed with drflac_close ( ) . Some platforms will restrict the number of files a process can have open
at any given time , so keep this mind if you have many decoders open at the same time .
See Also
- - - - - - - -
drflac_open_file_with_metadata ( )
drflac_open ( )
drflac_close ( )
*/
DRFLAC_API drflac * drflac_open_file ( const char * pFileName , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
DRFLAC_API drflac * drflac_open_file_w ( const wchar_t * pFileName , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/*
Opens a FLAC decoder from the file at the given path and notifies the caller of the metadata chunks ( album art , etc . )
Parameters
- - - - - - - - - -
pFileName ( in )
The path of the file to open , either absolute or relative to the current directory .
pAllocationCallbacks ( in , optional )
A pointer to application defined callbacks for managing memory allocations .
onMeta ( in )
The callback to fire for each metadata block .
pUserData ( in )
A pointer to the user data to pass to the metadata callback .
pAllocationCallbacks ( in )
A pointer to application defined callbacks for managing memory allocations .
Remarks
- - - - - - -
Look at the documentation for drflac_open_with_metadata ( ) for more information on how metadata is handled .
See Also
- - - - - - - -
drflac_open_with_metadata ( )
drflac_open ( )
drflac_close ( )
*/
DRFLAC_API drflac * drflac_open_file_with_metadata ( const char * pFileName , drflac_meta_proc onMeta , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
DRFLAC_API drflac * drflac_open_file_with_metadata_w ( const wchar_t * pFileName , drflac_meta_proc onMeta , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
# endif
/*
Opens a FLAC decoder from a pre - allocated block of memory
Parameters
- - - - - - - - - -
pData ( in )
A pointer to the raw encoded FLAC data .
dataSize ( in )
The size in bytes of ` data ` .
pAllocationCallbacks ( in )
A pointer to application defined callbacks for managing memory allocations .
Return Value
- - - - - - - - - - - -
A pointer to an object representing the decoder .
Remarks
- - - - - - -
This does not create a copy of the data . It is up to the application to ensure the buffer remains valid for the lifetime of the decoder .
See Also
- - - - - - - -
drflac_open ( )
drflac_close ( )
*/
DRFLAC_API drflac * drflac_open_memory ( const void * pData , size_t dataSize , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/*
Opens a FLAC decoder from a pre - allocated block of memory and notifies the caller of the metadata chunks ( album art , etc . )
Parameters
- - - - - - - - - -
pData ( in )
A pointer to the raw encoded FLAC data .
dataSize ( in )
The size in bytes of ` data ` .
onMeta ( in )
The callback to fire for each metadata block .
pUserData ( in )
A pointer to the user data to pass to the metadata callback .
pAllocationCallbacks ( in )
A pointer to application defined callbacks for managing memory allocations .
Remarks
- - - - - - -
Look at the documentation for drflac_open_with_metadata ( ) for more information on how metadata is handled .
See Also
- - - - - - -
drflac_open_with_metadata ( )
drflac_open ( )
drflac_close ( )
*/
DRFLAC_API drflac * drflac_open_memory_with_metadata ( const void * pData , size_t dataSize , drflac_meta_proc onMeta , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/* High Level APIs */
/*
Opens a FLAC stream from the given callbacks and fully decodes it in a single operation . The return value is a
pointer to the sample data as interleaved signed 32 - bit PCM . The returned data must be freed with drflac_free ( ) .
You can pass in custom memory allocation callbacks via the pAllocationCallbacks parameter . This can be NULL in which
case it will use DRFLAC_MALLOC , DRFLAC_REALLOC and DRFLAC_FREE .
Sometimes a FLAC file won ' t keep track of the total sample count . In this situation the function will continuously
read samples into a dynamically sized buffer on the heap until no samples are left .
Do not call this function on a broadcast type of stream ( like internet radio streams and whatnot ) .
*/
DRFLAC_API drflac_int32 * drflac_open_and_read_pcm_frames_s32 ( drflac_read_proc onRead , drflac_seek_proc onSeek , void * pUserData , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/* Same as drflac_open_and_read_pcm_frames_s32(), except returns signed 16-bit integer samples. */
DRFLAC_API drflac_int16 * drflac_open_and_read_pcm_frames_s16 ( drflac_read_proc onRead , drflac_seek_proc onSeek , void * pUserData , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/* Same as drflac_open_and_read_pcm_frames_s32(), except returns 32-bit floating-point samples. */
DRFLAC_API float * drflac_open_and_read_pcm_frames_f32 ( drflac_read_proc onRead , drflac_seek_proc onSeek , void * pUserData , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
# ifndef DR_FLAC_NO_STDIO
/* Same as drflac_open_and_read_pcm_frames_s32() except opens the decoder from a file. */
DRFLAC_API drflac_int32 * drflac_open_file_and_read_pcm_frames_s32 ( const char * filename , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/* Same as drflac_open_file_and_read_pcm_frames_s32(), except returns signed 16-bit integer samples. */
DRFLAC_API drflac_int16 * drflac_open_file_and_read_pcm_frames_s16 ( const char * filename , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/* Same as drflac_open_file_and_read_pcm_frames_s32(), except returns 32-bit floating-point samples. */
DRFLAC_API float * drflac_open_file_and_read_pcm_frames_f32 ( const char * filename , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
# endif
/* Same as drflac_open_and_read_pcm_frames_s32() except opens the decoder from a block of memory. */
DRFLAC_API drflac_int32 * drflac_open_memory_and_read_pcm_frames_s32 ( const void * data , size_t dataSize , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/* Same as drflac_open_memory_and_read_pcm_frames_s32(), except returns signed 16-bit integer samples. */
DRFLAC_API drflac_int16 * drflac_open_memory_and_read_pcm_frames_s16 ( const void * data , size_t dataSize , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/* Same as drflac_open_memory_and_read_pcm_frames_s32(), except returns 32-bit floating-point samples. */
DRFLAC_API float * drflac_open_memory_and_read_pcm_frames_f32 ( const void * data , size_t dataSize , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/*
Frees memory that was allocated internally by dr_flac .
Set pAllocationCallbacks to the same object that was passed to drflac_open_ * _and_read_pcm_frames_ * ( ) . If you originally passed in NULL , pass in NULL for this .
*/
DRFLAC_API void drflac_free ( void * p , const drflac_allocation_callbacks * pAllocationCallbacks ) ;
/* Structure representing an iterator for vorbis comments in a VORBIS_COMMENT metadata block. */
typedef struct
{
drflac_uint32 countRemaining ;
const char * pRunningData ;
} drflac_vorbis_comment_iterator ;
/*
Initializes a vorbis comment iterator . This can be used for iterating over the vorbis comments in a VORBIS_COMMENT
metadata block .
*/
DRFLAC_API void drflac_init_vorbis_comment_iterator ( drflac_vorbis_comment_iterator * pIter , drflac_uint32 commentCount , const void * pComments ) ;
/*
Goes to the next vorbis comment in the given iterator . If null is returned it means there are no more comments . The
returned string is NOT null terminated .
*/
DRFLAC_API const char * drflac_next_vorbis_comment ( drflac_vorbis_comment_iterator * pIter , drflac_uint32 * pCommentLengthOut ) ;
/* Structure representing an iterator for cuesheet tracks in a CUESHEET metadata block. */
typedef struct
{
drflac_uint32 countRemaining ;
const char * pRunningData ;
} drflac_cuesheet_track_iterator ;
/* Packing is important on this structure because we map this directly to the raw data within the CUESHEET metadata block. */
# pragma pack(4)
typedef struct
{
drflac_uint64 offset ;
drflac_uint8 index ;
drflac_uint8 reserved [ 3 ] ;
} drflac_cuesheet_track_index ;
# pragma pack()
typedef struct
{
drflac_uint64 offset ;
drflac_uint8 trackNumber ;
char ISRC [ 12 ] ;
drflac_bool8 isAudio ;
drflac_bool8 preEmphasis ;
drflac_uint8 indexCount ;
const drflac_cuesheet_track_index * pIndexPoints ;
} drflac_cuesheet_track ;
/*
Initializes a cuesheet track iterator . This can be used for iterating over the cuesheet tracks in a CUESHEET metadata
block .
*/
DRFLAC_API void drflac_init_cuesheet_track_iterator ( drflac_cuesheet_track_iterator * pIter , drflac_uint32 trackCount , const void * pTrackData ) ;
/* Goes to the next cuesheet track in the given iterator. If DRFLAC_FALSE is returned it means there are no more comments. */
DRFLAC_API drflac_bool32 drflac_next_cuesheet_track ( drflac_cuesheet_track_iterator * pIter , drflac_cuesheet_track * pCuesheetTrack ) ;
# ifdef __cplusplus
}
# endif
# endif /* dr_flac_h */
/************************************************************************************************************************************************************
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
IMPLEMENTATION
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * *
* * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * * */
# if defined(DR_FLAC_IMPLEMENTATION) || defined(DRFLAC_IMPLEMENTATION)
# ifndef dr_flac_c
# define dr_flac_c
/* Disable some annoying warnings. */
# if defined(__clang__) || (defined(__GNUC__) && (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 6)))
# pragma GCC diagnostic push
# if __GNUC__ >= 7
# pragma GCC diagnostic ignored "-Wimplicit-fallthrough"
# endif
# endif
# ifdef __linux__
# ifndef _BSD_SOURCE
# define _BSD_SOURCE
# endif
# ifndef _DEFAULT_SOURCE
# define _DEFAULT_SOURCE
# endif
# ifndef __USE_BSD
# define __USE_BSD
# endif
# include <endian.h>
# endif
# include <stdlib.h>
# include <string.h>
# ifdef _MSC_VER
# define DRFLAC_INLINE __forceinline
# elif defined(__GNUC__)
/*
I ' ve had a bug report where GCC is emitting warnings about functions possibly not being inlineable . This warning happens when
the __attribute__ ( ( always_inline ) ) attribute is defined without an " inline " statement . I think therefore there must be some
case where " __inline__ " is not always defined , thus the compiler emitting these warnings . When using - std = c89 or - ansi on the
command line , we cannot use the " inline " keyword and instead need to use " __inline__ " . In an attempt to work around this issue
I am using " __inline__ " only when we ' re compiling in strict ANSI mode .
*/
# if defined(__STRICT_ANSI__)
# define DRFLAC_INLINE __inline__ __attribute__((always_inline))
# else
# define DRFLAC_INLINE inline __attribute__((always_inline))
# endif
# elif defined(__WATCOMC__)
# define DRFLAC_INLINE __inline
# else
# define DRFLAC_INLINE
# endif
/* CPU architecture. */
# if defined(__x86_64__) || defined(_M_X64)
# define DRFLAC_X64
# elif defined(__i386) || defined(_M_IX86)
# define DRFLAC_X86
# elif defined(__arm__) || defined(_M_ARM) || defined(__arm64) || defined(__arm64__) || defined(__aarch64__) || defined(_M_ARM64)
# define DRFLAC_ARM
# endif
/*
Intrinsics Support
There ' s a bug in GCC 4.2 . x which results in an incorrect compilation error when using _mm_slli_epi32 ( ) where it complains with
" error: shift must be an immediate "
Unfortuantely dr_flac depends on this for a few things so we ' re just going to disable SSE on GCC 4.2 and below .
*/
# if !defined(DR_FLAC_NO_SIMD)
# if defined(DRFLAC_X64) || defined(DRFLAC_X86)
# if defined(_MSC_VER) && !defined(__clang__)
/* MSVC. */
# if _MSC_VER >= 1400 && !defined(DRFLAC_NO_SSE2) /* 2005 */
# define DRFLAC_SUPPORT_SSE2
# endif
# if _MSC_VER >= 1600 && !defined(DRFLAC_NO_SSE41) /* 2010 */
# define DRFLAC_SUPPORT_SSE41
# endif
# elif defined(__clang__) || (defined(__GNUC__) && (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 3)))
/* Assume GNUC-style. */
# if defined(__SSE2__) && !defined(DRFLAC_NO_SSE2)
# define DRFLAC_SUPPORT_SSE2
# endif
# if defined(__SSE4_1__) && !defined(DRFLAC_NO_SSE41)
# define DRFLAC_SUPPORT_SSE41
# endif
# endif
/* If at this point we still haven't determined compiler support for the intrinsics just fall back to __has_include. */
# if !defined(__GNUC__) && !defined(__clang__) && defined(__has_include)
# if !defined(DRFLAC_SUPPORT_SSE2) && !defined(DRFLAC_NO_SSE2) && __has_include(<emmintrin.h>)
# define DRFLAC_SUPPORT_SSE2
# endif
# if !defined(DRFLAC_SUPPORT_SSE41) && !defined(DRFLAC_NO_SSE41) && __has_include(<smmintrin.h>)
# define DRFLAC_SUPPORT_SSE41
# endif
# endif
# if defined(DRFLAC_SUPPORT_SSE41)
# include <smmintrin.h>
# elif defined(DRFLAC_SUPPORT_SSE2)
# include <emmintrin.h>
# endif
# endif
# if defined(DRFLAC_ARM)
# if !defined(DRFLAC_NO_NEON) && (defined(__ARM_NEON) || defined(__aarch64__) || defined(_M_ARM64))
# define DRFLAC_SUPPORT_NEON
# include <arm_neon.h>
# endif
# endif
# endif
/* Compile-time CPU feature support. */
# if !defined(DR_FLAC_NO_SIMD) && (defined(DRFLAC_X86) || defined(DRFLAC_X64))
# if defined(_MSC_VER) && !defined(__clang__)
# if _MSC_VER >= 1400
# include <intrin.h>
static void drflac__cpuid ( int info [ 4 ] , int fid )
{
__cpuid ( info , fid ) ;
}
# else
# define DRFLAC_NO_CPUID
# endif
# else
# if defined(__GNUC__) || defined(__clang__)
static void drflac__cpuid ( int info [ 4 ] , int fid )
{
/*
It looks like the - fPIC option uses the ebx register which GCC complains about . We can work around this by just using a different register , the
specific register of which I ' m letting the compiler decide on . The " k " prefix is used to specify a 32 - bit register . The { . . . } syntax is for
supporting different assembly dialects .
What ' s basically happening is that we ' re saving and restoring the ebx register manually .
*/
# if defined(DRFLAC_X86) && defined(__PIC__)
__asm__ __volatile__ (
" xchg{l} {%%}ebx, %k1; "
" cpuid; "
" xchg{l} {%%}ebx, %k1; "
: " =a " ( info [ 0 ] ) , " =&r " ( info [ 1 ] ) , " =c " ( info [ 2 ] ) , " =d " ( info [ 3 ] ) : " a " ( fid ) , " c " ( 0 )
) ;
# else
__asm__ __volatile__ (
" cpuid " : " =a " ( info [ 0 ] ) , " =b " ( info [ 1 ] ) , " =c " ( info [ 2 ] ) , " =d " ( info [ 3 ] ) : " a " ( fid ) , " c " ( 0 )
) ;
# endif
}
# else
# define DRFLAC_NO_CPUID
# endif
# endif
# else
# define DRFLAC_NO_CPUID
# endif
static DRFLAC_INLINE drflac_bool32 drflac_has_sse2 ( void )
{
# if defined(DRFLAC_SUPPORT_SSE2)
# if (defined(DRFLAC_X64) || defined(DRFLAC_X86)) && !defined(DRFLAC_NO_SSE2)
# if defined(DRFLAC_X64)
return DRFLAC_TRUE ; /* 64-bit targets always support SSE2. */
# elif (defined(_M_IX86_FP) && _M_IX86_FP == 2) || defined(__SSE2__)
return DRFLAC_TRUE ; /* If the compiler is allowed to freely generate SSE2 code we can assume support. */
# else
# if defined(DRFLAC_NO_CPUID)
return DRFLAC_FALSE ;
# else
int info [ 4 ] ;
drflac__cpuid ( info , 1 ) ;
return ( info [ 3 ] & ( 1 < < 26 ) ) ! = 0 ;
# endif
# endif
# else
return DRFLAC_FALSE ; /* SSE2 is only supported on x86 and x64 architectures. */
# endif
# else
return DRFLAC_FALSE ; /* No compiler support. */
# endif
}
static DRFLAC_INLINE drflac_bool32 drflac_has_sse41 ( void )
{
# if defined(DRFLAC_SUPPORT_SSE41)
# if (defined(DRFLAC_X64) || defined(DRFLAC_X86)) && !defined(DRFLAC_NO_SSE41)
# if defined(DRFLAC_X64)
return DRFLAC_TRUE ; /* 64-bit targets always support SSE4.1. */
# elif (defined(_M_IX86_FP) && _M_IX86_FP == 2) || defined(__SSE4_1__)
return DRFLAC_TRUE ; /* If the compiler is allowed to freely generate SSE41 code we can assume support. */
# else
# if defined(DRFLAC_NO_CPUID)
return DRFLAC_FALSE ;
# else
int info [ 4 ] ;
drflac__cpuid ( info , 1 ) ;
return ( info [ 2 ] & ( 1 < < 19 ) ) ! = 0 ;
# endif
# endif
# else
return DRFLAC_FALSE ; /* SSE41 is only supported on x86 and x64 architectures. */
# endif
# else
return DRFLAC_FALSE ; /* No compiler support. */
# endif
}
# if defined(_MSC_VER) && _MSC_VER >= 1500 && (defined(DRFLAC_X86) || defined(DRFLAC_X64)) && !defined(__clang__)
# define DRFLAC_HAS_LZCNT_INTRINSIC
# elif (defined(__GNUC__) && ((__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 7)))
# define DRFLAC_HAS_LZCNT_INTRINSIC
# elif defined(__clang__)
# if defined(__has_builtin)
# if __has_builtin(__builtin_clzll) || __has_builtin(__builtin_clzl)
# define DRFLAC_HAS_LZCNT_INTRINSIC
# endif
# endif
# endif
# if defined(_MSC_VER) && _MSC_VER >= 1400 && !defined(__clang__)
# define DRFLAC_HAS_BYTESWAP16_INTRINSIC
# define DRFLAC_HAS_BYTESWAP32_INTRINSIC
# define DRFLAC_HAS_BYTESWAP64_INTRINSIC
# elif defined(__clang__)
# if defined(__has_builtin)
# if __has_builtin(__builtin_bswap16)
# define DRFLAC_HAS_BYTESWAP16_INTRINSIC
# endif
# if __has_builtin(__builtin_bswap32)
# define DRFLAC_HAS_BYTESWAP32_INTRINSIC
# endif
# if __has_builtin(__builtin_bswap64)
# define DRFLAC_HAS_BYTESWAP64_INTRINSIC
# endif
# endif
# elif defined(__GNUC__)
# if ((__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 3))
# define DRFLAC_HAS_BYTESWAP32_INTRINSIC
# define DRFLAC_HAS_BYTESWAP64_INTRINSIC
# endif
# if ((__GNUC__ > 4) || (__GNUC__ == 4 && __GNUC_MINOR__ >= 8))
# define DRFLAC_HAS_BYTESWAP16_INTRINSIC
# endif
# elif defined(__WATCOMC__) && defined(__386__)
# define DRFLAC_HAS_BYTESWAP16_INTRINSIC
# define DRFLAC_HAS_BYTESWAP32_INTRINSIC
# define DRFLAC_HAS_BYTESWAP64_INTRINSIC
extern __inline drflac_uint16 _watcom_bswap16 ( drflac_uint16 ) ;
extern __inline drflac_uint32 _watcom_bswap32 ( drflac_uint32 ) ;
extern __inline drflac_uint64 _watcom_bswap64 ( drflac_uint64 ) ;
# pragma aux _watcom_bswap16 = \
" xchg al, ah " \
parm [ ax ] \
modify [ ax ] ;
# pragma aux _watcom_bswap32 = \
" bswap eax " \
parm [ eax ] \
modify [ eax ] ;
# pragma aux _watcom_bswap64 = \
" bswap eax " \
" bswap edx " \
" xchg eax,edx " \
parm [ eax edx ] \
modify [ eax edx ] ;
# endif
/* Standard library stuff. */
# ifndef DRFLAC_ASSERT
# include <assert.h>
# define DRFLAC_ASSERT(expression) assert(expression)
# endif
# ifndef DRFLAC_MALLOC
# define DRFLAC_MALLOC(sz) malloc((sz))
# endif
# ifndef DRFLAC_REALLOC
# define DRFLAC_REALLOC(p, sz) realloc((p), (sz))
# endif
# ifndef DRFLAC_FREE
# define DRFLAC_FREE(p) free((p))
# endif
# ifndef DRFLAC_COPY_MEMORY
# define DRFLAC_COPY_MEMORY(dst, src, sz) memcpy((dst), (src), (sz))
# endif
# ifndef DRFLAC_ZERO_MEMORY
# define DRFLAC_ZERO_MEMORY(p, sz) memset((p), 0, (sz))
# endif
# ifndef DRFLAC_ZERO_OBJECT
# define DRFLAC_ZERO_OBJECT(p) DRFLAC_ZERO_MEMORY((p), sizeof(*(p)))
# endif
# define DRFLAC_MAX_SIMD_VECTOR_SIZE 64 /* 64 for AVX-512 in the future. */
typedef drflac_int32 drflac_result ;
# define DRFLAC_SUCCESS 0
# define DRFLAC_ERROR -1 /* A generic error. */
# define DRFLAC_INVALID_ARGS -2
# define DRFLAC_INVALID_OPERATION -3
# define DRFLAC_OUT_OF_MEMORY -4
# define DRFLAC_OUT_OF_RANGE -5
# define DRFLAC_ACCESS_DENIED -6
# define DRFLAC_DOES_NOT_EXIST -7
# define DRFLAC_ALREADY_EXISTS -8
# define DRFLAC_TOO_MANY_OPEN_FILES -9
# define DRFLAC_INVALID_FILE -10
# define DRFLAC_TOO_BIG -11
# define DRFLAC_PATH_TOO_LONG -12
# define DRFLAC_NAME_TOO_LONG -13
# define DRFLAC_NOT_DIRECTORY -14
# define DRFLAC_IS_DIRECTORY -15
# define DRFLAC_DIRECTORY_NOT_EMPTY -16
# define DRFLAC_END_OF_FILE -17
# define DRFLAC_NO_SPACE -18
# define DRFLAC_BUSY -19
# define DRFLAC_IO_ERROR -20
# define DRFLAC_INTERRUPT -21
# define DRFLAC_UNAVAILABLE -22
# define DRFLAC_ALREADY_IN_USE -23
# define DRFLAC_BAD_ADDRESS -24
# define DRFLAC_BAD_SEEK -25
# define DRFLAC_BAD_PIPE -26
# define DRFLAC_DEADLOCK -27
# define DRFLAC_TOO_MANY_LINKS -28
# define DRFLAC_NOT_IMPLEMENTED -29
# define DRFLAC_NO_MESSAGE -30
# define DRFLAC_BAD_MESSAGE -31
# define DRFLAC_NO_DATA_AVAILABLE -32
# define DRFLAC_INVALID_DATA -33
# define DRFLAC_TIMEOUT -34
# define DRFLAC_NO_NETWORK -35
# define DRFLAC_NOT_UNIQUE -36
# define DRFLAC_NOT_SOCKET -37
# define DRFLAC_NO_ADDRESS -38
# define DRFLAC_BAD_PROTOCOL -39
# define DRFLAC_PROTOCOL_UNAVAILABLE -40
# define DRFLAC_PROTOCOL_NOT_SUPPORTED -41
# define DRFLAC_PROTOCOL_FAMILY_NOT_SUPPORTED -42
# define DRFLAC_ADDRESS_FAMILY_NOT_SUPPORTED -43
# define DRFLAC_SOCKET_NOT_SUPPORTED -44
# define DRFLAC_CONNECTION_RESET -45
# define DRFLAC_ALREADY_CONNECTED -46
# define DRFLAC_NOT_CONNECTED -47
# define DRFLAC_CONNECTION_REFUSED -48
# define DRFLAC_NO_HOST -49
# define DRFLAC_IN_PROGRESS -50
# define DRFLAC_CANCELLED -51
# define DRFLAC_MEMORY_ALREADY_MAPPED -52
# define DRFLAC_AT_END -53
# define DRFLAC_CRC_MISMATCH -128
# define DRFLAC_SUBFRAME_CONSTANT 0
# define DRFLAC_SUBFRAME_VERBATIM 1
# define DRFLAC_SUBFRAME_FIXED 8
# define DRFLAC_SUBFRAME_LPC 32
# define DRFLAC_SUBFRAME_RESERVED 255
# define DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE 0
# define DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE2 1
# define DRFLAC_CHANNEL_ASSIGNMENT_INDEPENDENT 0
# define DRFLAC_CHANNEL_ASSIGNMENT_LEFT_SIDE 8
# define DRFLAC_CHANNEL_ASSIGNMENT_RIGHT_SIDE 9
# define DRFLAC_CHANNEL_ASSIGNMENT_MID_SIDE 10
# define drflac_align(x, a) ((((x) + (a) - 1) / (a)) * (a))
DRFLAC_API void drflac_version ( drflac_uint32 * pMajor , drflac_uint32 * pMinor , drflac_uint32 * pRevision )
{
if ( pMajor ) {
* pMajor = DRFLAC_VERSION_MAJOR ;
}
if ( pMinor ) {
* pMinor = DRFLAC_VERSION_MINOR ;
}
if ( pRevision ) {
* pRevision = DRFLAC_VERSION_REVISION ;
}
}
DRFLAC_API const char * drflac_version_string ( void )
{
return DRFLAC_VERSION_STRING ;
}
/* CPU caps. */
# if defined(__has_feature)
# if __has_feature(thread_sanitizer)
# define DRFLAC_NO_THREAD_SANITIZE __attribute__((no_sanitize("thread")))
# else
# define DRFLAC_NO_THREAD_SANITIZE
# endif
# else
# define DRFLAC_NO_THREAD_SANITIZE
# endif
# if defined(DRFLAC_HAS_LZCNT_INTRINSIC)
static drflac_bool32 drflac__gIsLZCNTSupported = DRFLAC_FALSE ;
# endif
# ifndef DRFLAC_NO_CPUID
static drflac_bool32 drflac__gIsSSE2Supported = DRFLAC_FALSE ;
static drflac_bool32 drflac__gIsSSE41Supported = DRFLAC_FALSE ;
/*
I ' ve had a bug report that Clang ' s ThreadSanitizer presents a warning in this function . Having reviewed this , this does
actually make sense . However , since CPU caps should never differ for a running process , I don ' t think the trade off of
complicating internal API ' s by passing around CPU caps versus just disabling the warnings is worthwhile . I ' m therefore
just going to disable these warnings . This is disabled via the DRFLAC_NO_THREAD_SANITIZE attribute .
*/
DRFLAC_NO_THREAD_SANITIZE static void drflac__init_cpu_caps ( void )
{
static drflac_bool32 isCPUCapsInitialized = DRFLAC_FALSE ;
if ( ! isCPUCapsInitialized ) {
/* LZCNT */
# if defined(DRFLAC_HAS_LZCNT_INTRINSIC)
int info [ 4 ] = { 0 } ;
drflac__cpuid ( info , 0x80000001 ) ;
drflac__gIsLZCNTSupported = ( info [ 2 ] & ( 1 < < 5 ) ) ! = 0 ;
# endif
/* SSE2 */
drflac__gIsSSE2Supported = drflac_has_sse2 ( ) ;
/* SSE4.1 */
drflac__gIsSSE41Supported = drflac_has_sse41 ( ) ;
/* Initialized. */
isCPUCapsInitialized = DRFLAC_TRUE ;
}
}
# else
static drflac_bool32 drflac__gIsNEONSupported = DRFLAC_FALSE ;
static DRFLAC_INLINE drflac_bool32 drflac__has_neon ( void )
{
# if defined(DRFLAC_SUPPORT_NEON)
# if defined(DRFLAC_ARM) && !defined(DRFLAC_NO_NEON)
# if (defined(__ARM_NEON) || defined(__aarch64__) || defined(_M_ARM64))
return DRFLAC_TRUE ; /* If the compiler is allowed to freely generate NEON code we can assume support. */
# else
/* TODO: Runtime check. */
return DRFLAC_FALSE ;
# endif
# else
return DRFLAC_FALSE ; /* NEON is only supported on ARM architectures. */
# endif
# else
return DRFLAC_FALSE ; /* No compiler support. */
# endif
}
DRFLAC_NO_THREAD_SANITIZE static void drflac__init_cpu_caps ( void )
{
drflac__gIsNEONSupported = drflac__has_neon ( ) ;
# if defined(DRFLAC_HAS_LZCNT_INTRINSIC) && defined(DRFLAC_ARM) && (defined(__ARM_ARCH) && __ARM_ARCH >= 5)
drflac__gIsLZCNTSupported = DRFLAC_TRUE ;
# endif
}
# endif
/* Endian Management */
static DRFLAC_INLINE drflac_bool32 drflac__is_little_endian ( void )
{
# if defined(DRFLAC_X86) || defined(DRFLAC_X64)
return DRFLAC_TRUE ;
# elif defined(__BYTE_ORDER) && defined(__LITTLE_ENDIAN) && __BYTE_ORDER == __LITTLE_ENDIAN
return DRFLAC_TRUE ;
# else
int n = 1 ;
return ( * ( char * ) & n ) = = 1 ;
# endif
}
static DRFLAC_INLINE drflac_uint16 drflac__swap_endian_uint16 ( drflac_uint16 n )
{
# ifdef DRFLAC_HAS_BYTESWAP16_INTRINSIC
# if defined(_MSC_VER) && !defined(__clang__)
return _byteswap_ushort ( n ) ;
# elif defined(__GNUC__) || defined(__clang__)
return __builtin_bswap16 ( n ) ;
# elif defined(__WATCOMC__) && defined(__386__)
return _watcom_bswap16 ( n ) ;
# else
# error "This compiler does not support the byte swap intrinsic."
# endif
# else
return ( ( n & 0xFF00 ) > > 8 ) |
( ( n & 0x00FF ) < < 8 ) ;
# endif
}
static DRFLAC_INLINE drflac_uint32 drflac__swap_endian_uint32 ( drflac_uint32 n )
{
# ifdef DRFLAC_HAS_BYTESWAP32_INTRINSIC
# if defined(_MSC_VER) && !defined(__clang__)
return _byteswap_ulong ( n ) ;
# elif defined(__GNUC__) || defined(__clang__)
# if defined(DRFLAC_ARM) && (defined(__ARM_ARCH) && __ARM_ARCH >= 6) && !defined(DRFLAC_64BIT) /* <-- 64-bit inline assembly has not been tested, so disabling for now. */
/* Inline assembly optimized implementation for ARM. In my testing, GCC does not generate optimized code with __builtin_bswap32(). */
drflac_uint32 r ;
__asm__ __volatile__ (
# if defined(DRFLAC_64BIT)
" rev %w[out], %w[in] " : [ out ] " =r " ( r ) : [ in ] " r " ( n ) /* <-- This is untested. If someone in the community could test this, that would be appreciated! */
# else
" rev %[out], %[in] " : [ out ] " =r " ( r ) : [ in ] " r " ( n )
# endif
) ;
return r ;
# else
return __builtin_bswap32 ( n ) ;
# endif
# elif defined(__WATCOMC__) && defined(__386__)
return _watcom_bswap32 ( n ) ;
# else
# error "This compiler does not support the byte swap intrinsic."
# endif
# else
return ( ( n & 0xFF000000 ) > > 24 ) |
( ( n & 0x00FF0000 ) > > 8 ) |
( ( n & 0x0000FF00 ) < < 8 ) |
( ( n & 0x000000FF ) < < 24 ) ;
# endif
}
static DRFLAC_INLINE drflac_uint64 drflac__swap_endian_uint64 ( drflac_uint64 n )
{
# ifdef DRFLAC_HAS_BYTESWAP64_INTRINSIC
# if defined(_MSC_VER) && !defined(__clang__)
return _byteswap_uint64 ( n ) ;
# elif defined(__GNUC__) || defined(__clang__)
return __builtin_bswap64 ( n ) ;
# elif defined(__WATCOMC__) && defined(__386__)
return _watcom_bswap64 ( n ) ;
# else
# error "This compiler does not support the byte swap intrinsic."
# endif
# else
/* Weird "<< 32" bitshift is required for C89 because it doesn't support 64-bit constants. Should be optimized out by a good compiler. */
return ( ( n & ( ( drflac_uint64 ) 0xFF000000 < < 32 ) ) > > 56 ) |
( ( n & ( ( drflac_uint64 ) 0x00FF0000 < < 32 ) ) > > 40 ) |
( ( n & ( ( drflac_uint64 ) 0x0000FF00 < < 32 ) ) > > 24 ) |
( ( n & ( ( drflac_uint64 ) 0x000000FF < < 32 ) ) > > 8 ) |
( ( n & ( ( drflac_uint64 ) 0xFF000000 ) ) < < 8 ) |
( ( n & ( ( drflac_uint64 ) 0x00FF0000 ) ) < < 24 ) |
( ( n & ( ( drflac_uint64 ) 0x0000FF00 ) ) < < 40 ) |
( ( n & ( ( drflac_uint64 ) 0x000000FF ) ) < < 56 ) ;
# endif
}
static DRFLAC_INLINE drflac_uint16 drflac__be2host_16 ( drflac_uint16 n )
{
if ( drflac__is_little_endian ( ) ) {
return drflac__swap_endian_uint16 ( n ) ;
}
return n ;
}
static DRFLAC_INLINE drflac_uint32 drflac__be2host_32 ( drflac_uint32 n )
{
if ( drflac__is_little_endian ( ) ) {
return drflac__swap_endian_uint32 ( n ) ;
}
return n ;
}
static DRFLAC_INLINE drflac_uint32 drflac__be2host_32_ptr_unaligned ( const void * pData )
{
const drflac_uint8 * pNum = ( drflac_uint8 * ) pData ;
return * ( pNum ) < < 24 | * ( pNum + 1 ) < < 16 | * ( pNum + 2 ) < < 8 | * ( pNum + 3 ) ;
}
static DRFLAC_INLINE drflac_uint64 drflac__be2host_64 ( drflac_uint64 n )
{
if ( drflac__is_little_endian ( ) ) {
return drflac__swap_endian_uint64 ( n ) ;
}
return n ;
}
static DRFLAC_INLINE drflac_uint32 drflac__le2host_32 ( drflac_uint32 n )
{
if ( ! drflac__is_little_endian ( ) ) {
return drflac__swap_endian_uint32 ( n ) ;
}
return n ;
}
static DRFLAC_INLINE drflac_uint32 drflac__le2host_32_ptr_unaligned ( const void * pData )
{
const drflac_uint8 * pNum = ( drflac_uint8 * ) pData ;
return * pNum | * ( pNum + 1 ) < < 8 | * ( pNum + 2 ) < < 16 | * ( pNum + 3 ) < < 24 ;
}
static DRFLAC_INLINE drflac_uint32 drflac__unsynchsafe_32 ( drflac_uint32 n )
{
drflac_uint32 result = 0 ;
result | = ( n & 0x7F000000 ) > > 3 ;
result | = ( n & 0x007F0000 ) > > 2 ;
result | = ( n & 0x00007F00 ) > > 1 ;
result | = ( n & 0x0000007F ) > > 0 ;
return result ;
}
/* The CRC code below is based on this document: http://zlib.net/crc_v3.txt */
static drflac_uint8 drflac__crc8_table [ ] = {
0x00 , 0x07 , 0x0E , 0x09 , 0x1C , 0x1B , 0x12 , 0x15 , 0x38 , 0x3F , 0x36 , 0x31 , 0x24 , 0x23 , 0x2A , 0x2D ,
0x70 , 0x77 , 0x7E , 0x79 , 0x6C , 0x6B , 0x62 , 0x65 , 0x48 , 0x4F , 0x46 , 0x41 , 0x54 , 0x53 , 0x5A , 0x5D ,
0xE0 , 0xE7 , 0xEE , 0xE9 , 0xFC , 0xFB , 0xF2 , 0xF5 , 0xD8 , 0xDF , 0xD6 , 0xD1 , 0xC4 , 0xC3 , 0xCA , 0xCD ,
0x90 , 0x97 , 0x9E , 0x99 , 0x8C , 0x8B , 0x82 , 0x85 , 0xA8 , 0xAF , 0xA6 , 0xA1 , 0xB4 , 0xB3 , 0xBA , 0xBD ,
0xC7 , 0xC0 , 0xC9 , 0xCE , 0xDB , 0xDC , 0xD5 , 0xD2 , 0xFF , 0xF8 , 0xF1 , 0xF6 , 0xE3 , 0xE4 , 0xED , 0xEA ,
0xB7 , 0xB0 , 0xB9 , 0xBE , 0xAB , 0xAC , 0xA5 , 0xA2 , 0x8F , 0x88 , 0x81 , 0x86 , 0x93 , 0x94 , 0x9D , 0x9A ,
0x27 , 0x20 , 0x29 , 0x2E , 0x3B , 0x3C , 0x35 , 0x32 , 0x1F , 0x18 , 0x11 , 0x16 , 0x03 , 0x04 , 0x0D , 0x0A ,
0x57 , 0x50 , 0x59 , 0x5E , 0x4B , 0x4C , 0x45 , 0x42 , 0x6F , 0x68 , 0x61 , 0x66 , 0x73 , 0x74 , 0x7D , 0x7A ,
0x89 , 0x8E , 0x87 , 0x80 , 0x95 , 0x92 , 0x9B , 0x9C , 0xB1 , 0xB6 , 0xBF , 0xB8 , 0xAD , 0xAA , 0xA3 , 0xA4 ,
0xF9 , 0xFE , 0xF7 , 0xF0 , 0xE5 , 0xE2 , 0xEB , 0xEC , 0xC1 , 0xC6 , 0xCF , 0xC8 , 0xDD , 0xDA , 0xD3 , 0xD4 ,
0x69 , 0x6E , 0x67 , 0x60 , 0x75 , 0x72 , 0x7B , 0x7C , 0x51 , 0x56 , 0x5F , 0x58 , 0x4D , 0x4A , 0x43 , 0x44 ,
0x19 , 0x1E , 0x17 , 0x10 , 0x05 , 0x02 , 0x0B , 0x0C , 0x21 , 0x26 , 0x2F , 0x28 , 0x3D , 0x3A , 0x33 , 0x34 ,
0x4E , 0x49 , 0x40 , 0x47 , 0x52 , 0x55 , 0x5C , 0x5B , 0x76 , 0x71 , 0x78 , 0x7F , 0x6A , 0x6D , 0x64 , 0x63 ,
0x3E , 0x39 , 0x30 , 0x37 , 0x22 , 0x25 , 0x2C , 0x2B , 0x06 , 0x01 , 0x08 , 0x0F , 0x1A , 0x1D , 0x14 , 0x13 ,
0xAE , 0xA9 , 0xA0 , 0xA7 , 0xB2 , 0xB5 , 0xBC , 0xBB , 0x96 , 0x91 , 0x98 , 0x9F , 0x8A , 0x8D , 0x84 , 0x83 ,
0xDE , 0xD9 , 0xD0 , 0xD7 , 0xC2 , 0xC5 , 0xCC , 0xCB , 0xE6 , 0xE1 , 0xE8 , 0xEF , 0xFA , 0xFD , 0xF4 , 0xF3
} ;
static drflac_uint16 drflac__crc16_table [ ] = {
0x0000 , 0x8005 , 0x800F , 0x000A , 0x801B , 0x001E , 0x0014 , 0x8011 ,
0x8033 , 0x0036 , 0x003C , 0x8039 , 0x0028 , 0x802D , 0x8027 , 0x0022 ,
0x8063 , 0x0066 , 0x006C , 0x8069 , 0x0078 , 0x807D , 0x8077 , 0x0072 ,
0x0050 , 0x8055 , 0x805F , 0x005A , 0x804B , 0x004E , 0x0044 , 0x8041 ,
0x80C3 , 0x00C6 , 0x00CC , 0x80C9 , 0x00D8 , 0x80DD , 0x80D7 , 0x00D2 ,
0x00F0 , 0x80F5 , 0x80FF , 0x00FA , 0x80EB , 0x00EE , 0x00E4 , 0x80E1 ,
0x00A0 , 0x80A5 , 0x80AF , 0x00AA , 0x80BB , 0x00BE , 0x00B4 , 0x80B1 ,
0x8093 , 0x0096 , 0x009C , 0x8099 , 0x0088 , 0x808D , 0x8087 , 0x0082 ,
0x8183 , 0x0186 , 0x018C , 0x8189 , 0x0198 , 0x819D , 0x8197 , 0x0192 ,
0x01B0 , 0x81B5 , 0x81BF , 0x01BA , 0x81AB , 0x01AE , 0x01A4 , 0x81A1 ,
0x01E0 , 0x81E5 , 0x81EF , 0x01EA , 0x81FB , 0x01FE , 0x01F4 , 0x81F1 ,
0x81D3 , 0x01D6 , 0x01DC , 0x81D9 , 0x01C8 , 0x81CD , 0x81C7 , 0x01C2 ,
0x0140 , 0x8145 , 0x814F , 0x014A , 0x815B , 0x015E , 0x0154 , 0x8151 ,
0x8173 , 0x0176 , 0x017C , 0x8179 , 0x0168 , 0x816D , 0x8167 , 0x0162 ,
0x8123 , 0x0126 , 0x012C , 0x8129 , 0x0138 , 0x813D , 0x8137 , 0x0132 ,
0x0110 , 0x8115 , 0x811F , 0x011A , 0x810B , 0x010E , 0x0104 , 0x8101 ,
0x8303 , 0x0306 , 0x030C , 0x8309 , 0x0318 , 0x831D , 0x8317 , 0x0312 ,
0x0330 , 0x8335 , 0x833F , 0x033A , 0x832B , 0x032E , 0x0324 , 0x8321 ,
0x0360 , 0x8365 , 0x836F , 0x036A , 0x837B , 0x037E , 0x0374 , 0x8371 ,
0x8353 , 0x0356 , 0x035C , 0x8359 , 0x0348 , 0x834D , 0x8347 , 0x0342 ,
0x03C0 , 0x83C5 , 0x83CF , 0x03CA , 0x83DB , 0x03DE , 0x03D4 , 0x83D1 ,
0x83F3 , 0x03F6 , 0x03FC , 0x83F9 , 0x03E8 , 0x83ED , 0x83E7 , 0x03E2 ,
0x83A3 , 0x03A6 , 0x03AC , 0x83A9 , 0x03B8 , 0x83BD , 0x83B7 , 0x03B2 ,
0x0390 , 0x8395 , 0x839F , 0x039A , 0x838B , 0x038E , 0x0384 , 0x8381 ,
0x0280 , 0x8285 , 0x828F , 0x028A , 0x829B , 0x029E , 0x0294 , 0x8291 ,
0x82B3 , 0x02B6 , 0x02BC , 0x82B9 , 0x02A8 , 0x82AD , 0x82A7 , 0x02A2 ,
0x82E3 , 0x02E6 , 0x02EC , 0x82E9 , 0x02F8 , 0x82FD , 0x82F7 , 0x02F2 ,
0x02D0 , 0x82D5 , 0x82DF , 0x02DA , 0x82CB , 0x02CE , 0x02C4 , 0x82C1 ,
0x8243 , 0x0246 , 0x024C , 0x8249 , 0x0258 , 0x825D , 0x8257 , 0x0252 ,
0x0270 , 0x8275 , 0x827F , 0x027A , 0x826B , 0x026E , 0x0264 , 0x8261 ,
0x0220 , 0x8225 , 0x822F , 0x022A , 0x823B , 0x023E , 0x0234 , 0x8231 ,
0x8213 , 0x0216 , 0x021C , 0x8219 , 0x0208 , 0x820D , 0x8207 , 0x0202
} ;
static DRFLAC_INLINE drflac_uint8 drflac_crc8_byte ( drflac_uint8 crc , drflac_uint8 data )
{
return drflac__crc8_table [ crc ^ data ] ;
}
static DRFLAC_INLINE drflac_uint8 drflac_crc8 ( drflac_uint8 crc , drflac_uint32 data , drflac_uint32 count )
{
# ifdef DR_FLAC_NO_CRC
( void ) crc ;
( void ) data ;
( void ) count ;
return 0 ;
# else
#if 0
/* REFERENCE (use of this implementation requires an explicit flush by doing "drflac_crc8(crc, 0, 8);") */
drflac_uint8 p = 0x07 ;
for ( int i = count - 1 ; i > = 0 ; - - i ) {
drflac_uint8 bit = ( data & ( 1 < < i ) ) > > i ;
if ( crc & 0x80 ) {
crc = ( ( crc < < 1 ) | bit ) ^ p ;
} else {
crc = ( ( crc < < 1 ) | bit ) ;
}
}
return crc ;
# else
drflac_uint32 wholeBytes ;
drflac_uint32 leftoverBits ;
drflac_uint64 leftoverDataMask ;
static drflac_uint64 leftoverDataMaskTable [ 8 ] = {
0x00 , 0x01 , 0x03 , 0x07 , 0x0F , 0x1F , 0x3F , 0x7F
} ;
DRFLAC_ASSERT ( count < = 32 ) ;
wholeBytes = count > > 3 ;
leftoverBits = count - ( wholeBytes * 8 ) ;
leftoverDataMask = leftoverDataMaskTable [ leftoverBits ] ;
switch ( wholeBytes ) {
case 4 : crc = drflac_crc8_byte ( crc , ( drflac_uint8 ) ( ( data & ( 0xFF000000UL < < leftoverBits ) ) > > ( 24 + leftoverBits ) ) ) ;
case 3 : crc = drflac_crc8_byte ( crc , ( drflac_uint8 ) ( ( data & ( 0x00FF0000UL < < leftoverBits ) ) > > ( 16 + leftoverBits ) ) ) ;
case 2 : crc = drflac_crc8_byte ( crc , ( drflac_uint8 ) ( ( data & ( 0x0000FF00UL < < leftoverBits ) ) > > ( 8 + leftoverBits ) ) ) ;
case 1 : crc = drflac_crc8_byte ( crc , ( drflac_uint8 ) ( ( data & ( 0x000000FFUL < < leftoverBits ) ) > > ( 0 + leftoverBits ) ) ) ;
case 0 : if ( leftoverBits > 0 ) crc = ( drflac_uint8 ) ( ( crc < < leftoverBits ) ^ drflac__crc8_table [ ( crc > > ( 8 - leftoverBits ) ) ^ ( data & leftoverDataMask ) ] ) ;
}
return crc ;
# endif
# endif
}
static DRFLAC_INLINE drflac_uint16 drflac_crc16_byte ( drflac_uint16 crc , drflac_uint8 data )
{
return ( crc < < 8 ) ^ drflac__crc16_table [ ( drflac_uint8 ) ( crc > > 8 ) ^ data ] ;
}
static DRFLAC_INLINE drflac_uint16 drflac_crc16_cache ( drflac_uint16 crc , drflac_cache_t data )
{
# ifdef DRFLAC_64BIT
crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 56 ) & 0xFF ) ) ;
crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 48 ) & 0xFF ) ) ;
crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 40 ) & 0xFF ) ) ;
crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 32 ) & 0xFF ) ) ;
# endif
crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 24 ) & 0xFF ) ) ;
crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 16 ) & 0xFF ) ) ;
crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 8 ) & 0xFF ) ) ;
crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 0 ) & 0xFF ) ) ;
return crc ;
}
static DRFLAC_INLINE drflac_uint16 drflac_crc16_bytes ( drflac_uint16 crc , drflac_cache_t data , drflac_uint32 byteCount )
{
switch ( byteCount )
{
# ifdef DRFLAC_64BIT
case 8 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 56 ) & 0xFF ) ) ;
case 7 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 48 ) & 0xFF ) ) ;
case 6 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 40 ) & 0xFF ) ) ;
case 5 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 32 ) & 0xFF ) ) ;
# endif
case 4 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 24 ) & 0xFF ) ) ;
case 3 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 16 ) & 0xFF ) ) ;
case 2 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 8 ) & 0xFF ) ) ;
case 1 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data > > 0 ) & 0xFF ) ) ;
}
return crc ;
}
#if 0
static DRFLAC_INLINE drflac_uint16 drflac_crc16__32bit ( drflac_uint16 crc , drflac_uint32 data , drflac_uint32 count )
{
# ifdef DR_FLAC_NO_CRC
( void ) crc ;
( void ) data ;
( void ) count ;
return 0 ;
# else
#if 0
/* REFERENCE (use of this implementation requires an explicit flush by doing "drflac_crc16(crc, 0, 16);") */
drflac_uint16 p = 0x8005 ;
for ( int i = count - 1 ; i > = 0 ; - - i ) {
drflac_uint16 bit = ( data & ( 1ULL < < i ) ) > > i ;
if ( r & 0x8000 ) {
r = ( ( r < < 1 ) | bit ) ^ p ;
} else {
r = ( ( r < < 1 ) | bit ) ;
}
}
return crc ;
# else
drflac_uint32 wholeBytes ;
drflac_uint32 leftoverBits ;
drflac_uint64 leftoverDataMask ;
static drflac_uint64 leftoverDataMaskTable [ 8 ] = {
0x00 , 0x01 , 0x03 , 0x07 , 0x0F , 0x1F , 0x3F , 0x7F
} ;
DRFLAC_ASSERT ( count < = 64 ) ;
wholeBytes = count > > 3 ;
leftoverBits = count & 7 ;
leftoverDataMask = leftoverDataMaskTable [ leftoverBits ] ;
switch ( wholeBytes ) {
default :
case 4 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( 0xFF000000UL < < leftoverBits ) ) > > ( 24 + leftoverBits ) ) ) ;
case 3 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( 0x00FF0000UL < < leftoverBits ) ) > > ( 16 + leftoverBits ) ) ) ;
case 2 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( 0x0000FF00UL < < leftoverBits ) ) > > ( 8 + leftoverBits ) ) ) ;
case 1 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( 0x000000FFUL < < leftoverBits ) ) > > ( 0 + leftoverBits ) ) ) ;
case 0 : if ( leftoverBits > 0 ) crc = ( crc < < leftoverBits ) ^ drflac__crc16_table [ ( crc > > ( 16 - leftoverBits ) ) ^ ( data & leftoverDataMask ) ] ;
}
return crc ;
# endif
# endif
}
static DRFLAC_INLINE drflac_uint16 drflac_crc16__64bit ( drflac_uint16 crc , drflac_uint64 data , drflac_uint32 count )
{
# ifdef DR_FLAC_NO_CRC
( void ) crc ;
( void ) data ;
( void ) count ;
return 0 ;
# else
drflac_uint32 wholeBytes ;
drflac_uint32 leftoverBits ;
drflac_uint64 leftoverDataMask ;
static drflac_uint64 leftoverDataMaskTable [ 8 ] = {
0x00 , 0x01 , 0x03 , 0x07 , 0x0F , 0x1F , 0x3F , 0x7F
} ;
DRFLAC_ASSERT ( count < = 64 ) ;
wholeBytes = count > > 3 ;
leftoverBits = count & 7 ;
leftoverDataMask = leftoverDataMaskTable [ leftoverBits ] ;
switch ( wholeBytes ) {
default :
case 8 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( ( ( drflac_uint64 ) 0xFF000000 < < 32 ) < < leftoverBits ) ) > > ( 56 + leftoverBits ) ) ) ; /* Weird "<< 32" bitshift is required for C89 because it doesn't support 64-bit constants. Should be optimized out by a good compiler. */
case 7 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( ( ( drflac_uint64 ) 0x00FF0000 < < 32 ) < < leftoverBits ) ) > > ( 48 + leftoverBits ) ) ) ;
case 6 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( ( ( drflac_uint64 ) 0x0000FF00 < < 32 ) < < leftoverBits ) ) > > ( 40 + leftoverBits ) ) ) ;
case 5 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( ( ( drflac_uint64 ) 0x000000FF < < 32 ) < < leftoverBits ) ) > > ( 32 + leftoverBits ) ) ) ;
case 4 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( ( ( drflac_uint64 ) 0xFF000000 ) < < leftoverBits ) ) > > ( 24 + leftoverBits ) ) ) ;
case 3 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( ( ( drflac_uint64 ) 0x00FF0000 ) < < leftoverBits ) ) > > ( 16 + leftoverBits ) ) ) ;
case 2 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( ( ( drflac_uint64 ) 0x0000FF00 ) < < leftoverBits ) ) > > ( 8 + leftoverBits ) ) ) ;
case 1 : crc = drflac_crc16_byte ( crc , ( drflac_uint8 ) ( ( data & ( ( ( drflac_uint64 ) 0x000000FF ) < < leftoverBits ) ) > > ( 0 + leftoverBits ) ) ) ;
case 0 : if ( leftoverBits > 0 ) crc = ( crc < < leftoverBits ) ^ drflac__crc16_table [ ( crc > > ( 16 - leftoverBits ) ) ^ ( data & leftoverDataMask ) ] ;
}
return crc ;
# endif
}
static DRFLAC_INLINE drflac_uint16 drflac_crc16 ( drflac_uint16 crc , drflac_cache_t data , drflac_uint32 count )
{
# ifdef DRFLAC_64BIT
return drflac_crc16__64bit ( crc , data , count ) ;
# else
return drflac_crc16__32bit ( crc , data , count ) ;
# endif
}
# endif
# ifdef DRFLAC_64BIT
# define drflac__be2host__cache_line drflac__be2host_64
# else
# define drflac__be2host__cache_line drflac__be2host_32
# endif
/*
BIT READING ATTEMPT # 2
This uses a 32 - or 64 - bit bit - shifted cache - as bits are read , the cache is shifted such that the first valid bit is sitting
on the most significant bit . It uses the notion of an L1 and L2 cache ( borrowed from CPU architecture ) , where the L1 cache
is a 32 - or 64 - bit unsigned integer ( depending on whether or not a 32 - or 64 - bit build is being compiled ) and the L2 is an
array of " cache lines " , with each cache line being the same size as the L1 . The L2 is a buffer of about 4 KB and is where data
from onRead ( ) is read into .
*/
# define DRFLAC_CACHE_L1_SIZE_BYTES(bs) (sizeof((bs)->cache))
# define DRFLAC_CACHE_L1_SIZE_BITS(bs) (sizeof((bs)->cache)*8)
# define DRFLAC_CACHE_L1_BITS_REMAINING(bs) (DRFLAC_CACHE_L1_SIZE_BITS(bs) - (bs)->consumedBits)
# define DRFLAC_CACHE_L1_SELECTION_MASK(_bitCount) (~((~(drflac_cache_t)0) >> (_bitCount)))
# define DRFLAC_CACHE_L1_SELECTION_SHIFT(bs, _bitCount) (DRFLAC_CACHE_L1_SIZE_BITS(bs) - (_bitCount))
# define DRFLAC_CACHE_L1_SELECT(bs, _bitCount) (((bs)->cache) & DRFLAC_CACHE_L1_SELECTION_MASK(_bitCount))
# define DRFLAC_CACHE_L1_SELECT_AND_SHIFT(bs, _bitCount) (DRFLAC_CACHE_L1_SELECT((bs), (_bitCount)) >> DRFLAC_CACHE_L1_SELECTION_SHIFT((bs), (_bitCount)))
# define DRFLAC_CACHE_L1_SELECT_AND_SHIFT_SAFE(bs, _bitCount)(DRFLAC_CACHE_L1_SELECT((bs), (_bitCount)) >> (DRFLAC_CACHE_L1_SELECTION_SHIFT((bs), (_bitCount)) & (DRFLAC_CACHE_L1_SIZE_BITS(bs)-1)))
# define DRFLAC_CACHE_L2_SIZE_BYTES(bs) (sizeof((bs)->cacheL2))
# define DRFLAC_CACHE_L2_LINE_COUNT(bs) (DRFLAC_CACHE_L2_SIZE_BYTES(bs) / sizeof((bs)->cacheL2[0]))
# define DRFLAC_CACHE_L2_LINES_REMAINING(bs) (DRFLAC_CACHE_L2_LINE_COUNT(bs) - (bs)->nextL2Line)
# ifndef DR_FLAC_NO_CRC
static DRFLAC_INLINE void drflac__reset_crc16 ( drflac_bs * bs )
{
bs - > crc16 = 0 ;
bs - > crc16CacheIgnoredBytes = bs - > consumedBits > > 3 ;
}
static DRFLAC_INLINE void drflac__update_crc16 ( drflac_bs * bs )
{
if ( bs - > crc16CacheIgnoredBytes = = 0 ) {
bs - > crc16 = drflac_crc16_cache ( bs - > crc16 , bs - > crc16Cache ) ;
} else {
bs - > crc16 = drflac_crc16_bytes ( bs - > crc16 , bs - > crc16Cache , DRFLAC_CACHE_L1_SIZE_BYTES ( bs ) - bs - > crc16CacheIgnoredBytes ) ;
bs - > crc16CacheIgnoredBytes = 0 ;
}
}
static DRFLAC_INLINE drflac_uint16 drflac__flush_crc16 ( drflac_bs * bs )
{
/* We should never be flushing in a situation where we are not aligned on a byte boundary. */
DRFLAC_ASSERT ( ( DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) & 7 ) = = 0 ) ;
/*
The bits that were read from the L1 cache need to be accumulated . The number of bytes needing to be accumulated is determined
by the number of bits that have been consumed .
*/
if ( DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) = = 0 ) {
drflac__update_crc16 ( bs ) ;
} else {
/* We only accumulate the consumed bits. */
bs - > crc16 = drflac_crc16_bytes ( bs - > crc16 , bs - > crc16Cache > > DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) , ( bs - > consumedBits > > 3 ) - bs - > crc16CacheIgnoredBytes ) ;
/*
The bits that we just accumulated should never be accumulated again . We need to keep track of how many bytes were accumulated
so we can handle that later .
*/
bs - > crc16CacheIgnoredBytes = bs - > consumedBits > > 3 ;
}
return bs - > crc16 ;
}
# endif
static DRFLAC_INLINE drflac_bool32 drflac__reload_l1_cache_from_l2 ( drflac_bs * bs )
{
size_t bytesRead ;
size_t alignedL1LineCount ;
/* Fast path. Try loading straight from L2. */
if ( bs - > nextL2Line < DRFLAC_CACHE_L2_LINE_COUNT ( bs ) ) {
bs - > cache = bs - > cacheL2 [ bs - > nextL2Line + + ] ;
return DRFLAC_TRUE ;
}
/*
If we get here it means we ' ve run out of data in the L2 cache . We ' ll need to fetch more from the client , if there ' s
any left .
*/
if ( bs - > unalignedByteCount > 0 ) {
return DRFLAC_FALSE ; /* If we have any unaligned bytes it means there's no more aligned bytes left in the client. */
}
bytesRead = bs - > onRead ( bs - > pUserData , bs - > cacheL2 , DRFLAC_CACHE_L2_SIZE_BYTES ( bs ) ) ;
bs - > nextL2Line = 0 ;
if ( bytesRead = = DRFLAC_CACHE_L2_SIZE_BYTES ( bs ) ) {
bs - > cache = bs - > cacheL2 [ bs - > nextL2Line + + ] ;
return DRFLAC_TRUE ;
}
/*
If we get here it means we were unable to retrieve enough data to fill the entire L2 cache . It probably
means we ' ve just reached the end of the file . We need to move the valid data down to the end of the buffer
and adjust the index of the next line accordingly . Also keep in mind that the L2 cache must be aligned to
the size of the L1 so we ' ll need to seek backwards by any misaligned bytes .
*/
alignedL1LineCount = bytesRead / DRFLAC_CACHE_L1_SIZE_BYTES ( bs ) ;
/* We need to keep track of any unaligned bytes for later use. */
bs - > unalignedByteCount = bytesRead - ( alignedL1LineCount * DRFLAC_CACHE_L1_SIZE_BYTES ( bs ) ) ;
if ( bs - > unalignedByteCount > 0 ) {
bs - > unalignedCache = bs - > cacheL2 [ alignedL1LineCount ] ;
}
if ( alignedL1LineCount > 0 ) {
size_t offset = DRFLAC_CACHE_L2_LINE_COUNT ( bs ) - alignedL1LineCount ;
size_t i ;
for ( i = alignedL1LineCount ; i > 0 ; - - i ) {
bs - > cacheL2 [ i - 1 + offset ] = bs - > cacheL2 [ i - 1 ] ;
}
bs - > nextL2Line = ( drflac_uint32 ) offset ;
bs - > cache = bs - > cacheL2 [ bs - > nextL2Line + + ] ;
return DRFLAC_TRUE ;
} else {
/* If we get into this branch it means we weren't able to load any L1-aligned data. */
bs - > nextL2Line = DRFLAC_CACHE_L2_LINE_COUNT ( bs ) ;
return DRFLAC_FALSE ;
}
}
static drflac_bool32 drflac__reload_cache ( drflac_bs * bs )
{
size_t bytesRead ;
# ifndef DR_FLAC_NO_CRC
drflac__update_crc16 ( bs ) ;
# endif
/* Fast path. Try just moving the next value in the L2 cache to the L1 cache. */
if ( drflac__reload_l1_cache_from_l2 ( bs ) ) {
bs - > cache = drflac__be2host__cache_line ( bs - > cache ) ;
bs - > consumedBits = 0 ;
# ifndef DR_FLAC_NO_CRC
bs - > crc16Cache = bs - > cache ;
# endif
return DRFLAC_TRUE ;
}
/* Slow path. */
/*
If we get here it means we have failed to load the L1 cache from the L2 . Likely we ' ve just reached the end of the stream and the last
few bytes did not meet the alignment requirements for the L2 cache . In this case we need to fall back to a slower path and read the
data from the unaligned cache .
*/
bytesRead = bs - > unalignedByteCount ;
if ( bytesRead = = 0 ) {
bs - > consumedBits = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ; /* <-- The stream has been exhausted, so marked the bits as consumed. */
return DRFLAC_FALSE ;
}
DRFLAC_ASSERT ( bytesRead < DRFLAC_CACHE_L1_SIZE_BYTES ( bs ) ) ;
bs - > consumedBits = ( drflac_uint32 ) ( DRFLAC_CACHE_L1_SIZE_BYTES ( bs ) - bytesRead ) * 8 ;
bs - > cache = drflac__be2host__cache_line ( bs - > unalignedCache ) ;
bs - > cache & = DRFLAC_CACHE_L1_SELECTION_MASK ( DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) ; /* <-- Make sure the consumed bits are always set to zero. Other parts of the library depend on this property. */
bs - > unalignedByteCount = 0 ; /* <-- At this point the unaligned bytes have been moved into the cache and we thus have no more unaligned bytes. */
# ifndef DR_FLAC_NO_CRC
bs - > crc16Cache = bs - > cache > > bs - > consumedBits ;
bs - > crc16CacheIgnoredBytes = bs - > consumedBits > > 3 ;
# endif
return DRFLAC_TRUE ;
}
static void drflac__reset_cache ( drflac_bs * bs )
{
bs - > nextL2Line = DRFLAC_CACHE_L2_LINE_COUNT ( bs ) ; /* <-- This clears the L2 cache. */
bs - > consumedBits = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ; /* <-- This clears the L1 cache. */
bs - > cache = 0 ;
bs - > unalignedByteCount = 0 ; /* <-- This clears the trailing unaligned bytes. */
bs - > unalignedCache = 0 ;
# ifndef DR_FLAC_NO_CRC
bs - > crc16Cache = 0 ;
bs - > crc16CacheIgnoredBytes = 0 ;
# endif
}
static DRFLAC_INLINE drflac_bool32 drflac__read_uint32 ( drflac_bs * bs , unsigned int bitCount , drflac_uint32 * pResultOut )
{
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pResultOut ! = NULL ) ;
DRFLAC_ASSERT ( bitCount > 0 ) ;
DRFLAC_ASSERT ( bitCount < = 32 ) ;
if ( bs - > consumedBits = = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ) {
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
}
if ( bitCount < = DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) {
/*
If we want to load all 32 - bits from a 32 - bit cache we need to do it slightly differently because we can ' t do
a 32 - bit shift on a 32 - bit integer . This will never be the case on 64 - bit caches , so we can have a slightly
more optimal solution for this .
*/
# ifdef DRFLAC_64BIT
* pResultOut = ( drflac_uint32 ) DRFLAC_CACHE_L1_SELECT_AND_SHIFT ( bs , bitCount ) ;
bs - > consumedBits + = bitCount ;
bs - > cache < < = bitCount ;
# else
if ( bitCount < DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ) {
* pResultOut = ( drflac_uint32 ) DRFLAC_CACHE_L1_SELECT_AND_SHIFT ( bs , bitCount ) ;
bs - > consumedBits + = bitCount ;
bs - > cache < < = bitCount ;
} else {
/* Cannot shift by 32-bits, so need to do it differently. */
* pResultOut = ( drflac_uint32 ) bs - > cache ;
bs - > consumedBits = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ;
bs - > cache = 0 ;
}
# endif
return DRFLAC_TRUE ;
} else {
/* It straddles the cached data. It will never cover more than the next chunk. We just read the number in two parts and combine them. */
drflac_uint32 bitCountHi = DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ;
drflac_uint32 bitCountLo = bitCount - bitCountHi ;
drflac_uint32 resultHi ;
DRFLAC_ASSERT ( bitCountHi > 0 ) ;
DRFLAC_ASSERT ( bitCountHi < 32 ) ;
resultHi = ( drflac_uint32 ) DRFLAC_CACHE_L1_SELECT_AND_SHIFT ( bs , bitCountHi ) ;
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
if ( bitCountLo > DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) {
/* This happens when we get to end of stream */
return DRFLAC_FALSE ;
}
* pResultOut = ( resultHi < < bitCountLo ) | ( drflac_uint32 ) DRFLAC_CACHE_L1_SELECT_AND_SHIFT ( bs , bitCountLo ) ;
bs - > consumedBits + = bitCountLo ;
bs - > cache < < = bitCountLo ;
return DRFLAC_TRUE ;
}
}
static drflac_bool32 drflac__read_int32 ( drflac_bs * bs , unsigned int bitCount , drflac_int32 * pResult )
{
drflac_uint32 result ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pResult ! = NULL ) ;
DRFLAC_ASSERT ( bitCount > 0 ) ;
DRFLAC_ASSERT ( bitCount < = 32 ) ;
if ( ! drflac__read_uint32 ( bs , bitCount , & result ) ) {
return DRFLAC_FALSE ;
}
/* Do not attempt to shift by 32 as it's undefined. */
if ( bitCount < 32 ) {
drflac_uint32 signbit ;
signbit = ( ( result > > ( bitCount - 1 ) ) & 0x01 ) ;
result | = ( ~ signbit + 1 ) < < bitCount ;
}
* pResult = ( drflac_int32 ) result ;
return DRFLAC_TRUE ;
}
# ifdef DRFLAC_64BIT
static drflac_bool32 drflac__read_uint64 ( drflac_bs * bs , unsigned int bitCount , drflac_uint64 * pResultOut )
{
drflac_uint32 resultHi ;
drflac_uint32 resultLo ;
DRFLAC_ASSERT ( bitCount < = 64 ) ;
DRFLAC_ASSERT ( bitCount > 32 ) ;
if ( ! drflac__read_uint32 ( bs , bitCount - 32 , & resultHi ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac__read_uint32 ( bs , 32 , & resultLo ) ) {
return DRFLAC_FALSE ;
}
* pResultOut = ( ( ( drflac_uint64 ) resultHi ) < < 32 ) | ( ( drflac_uint64 ) resultLo ) ;
return DRFLAC_TRUE ;
}
# endif
/* Function below is unused, but leaving it here in case I need to quickly add it again. */
#if 0
static drflac_bool32 drflac__read_int64 ( drflac_bs * bs , unsigned int bitCount , drflac_int64 * pResultOut )
{
drflac_uint64 result ;
drflac_uint64 signbit ;
DRFLAC_ASSERT ( bitCount < = 64 ) ;
if ( ! drflac__read_uint64 ( bs , bitCount , & result ) ) {
return DRFLAC_FALSE ;
}
signbit = ( ( result > > ( bitCount - 1 ) ) & 0x01 ) ;
result | = ( ~ signbit + 1 ) < < bitCount ;
* pResultOut = ( drflac_int64 ) result ;
return DRFLAC_TRUE ;
}
# endif
static drflac_bool32 drflac__read_uint16 ( drflac_bs * bs , unsigned int bitCount , drflac_uint16 * pResult )
{
drflac_uint32 result ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pResult ! = NULL ) ;
DRFLAC_ASSERT ( bitCount > 0 ) ;
DRFLAC_ASSERT ( bitCount < = 16 ) ;
if ( ! drflac__read_uint32 ( bs , bitCount , & result ) ) {
return DRFLAC_FALSE ;
}
* pResult = ( drflac_uint16 ) result ;
return DRFLAC_TRUE ;
}
#if 0
static drflac_bool32 drflac__read_int16 ( drflac_bs * bs , unsigned int bitCount , drflac_int16 * pResult )
{
drflac_int32 result ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pResult ! = NULL ) ;
DRFLAC_ASSERT ( bitCount > 0 ) ;
DRFLAC_ASSERT ( bitCount < = 16 ) ;
if ( ! drflac__read_int32 ( bs , bitCount , & result ) ) {
return DRFLAC_FALSE ;
}
* pResult = ( drflac_int16 ) result ;
return DRFLAC_TRUE ;
}
# endif
static drflac_bool32 drflac__read_uint8 ( drflac_bs * bs , unsigned int bitCount , drflac_uint8 * pResult )
{
drflac_uint32 result ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pResult ! = NULL ) ;
DRFLAC_ASSERT ( bitCount > 0 ) ;
DRFLAC_ASSERT ( bitCount < = 8 ) ;
if ( ! drflac__read_uint32 ( bs , bitCount , & result ) ) {
return DRFLAC_FALSE ;
}
* pResult = ( drflac_uint8 ) result ;
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__read_int8 ( drflac_bs * bs , unsigned int bitCount , drflac_int8 * pResult )
{
drflac_int32 result ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pResult ! = NULL ) ;
DRFLAC_ASSERT ( bitCount > 0 ) ;
DRFLAC_ASSERT ( bitCount < = 8 ) ;
if ( ! drflac__read_int32 ( bs , bitCount , & result ) ) {
return DRFLAC_FALSE ;
}
* pResult = ( drflac_int8 ) result ;
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__seek_bits ( drflac_bs * bs , size_t bitsToSeek )
{
if ( bitsToSeek < = DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) {
bs - > consumedBits + = ( drflac_uint32 ) bitsToSeek ;
bs - > cache < < = bitsToSeek ;
return DRFLAC_TRUE ;
} else {
/* It straddles the cached data. This function isn't called too frequently so I'm favouring simplicity here. */
bitsToSeek - = DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ;
bs - > consumedBits + = DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ;
bs - > cache = 0 ;
/* Simple case. Seek in groups of the same number as bits that fit within a cache line. */
# ifdef DRFLAC_64BIT
while ( bitsToSeek > = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ) {
drflac_uint64 bin ;
if ( ! drflac__read_uint64 ( bs , DRFLAC_CACHE_L1_SIZE_BITS ( bs ) , & bin ) ) {
return DRFLAC_FALSE ;
}
bitsToSeek - = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ;
}
# else
while ( bitsToSeek > = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ) {
drflac_uint32 bin ;
if ( ! drflac__read_uint32 ( bs , DRFLAC_CACHE_L1_SIZE_BITS ( bs ) , & bin ) ) {
return DRFLAC_FALSE ;
}
bitsToSeek - = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ;
}
# endif
/* Whole leftover bytes. */
while ( bitsToSeek > = 8 ) {
drflac_uint8 bin ;
if ( ! drflac__read_uint8 ( bs , 8 , & bin ) ) {
return DRFLAC_FALSE ;
}
bitsToSeek - = 8 ;
}
/* Leftover bits. */
if ( bitsToSeek > 0 ) {
drflac_uint8 bin ;
if ( ! drflac__read_uint8 ( bs , ( drflac_uint32 ) bitsToSeek , & bin ) ) {
return DRFLAC_FALSE ;
}
bitsToSeek = 0 ; /* <-- Necessary for the assert below. */
}
DRFLAC_ASSERT ( bitsToSeek = = 0 ) ;
return DRFLAC_TRUE ;
}
}
/* This function moves the bit streamer to the first bit after the sync code (bit 15 of the of the frame header). It will also update the CRC-16. */
static drflac_bool32 drflac__find_and_seek_to_next_sync_code ( drflac_bs * bs )
{
DRFLAC_ASSERT ( bs ! = NULL ) ;
/*
The sync code is always aligned to 8 bits . This is convenient for us because it means we can do byte - aligned movements . The first
thing to do is align to the next byte .
*/
if ( ! drflac__seek_bits ( bs , DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) & 7 ) ) {
return DRFLAC_FALSE ;
}
for ( ; ; ) {
drflac_uint8 hi ;
# ifndef DR_FLAC_NO_CRC
drflac__reset_crc16 ( bs ) ;
# endif
if ( ! drflac__read_uint8 ( bs , 8 , & hi ) ) {
return DRFLAC_FALSE ;
}
if ( hi = = 0xFF ) {
drflac_uint8 lo ;
if ( ! drflac__read_uint8 ( bs , 6 , & lo ) ) {
return DRFLAC_FALSE ;
}
if ( lo = = 0x3E ) {
return DRFLAC_TRUE ;
} else {
if ( ! drflac__seek_bits ( bs , DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) & 7 ) ) {
return DRFLAC_FALSE ;
}
}
}
}
/* Should never get here. */
/*return DRFLAC_FALSE;*/
}
# if defined(DRFLAC_HAS_LZCNT_INTRINSIC)
# define DRFLAC_IMPLEMENT_CLZ_LZCNT
# endif
# if defined(_MSC_VER) && _MSC_VER >= 1400 && (defined(DRFLAC_X64) || defined(DRFLAC_X86)) && !defined(__clang__)
# define DRFLAC_IMPLEMENT_CLZ_MSVC
# endif
# if defined(__WATCOMC__) && defined(__386__)
# define DRFLAC_IMPLEMENT_CLZ_WATCOM
# endif
static DRFLAC_INLINE drflac_uint32 drflac__clz_software ( drflac_cache_t x )
{
drflac_uint32 n ;
static drflac_uint32 clz_table_4 [ ] = {
0 ,
4 ,
3 , 3 ,
2 , 2 , 2 , 2 ,
1 , 1 , 1 , 1 , 1 , 1 , 1 , 1
} ;
if ( x = = 0 ) {
return sizeof ( x ) * 8 ;
}
n = clz_table_4 [ x > > ( sizeof ( x ) * 8 - 4 ) ] ;
if ( n = = 0 ) {
# ifdef DRFLAC_64BIT
if ( ( x & ( ( drflac_uint64 ) 0xFFFFFFFF < < 32 ) ) = = 0 ) { n = 32 ; x < < = 32 ; }
if ( ( x & ( ( drflac_uint64 ) 0xFFFF0000 < < 32 ) ) = = 0 ) { n + = 16 ; x < < = 16 ; }
if ( ( x & ( ( drflac_uint64 ) 0xFF000000 < < 32 ) ) = = 0 ) { n + = 8 ; x < < = 8 ; }
if ( ( x & ( ( drflac_uint64 ) 0xF0000000 < < 32 ) ) = = 0 ) { n + = 4 ; x < < = 4 ; }
# else
if ( ( x & 0xFFFF0000 ) = = 0 ) { n = 16 ; x < < = 16 ; }
if ( ( x & 0xFF000000 ) = = 0 ) { n + = 8 ; x < < = 8 ; }
if ( ( x & 0xF0000000 ) = = 0 ) { n + = 4 ; x < < = 4 ; }
# endif
n + = clz_table_4 [ x > > ( sizeof ( x ) * 8 - 4 ) ] ;
}
return n - 1 ;
}
# ifdef DRFLAC_IMPLEMENT_CLZ_LZCNT
static DRFLAC_INLINE drflac_bool32 drflac__is_lzcnt_supported ( void )
{
/* Fast compile time check for ARM. */
# if defined(DRFLAC_HAS_LZCNT_INTRINSIC) && defined(DRFLAC_ARM) && (defined(__ARM_ARCH) && __ARM_ARCH >= 5)
return DRFLAC_TRUE ;
# else
/* If the compiler itself does not support the intrinsic then we'll need to return false. */
# ifdef DRFLAC_HAS_LZCNT_INTRINSIC
return drflac__gIsLZCNTSupported ;
# else
return DRFLAC_FALSE ;
# endif
# endif
}
static DRFLAC_INLINE drflac_uint32 drflac__clz_lzcnt ( drflac_cache_t x )
{
/*
It ' s critical for competitive decoding performance that this function be highly optimal . With MSVC we can use the __lzcnt64 ( ) and __lzcnt ( ) intrinsics
to achieve good performance , however on GCC and Clang it ' s a little bit more annoying . The __builtin_clzl ( ) and __builtin_clzll ( ) intrinsics leave
it undefined as to the return value when ` x ` is 0. We need this to be well defined as returning 32 or 64 , depending on whether or not it ' s a 32 - or
64 - bit build . To work around this we would need to add a conditional to check for the x = 0 case , but this creates unnecessary inefficiency . To work
around this problem I have written some inline assembly to emit the LZCNT ( x86 ) or CLZ ( ARM ) instruction directly which removes the need to include
the conditional . This has worked well in the past , but for some reason Clang ' s MSVC compatible driver , clang - cl , does not seem to be handling this
in the same way as the normal Clang driver . It seems that ` clang - cl ` is just outputting the wrong results sometimes , maybe due to some register
getting clobbered ?
I ' m not sure if this is a bug with dr_flac ' s inlined assembly ( most likely ) , a bug in ` clang - cl ` or just a misunderstanding on my part with inline
assembly rules for ` clang - cl ` . If somebody can identify an error in dr_flac ' s inlined assembly I ' m happy to get that fixed .
Fortunately there is an easy workaround for this . Clang implements MSVC - specific intrinsics for compatibility . It also defines _MSC_VER for extra
compatibility . We can therefore just check for _MSC_VER and use the MSVC intrinsic which , fortunately for us , Clang supports . It would still be nice
to know how to fix the inlined assembly for correctness sake , however .
*/
# if defined(_MSC_VER) /*&& !defined(__clang__)*/ /* <-- Intentionally wanting Clang to use the MSVC __lzcnt64/__lzcnt intrinsics due to above ^. */
# ifdef DRFLAC_64BIT
return ( drflac_uint32 ) __lzcnt64 ( x ) ;
# else
return ( drflac_uint32 ) __lzcnt ( x ) ;
# endif
# else
# if defined(__GNUC__) || defined(__clang__)
# if defined(DRFLAC_X64)
{
drflac_uint64 r ;
__asm__ __volatile__ (
" lzcnt{ %1, %0| %0, %1} " : " =r " ( r ) : " r " ( x ) : " cc "
) ;
return ( drflac_uint32 ) r ;
}
# elif defined(DRFLAC_X86)
{
drflac_uint32 r ;
__asm__ __volatile__ (
" lzcnt{l %1, %0| %0, %1} " : " =r " ( r ) : " r " ( x ) : " cc "
) ;
return r ;
}
# elif defined(DRFLAC_ARM) && (defined(__ARM_ARCH) && __ARM_ARCH >= 5) && !defined(DRFLAC_64BIT) /* <-- I haven't tested 64-bit inline assembly, so only enabling this for the 32-bit build for now. */
{
unsigned int r ;
__asm__ __volatile__ (
# if defined(DRFLAC_64BIT)
" clz %w[out], %w[in] " : [ out ] " =r " ( r ) : [ in ] " r " ( x ) /* <-- This is untested. If someone in the community could test this, that would be appreciated! */
# else
" clz %[out], %[in] " : [ out ] " =r " ( r ) : [ in ] " r " ( x )
# endif
) ;
return r ;
}
# else
if ( x = = 0 ) {
return sizeof ( x ) * 8 ;
}
# ifdef DRFLAC_64BIT
return ( drflac_uint32 ) __builtin_clzll ( ( drflac_uint64 ) x ) ;
# else
return ( drflac_uint32 ) __builtin_clzl ( ( drflac_uint32 ) x ) ;
# endif
# endif
# else
/* Unsupported compiler. */
# error "This compiler does not support the lzcnt intrinsic."
# endif
# endif
}
# endif
# ifdef DRFLAC_IMPLEMENT_CLZ_MSVC
# include <intrin.h> /* For BitScanReverse(). */
static DRFLAC_INLINE drflac_uint32 drflac__clz_msvc ( drflac_cache_t x )
{
drflac_uint32 n ;
if ( x = = 0 ) {
return sizeof ( x ) * 8 ;
}
# ifdef DRFLAC_64BIT
_BitScanReverse64 ( ( unsigned long * ) & n , x ) ;
# else
_BitScanReverse ( ( unsigned long * ) & n , x ) ;
# endif
return sizeof ( x ) * 8 - n - 1 ;
}
# endif
# ifdef DRFLAC_IMPLEMENT_CLZ_WATCOM
static __inline drflac_uint32 drflac__clz_watcom ( drflac_uint32 ) ;
# pragma aux drflac__clz_watcom = \
" bsr eax, eax " \
" xor eax, 31 " \
parm [ eax ] nomemory \
value [ eax ] \
modify exact [ eax ] nomemory ;
# endif
static DRFLAC_INLINE drflac_uint32 drflac__clz ( drflac_cache_t x )
{
# ifdef DRFLAC_IMPLEMENT_CLZ_LZCNT
if ( drflac__is_lzcnt_supported ( ) ) {
return drflac__clz_lzcnt ( x ) ;
} else
# endif
{
# ifdef DRFLAC_IMPLEMENT_CLZ_MSVC
return drflac__clz_msvc ( x ) ;
# elif defined(DRFLAC_IMPLEMENT_CLZ_WATCOM)
return ( x = = 0 ) ? sizeof ( x ) * 8 : drflac__clz_watcom ( x ) ;
# else
return drflac__clz_software ( x ) ;
# endif
}
}
static DRFLAC_INLINE drflac_bool32 drflac__seek_past_next_set_bit ( drflac_bs * bs , unsigned int * pOffsetOut )
{
drflac_uint32 zeroCounter = 0 ;
drflac_uint32 setBitOffsetPlus1 ;
while ( bs - > cache = = 0 ) {
zeroCounter + = ( drflac_uint32 ) DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ;
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
}
if ( bs - > cache = = 1 ) {
/* Not catching this would lead to undefined behaviour: a shift of a 32-bit number by 32 or more is undefined */
* pOffsetOut = zeroCounter + ( drflac_uint32 ) DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) - 1 ;
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
return DRFLAC_TRUE ;
}
setBitOffsetPlus1 = drflac__clz ( bs - > cache ) ;
setBitOffsetPlus1 + = 1 ;
if ( setBitOffsetPlus1 > DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) {
/* This happens when we get to end of stream */
return DRFLAC_FALSE ;
}
bs - > consumedBits + = setBitOffsetPlus1 ;
bs - > cache < < = setBitOffsetPlus1 ;
* pOffsetOut = zeroCounter + setBitOffsetPlus1 - 1 ;
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__seek_to_byte ( drflac_bs * bs , drflac_uint64 offsetFromStart )
{
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( offsetFromStart > 0 ) ;
/*
Seeking from the start is not quite as trivial as it sounds because the onSeek callback takes a signed 32 - bit integer ( which
is intentional because it simplifies the implementation of the onSeek callbacks ) , however offsetFromStart is unsigned 64 - bit .
To resolve we just need to do an initial seek from the start , and then a series of offset seeks to make up the remainder .
*/
if ( offsetFromStart > 0x7FFFFFFF ) {
drflac_uint64 bytesRemaining = offsetFromStart ;
if ( ! bs - > onSeek ( bs - > pUserData , 0x7FFFFFFF , drflac_seek_origin_start ) ) {
return DRFLAC_FALSE ;
}
bytesRemaining - = 0x7FFFFFFF ;
while ( bytesRemaining > 0x7FFFFFFF ) {
if ( ! bs - > onSeek ( bs - > pUserData , 0x7FFFFFFF , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ;
}
bytesRemaining - = 0x7FFFFFFF ;
}
if ( bytesRemaining > 0 ) {
if ( ! bs - > onSeek ( bs - > pUserData , ( int ) bytesRemaining , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ;
}
}
} else {
if ( ! bs - > onSeek ( bs - > pUserData , ( int ) offsetFromStart , drflac_seek_origin_start ) ) {
return DRFLAC_FALSE ;
}
}
/* The cache should be reset to force a reload of fresh data from the client. */
drflac__reset_cache ( bs ) ;
return DRFLAC_TRUE ;
}
static drflac_result drflac__read_utf8_coded_number ( drflac_bs * bs , drflac_uint64 * pNumberOut , drflac_uint8 * pCRCOut )
{
drflac_uint8 crc ;
drflac_uint64 result ;
drflac_uint8 utf8 [ 7 ] = { 0 } ;
int byteCount ;
int i ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pNumberOut ! = NULL ) ;
DRFLAC_ASSERT ( pCRCOut ! = NULL ) ;
crc = * pCRCOut ;
if ( ! drflac__read_uint8 ( bs , 8 , utf8 ) ) {
* pNumberOut = 0 ;
return DRFLAC_AT_END ;
}
crc = drflac_crc8 ( crc , utf8 [ 0 ] , 8 ) ;
if ( ( utf8 [ 0 ] & 0x80 ) = = 0 ) {
* pNumberOut = utf8 [ 0 ] ;
* pCRCOut = crc ;
return DRFLAC_SUCCESS ;
}
/*byteCount = 1;*/
if ( ( utf8 [ 0 ] & 0xE0 ) = = 0xC0 ) {
byteCount = 2 ;
} else if ( ( utf8 [ 0 ] & 0xF0 ) = = 0xE0 ) {
byteCount = 3 ;
} else if ( ( utf8 [ 0 ] & 0xF8 ) = = 0xF0 ) {
byteCount = 4 ;
} else if ( ( utf8 [ 0 ] & 0xFC ) = = 0xF8 ) {
byteCount = 5 ;
} else if ( ( utf8 [ 0 ] & 0xFE ) = = 0xFC ) {
byteCount = 6 ;
} else if ( ( utf8 [ 0 ] & 0xFF ) = = 0xFE ) {
byteCount = 7 ;
} else {
* pNumberOut = 0 ;
return DRFLAC_CRC_MISMATCH ; /* Bad UTF-8 encoding. */
}
/* Read extra bytes. */
DRFLAC_ASSERT ( byteCount > 1 ) ;
result = ( drflac_uint64 ) ( utf8 [ 0 ] & ( 0xFF > > ( byteCount + 1 ) ) ) ;
for ( i = 1 ; i < byteCount ; + + i ) {
if ( ! drflac__read_uint8 ( bs , 8 , utf8 + i ) ) {
* pNumberOut = 0 ;
return DRFLAC_AT_END ;
}
crc = drflac_crc8 ( crc , utf8 [ i ] , 8 ) ;
result = ( result < < 6 ) | ( utf8 [ i ] & 0x3F ) ;
}
* pNumberOut = result ;
* pCRCOut = crc ;
return DRFLAC_SUCCESS ;
}
static DRFLAC_INLINE drflac_uint32 drflac__ilog2_u32 ( drflac_uint32 x )
{
# if 1 /* Needs optimizing. */
drflac_uint32 result = 0 ;
while ( x > 0 ) {
result + = 1 ;
x > > = 1 ;
}
return result ;
# endif
}
static DRFLAC_INLINE drflac_bool32 drflac__use_64_bit_prediction ( drflac_uint32 bitsPerSample , drflac_uint32 order , drflac_uint32 precision )
{
/* https://web.archive.org/web/20220205005724/https://github.com/ietf-wg-cellar/flac-specification/blob/37a49aa48ba4ba12e8757badfc59c0df35435fec/rfc_backmatter.md */
return bitsPerSample + precision + drflac__ilog2_u32 ( order ) > 32 ;
}
/*
The next two functions are responsible for calculating the prediction .
When the bits per sample is > 16 we need to use 64 - bit integer arithmetic because otherwise we ' ll run out of precision . It ' s
safe to assume this will be slower on 32 - bit platforms so we use a more optimal solution when the bits per sample is < = 16.
*/
# if defined(__clang__)
__attribute__ ( ( no_sanitize ( " signed-integer-overflow " ) ) )
# endif
static DRFLAC_INLINE drflac_int32 drflac__calculate_prediction_32 ( drflac_uint32 order , drflac_int32 shift , const drflac_int32 * coefficients , drflac_int32 * pDecodedSamples )
{
drflac_int32 prediction = 0 ;
DRFLAC_ASSERT ( order < = 32 ) ;
/* 32-bit version. */
/* VC++ optimizes this to a single jmp. I've not yet verified this for other compilers. */
switch ( order )
{
case 32 : prediction + = coefficients [ 31 ] * pDecodedSamples [ - 32 ] ;
case 31 : prediction + = coefficients [ 30 ] * pDecodedSamples [ - 31 ] ;
case 30 : prediction + = coefficients [ 29 ] * pDecodedSamples [ - 30 ] ;
case 29 : prediction + = coefficients [ 28 ] * pDecodedSamples [ - 29 ] ;
case 28 : prediction + = coefficients [ 27 ] * pDecodedSamples [ - 28 ] ;
case 27 : prediction + = coefficients [ 26 ] * pDecodedSamples [ - 27 ] ;
case 26 : prediction + = coefficients [ 25 ] * pDecodedSamples [ - 26 ] ;
case 25 : prediction + = coefficients [ 24 ] * pDecodedSamples [ - 25 ] ;
case 24 : prediction + = coefficients [ 23 ] * pDecodedSamples [ - 24 ] ;
case 23 : prediction + = coefficients [ 22 ] * pDecodedSamples [ - 23 ] ;
case 22 : prediction + = coefficients [ 21 ] * pDecodedSamples [ - 22 ] ;
case 21 : prediction + = coefficients [ 20 ] * pDecodedSamples [ - 21 ] ;
case 20 : prediction + = coefficients [ 19 ] * pDecodedSamples [ - 20 ] ;
case 19 : prediction + = coefficients [ 18 ] * pDecodedSamples [ - 19 ] ;
case 18 : prediction + = coefficients [ 17 ] * pDecodedSamples [ - 18 ] ;
case 17 : prediction + = coefficients [ 16 ] * pDecodedSamples [ - 17 ] ;
case 16 : prediction + = coefficients [ 15 ] * pDecodedSamples [ - 16 ] ;
case 15 : prediction + = coefficients [ 14 ] * pDecodedSamples [ - 15 ] ;
case 14 : prediction + = coefficients [ 13 ] * pDecodedSamples [ - 14 ] ;
case 13 : prediction + = coefficients [ 12 ] * pDecodedSamples [ - 13 ] ;
case 12 : prediction + = coefficients [ 11 ] * pDecodedSamples [ - 12 ] ;
case 11 : prediction + = coefficients [ 10 ] * pDecodedSamples [ - 11 ] ;
case 10 : prediction + = coefficients [ 9 ] * pDecodedSamples [ - 10 ] ;
case 9 : prediction + = coefficients [ 8 ] * pDecodedSamples [ - 9 ] ;
case 8 : prediction + = coefficients [ 7 ] * pDecodedSamples [ - 8 ] ;
case 7 : prediction + = coefficients [ 6 ] * pDecodedSamples [ - 7 ] ;
case 6 : prediction + = coefficients [ 5 ] * pDecodedSamples [ - 6 ] ;
case 5 : prediction + = coefficients [ 4 ] * pDecodedSamples [ - 5 ] ;
case 4 : prediction + = coefficients [ 3 ] * pDecodedSamples [ - 4 ] ;
case 3 : prediction + = coefficients [ 2 ] * pDecodedSamples [ - 3 ] ;
case 2 : prediction + = coefficients [ 1 ] * pDecodedSamples [ - 2 ] ;
case 1 : prediction + = coefficients [ 0 ] * pDecodedSamples [ - 1 ] ;
}
return ( drflac_int32 ) ( prediction > > shift ) ;
}
static DRFLAC_INLINE drflac_int32 drflac__calculate_prediction_64 ( drflac_uint32 order , drflac_int32 shift , const drflac_int32 * coefficients , drflac_int32 * pDecodedSamples )
{
drflac_int64 prediction ;
DRFLAC_ASSERT ( order < = 32 ) ;
/* 64-bit version. */
/* This method is faster on the 32-bit build when compiling with VC++. See note below. */
# ifndef DRFLAC_64BIT
if ( order = = 8 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
prediction + = coefficients [ 5 ] * ( drflac_int64 ) pDecodedSamples [ - 6 ] ;
prediction + = coefficients [ 6 ] * ( drflac_int64 ) pDecodedSamples [ - 7 ] ;
prediction + = coefficients [ 7 ] * ( drflac_int64 ) pDecodedSamples [ - 8 ] ;
}
else if ( order = = 7 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
prediction + = coefficients [ 5 ] * ( drflac_int64 ) pDecodedSamples [ - 6 ] ;
prediction + = coefficients [ 6 ] * ( drflac_int64 ) pDecodedSamples [ - 7 ] ;
}
else if ( order = = 3 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
}
else if ( order = = 6 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
prediction + = coefficients [ 5 ] * ( drflac_int64 ) pDecodedSamples [ - 6 ] ;
}
else if ( order = = 5 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
}
else if ( order = = 4 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
}
else if ( order = = 12 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
prediction + = coefficients [ 5 ] * ( drflac_int64 ) pDecodedSamples [ - 6 ] ;
prediction + = coefficients [ 6 ] * ( drflac_int64 ) pDecodedSamples [ - 7 ] ;
prediction + = coefficients [ 7 ] * ( drflac_int64 ) pDecodedSamples [ - 8 ] ;
prediction + = coefficients [ 8 ] * ( drflac_int64 ) pDecodedSamples [ - 9 ] ;
prediction + = coefficients [ 9 ] * ( drflac_int64 ) pDecodedSamples [ - 10 ] ;
prediction + = coefficients [ 10 ] * ( drflac_int64 ) pDecodedSamples [ - 11 ] ;
prediction + = coefficients [ 11 ] * ( drflac_int64 ) pDecodedSamples [ - 12 ] ;
}
else if ( order = = 2 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
}
else if ( order = = 1 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
}
else if ( order = = 10 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
prediction + = coefficients [ 5 ] * ( drflac_int64 ) pDecodedSamples [ - 6 ] ;
prediction + = coefficients [ 6 ] * ( drflac_int64 ) pDecodedSamples [ - 7 ] ;
prediction + = coefficients [ 7 ] * ( drflac_int64 ) pDecodedSamples [ - 8 ] ;
prediction + = coefficients [ 8 ] * ( drflac_int64 ) pDecodedSamples [ - 9 ] ;
prediction + = coefficients [ 9 ] * ( drflac_int64 ) pDecodedSamples [ - 10 ] ;
}
else if ( order = = 9 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
prediction + = coefficients [ 5 ] * ( drflac_int64 ) pDecodedSamples [ - 6 ] ;
prediction + = coefficients [ 6 ] * ( drflac_int64 ) pDecodedSamples [ - 7 ] ;
prediction + = coefficients [ 7 ] * ( drflac_int64 ) pDecodedSamples [ - 8 ] ;
prediction + = coefficients [ 8 ] * ( drflac_int64 ) pDecodedSamples [ - 9 ] ;
}
else if ( order = = 11 )
{
prediction = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
prediction + = coefficients [ 5 ] * ( drflac_int64 ) pDecodedSamples [ - 6 ] ;
prediction + = coefficients [ 6 ] * ( drflac_int64 ) pDecodedSamples [ - 7 ] ;
prediction + = coefficients [ 7 ] * ( drflac_int64 ) pDecodedSamples [ - 8 ] ;
prediction + = coefficients [ 8 ] * ( drflac_int64 ) pDecodedSamples [ - 9 ] ;
prediction + = coefficients [ 9 ] * ( drflac_int64 ) pDecodedSamples [ - 10 ] ;
prediction + = coefficients [ 10 ] * ( drflac_int64 ) pDecodedSamples [ - 11 ] ;
}
else
{
int j ;
prediction = 0 ;
for ( j = 0 ; j < ( int ) order ; + + j ) {
prediction + = coefficients [ j ] * ( drflac_int64 ) pDecodedSamples [ - j - 1 ] ;
}
}
# endif
/*
VC + + optimizes this to a single jmp instruction , but only the 64 - bit build . The 32 - bit build generates less efficient code for some
reason . The ugly version above is faster so we ' ll just switch between the two depending on the target platform .
*/
# ifdef DRFLAC_64BIT
prediction = 0 ;
switch ( order )
{
case 32 : prediction + = coefficients [ 31 ] * ( drflac_int64 ) pDecodedSamples [ - 32 ] ;
case 31 : prediction + = coefficients [ 30 ] * ( drflac_int64 ) pDecodedSamples [ - 31 ] ;
case 30 : prediction + = coefficients [ 29 ] * ( drflac_int64 ) pDecodedSamples [ - 30 ] ;
case 29 : prediction + = coefficients [ 28 ] * ( drflac_int64 ) pDecodedSamples [ - 29 ] ;
case 28 : prediction + = coefficients [ 27 ] * ( drflac_int64 ) pDecodedSamples [ - 28 ] ;
case 27 : prediction + = coefficients [ 26 ] * ( drflac_int64 ) pDecodedSamples [ - 27 ] ;
case 26 : prediction + = coefficients [ 25 ] * ( drflac_int64 ) pDecodedSamples [ - 26 ] ;
case 25 : prediction + = coefficients [ 24 ] * ( drflac_int64 ) pDecodedSamples [ - 25 ] ;
case 24 : prediction + = coefficients [ 23 ] * ( drflac_int64 ) pDecodedSamples [ - 24 ] ;
case 23 : prediction + = coefficients [ 22 ] * ( drflac_int64 ) pDecodedSamples [ - 23 ] ;
case 22 : prediction + = coefficients [ 21 ] * ( drflac_int64 ) pDecodedSamples [ - 22 ] ;
case 21 : prediction + = coefficients [ 20 ] * ( drflac_int64 ) pDecodedSamples [ - 21 ] ;
case 20 : prediction + = coefficients [ 19 ] * ( drflac_int64 ) pDecodedSamples [ - 20 ] ;
case 19 : prediction + = coefficients [ 18 ] * ( drflac_int64 ) pDecodedSamples [ - 19 ] ;
case 18 : prediction + = coefficients [ 17 ] * ( drflac_int64 ) pDecodedSamples [ - 18 ] ;
case 17 : prediction + = coefficients [ 16 ] * ( drflac_int64 ) pDecodedSamples [ - 17 ] ;
case 16 : prediction + = coefficients [ 15 ] * ( drflac_int64 ) pDecodedSamples [ - 16 ] ;
case 15 : prediction + = coefficients [ 14 ] * ( drflac_int64 ) pDecodedSamples [ - 15 ] ;
case 14 : prediction + = coefficients [ 13 ] * ( drflac_int64 ) pDecodedSamples [ - 14 ] ;
case 13 : prediction + = coefficients [ 12 ] * ( drflac_int64 ) pDecodedSamples [ - 13 ] ;
case 12 : prediction + = coefficients [ 11 ] * ( drflac_int64 ) pDecodedSamples [ - 12 ] ;
case 11 : prediction + = coefficients [ 10 ] * ( drflac_int64 ) pDecodedSamples [ - 11 ] ;
case 10 : prediction + = coefficients [ 9 ] * ( drflac_int64 ) pDecodedSamples [ - 10 ] ;
case 9 : prediction + = coefficients [ 8 ] * ( drflac_int64 ) pDecodedSamples [ - 9 ] ;
case 8 : prediction + = coefficients [ 7 ] * ( drflac_int64 ) pDecodedSamples [ - 8 ] ;
case 7 : prediction + = coefficients [ 6 ] * ( drflac_int64 ) pDecodedSamples [ - 7 ] ;
case 6 : prediction + = coefficients [ 5 ] * ( drflac_int64 ) pDecodedSamples [ - 6 ] ;
case 5 : prediction + = coefficients [ 4 ] * ( drflac_int64 ) pDecodedSamples [ - 5 ] ;
case 4 : prediction + = coefficients [ 3 ] * ( drflac_int64 ) pDecodedSamples [ - 4 ] ;
case 3 : prediction + = coefficients [ 2 ] * ( drflac_int64 ) pDecodedSamples [ - 3 ] ;
case 2 : prediction + = coefficients [ 1 ] * ( drflac_int64 ) pDecodedSamples [ - 2 ] ;
case 1 : prediction + = coefficients [ 0 ] * ( drflac_int64 ) pDecodedSamples [ - 1 ] ;
}
# endif
return ( drflac_int32 ) ( prediction > > shift ) ;
}
#if 0
/*
Reference implementation for reading and decoding samples with residual . This is intentionally left unoptimized for the
sake of readability and should only be used as a reference .
*/
static drflac_bool32 drflac__decode_samples_with_residual__rice__reference ( drflac_bs * bs , drflac_uint32 bitsPerSample , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 lpcOrder , drflac_int32 lpcShift , drflac_uint32 lpcPrecision , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
drflac_uint32 i ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pSamplesOut ! = NULL ) ;
for ( i = 0 ; i < count ; + + i ) {
drflac_uint32 zeroCounter = 0 ;
for ( ; ; ) {
drflac_uint8 bit ;
if ( ! drflac__read_uint8 ( bs , 1 , & bit ) ) {
return DRFLAC_FALSE ;
}
if ( bit = = 0 ) {
zeroCounter + = 1 ;
} else {
break ;
}
}
drflac_uint32 decodedRice ;
if ( riceParam > 0 ) {
if ( ! drflac__read_uint32 ( bs , riceParam , & decodedRice ) ) {
return DRFLAC_FALSE ;
}
} else {
decodedRice = 0 ;
}
decodedRice | = ( zeroCounter < < riceParam ) ;
if ( ( decodedRice & 0x01 ) ) {
decodedRice = ~ ( decodedRice > > 1 ) ;
} else {
decodedRice = ( decodedRice > > 1 ) ;
}
if ( drflac__use_64_bit_prediction ( bitsPerSample , lpcOrder , lpcPrecision ) ) {
pSamplesOut [ i ] = decodedRice + drflac__calculate_prediction_64 ( lpcOrder , lpcShift , coefficients , pSamplesOut + i ) ;
} else {
pSamplesOut [ i ] = decodedRice + drflac__calculate_prediction_32 ( lpcOrder , lpcShift , coefficients , pSamplesOut + i ) ;
}
}
return DRFLAC_TRUE ;
}
# endif
#if 0
static drflac_bool32 drflac__read_rice_parts__reference ( drflac_bs * bs , drflac_uint8 riceParam , drflac_uint32 * pZeroCounterOut , drflac_uint32 * pRiceParamPartOut )
{
drflac_uint32 zeroCounter = 0 ;
drflac_uint32 decodedRice ;
for ( ; ; ) {
drflac_uint8 bit ;
if ( ! drflac__read_uint8 ( bs , 1 , & bit ) ) {
return DRFLAC_FALSE ;
}
if ( bit = = 0 ) {
zeroCounter + = 1 ;
} else {
break ;
}
}
if ( riceParam > 0 ) {
if ( ! drflac__read_uint32 ( bs , riceParam , & decodedRice ) ) {
return DRFLAC_FALSE ;
}
} else {
decodedRice = 0 ;
}
* pZeroCounterOut = zeroCounter ;
* pRiceParamPartOut = decodedRice ;
return DRFLAC_TRUE ;
}
# endif
#if 0
static DRFLAC_INLINE drflac_bool32 drflac__read_rice_parts ( drflac_bs * bs , drflac_uint8 riceParam , drflac_uint32 * pZeroCounterOut , drflac_uint32 * pRiceParamPartOut )
{
drflac_cache_t riceParamMask ;
drflac_uint32 zeroCounter ;
drflac_uint32 setBitOffsetPlus1 ;
drflac_uint32 riceParamPart ;
drflac_uint32 riceLength ;
DRFLAC_ASSERT ( riceParam > 0 ) ; /* <-- riceParam should never be 0. drflac__read_rice_parts__param_equals_zero() should be used instead for this case. */
riceParamMask = DRFLAC_CACHE_L1_SELECTION_MASK ( riceParam ) ;
zeroCounter = 0 ;
while ( bs - > cache = = 0 ) {
zeroCounter + = ( drflac_uint32 ) DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ;
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
}
setBitOffsetPlus1 = drflac__clz ( bs - > cache ) ;
zeroCounter + = setBitOffsetPlus1 ;
setBitOffsetPlus1 + = 1 ;
riceLength = setBitOffsetPlus1 + riceParam ;
if ( riceLength < DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) {
riceParamPart = ( drflac_uint32 ) ( ( bs - > cache & ( riceParamMask > > setBitOffsetPlus1 ) ) > > DRFLAC_CACHE_L1_SELECTION_SHIFT ( bs , riceLength ) ) ;
bs - > consumedBits + = riceLength ;
bs - > cache < < = riceLength ;
} else {
drflac_uint32 bitCountLo ;
drflac_cache_t resultHi ;
bs - > consumedBits + = riceLength ;
bs - > cache < < = setBitOffsetPlus1 & ( DRFLAC_CACHE_L1_SIZE_BITS ( bs ) - 1 ) ; /* <-- Equivalent to "if (setBitOffsetPlus1 < DRFLAC_CACHE_L1_SIZE_BITS(bs)) { bs->cache <<= setBitOffsetPlus1; }" */
/* It straddles the cached data. It will never cover more than the next chunk. We just read the number in two parts and combine them. */
bitCountLo = bs - > consumedBits - DRFLAC_CACHE_L1_SIZE_BITS ( bs ) ;
resultHi = DRFLAC_CACHE_L1_SELECT_AND_SHIFT ( bs , riceParam ) ; /* <-- Use DRFLAC_CACHE_L1_SELECT_AND_SHIFT_SAFE() if ever this function allows riceParam=0. */
if ( bs - > nextL2Line < DRFLAC_CACHE_L2_LINE_COUNT ( bs ) ) {
# ifndef DR_FLAC_NO_CRC
drflac__update_crc16 ( bs ) ;
# endif
bs - > cache = drflac__be2host__cache_line ( bs - > cacheL2 [ bs - > nextL2Line + + ] ) ;
bs - > consumedBits = 0 ;
# ifndef DR_FLAC_NO_CRC
bs - > crc16Cache = bs - > cache ;
# endif
} else {
/* Slow path. We need to fetch more data from the client. */
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
if ( bitCountLo > DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) {
/* This happens when we get to end of stream */
return DRFLAC_FALSE ;
}
}
riceParamPart = ( drflac_uint32 ) ( resultHi | DRFLAC_CACHE_L1_SELECT_AND_SHIFT_SAFE ( bs , bitCountLo ) ) ;
bs - > consumedBits + = bitCountLo ;
bs - > cache < < = bitCountLo ;
}
pZeroCounterOut [ 0 ] = zeroCounter ;
pRiceParamPartOut [ 0 ] = riceParamPart ;
return DRFLAC_TRUE ;
}
# endif
static DRFLAC_INLINE drflac_bool32 drflac__read_rice_parts_x1 ( drflac_bs * bs , drflac_uint8 riceParam , drflac_uint32 * pZeroCounterOut , drflac_uint32 * pRiceParamPartOut )
{
drflac_uint32 riceParamPlus1 = riceParam + 1 ;
/*drflac_cache_t riceParamPlus1Mask = DRFLAC_CACHE_L1_SELECTION_MASK(riceParamPlus1);*/
drflac_uint32 riceParamPlus1Shift = DRFLAC_CACHE_L1_SELECTION_SHIFT ( bs , riceParamPlus1 ) ;
drflac_uint32 riceParamPlus1MaxConsumedBits = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) - riceParamPlus1 ;
/*
The idea here is to use local variables for the cache in an attempt to encourage the compiler to store them in registers . I have
no idea how this will work in practice . . .
*/
drflac_cache_t bs_cache = bs - > cache ;
drflac_uint32 bs_consumedBits = bs - > consumedBits ;
/* The first thing to do is find the first unset bit. Most likely a bit will be set in the current cache line. */
drflac_uint32 lzcount = drflac__clz ( bs_cache ) ;
if ( lzcount < sizeof ( bs_cache ) * 8 ) {
pZeroCounterOut [ 0 ] = lzcount ;
/*
It is most likely that the riceParam part ( which comes after the zero counter ) is also on this cache line . When extracting
this , we include the set bit from the unary coded part because it simplifies cache management . This bit will be handled
outside of this function at a higher level .
*/
extract_rice_param_part :
bs_cache < < = lzcount ;
bs_consumedBits + = lzcount ;
if ( bs_consumedBits < = riceParamPlus1MaxConsumedBits ) {
/* Getting here means the rice parameter part is wholly contained within the current cache line. */
pRiceParamPartOut [ 0 ] = ( drflac_uint32 ) ( bs_cache > > riceParamPlus1Shift ) ;
bs_cache < < = riceParamPlus1 ;
bs_consumedBits + = riceParamPlus1 ;
} else {
drflac_uint32 riceParamPartHi ;
drflac_uint32 riceParamPartLo ;
drflac_uint32 riceParamPartLoBitCount ;
/*
Getting here means the rice parameter part straddles the cache line . We need to read from the tail of the current cache
line , reload the cache , and then combine it with the head of the next cache line .
*/
/* Grab the high part of the rice parameter part. */
riceParamPartHi = ( drflac_uint32 ) ( bs_cache > > riceParamPlus1Shift ) ;
/* Before reloading the cache we need to grab the size in bits of the low part. */
riceParamPartLoBitCount = bs_consumedBits - riceParamPlus1MaxConsumedBits ;
DRFLAC_ASSERT ( riceParamPartLoBitCount > 0 & & riceParamPartLoBitCount < 32 ) ;
/* Now reload the cache. */
if ( bs - > nextL2Line < DRFLAC_CACHE_L2_LINE_COUNT ( bs ) ) {
# ifndef DR_FLAC_NO_CRC
drflac__update_crc16 ( bs ) ;
# endif
bs_cache = drflac__be2host__cache_line ( bs - > cacheL2 [ bs - > nextL2Line + + ] ) ;
bs_consumedBits = riceParamPartLoBitCount ;
# ifndef DR_FLAC_NO_CRC
bs - > crc16Cache = bs_cache ;
# endif
} else {
/* Slow path. We need to fetch more data from the client. */
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
if ( riceParamPartLoBitCount > DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) {
/* This happens when we get to end of stream */
return DRFLAC_FALSE ;
}
bs_cache = bs - > cache ;
bs_consumedBits = bs - > consumedBits + riceParamPartLoBitCount ;
}
/* We should now have enough information to construct the rice parameter part. */
riceParamPartLo = ( drflac_uint32 ) ( bs_cache > > ( DRFLAC_CACHE_L1_SELECTION_SHIFT ( bs , riceParamPartLoBitCount ) ) ) ;
pRiceParamPartOut [ 0 ] = riceParamPartHi | riceParamPartLo ;
bs_cache < < = riceParamPartLoBitCount ;
}
} else {
/*
Getting here means there are no bits set on the cache line . This is a less optimal case because we just wasted a call
to drflac__clz ( ) and we need to reload the cache .
*/
drflac_uint32 zeroCounter = ( drflac_uint32 ) ( DRFLAC_CACHE_L1_SIZE_BITS ( bs ) - bs_consumedBits ) ;
for ( ; ; ) {
if ( bs - > nextL2Line < DRFLAC_CACHE_L2_LINE_COUNT ( bs ) ) {
# ifndef DR_FLAC_NO_CRC
drflac__update_crc16 ( bs ) ;
# endif
bs_cache = drflac__be2host__cache_line ( bs - > cacheL2 [ bs - > nextL2Line + + ] ) ;
bs_consumedBits = 0 ;
# ifndef DR_FLAC_NO_CRC
bs - > crc16Cache = bs_cache ;
# endif
} else {
/* Slow path. We need to fetch more data from the client. */
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
bs_cache = bs - > cache ;
bs_consumedBits = bs - > consumedBits ;
}
lzcount = drflac__clz ( bs_cache ) ;
zeroCounter + = lzcount ;
if ( lzcount < sizeof ( bs_cache ) * 8 ) {
break ;
}
}
pZeroCounterOut [ 0 ] = zeroCounter ;
goto extract_rice_param_part ;
}
/* Make sure the cache is restored at the end of it all. */
bs - > cache = bs_cache ;
bs - > consumedBits = bs_consumedBits ;
return DRFLAC_TRUE ;
}
static DRFLAC_INLINE drflac_bool32 drflac__seek_rice_parts ( drflac_bs * bs , drflac_uint8 riceParam )
{
drflac_uint32 riceParamPlus1 = riceParam + 1 ;
drflac_uint32 riceParamPlus1MaxConsumedBits = DRFLAC_CACHE_L1_SIZE_BITS ( bs ) - riceParamPlus1 ;
/*
The idea here is to use local variables for the cache in an attempt to encourage the compiler to store them in registers . I have
no idea how this will work in practice . . .
*/
drflac_cache_t bs_cache = bs - > cache ;
drflac_uint32 bs_consumedBits = bs - > consumedBits ;
/* The first thing to do is find the first unset bit. Most likely a bit will be set in the current cache line. */
drflac_uint32 lzcount = drflac__clz ( bs_cache ) ;
if ( lzcount < sizeof ( bs_cache ) * 8 ) {
/*
It is most likely that the riceParam part ( which comes after the zero counter ) is also on this cache line . When extracting
this , we include the set bit from the unary coded part because it simplifies cache management . This bit will be handled
outside of this function at a higher level .
*/
extract_rice_param_part :
bs_cache < < = lzcount ;
bs_consumedBits + = lzcount ;
if ( bs_consumedBits < = riceParamPlus1MaxConsumedBits ) {
/* Getting here means the rice parameter part is wholly contained within the current cache line. */
bs_cache < < = riceParamPlus1 ;
bs_consumedBits + = riceParamPlus1 ;
} else {
/*
Getting here means the rice parameter part straddles the cache line . We need to read from the tail of the current cache
line , reload the cache , and then combine it with the head of the next cache line .
*/
/* Before reloading the cache we need to grab the size in bits of the low part. */
drflac_uint32 riceParamPartLoBitCount = bs_consumedBits - riceParamPlus1MaxConsumedBits ;
DRFLAC_ASSERT ( riceParamPartLoBitCount > 0 & & riceParamPartLoBitCount < 32 ) ;
/* Now reload the cache. */
if ( bs - > nextL2Line < DRFLAC_CACHE_L2_LINE_COUNT ( bs ) ) {
# ifndef DR_FLAC_NO_CRC
drflac__update_crc16 ( bs ) ;
# endif
bs_cache = drflac__be2host__cache_line ( bs - > cacheL2 [ bs - > nextL2Line + + ] ) ;
bs_consumedBits = riceParamPartLoBitCount ;
# ifndef DR_FLAC_NO_CRC
bs - > crc16Cache = bs_cache ;
# endif
} else {
/* Slow path. We need to fetch more data from the client. */
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
if ( riceParamPartLoBitCount > DRFLAC_CACHE_L1_BITS_REMAINING ( bs ) ) {
/* This happens when we get to end of stream */
return DRFLAC_FALSE ;
}
bs_cache = bs - > cache ;
bs_consumedBits = bs - > consumedBits + riceParamPartLoBitCount ;
}
bs_cache < < = riceParamPartLoBitCount ;
}
} else {
/*
Getting here means there are no bits set on the cache line . This is a less optimal case because we just wasted a call
to drflac__clz ( ) and we need to reload the cache .
*/
for ( ; ; ) {
if ( bs - > nextL2Line < DRFLAC_CACHE_L2_LINE_COUNT ( bs ) ) {
# ifndef DR_FLAC_NO_CRC
drflac__update_crc16 ( bs ) ;
# endif
bs_cache = drflac__be2host__cache_line ( bs - > cacheL2 [ bs - > nextL2Line + + ] ) ;
bs_consumedBits = 0 ;
# ifndef DR_FLAC_NO_CRC
bs - > crc16Cache = bs_cache ;
# endif
} else {
/* Slow path. We need to fetch more data from the client. */
if ( ! drflac__reload_cache ( bs ) ) {
return DRFLAC_FALSE ;
}
bs_cache = bs - > cache ;
bs_consumedBits = bs - > consumedBits ;
}
lzcount = drflac__clz ( bs_cache ) ;
if ( lzcount < sizeof ( bs_cache ) * 8 ) {
break ;
}
}
goto extract_rice_param_part ;
}
/* Make sure the cache is restored at the end of it all. */
bs - > cache = bs_cache ;
bs - > consumedBits = bs_consumedBits ;
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples_with_residual__rice__scalar_zeroorder ( drflac_bs * bs , drflac_uint32 bitsPerSample , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 order , drflac_int32 shift , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
drflac_uint32 t [ 2 ] = { 0x00000000 , 0xFFFFFFFF } ;
drflac_uint32 zeroCountPart0 ;
drflac_uint32 riceParamPart0 ;
drflac_uint32 riceParamMask ;
drflac_uint32 i ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pSamplesOut ! = NULL ) ;
( void ) bitsPerSample ;
( void ) order ;
( void ) shift ;
( void ) coefficients ;
riceParamMask = ( drflac_uint32 ) ~ ( ( ~ 0UL ) < < riceParam ) ;
i = 0 ;
while ( i < count ) {
/* Rice extraction. */
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart0 , & riceParamPart0 ) ) {
return DRFLAC_FALSE ;
}
/* Rice reconstruction. */
riceParamPart0 & = riceParamMask ;
riceParamPart0 | = ( zeroCountPart0 < < riceParam ) ;
riceParamPart0 = ( riceParamPart0 > > 1 ) ^ t [ riceParamPart0 & 0x01 ] ;
pSamplesOut [ i ] = riceParamPart0 ;
i + = 1 ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples_with_residual__rice__scalar ( drflac_bs * bs , drflac_uint32 bitsPerSample , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 lpcOrder , drflac_int32 lpcShift , drflac_uint32 lpcPrecision , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
drflac_uint32 t [ 2 ] = { 0x00000000 , 0xFFFFFFFF } ;
drflac_uint32 zeroCountPart0 = 0 ;
drflac_uint32 zeroCountPart1 = 0 ;
drflac_uint32 zeroCountPart2 = 0 ;
drflac_uint32 zeroCountPart3 = 0 ;
drflac_uint32 riceParamPart0 = 0 ;
drflac_uint32 riceParamPart1 = 0 ;
drflac_uint32 riceParamPart2 = 0 ;
drflac_uint32 riceParamPart3 = 0 ;
drflac_uint32 riceParamMask ;
const drflac_int32 * pSamplesOutEnd ;
drflac_uint32 i ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pSamplesOut ! = NULL ) ;
if ( lpcOrder = = 0 ) {
return drflac__decode_samples_with_residual__rice__scalar_zeroorder ( bs , bitsPerSample , count , riceParam , lpcOrder , lpcShift , coefficients , pSamplesOut ) ;
}
riceParamMask = ( drflac_uint32 ) ~ ( ( ~ 0UL ) < < riceParam ) ;
pSamplesOutEnd = pSamplesOut + ( count & ~ 3 ) ;
if ( drflac__use_64_bit_prediction ( bitsPerSample , lpcOrder , lpcPrecision ) ) {
while ( pSamplesOut < pSamplesOutEnd ) {
/*
Rice extraction . It ' s faster to do this one at a time against local variables than it is to use the x4 version
against an array . Not sure why , but perhaps it ' s making more efficient use of registers ?
*/
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart0 , & riceParamPart0 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart1 , & riceParamPart1 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart2 , & riceParamPart2 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart3 , & riceParamPart3 ) ) {
return DRFLAC_FALSE ;
}
riceParamPart0 & = riceParamMask ;
riceParamPart1 & = riceParamMask ;
riceParamPart2 & = riceParamMask ;
riceParamPart3 & = riceParamMask ;
riceParamPart0 | = ( zeroCountPart0 < < riceParam ) ;
riceParamPart1 | = ( zeroCountPart1 < < riceParam ) ;
riceParamPart2 | = ( zeroCountPart2 < < riceParam ) ;
riceParamPart3 | = ( zeroCountPart3 < < riceParam ) ;
riceParamPart0 = ( riceParamPart0 > > 1 ) ^ t [ riceParamPart0 & 0x01 ] ;
riceParamPart1 = ( riceParamPart1 > > 1 ) ^ t [ riceParamPart1 & 0x01 ] ;
riceParamPart2 = ( riceParamPart2 > > 1 ) ^ t [ riceParamPart2 & 0x01 ] ;
riceParamPart3 = ( riceParamPart3 > > 1 ) ^ t [ riceParamPart3 & 0x01 ] ;
pSamplesOut [ 0 ] = riceParamPart0 + drflac__calculate_prediction_64 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 0 ) ;
pSamplesOut [ 1 ] = riceParamPart1 + drflac__calculate_prediction_64 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 1 ) ;
pSamplesOut [ 2 ] = riceParamPart2 + drflac__calculate_prediction_64 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 2 ) ;
pSamplesOut [ 3 ] = riceParamPart3 + drflac__calculate_prediction_64 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 3 ) ;
pSamplesOut + = 4 ;
}
} else {
while ( pSamplesOut < pSamplesOutEnd ) {
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart0 , & riceParamPart0 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart1 , & riceParamPart1 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart2 , & riceParamPart2 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart3 , & riceParamPart3 ) ) {
return DRFLAC_FALSE ;
}
riceParamPart0 & = riceParamMask ;
riceParamPart1 & = riceParamMask ;
riceParamPart2 & = riceParamMask ;
riceParamPart3 & = riceParamMask ;
riceParamPart0 | = ( zeroCountPart0 < < riceParam ) ;
riceParamPart1 | = ( zeroCountPart1 < < riceParam ) ;
riceParamPart2 | = ( zeroCountPart2 < < riceParam ) ;
riceParamPart3 | = ( zeroCountPart3 < < riceParam ) ;
riceParamPart0 = ( riceParamPart0 > > 1 ) ^ t [ riceParamPart0 & 0x01 ] ;
riceParamPart1 = ( riceParamPart1 > > 1 ) ^ t [ riceParamPart1 & 0x01 ] ;
riceParamPart2 = ( riceParamPart2 > > 1 ) ^ t [ riceParamPart2 & 0x01 ] ;
riceParamPart3 = ( riceParamPart3 > > 1 ) ^ t [ riceParamPart3 & 0x01 ] ;
pSamplesOut [ 0 ] = riceParamPart0 + drflac__calculate_prediction_32 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 0 ) ;
pSamplesOut [ 1 ] = riceParamPart1 + drflac__calculate_prediction_32 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 1 ) ;
pSamplesOut [ 2 ] = riceParamPart2 + drflac__calculate_prediction_32 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 2 ) ;
pSamplesOut [ 3 ] = riceParamPart3 + drflac__calculate_prediction_32 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 3 ) ;
pSamplesOut + = 4 ;
}
}
i = ( count & ~ 3 ) ;
while ( i < count ) {
/* Rice extraction. */
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountPart0 , & riceParamPart0 ) ) {
return DRFLAC_FALSE ;
}
/* Rice reconstruction. */
riceParamPart0 & = riceParamMask ;
riceParamPart0 | = ( zeroCountPart0 < < riceParam ) ;
riceParamPart0 = ( riceParamPart0 > > 1 ) ^ t [ riceParamPart0 & 0x01 ] ;
/*riceParamPart0 = (riceParamPart0 >> 1) ^ (~(riceParamPart0 & 0x01) + 1);*/
/* Sample reconstruction. */
if ( drflac__use_64_bit_prediction ( bitsPerSample , lpcOrder , lpcPrecision ) ) {
pSamplesOut [ 0 ] = riceParamPart0 + drflac__calculate_prediction_64 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 0 ) ;
} else {
pSamplesOut [ 0 ] = riceParamPart0 + drflac__calculate_prediction_32 ( lpcOrder , lpcShift , coefficients , pSamplesOut + 0 ) ;
}
i + = 1 ;
pSamplesOut + = 1 ;
}
return DRFLAC_TRUE ;
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE __m128i drflac__mm_packs_interleaved_epi32 ( __m128i a , __m128i b )
{
__m128i r ;
/* Pack. */
r = _mm_packs_epi32 ( a , b ) ;
/* a3a2 a1a0 b3b2 b1b0 -> a3a2 b3b2 a1a0 b1b0 */
r = _mm_shuffle_epi32 ( r , _MM_SHUFFLE ( 3 , 1 , 2 , 0 ) ) ;
/* a3a2 b3b2 a1a0 b1b0 -> a3b3 a2b2 a1b1 a0b0 */
r = _mm_shufflehi_epi16 ( r , _MM_SHUFFLE ( 3 , 1 , 2 , 0 ) ) ;
r = _mm_shufflelo_epi16 ( r , _MM_SHUFFLE ( 3 , 1 , 2 , 0 ) ) ;
return r ;
}
# endif
# if defined(DRFLAC_SUPPORT_SSE41)
static DRFLAC_INLINE __m128i drflac__mm_not_si128 ( __m128i a )
{
return _mm_xor_si128 ( a , _mm_cmpeq_epi32 ( _mm_setzero_si128 ( ) , _mm_setzero_si128 ( ) ) ) ;
}
static DRFLAC_INLINE __m128i drflac__mm_hadd_epi32 ( __m128i x )
{
__m128i x64 = _mm_add_epi32 ( x , _mm_shuffle_epi32 ( x , _MM_SHUFFLE ( 1 , 0 , 3 , 2 ) ) ) ;
__m128i x32 = _mm_shufflelo_epi16 ( x64 , _MM_SHUFFLE ( 1 , 0 , 3 , 2 ) ) ;
return _mm_add_epi32 ( x64 , x32 ) ;
}
static DRFLAC_INLINE __m128i drflac__mm_hadd_epi64 ( __m128i x )
{
return _mm_add_epi64 ( x , _mm_shuffle_epi32 ( x , _MM_SHUFFLE ( 1 , 0 , 3 , 2 ) ) ) ;
}
static DRFLAC_INLINE __m128i drflac__mm_srai_epi64 ( __m128i x , int count )
{
/*
To simplify this we are assuming count < 32. This restriction allows us to work on a low side and a high side . The low side
is shifted with zero bits , whereas the right side is shifted with sign bits .
*/
__m128i lo = _mm_srli_epi64 ( x , count ) ;
__m128i hi = _mm_srai_epi32 ( x , count ) ;
hi = _mm_and_si128 ( hi , _mm_set_epi32 ( 0xFFFFFFFF , 0 , 0xFFFFFFFF , 0 ) ) ; /* The high part needs to have the low part cleared. */
return _mm_or_si128 ( lo , hi ) ;
}
static drflac_bool32 drflac__decode_samples_with_residual__rice__sse41_32 ( drflac_bs * bs , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 order , drflac_int32 shift , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
int i ;
drflac_uint32 riceParamMask ;
drflac_int32 * pDecodedSamples = pSamplesOut ;
drflac_int32 * pDecodedSamplesEnd = pSamplesOut + ( count & ~ 3 ) ;
drflac_uint32 zeroCountParts0 = 0 ;
drflac_uint32 zeroCountParts1 = 0 ;
drflac_uint32 zeroCountParts2 = 0 ;
drflac_uint32 zeroCountParts3 = 0 ;
drflac_uint32 riceParamParts0 = 0 ;
drflac_uint32 riceParamParts1 = 0 ;
drflac_uint32 riceParamParts2 = 0 ;
drflac_uint32 riceParamParts3 = 0 ;
__m128i coefficients128_0 ;
__m128i coefficients128_4 ;
__m128i coefficients128_8 ;
__m128i samples128_0 ;
__m128i samples128_4 ;
__m128i samples128_8 ;
__m128i riceParamMask128 ;
const drflac_uint32 t [ 2 ] = { 0x00000000 , 0xFFFFFFFF } ;
riceParamMask = ( drflac_uint32 ) ~ ( ( ~ 0UL ) < < riceParam ) ;
riceParamMask128 = _mm_set1_epi32 ( riceParamMask ) ;
/* Pre-load. */
coefficients128_0 = _mm_setzero_si128 ( ) ;
coefficients128_4 = _mm_setzero_si128 ( ) ;
coefficients128_8 = _mm_setzero_si128 ( ) ;
samples128_0 = _mm_setzero_si128 ( ) ;
samples128_4 = _mm_setzero_si128 ( ) ;
samples128_8 = _mm_setzero_si128 ( ) ;
/*
Pre - loading the coefficients and prior samples is annoying because we need to ensure we don ' t try reading more than
what ' s available in the input buffers . It would be convenient to use a fall - through switch to do this , but this results
in strict aliasing warnings with GCC . To work around this I ' m just doing something hacky . This feels a bit convoluted
so I think there ' s opportunity for this to be simplified .
*/
# if 1
{
int runningOrder = order ;
/* 0 - 3. */
if ( runningOrder > = 4 ) {
coefficients128_0 = _mm_loadu_si128 ( ( const __m128i * ) ( coefficients + 0 ) ) ;
samples128_0 = _mm_loadu_si128 ( ( const __m128i * ) ( pSamplesOut - 4 ) ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : coefficients128_0 = _mm_set_epi32 ( 0 , coefficients [ 2 ] , coefficients [ 1 ] , coefficients [ 0 ] ) ; samples128_0 = _mm_set_epi32 ( pSamplesOut [ - 1 ] , pSamplesOut [ - 2 ] , pSamplesOut [ - 3 ] , 0 ) ; break ;
case 2 : coefficients128_0 = _mm_set_epi32 ( 0 , 0 , coefficients [ 1 ] , coefficients [ 0 ] ) ; samples128_0 = _mm_set_epi32 ( pSamplesOut [ - 1 ] , pSamplesOut [ - 2 ] , 0 , 0 ) ; break ;
case 1 : coefficients128_0 = _mm_set_epi32 ( 0 , 0 , 0 , coefficients [ 0 ] ) ; samples128_0 = _mm_set_epi32 ( pSamplesOut [ - 1 ] , 0 , 0 , 0 ) ; break ;
}
runningOrder = 0 ;
}
/* 4 - 7 */
if ( runningOrder > = 4 ) {
coefficients128_4 = _mm_loadu_si128 ( ( const __m128i * ) ( coefficients + 4 ) ) ;
samples128_4 = _mm_loadu_si128 ( ( const __m128i * ) ( pSamplesOut - 8 ) ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : coefficients128_4 = _mm_set_epi32 ( 0 , coefficients [ 6 ] , coefficients [ 5 ] , coefficients [ 4 ] ) ; samples128_4 = _mm_set_epi32 ( pSamplesOut [ - 5 ] , pSamplesOut [ - 6 ] , pSamplesOut [ - 7 ] , 0 ) ; break ;
case 2 : coefficients128_4 = _mm_set_epi32 ( 0 , 0 , coefficients [ 5 ] , coefficients [ 4 ] ) ; samples128_4 = _mm_set_epi32 ( pSamplesOut [ - 5 ] , pSamplesOut [ - 6 ] , 0 , 0 ) ; break ;
case 1 : coefficients128_4 = _mm_set_epi32 ( 0 , 0 , 0 , coefficients [ 4 ] ) ; samples128_4 = _mm_set_epi32 ( pSamplesOut [ - 5 ] , 0 , 0 , 0 ) ; break ;
}
runningOrder = 0 ;
}
/* 8 - 11 */
if ( runningOrder = = 4 ) {
coefficients128_8 = _mm_loadu_si128 ( ( const __m128i * ) ( coefficients + 8 ) ) ;
samples128_8 = _mm_loadu_si128 ( ( const __m128i * ) ( pSamplesOut - 12 ) ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : coefficients128_8 = _mm_set_epi32 ( 0 , coefficients [ 10 ] , coefficients [ 9 ] , coefficients [ 8 ] ) ; samples128_8 = _mm_set_epi32 ( pSamplesOut [ - 9 ] , pSamplesOut [ - 10 ] , pSamplesOut [ - 11 ] , 0 ) ; break ;
case 2 : coefficients128_8 = _mm_set_epi32 ( 0 , 0 , coefficients [ 9 ] , coefficients [ 8 ] ) ; samples128_8 = _mm_set_epi32 ( pSamplesOut [ - 9 ] , pSamplesOut [ - 10 ] , 0 , 0 ) ; break ;
case 1 : coefficients128_8 = _mm_set_epi32 ( 0 , 0 , 0 , coefficients [ 8 ] ) ; samples128_8 = _mm_set_epi32 ( pSamplesOut [ - 9 ] , 0 , 0 , 0 ) ; break ;
}
runningOrder = 0 ;
}
/* Coefficients need to be shuffled for our streaming algorithm below to work. Samples are already in the correct order from the loading routine above. */
coefficients128_0 = _mm_shuffle_epi32 ( coefficients128_0 , _MM_SHUFFLE ( 0 , 1 , 2 , 3 ) ) ;
coefficients128_4 = _mm_shuffle_epi32 ( coefficients128_4 , _MM_SHUFFLE ( 0 , 1 , 2 , 3 ) ) ;
coefficients128_8 = _mm_shuffle_epi32 ( coefficients128_8 , _MM_SHUFFLE ( 0 , 1 , 2 , 3 ) ) ;
}
# else
/* This causes strict-aliasing warnings with GCC. */
switch ( order )
{
case 12 : ( ( drflac_int32 * ) & coefficients128_8 ) [ 0 ] = coefficients [ 11 ] ; ( ( drflac_int32 * ) & samples128_8 ) [ 0 ] = pDecodedSamples [ - 12 ] ;
case 11 : ( ( drflac_int32 * ) & coefficients128_8 ) [ 1 ] = coefficients [ 10 ] ; ( ( drflac_int32 * ) & samples128_8 ) [ 1 ] = pDecodedSamples [ - 11 ] ;
case 10 : ( ( drflac_int32 * ) & coefficients128_8 ) [ 2 ] = coefficients [ 9 ] ; ( ( drflac_int32 * ) & samples128_8 ) [ 2 ] = pDecodedSamples [ - 10 ] ;
case 9 : ( ( drflac_int32 * ) & coefficients128_8 ) [ 3 ] = coefficients [ 8 ] ; ( ( drflac_int32 * ) & samples128_8 ) [ 3 ] = pDecodedSamples [ - 9 ] ;
case 8 : ( ( drflac_int32 * ) & coefficients128_4 ) [ 0 ] = coefficients [ 7 ] ; ( ( drflac_int32 * ) & samples128_4 ) [ 0 ] = pDecodedSamples [ - 8 ] ;
case 7 : ( ( drflac_int32 * ) & coefficients128_4 ) [ 1 ] = coefficients [ 6 ] ; ( ( drflac_int32 * ) & samples128_4 ) [ 1 ] = pDecodedSamples [ - 7 ] ;
case 6 : ( ( drflac_int32 * ) & coefficients128_4 ) [ 2 ] = coefficients [ 5 ] ; ( ( drflac_int32 * ) & samples128_4 ) [ 2 ] = pDecodedSamples [ - 6 ] ;
case 5 : ( ( drflac_int32 * ) & coefficients128_4 ) [ 3 ] = coefficients [ 4 ] ; ( ( drflac_int32 * ) & samples128_4 ) [ 3 ] = pDecodedSamples [ - 5 ] ;
case 4 : ( ( drflac_int32 * ) & coefficients128_0 ) [ 0 ] = coefficients [ 3 ] ; ( ( drflac_int32 * ) & samples128_0 ) [ 0 ] = pDecodedSamples [ - 4 ] ;
case 3 : ( ( drflac_int32 * ) & coefficients128_0 ) [ 1 ] = coefficients [ 2 ] ; ( ( drflac_int32 * ) & samples128_0 ) [ 1 ] = pDecodedSamples [ - 3 ] ;
case 2 : ( ( drflac_int32 * ) & coefficients128_0 ) [ 2 ] = coefficients [ 1 ] ; ( ( drflac_int32 * ) & samples128_0 ) [ 2 ] = pDecodedSamples [ - 2 ] ;
case 1 : ( ( drflac_int32 * ) & coefficients128_0 ) [ 3 ] = coefficients [ 0 ] ; ( ( drflac_int32 * ) & samples128_0 ) [ 3 ] = pDecodedSamples [ - 1 ] ;
}
# endif
/* For this version we are doing one sample at a time. */
while ( pDecodedSamples < pDecodedSamplesEnd ) {
__m128i prediction128 ;
__m128i zeroCountPart128 ;
__m128i riceParamPart128 ;
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts0 , & riceParamParts0 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts1 , & riceParamParts1 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts2 , & riceParamParts2 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts3 , & riceParamParts3 ) ) {
return DRFLAC_FALSE ;
}
zeroCountPart128 = _mm_set_epi32 ( zeroCountParts3 , zeroCountParts2 , zeroCountParts1 , zeroCountParts0 ) ;
riceParamPart128 = _mm_set_epi32 ( riceParamParts3 , riceParamParts2 , riceParamParts1 , riceParamParts0 ) ;
riceParamPart128 = _mm_and_si128 ( riceParamPart128 , riceParamMask128 ) ;
riceParamPart128 = _mm_or_si128 ( riceParamPart128 , _mm_slli_epi32 ( zeroCountPart128 , riceParam ) ) ;
riceParamPart128 = _mm_xor_si128 ( _mm_srli_epi32 ( riceParamPart128 , 1 ) , _mm_add_epi32 ( drflac__mm_not_si128 ( _mm_and_si128 ( riceParamPart128 , _mm_set1_epi32 ( 0x01 ) ) ) , _mm_set1_epi32 ( 0x01 ) ) ) ; /* <-- SSE2 compatible */
/*riceParamPart128 = _mm_xor_si128(_mm_srli_epi32(riceParamPart128, 1), _mm_mullo_epi32(_mm_and_si128(riceParamPart128, _mm_set1_epi32(0x01)), _mm_set1_epi32(0xFFFFFFFF)));*/ /* <-- Only supported from SSE4.1 and is slower in my testing... */
if ( order < = 4 ) {
for ( i = 0 ; i < 4 ; i + = 1 ) {
prediction128 = _mm_mullo_epi32 ( coefficients128_0 , samples128_0 ) ;
/* Horizontal add and shift. */
prediction128 = drflac__mm_hadd_epi32 ( prediction128 ) ;
prediction128 = _mm_srai_epi32 ( prediction128 , shift ) ;
prediction128 = _mm_add_epi32 ( riceParamPart128 , prediction128 ) ;
samples128_0 = _mm_alignr_epi8 ( prediction128 , samples128_0 , 4 ) ;
riceParamPart128 = _mm_alignr_epi8 ( _mm_setzero_si128 ( ) , riceParamPart128 , 4 ) ;
}
} else if ( order < = 8 ) {
for ( i = 0 ; i < 4 ; i + = 1 ) {
prediction128 = _mm_mullo_epi32 ( coefficients128_4 , samples128_4 ) ;
prediction128 = _mm_add_epi32 ( prediction128 , _mm_mullo_epi32 ( coefficients128_0 , samples128_0 ) ) ;
/* Horizontal add and shift. */
prediction128 = drflac__mm_hadd_epi32 ( prediction128 ) ;
prediction128 = _mm_srai_epi32 ( prediction128 , shift ) ;
prediction128 = _mm_add_epi32 ( riceParamPart128 , prediction128 ) ;
samples128_4 = _mm_alignr_epi8 ( samples128_0 , samples128_4 , 4 ) ;
samples128_0 = _mm_alignr_epi8 ( prediction128 , samples128_0 , 4 ) ;
riceParamPart128 = _mm_alignr_epi8 ( _mm_setzero_si128 ( ) , riceParamPart128 , 4 ) ;
}
} else {
for ( i = 0 ; i < 4 ; i + = 1 ) {
prediction128 = _mm_mullo_epi32 ( coefficients128_8 , samples128_8 ) ;
prediction128 = _mm_add_epi32 ( prediction128 , _mm_mullo_epi32 ( coefficients128_4 , samples128_4 ) ) ;
prediction128 = _mm_add_epi32 ( prediction128 , _mm_mullo_epi32 ( coefficients128_0 , samples128_0 ) ) ;
/* Horizontal add and shift. */
prediction128 = drflac__mm_hadd_epi32 ( prediction128 ) ;
prediction128 = _mm_srai_epi32 ( prediction128 , shift ) ;
prediction128 = _mm_add_epi32 ( riceParamPart128 , prediction128 ) ;
samples128_8 = _mm_alignr_epi8 ( samples128_4 , samples128_8 , 4 ) ;
samples128_4 = _mm_alignr_epi8 ( samples128_0 , samples128_4 , 4 ) ;
samples128_0 = _mm_alignr_epi8 ( prediction128 , samples128_0 , 4 ) ;
riceParamPart128 = _mm_alignr_epi8 ( _mm_setzero_si128 ( ) , riceParamPart128 , 4 ) ;
}
}
/* We store samples in groups of 4. */
_mm_storeu_si128 ( ( __m128i * ) pDecodedSamples , samples128_0 ) ;
pDecodedSamples + = 4 ;
}
/* Make sure we process the last few samples. */
i = ( count & ~ 3 ) ;
while ( i < ( int ) count ) {
/* Rice extraction. */
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts0 , & riceParamParts0 ) ) {
return DRFLAC_FALSE ;
}
/* Rice reconstruction. */
riceParamParts0 & = riceParamMask ;
riceParamParts0 | = ( zeroCountParts0 < < riceParam ) ;
riceParamParts0 = ( riceParamParts0 > > 1 ) ^ t [ riceParamParts0 & 0x01 ] ;
/* Sample reconstruction. */
pDecodedSamples [ 0 ] = riceParamParts0 + drflac__calculate_prediction_32 ( order , shift , coefficients , pDecodedSamples ) ;
i + = 1 ;
pDecodedSamples + = 1 ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples_with_residual__rice__sse41_64 ( drflac_bs * bs , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 order , drflac_int32 shift , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
int i ;
drflac_uint32 riceParamMask ;
drflac_int32 * pDecodedSamples = pSamplesOut ;
drflac_int32 * pDecodedSamplesEnd = pSamplesOut + ( count & ~ 3 ) ;
drflac_uint32 zeroCountParts0 = 0 ;
drflac_uint32 zeroCountParts1 = 0 ;
drflac_uint32 zeroCountParts2 = 0 ;
drflac_uint32 zeroCountParts3 = 0 ;
drflac_uint32 riceParamParts0 = 0 ;
drflac_uint32 riceParamParts1 = 0 ;
drflac_uint32 riceParamParts2 = 0 ;
drflac_uint32 riceParamParts3 = 0 ;
__m128i coefficients128_0 ;
__m128i coefficients128_4 ;
__m128i coefficients128_8 ;
__m128i samples128_0 ;
__m128i samples128_4 ;
__m128i samples128_8 ;
__m128i prediction128 ;
__m128i riceParamMask128 ;
const drflac_uint32 t [ 2 ] = { 0x00000000 , 0xFFFFFFFF } ;
DRFLAC_ASSERT ( order < = 12 ) ;
riceParamMask = ( drflac_uint32 ) ~ ( ( ~ 0UL ) < < riceParam ) ;
riceParamMask128 = _mm_set1_epi32 ( riceParamMask ) ;
prediction128 = _mm_setzero_si128 ( ) ;
/* Pre-load. */
coefficients128_0 = _mm_setzero_si128 ( ) ;
coefficients128_4 = _mm_setzero_si128 ( ) ;
coefficients128_8 = _mm_setzero_si128 ( ) ;
samples128_0 = _mm_setzero_si128 ( ) ;
samples128_4 = _mm_setzero_si128 ( ) ;
samples128_8 = _mm_setzero_si128 ( ) ;
# if 1
{
int runningOrder = order ;
/* 0 - 3. */
if ( runningOrder > = 4 ) {
coefficients128_0 = _mm_loadu_si128 ( ( const __m128i * ) ( coefficients + 0 ) ) ;
samples128_0 = _mm_loadu_si128 ( ( const __m128i * ) ( pSamplesOut - 4 ) ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : coefficients128_0 = _mm_set_epi32 ( 0 , coefficients [ 2 ] , coefficients [ 1 ] , coefficients [ 0 ] ) ; samples128_0 = _mm_set_epi32 ( pSamplesOut [ - 1 ] , pSamplesOut [ - 2 ] , pSamplesOut [ - 3 ] , 0 ) ; break ;
case 2 : coefficients128_0 = _mm_set_epi32 ( 0 , 0 , coefficients [ 1 ] , coefficients [ 0 ] ) ; samples128_0 = _mm_set_epi32 ( pSamplesOut [ - 1 ] , pSamplesOut [ - 2 ] , 0 , 0 ) ; break ;
case 1 : coefficients128_0 = _mm_set_epi32 ( 0 , 0 , 0 , coefficients [ 0 ] ) ; samples128_0 = _mm_set_epi32 ( pSamplesOut [ - 1 ] , 0 , 0 , 0 ) ; break ;
}
runningOrder = 0 ;
}
/* 4 - 7 */
if ( runningOrder > = 4 ) {
coefficients128_4 = _mm_loadu_si128 ( ( const __m128i * ) ( coefficients + 4 ) ) ;
samples128_4 = _mm_loadu_si128 ( ( const __m128i * ) ( pSamplesOut - 8 ) ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : coefficients128_4 = _mm_set_epi32 ( 0 , coefficients [ 6 ] , coefficients [ 5 ] , coefficients [ 4 ] ) ; samples128_4 = _mm_set_epi32 ( pSamplesOut [ - 5 ] , pSamplesOut [ - 6 ] , pSamplesOut [ - 7 ] , 0 ) ; break ;
case 2 : coefficients128_4 = _mm_set_epi32 ( 0 , 0 , coefficients [ 5 ] , coefficients [ 4 ] ) ; samples128_4 = _mm_set_epi32 ( pSamplesOut [ - 5 ] , pSamplesOut [ - 6 ] , 0 , 0 ) ; break ;
case 1 : coefficients128_4 = _mm_set_epi32 ( 0 , 0 , 0 , coefficients [ 4 ] ) ; samples128_4 = _mm_set_epi32 ( pSamplesOut [ - 5 ] , 0 , 0 , 0 ) ; break ;
}
runningOrder = 0 ;
}
/* 8 - 11 */
if ( runningOrder = = 4 ) {
coefficients128_8 = _mm_loadu_si128 ( ( const __m128i * ) ( coefficients + 8 ) ) ;
samples128_8 = _mm_loadu_si128 ( ( const __m128i * ) ( pSamplesOut - 12 ) ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : coefficients128_8 = _mm_set_epi32 ( 0 , coefficients [ 10 ] , coefficients [ 9 ] , coefficients [ 8 ] ) ; samples128_8 = _mm_set_epi32 ( pSamplesOut [ - 9 ] , pSamplesOut [ - 10 ] , pSamplesOut [ - 11 ] , 0 ) ; break ;
case 2 : coefficients128_8 = _mm_set_epi32 ( 0 , 0 , coefficients [ 9 ] , coefficients [ 8 ] ) ; samples128_8 = _mm_set_epi32 ( pSamplesOut [ - 9 ] , pSamplesOut [ - 10 ] , 0 , 0 ) ; break ;
case 1 : coefficients128_8 = _mm_set_epi32 ( 0 , 0 , 0 , coefficients [ 8 ] ) ; samples128_8 = _mm_set_epi32 ( pSamplesOut [ - 9 ] , 0 , 0 , 0 ) ; break ;
}
runningOrder = 0 ;
}
/* Coefficients need to be shuffled for our streaming algorithm below to work. Samples are already in the correct order from the loading routine above. */
coefficients128_0 = _mm_shuffle_epi32 ( coefficients128_0 , _MM_SHUFFLE ( 0 , 1 , 2 , 3 ) ) ;
coefficients128_4 = _mm_shuffle_epi32 ( coefficients128_4 , _MM_SHUFFLE ( 0 , 1 , 2 , 3 ) ) ;
coefficients128_8 = _mm_shuffle_epi32 ( coefficients128_8 , _MM_SHUFFLE ( 0 , 1 , 2 , 3 ) ) ;
}
# else
switch ( order )
{
case 12 : ( ( drflac_int32 * ) & coefficients128_8 ) [ 0 ] = coefficients [ 11 ] ; ( ( drflac_int32 * ) & samples128_8 ) [ 0 ] = pDecodedSamples [ - 12 ] ;
case 11 : ( ( drflac_int32 * ) & coefficients128_8 ) [ 1 ] = coefficients [ 10 ] ; ( ( drflac_int32 * ) & samples128_8 ) [ 1 ] = pDecodedSamples [ - 11 ] ;
case 10 : ( ( drflac_int32 * ) & coefficients128_8 ) [ 2 ] = coefficients [ 9 ] ; ( ( drflac_int32 * ) & samples128_8 ) [ 2 ] = pDecodedSamples [ - 10 ] ;
case 9 : ( ( drflac_int32 * ) & coefficients128_8 ) [ 3 ] = coefficients [ 8 ] ; ( ( drflac_int32 * ) & samples128_8 ) [ 3 ] = pDecodedSamples [ - 9 ] ;
case 8 : ( ( drflac_int32 * ) & coefficients128_4 ) [ 0 ] = coefficients [ 7 ] ; ( ( drflac_int32 * ) & samples128_4 ) [ 0 ] = pDecodedSamples [ - 8 ] ;
case 7 : ( ( drflac_int32 * ) & coefficients128_4 ) [ 1 ] = coefficients [ 6 ] ; ( ( drflac_int32 * ) & samples128_4 ) [ 1 ] = pDecodedSamples [ - 7 ] ;
case 6 : ( ( drflac_int32 * ) & coefficients128_4 ) [ 2 ] = coefficients [ 5 ] ; ( ( drflac_int32 * ) & samples128_4 ) [ 2 ] = pDecodedSamples [ - 6 ] ;
case 5 : ( ( drflac_int32 * ) & coefficients128_4 ) [ 3 ] = coefficients [ 4 ] ; ( ( drflac_int32 * ) & samples128_4 ) [ 3 ] = pDecodedSamples [ - 5 ] ;
case 4 : ( ( drflac_int32 * ) & coefficients128_0 ) [ 0 ] = coefficients [ 3 ] ; ( ( drflac_int32 * ) & samples128_0 ) [ 0 ] = pDecodedSamples [ - 4 ] ;
case 3 : ( ( drflac_int32 * ) & coefficients128_0 ) [ 1 ] = coefficients [ 2 ] ; ( ( drflac_int32 * ) & samples128_0 ) [ 1 ] = pDecodedSamples [ - 3 ] ;
case 2 : ( ( drflac_int32 * ) & coefficients128_0 ) [ 2 ] = coefficients [ 1 ] ; ( ( drflac_int32 * ) & samples128_0 ) [ 2 ] = pDecodedSamples [ - 2 ] ;
case 1 : ( ( drflac_int32 * ) & coefficients128_0 ) [ 3 ] = coefficients [ 0 ] ; ( ( drflac_int32 * ) & samples128_0 ) [ 3 ] = pDecodedSamples [ - 1 ] ;
}
# endif
/* For this version we are doing one sample at a time. */
while ( pDecodedSamples < pDecodedSamplesEnd ) {
__m128i zeroCountPart128 ;
__m128i riceParamPart128 ;
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts0 , & riceParamParts0 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts1 , & riceParamParts1 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts2 , & riceParamParts2 ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts3 , & riceParamParts3 ) ) {
return DRFLAC_FALSE ;
}
zeroCountPart128 = _mm_set_epi32 ( zeroCountParts3 , zeroCountParts2 , zeroCountParts1 , zeroCountParts0 ) ;
riceParamPart128 = _mm_set_epi32 ( riceParamParts3 , riceParamParts2 , riceParamParts1 , riceParamParts0 ) ;
riceParamPart128 = _mm_and_si128 ( riceParamPart128 , riceParamMask128 ) ;
riceParamPart128 = _mm_or_si128 ( riceParamPart128 , _mm_slli_epi32 ( zeroCountPart128 , riceParam ) ) ;
riceParamPart128 = _mm_xor_si128 ( _mm_srli_epi32 ( riceParamPart128 , 1 ) , _mm_add_epi32 ( drflac__mm_not_si128 ( _mm_and_si128 ( riceParamPart128 , _mm_set1_epi32 ( 1 ) ) ) , _mm_set1_epi32 ( 1 ) ) ) ;
for ( i = 0 ; i < 4 ; i + = 1 ) {
prediction128 = _mm_xor_si128 ( prediction128 , prediction128 ) ; /* Reset to 0. */
switch ( order )
{
case 12 :
case 11 : prediction128 = _mm_add_epi64 ( prediction128 , _mm_mul_epi32 ( _mm_shuffle_epi32 ( coefficients128_8 , _MM_SHUFFLE ( 1 , 1 , 0 , 0 ) ) , _mm_shuffle_epi32 ( samples128_8 , _MM_SHUFFLE ( 1 , 1 , 0 , 0 ) ) ) ) ;
case 10 :
case 9 : prediction128 = _mm_add_epi64 ( prediction128 , _mm_mul_epi32 ( _mm_shuffle_epi32 ( coefficients128_8 , _MM_SHUFFLE ( 3 , 3 , 2 , 2 ) ) , _mm_shuffle_epi32 ( samples128_8 , _MM_SHUFFLE ( 3 , 3 , 2 , 2 ) ) ) ) ;
case 8 :
case 7 : prediction128 = _mm_add_epi64 ( prediction128 , _mm_mul_epi32 ( _mm_shuffle_epi32 ( coefficients128_4 , _MM_SHUFFLE ( 1 , 1 , 0 , 0 ) ) , _mm_shuffle_epi32 ( samples128_4 , _MM_SHUFFLE ( 1 , 1 , 0 , 0 ) ) ) ) ;
case 6 :
case 5 : prediction128 = _mm_add_epi64 ( prediction128 , _mm_mul_epi32 ( _mm_shuffle_epi32 ( coefficients128_4 , _MM_SHUFFLE ( 3 , 3 , 2 , 2 ) ) , _mm_shuffle_epi32 ( samples128_4 , _MM_SHUFFLE ( 3 , 3 , 2 , 2 ) ) ) ) ;
case 4 :
case 3 : prediction128 = _mm_add_epi64 ( prediction128 , _mm_mul_epi32 ( _mm_shuffle_epi32 ( coefficients128_0 , _MM_SHUFFLE ( 1 , 1 , 0 , 0 ) ) , _mm_shuffle_epi32 ( samples128_0 , _MM_SHUFFLE ( 1 , 1 , 0 , 0 ) ) ) ) ;
case 2 :
case 1 : prediction128 = _mm_add_epi64 ( prediction128 , _mm_mul_epi32 ( _mm_shuffle_epi32 ( coefficients128_0 , _MM_SHUFFLE ( 3 , 3 , 2 , 2 ) ) , _mm_shuffle_epi32 ( samples128_0 , _MM_SHUFFLE ( 3 , 3 , 2 , 2 ) ) ) ) ;
}
/* Horizontal add and shift. */
prediction128 = drflac__mm_hadd_epi64 ( prediction128 ) ;
prediction128 = drflac__mm_srai_epi64 ( prediction128 , shift ) ;
prediction128 = _mm_add_epi32 ( riceParamPart128 , prediction128 ) ;
/* Our value should be sitting in prediction128[0]. We need to combine this with our SSE samples. */
samples128_8 = _mm_alignr_epi8 ( samples128_4 , samples128_8 , 4 ) ;
samples128_4 = _mm_alignr_epi8 ( samples128_0 , samples128_4 , 4 ) ;
samples128_0 = _mm_alignr_epi8 ( prediction128 , samples128_0 , 4 ) ;
/* Slide our rice parameter down so that the value in position 0 contains the next one to process. */
riceParamPart128 = _mm_alignr_epi8 ( _mm_setzero_si128 ( ) , riceParamPart128 , 4 ) ;
}
/* We store samples in groups of 4. */
_mm_storeu_si128 ( ( __m128i * ) pDecodedSamples , samples128_0 ) ;
pDecodedSamples + = 4 ;
}
/* Make sure we process the last few samples. */
i = ( count & ~ 3 ) ;
while ( i < ( int ) count ) {
/* Rice extraction. */
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts0 , & riceParamParts0 ) ) {
return DRFLAC_FALSE ;
}
/* Rice reconstruction. */
riceParamParts0 & = riceParamMask ;
riceParamParts0 | = ( zeroCountParts0 < < riceParam ) ;
riceParamParts0 = ( riceParamParts0 > > 1 ) ^ t [ riceParamParts0 & 0x01 ] ;
/* Sample reconstruction. */
pDecodedSamples [ 0 ] = riceParamParts0 + drflac__calculate_prediction_64 ( order , shift , coefficients , pDecodedSamples ) ;
i + = 1 ;
pDecodedSamples + = 1 ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples_with_residual__rice__sse41 ( drflac_bs * bs , drflac_uint32 bitsPerSample , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 lpcOrder , drflac_int32 lpcShift , drflac_uint32 lpcPrecision , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pSamplesOut ! = NULL ) ;
/* In my testing the order is rarely > 12, so in this case I'm going to simplify the SSE implementation by only handling order <= 12. */
if ( lpcOrder > 0 & & lpcOrder < = 12 ) {
if ( drflac__use_64_bit_prediction ( bitsPerSample , lpcOrder , lpcPrecision ) ) {
return drflac__decode_samples_with_residual__rice__sse41_64 ( bs , count , riceParam , lpcOrder , lpcShift , coefficients , pSamplesOut ) ;
} else {
return drflac__decode_samples_with_residual__rice__sse41_32 ( bs , count , riceParam , lpcOrder , lpcShift , coefficients , pSamplesOut ) ;
}
} else {
return drflac__decode_samples_with_residual__rice__scalar ( bs , bitsPerSample , count , riceParam , lpcOrder , lpcShift , lpcPrecision , coefficients , pSamplesOut ) ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac__vst2q_s32 ( drflac_int32 * p , int32x4x2_t x )
{
vst1q_s32 ( p + 0 , x . val [ 0 ] ) ;
vst1q_s32 ( p + 4 , x . val [ 1 ] ) ;
}
static DRFLAC_INLINE void drflac__vst2q_u32 ( drflac_uint32 * p , uint32x4x2_t x )
{
vst1q_u32 ( p + 0 , x . val [ 0 ] ) ;
vst1q_u32 ( p + 4 , x . val [ 1 ] ) ;
}
static DRFLAC_INLINE void drflac__vst2q_f32 ( float * p , float32x4x2_t x )
{
vst1q_f32 ( p + 0 , x . val [ 0 ] ) ;
vst1q_f32 ( p + 4 , x . val [ 1 ] ) ;
}
static DRFLAC_INLINE void drflac__vst2q_s16 ( drflac_int16 * p , int16x4x2_t x )
{
vst1q_s16 ( p , vcombine_s16 ( x . val [ 0 ] , x . val [ 1 ] ) ) ;
}
static DRFLAC_INLINE void drflac__vst2q_u16 ( drflac_uint16 * p , uint16x4x2_t x )
{
vst1q_u16 ( p , vcombine_u16 ( x . val [ 0 ] , x . val [ 1 ] ) ) ;
}
static DRFLAC_INLINE int32x4_t drflac__vdupq_n_s32x4 ( drflac_int32 x3 , drflac_int32 x2 , drflac_int32 x1 , drflac_int32 x0 )
{
drflac_int32 x [ 4 ] ;
x [ 3 ] = x3 ;
x [ 2 ] = x2 ;
x [ 1 ] = x1 ;
x [ 0 ] = x0 ;
return vld1q_s32 ( x ) ;
}
static DRFLAC_INLINE int32x4_t drflac__valignrq_s32_1 ( int32x4_t a , int32x4_t b )
{
/* Equivalent to SSE's _mm_alignr_epi8(a, b, 4) */
/* Reference */
/*return drflac__vdupq_n_s32x4(
vgetq_lane_s32 ( a , 0 ) ,
vgetq_lane_s32 ( b , 3 ) ,
vgetq_lane_s32 ( b , 2 ) ,
vgetq_lane_s32 ( b , 1 )
) ; */
return vextq_s32 ( b , a , 1 ) ;
}
static DRFLAC_INLINE uint32x4_t drflac__valignrq_u32_1 ( uint32x4_t a , uint32x4_t b )
{
/* Equivalent to SSE's _mm_alignr_epi8(a, b, 4) */
/* Reference */
/*return drflac__vdupq_n_s32x4(
vgetq_lane_s32 ( a , 0 ) ,
vgetq_lane_s32 ( b , 3 ) ,
vgetq_lane_s32 ( b , 2 ) ,
vgetq_lane_s32 ( b , 1 )
) ; */
return vextq_u32 ( b , a , 1 ) ;
}
static DRFLAC_INLINE int32x2_t drflac__vhaddq_s32 ( int32x4_t x )
{
/* The sum must end up in position 0. */
/* Reference */
/*return vdupq_n_s32(
vgetq_lane_s32 ( x , 3 ) +
vgetq_lane_s32 ( x , 2 ) +
vgetq_lane_s32 ( x , 1 ) +
vgetq_lane_s32 ( x , 0 )
) ; */
int32x2_t r = vadd_s32 ( vget_high_s32 ( x ) , vget_low_s32 ( x ) ) ;
return vpadd_s32 ( r , r ) ;
}
static DRFLAC_INLINE int64x1_t drflac__vhaddq_s64 ( int64x2_t x )
{
return vadd_s64 ( vget_high_s64 ( x ) , vget_low_s64 ( x ) ) ;
}
static DRFLAC_INLINE int32x4_t drflac__vrevq_s32 ( int32x4_t x )
{
/* Reference */
/*return drflac__vdupq_n_s32x4(
vgetq_lane_s32 ( x , 0 ) ,
vgetq_lane_s32 ( x , 1 ) ,
vgetq_lane_s32 ( x , 2 ) ,
vgetq_lane_s32 ( x , 3 )
) ; */
return vrev64q_s32 ( vcombine_s32 ( vget_high_s32 ( x ) , vget_low_s32 ( x ) ) ) ;
}
static DRFLAC_INLINE int32x4_t drflac__vnotq_s32 ( int32x4_t x )
{
return veorq_s32 ( x , vdupq_n_s32 ( 0xFFFFFFFF ) ) ;
}
static DRFLAC_INLINE uint32x4_t drflac__vnotq_u32 ( uint32x4_t x )
{
return veorq_u32 ( x , vdupq_n_u32 ( 0xFFFFFFFF ) ) ;
}
static drflac_bool32 drflac__decode_samples_with_residual__rice__neon_32 ( drflac_bs * bs , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 order , drflac_int32 shift , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
int i ;
drflac_uint32 riceParamMask ;
drflac_int32 * pDecodedSamples = pSamplesOut ;
drflac_int32 * pDecodedSamplesEnd = pSamplesOut + ( count & ~ 3 ) ;
drflac_uint32 zeroCountParts [ 4 ] ;
drflac_uint32 riceParamParts [ 4 ] ;
int32x4_t coefficients128_0 ;
int32x4_t coefficients128_4 ;
int32x4_t coefficients128_8 ;
int32x4_t samples128_0 ;
int32x4_t samples128_4 ;
int32x4_t samples128_8 ;
uint32x4_t riceParamMask128 ;
int32x4_t riceParam128 ;
int32x2_t shift64 ;
uint32x4_t one128 ;
const drflac_uint32 t [ 2 ] = { 0x00000000 , 0xFFFFFFFF } ;
riceParamMask = ~ ( ( ~ 0UL ) < < riceParam ) ;
riceParamMask128 = vdupq_n_u32 ( riceParamMask ) ;
riceParam128 = vdupq_n_s32 ( riceParam ) ;
shift64 = vdup_n_s32 ( - shift ) ; /* Negate the shift because we'll be doing a variable shift using vshlq_s32(). */
one128 = vdupq_n_u32 ( 1 ) ;
/*
Pre - loading the coefficients and prior samples is annoying because we need to ensure we don ' t try reading more than
what ' s available in the input buffers . It would be conenient to use a fall - through switch to do this , but this results
in strict aliasing warnings with GCC . To work around this I ' m just doing something hacky . This feels a bit convoluted
so I think there ' s opportunity for this to be simplified .
*/
{
int runningOrder = order ;
drflac_int32 tempC [ 4 ] = { 0 , 0 , 0 , 0 } ;
drflac_int32 tempS [ 4 ] = { 0 , 0 , 0 , 0 } ;
/* 0 - 3. */
if ( runningOrder > = 4 ) {
coefficients128_0 = vld1q_s32 ( coefficients + 0 ) ;
samples128_0 = vld1q_s32 ( pSamplesOut - 4 ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : tempC [ 2 ] = coefficients [ 2 ] ; tempS [ 1 ] = pSamplesOut [ - 3 ] ; /* fallthrough */
case 2 : tempC [ 1 ] = coefficients [ 1 ] ; tempS [ 2 ] = pSamplesOut [ - 2 ] ; /* fallthrough */
case 1 : tempC [ 0 ] = coefficients [ 0 ] ; tempS [ 3 ] = pSamplesOut [ - 1 ] ; /* fallthrough */
}
coefficients128_0 = vld1q_s32 ( tempC ) ;
samples128_0 = vld1q_s32 ( tempS ) ;
runningOrder = 0 ;
}
/* 4 - 7 */
if ( runningOrder > = 4 ) {
coefficients128_4 = vld1q_s32 ( coefficients + 4 ) ;
samples128_4 = vld1q_s32 ( pSamplesOut - 8 ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : tempC [ 2 ] = coefficients [ 6 ] ; tempS [ 1 ] = pSamplesOut [ - 7 ] ; /* fallthrough */
case 2 : tempC [ 1 ] = coefficients [ 5 ] ; tempS [ 2 ] = pSamplesOut [ - 6 ] ; /* fallthrough */
case 1 : tempC [ 0 ] = coefficients [ 4 ] ; tempS [ 3 ] = pSamplesOut [ - 5 ] ; /* fallthrough */
}
coefficients128_4 = vld1q_s32 ( tempC ) ;
samples128_4 = vld1q_s32 ( tempS ) ;
runningOrder = 0 ;
}
/* 8 - 11 */
if ( runningOrder = = 4 ) {
coefficients128_8 = vld1q_s32 ( coefficients + 8 ) ;
samples128_8 = vld1q_s32 ( pSamplesOut - 12 ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : tempC [ 2 ] = coefficients [ 10 ] ; tempS [ 1 ] = pSamplesOut [ - 11 ] ; /* fallthrough */
case 2 : tempC [ 1 ] = coefficients [ 9 ] ; tempS [ 2 ] = pSamplesOut [ - 10 ] ; /* fallthrough */
case 1 : tempC [ 0 ] = coefficients [ 8 ] ; tempS [ 3 ] = pSamplesOut [ - 9 ] ; /* fallthrough */
}
coefficients128_8 = vld1q_s32 ( tempC ) ;
samples128_8 = vld1q_s32 ( tempS ) ;
runningOrder = 0 ;
}
/* Coefficients need to be shuffled for our streaming algorithm below to work. Samples are already in the correct order from the loading routine above. */
coefficients128_0 = drflac__vrevq_s32 ( coefficients128_0 ) ;
coefficients128_4 = drflac__vrevq_s32 ( coefficients128_4 ) ;
coefficients128_8 = drflac__vrevq_s32 ( coefficients128_8 ) ;
}
/* For this version we are doing one sample at a time. */
while ( pDecodedSamples < pDecodedSamplesEnd ) {
int32x4_t prediction128 ;
int32x2_t prediction64 ;
uint32x4_t zeroCountPart128 ;
uint32x4_t riceParamPart128 ;
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 0 ] , & riceParamParts [ 0 ] ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 1 ] , & riceParamParts [ 1 ] ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 2 ] , & riceParamParts [ 2 ] ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 3 ] , & riceParamParts [ 3 ] ) ) {
return DRFLAC_FALSE ;
}
zeroCountPart128 = vld1q_u32 ( zeroCountParts ) ;
riceParamPart128 = vld1q_u32 ( riceParamParts ) ;
riceParamPart128 = vandq_u32 ( riceParamPart128 , riceParamMask128 ) ;
riceParamPart128 = vorrq_u32 ( riceParamPart128 , vshlq_u32 ( zeroCountPart128 , riceParam128 ) ) ;
riceParamPart128 = veorq_u32 ( vshrq_n_u32 ( riceParamPart128 , 1 ) , vaddq_u32 ( drflac__vnotq_u32 ( vandq_u32 ( riceParamPart128 , one128 ) ) , one128 ) ) ;
if ( order < = 4 ) {
for ( i = 0 ; i < 4 ; i + = 1 ) {
prediction128 = vmulq_s32 ( coefficients128_0 , samples128_0 ) ;
/* Horizontal add and shift. */
prediction64 = drflac__vhaddq_s32 ( prediction128 ) ;
prediction64 = vshl_s32 ( prediction64 , shift64 ) ;
prediction64 = vadd_s32 ( prediction64 , vget_low_s32 ( vreinterpretq_s32_u32 ( riceParamPart128 ) ) ) ;
samples128_0 = drflac__valignrq_s32_1 ( vcombine_s32 ( prediction64 , vdup_n_s32 ( 0 ) ) , samples128_0 ) ;
riceParamPart128 = drflac__valignrq_u32_1 ( vdupq_n_u32 ( 0 ) , riceParamPart128 ) ;
}
} else if ( order < = 8 ) {
for ( i = 0 ; i < 4 ; i + = 1 ) {
prediction128 = vmulq_s32 ( coefficients128_4 , samples128_4 ) ;
prediction128 = vmlaq_s32 ( prediction128 , coefficients128_0 , samples128_0 ) ;
/* Horizontal add and shift. */
prediction64 = drflac__vhaddq_s32 ( prediction128 ) ;
prediction64 = vshl_s32 ( prediction64 , shift64 ) ;
prediction64 = vadd_s32 ( prediction64 , vget_low_s32 ( vreinterpretq_s32_u32 ( riceParamPart128 ) ) ) ;
samples128_4 = drflac__valignrq_s32_1 ( samples128_0 , samples128_4 ) ;
samples128_0 = drflac__valignrq_s32_1 ( vcombine_s32 ( prediction64 , vdup_n_s32 ( 0 ) ) , samples128_0 ) ;
riceParamPart128 = drflac__valignrq_u32_1 ( vdupq_n_u32 ( 0 ) , riceParamPart128 ) ;
}
} else {
for ( i = 0 ; i < 4 ; i + = 1 ) {
prediction128 = vmulq_s32 ( coefficients128_8 , samples128_8 ) ;
prediction128 = vmlaq_s32 ( prediction128 , coefficients128_4 , samples128_4 ) ;
prediction128 = vmlaq_s32 ( prediction128 , coefficients128_0 , samples128_0 ) ;
/* Horizontal add and shift. */
prediction64 = drflac__vhaddq_s32 ( prediction128 ) ;
prediction64 = vshl_s32 ( prediction64 , shift64 ) ;
prediction64 = vadd_s32 ( prediction64 , vget_low_s32 ( vreinterpretq_s32_u32 ( riceParamPart128 ) ) ) ;
samples128_8 = drflac__valignrq_s32_1 ( samples128_4 , samples128_8 ) ;
samples128_4 = drflac__valignrq_s32_1 ( samples128_0 , samples128_4 ) ;
samples128_0 = drflac__valignrq_s32_1 ( vcombine_s32 ( prediction64 , vdup_n_s32 ( 0 ) ) , samples128_0 ) ;
riceParamPart128 = drflac__valignrq_u32_1 ( vdupq_n_u32 ( 0 ) , riceParamPart128 ) ;
}
}
/* We store samples in groups of 4. */
vst1q_s32 ( pDecodedSamples , samples128_0 ) ;
pDecodedSamples + = 4 ;
}
/* Make sure we process the last few samples. */
i = ( count & ~ 3 ) ;
while ( i < ( int ) count ) {
/* Rice extraction. */
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 0 ] , & riceParamParts [ 0 ] ) ) {
return DRFLAC_FALSE ;
}
/* Rice reconstruction. */
riceParamParts [ 0 ] & = riceParamMask ;
riceParamParts [ 0 ] | = ( zeroCountParts [ 0 ] < < riceParam ) ;
riceParamParts [ 0 ] = ( riceParamParts [ 0 ] > > 1 ) ^ t [ riceParamParts [ 0 ] & 0x01 ] ;
/* Sample reconstruction. */
pDecodedSamples [ 0 ] = riceParamParts [ 0 ] + drflac__calculate_prediction_32 ( order , shift , coefficients , pDecodedSamples ) ;
i + = 1 ;
pDecodedSamples + = 1 ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples_with_residual__rice__neon_64 ( drflac_bs * bs , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 order , drflac_int32 shift , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
int i ;
drflac_uint32 riceParamMask ;
drflac_int32 * pDecodedSamples = pSamplesOut ;
drflac_int32 * pDecodedSamplesEnd = pSamplesOut + ( count & ~ 3 ) ;
drflac_uint32 zeroCountParts [ 4 ] ;
drflac_uint32 riceParamParts [ 4 ] ;
int32x4_t coefficients128_0 ;
int32x4_t coefficients128_4 ;
int32x4_t coefficients128_8 ;
int32x4_t samples128_0 ;
int32x4_t samples128_4 ;
int32x4_t samples128_8 ;
uint32x4_t riceParamMask128 ;
int32x4_t riceParam128 ;
int64x1_t shift64 ;
uint32x4_t one128 ;
const drflac_uint32 t [ 2 ] = { 0x00000000 , 0xFFFFFFFF } ;
riceParamMask = ~ ( ( ~ 0UL ) < < riceParam ) ;
riceParamMask128 = vdupq_n_u32 ( riceParamMask ) ;
riceParam128 = vdupq_n_s32 ( riceParam ) ;
shift64 = vdup_n_s64 ( - shift ) ; /* Negate the shift because we'll be doing a variable shift using vshlq_s32(). */
one128 = vdupq_n_u32 ( 1 ) ;
/*
Pre - loading the coefficients and prior samples is annoying because we need to ensure we don ' t try reading more than
what ' s available in the input buffers . It would be convenient to use a fall - through switch to do this , but this results
in strict aliasing warnings with GCC . To work around this I ' m just doing something hacky . This feels a bit convoluted
so I think there ' s opportunity for this to be simplified .
*/
{
int runningOrder = order ;
drflac_int32 tempC [ 4 ] = { 0 , 0 , 0 , 0 } ;
drflac_int32 tempS [ 4 ] = { 0 , 0 , 0 , 0 } ;
/* 0 - 3. */
if ( runningOrder > = 4 ) {
coefficients128_0 = vld1q_s32 ( coefficients + 0 ) ;
samples128_0 = vld1q_s32 ( pSamplesOut - 4 ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : tempC [ 2 ] = coefficients [ 2 ] ; tempS [ 1 ] = pSamplesOut [ - 3 ] ; /* fallthrough */
case 2 : tempC [ 1 ] = coefficients [ 1 ] ; tempS [ 2 ] = pSamplesOut [ - 2 ] ; /* fallthrough */
case 1 : tempC [ 0 ] = coefficients [ 0 ] ; tempS [ 3 ] = pSamplesOut [ - 1 ] ; /* fallthrough */
}
coefficients128_0 = vld1q_s32 ( tempC ) ;
samples128_0 = vld1q_s32 ( tempS ) ;
runningOrder = 0 ;
}
/* 4 - 7 */
if ( runningOrder > = 4 ) {
coefficients128_4 = vld1q_s32 ( coefficients + 4 ) ;
samples128_4 = vld1q_s32 ( pSamplesOut - 8 ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : tempC [ 2 ] = coefficients [ 6 ] ; tempS [ 1 ] = pSamplesOut [ - 7 ] ; /* fallthrough */
case 2 : tempC [ 1 ] = coefficients [ 5 ] ; tempS [ 2 ] = pSamplesOut [ - 6 ] ; /* fallthrough */
case 1 : tempC [ 0 ] = coefficients [ 4 ] ; tempS [ 3 ] = pSamplesOut [ - 5 ] ; /* fallthrough */
}
coefficients128_4 = vld1q_s32 ( tempC ) ;
samples128_4 = vld1q_s32 ( tempS ) ;
runningOrder = 0 ;
}
/* 8 - 11 */
if ( runningOrder = = 4 ) {
coefficients128_8 = vld1q_s32 ( coefficients + 8 ) ;
samples128_8 = vld1q_s32 ( pSamplesOut - 12 ) ;
runningOrder - = 4 ;
} else {
switch ( runningOrder ) {
case 3 : tempC [ 2 ] = coefficients [ 10 ] ; tempS [ 1 ] = pSamplesOut [ - 11 ] ; /* fallthrough */
case 2 : tempC [ 1 ] = coefficients [ 9 ] ; tempS [ 2 ] = pSamplesOut [ - 10 ] ; /* fallthrough */
case 1 : tempC [ 0 ] = coefficients [ 8 ] ; tempS [ 3 ] = pSamplesOut [ - 9 ] ; /* fallthrough */
}
coefficients128_8 = vld1q_s32 ( tempC ) ;
samples128_8 = vld1q_s32 ( tempS ) ;
runningOrder = 0 ;
}
/* Coefficients need to be shuffled for our streaming algorithm below to work. Samples are already in the correct order from the loading routine above. */
coefficients128_0 = drflac__vrevq_s32 ( coefficients128_0 ) ;
coefficients128_4 = drflac__vrevq_s32 ( coefficients128_4 ) ;
coefficients128_8 = drflac__vrevq_s32 ( coefficients128_8 ) ;
}
/* For this version we are doing one sample at a time. */
while ( pDecodedSamples < pDecodedSamplesEnd ) {
2022-04-03 11:31:13 +00:00
int64x2_t prediction128 = vdupq_n_s64 ( 0 ) ;
2022-04-03 10:27:06 +00:00
uint32x4_t zeroCountPart128 ;
uint32x4_t riceParamPart128 ;
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 0 ] , & riceParamParts [ 0 ] ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 1 ] , & riceParamParts [ 1 ] ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 2 ] , & riceParamParts [ 2 ] ) | |
! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 3 ] , & riceParamParts [ 3 ] ) ) {
return DRFLAC_FALSE ;
}
zeroCountPart128 = vld1q_u32 ( zeroCountParts ) ;
riceParamPart128 = vld1q_u32 ( riceParamParts ) ;
riceParamPart128 = vandq_u32 ( riceParamPart128 , riceParamMask128 ) ;
riceParamPart128 = vorrq_u32 ( riceParamPart128 , vshlq_u32 ( zeroCountPart128 , riceParam128 ) ) ;
riceParamPart128 = veorq_u32 ( vshrq_n_u32 ( riceParamPart128 , 1 ) , vaddq_u32 ( drflac__vnotq_u32 ( vandq_u32 ( riceParamPart128 , one128 ) ) , one128 ) ) ;
for ( i = 0 ; i < 4 ; i + = 1 ) {
int64x1_t prediction64 ;
prediction128 = veorq_s64 ( prediction128 , prediction128 ) ; /* Reset to 0. */
switch ( order )
{
case 12 :
case 11 : prediction128 = vaddq_s64 ( prediction128 , vmull_s32 ( vget_low_s32 ( coefficients128_8 ) , vget_low_s32 ( samples128_8 ) ) ) ;
case 10 :
case 9 : prediction128 = vaddq_s64 ( prediction128 , vmull_s32 ( vget_high_s32 ( coefficients128_8 ) , vget_high_s32 ( samples128_8 ) ) ) ;
case 8 :
case 7 : prediction128 = vaddq_s64 ( prediction128 , vmull_s32 ( vget_low_s32 ( coefficients128_4 ) , vget_low_s32 ( samples128_4 ) ) ) ;
case 6 :
case 5 : prediction128 = vaddq_s64 ( prediction128 , vmull_s32 ( vget_high_s32 ( coefficients128_4 ) , vget_high_s32 ( samples128_4 ) ) ) ;
case 4 :
case 3 : prediction128 = vaddq_s64 ( prediction128 , vmull_s32 ( vget_low_s32 ( coefficients128_0 ) , vget_low_s32 ( samples128_0 ) ) ) ;
case 2 :
case 1 : prediction128 = vaddq_s64 ( prediction128 , vmull_s32 ( vget_high_s32 ( coefficients128_0 ) , vget_high_s32 ( samples128_0 ) ) ) ;
}
/* Horizontal add and shift. */
prediction64 = drflac__vhaddq_s64 ( prediction128 ) ;
prediction64 = vshl_s64 ( prediction64 , shift64 ) ;
prediction64 = vadd_s64 ( prediction64 , vdup_n_s64 ( vgetq_lane_u32 ( riceParamPart128 , 0 ) ) ) ;
/* Our value should be sitting in prediction64[0]. We need to combine this with our SSE samples. */
samples128_8 = drflac__valignrq_s32_1 ( samples128_4 , samples128_8 ) ;
samples128_4 = drflac__valignrq_s32_1 ( samples128_0 , samples128_4 ) ;
samples128_0 = drflac__valignrq_s32_1 ( vcombine_s32 ( vreinterpret_s32_s64 ( prediction64 ) , vdup_n_s32 ( 0 ) ) , samples128_0 ) ;
/* Slide our rice parameter down so that the value in position 0 contains the next one to process. */
riceParamPart128 = drflac__valignrq_u32_1 ( vdupq_n_u32 ( 0 ) , riceParamPart128 ) ;
}
/* We store samples in groups of 4. */
vst1q_s32 ( pDecodedSamples , samples128_0 ) ;
pDecodedSamples + = 4 ;
}
/* Make sure we process the last few samples. */
i = ( count & ~ 3 ) ;
while ( i < ( int ) count ) {
/* Rice extraction. */
if ( ! drflac__read_rice_parts_x1 ( bs , riceParam , & zeroCountParts [ 0 ] , & riceParamParts [ 0 ] ) ) {
return DRFLAC_FALSE ;
}
/* Rice reconstruction. */
riceParamParts [ 0 ] & = riceParamMask ;
riceParamParts [ 0 ] | = ( zeroCountParts [ 0 ] < < riceParam ) ;
riceParamParts [ 0 ] = ( riceParamParts [ 0 ] > > 1 ) ^ t [ riceParamParts [ 0 ] & 0x01 ] ;
/* Sample reconstruction. */
pDecodedSamples [ 0 ] = riceParamParts [ 0 ] + drflac__calculate_prediction_64 ( order , shift , coefficients , pDecodedSamples ) ;
i + = 1 ;
pDecodedSamples + = 1 ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples_with_residual__rice__neon ( drflac_bs * bs , drflac_uint32 bitsPerSample , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 lpcOrder , drflac_int32 lpcShift , drflac_uint32 lpcPrecision , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( pSamplesOut ! = NULL ) ;
/* In my testing the order is rarely > 12, so in this case I'm going to simplify the NEON implementation by only handling order <= 12. */
if ( lpcOrder > 0 & & lpcOrder < = 12 ) {
if ( drflac__use_64_bit_prediction ( bitsPerSample , lpcOrder , lpcPrecision ) ) {
return drflac__decode_samples_with_residual__rice__neon_64 ( bs , count , riceParam , lpcOrder , lpcShift , coefficients , pSamplesOut ) ;
} else {
return drflac__decode_samples_with_residual__rice__neon_32 ( bs , count , riceParam , lpcOrder , lpcShift , coefficients , pSamplesOut ) ;
}
} else {
return drflac__decode_samples_with_residual__rice__scalar ( bs , bitsPerSample , count , riceParam , lpcOrder , lpcShift , lpcPrecision , coefficients , pSamplesOut ) ;
}
}
# endif
static drflac_bool32 drflac__decode_samples_with_residual__rice ( drflac_bs * bs , drflac_uint32 bitsPerSample , drflac_uint32 count , drflac_uint8 riceParam , drflac_uint32 lpcOrder , drflac_int32 lpcShift , drflac_uint32 lpcPrecision , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
# if defined(DRFLAC_SUPPORT_SSE41)
if ( drflac__gIsSSE41Supported ) {
return drflac__decode_samples_with_residual__rice__sse41 ( bs , bitsPerSample , count , riceParam , lpcOrder , lpcShift , lpcPrecision , coefficients , pSamplesOut ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported ) {
return drflac__decode_samples_with_residual__rice__neon ( bs , bitsPerSample , count , riceParam , lpcOrder , lpcShift , lpcPrecision , coefficients , pSamplesOut ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
return drflac__decode_samples_with_residual__rice__reference ( bs , bitsPerSample , count , riceParam , lpcOrder , lpcShift , lpcPrecision , coefficients , pSamplesOut ) ;
# else
return drflac__decode_samples_with_residual__rice__scalar ( bs , bitsPerSample , count , riceParam , lpcOrder , lpcShift , lpcPrecision , coefficients , pSamplesOut ) ;
# endif
}
}
/* Reads and seeks past a string of residual values as Rice codes. The decoder should be sitting on the first bit of the Rice codes. */
static drflac_bool32 drflac__read_and_seek_residual__rice ( drflac_bs * bs , drflac_uint32 count , drflac_uint8 riceParam )
{
drflac_uint32 i ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
for ( i = 0 ; i < count ; + + i ) {
if ( ! drflac__seek_rice_parts ( bs , riceParam ) ) {
return DRFLAC_FALSE ;
}
}
return DRFLAC_TRUE ;
}
# if defined(__clang__)
__attribute__ ( ( no_sanitize ( " signed-integer-overflow " ) ) )
# endif
static drflac_bool32 drflac__decode_samples_with_residual__unencoded ( drflac_bs * bs , drflac_uint32 bitsPerSample , drflac_uint32 count , drflac_uint8 unencodedBitsPerSample , drflac_uint32 lpcOrder , drflac_int32 lpcShift , drflac_uint32 lpcPrecision , const drflac_int32 * coefficients , drflac_int32 * pSamplesOut )
{
drflac_uint32 i ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( unencodedBitsPerSample < = 31 ) ; /* <-- unencodedBitsPerSample is a 5 bit number, so cannot exceed 31. */
DRFLAC_ASSERT ( pSamplesOut ! = NULL ) ;
for ( i = 0 ; i < count ; + + i ) {
if ( unencodedBitsPerSample > 0 ) {
if ( ! drflac__read_int32 ( bs , unencodedBitsPerSample , pSamplesOut + i ) ) {
return DRFLAC_FALSE ;
}
} else {
pSamplesOut [ i ] = 0 ;
}
if ( drflac__use_64_bit_prediction ( bitsPerSample , lpcOrder , lpcPrecision ) ) {
pSamplesOut [ i ] + = drflac__calculate_prediction_64 ( lpcOrder , lpcShift , coefficients , pSamplesOut + i ) ;
} else {
pSamplesOut [ i ] + = drflac__calculate_prediction_32 ( lpcOrder , lpcShift , coefficients , pSamplesOut + i ) ;
}
}
return DRFLAC_TRUE ;
}
/*
Reads and decodes the residual for the sub - frame the decoder is currently sitting on . This function should be called
when the decoder is sitting at the very start of the RESIDUAL block . The first < order > residuals will be ignored . The
< blockSize > and < order > parameters are used to determine how many residual values need to be decoded .
*/
static drflac_bool32 drflac__decode_samples_with_residual ( drflac_bs * bs , drflac_uint32 bitsPerSample , drflac_uint32 blockSize , drflac_uint32 lpcOrder , drflac_int32 lpcShift , drflac_uint32 lpcPrecision , const drflac_int32 * coefficients , drflac_int32 * pDecodedSamples )
{
drflac_uint8 residualMethod ;
drflac_uint8 partitionOrder ;
drflac_uint32 samplesInPartition ;
drflac_uint32 partitionsRemaining ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( blockSize ! = 0 ) ;
DRFLAC_ASSERT ( pDecodedSamples ! = NULL ) ; /* <-- Should we allow NULL, in which case we just seek past the residual rather than do a full decode? */
if ( ! drflac__read_uint8 ( bs , 2 , & residualMethod ) ) {
return DRFLAC_FALSE ;
}
if ( residualMethod ! = DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE & & residualMethod ! = DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE2 ) {
return DRFLAC_FALSE ; /* Unknown or unsupported residual coding method. */
}
/* Ignore the first <order> values. */
pDecodedSamples + = lpcOrder ;
if ( ! drflac__read_uint8 ( bs , 4 , & partitionOrder ) ) {
return DRFLAC_FALSE ;
}
/*
From the FLAC spec :
The Rice partition order in a Rice - coded residual section must be less than or equal to 8.
*/
if ( partitionOrder > 8 ) {
return DRFLAC_FALSE ;
}
/* Validation check. */
if ( ( blockSize / ( 1 < < partitionOrder ) ) < lpcOrder ) {
return DRFLAC_FALSE ;
}
samplesInPartition = ( blockSize / ( 1 < < partitionOrder ) ) - lpcOrder ;
partitionsRemaining = ( 1 < < partitionOrder ) ;
for ( ; ; ) {
drflac_uint8 riceParam = 0 ;
if ( residualMethod = = DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE ) {
if ( ! drflac__read_uint8 ( bs , 4 , & riceParam ) ) {
return DRFLAC_FALSE ;
}
if ( riceParam = = 15 ) {
riceParam = 0xFF ;
}
} else if ( residualMethod = = DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE2 ) {
if ( ! drflac__read_uint8 ( bs , 5 , & riceParam ) ) {
return DRFLAC_FALSE ;
}
if ( riceParam = = 31 ) {
riceParam = 0xFF ;
}
}
if ( riceParam ! = 0xFF ) {
if ( ! drflac__decode_samples_with_residual__rice ( bs , bitsPerSample , samplesInPartition , riceParam , lpcOrder , lpcShift , lpcPrecision , coefficients , pDecodedSamples ) ) {
return DRFLAC_FALSE ;
}
} else {
drflac_uint8 unencodedBitsPerSample = 0 ;
if ( ! drflac__read_uint8 ( bs , 5 , & unencodedBitsPerSample ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac__decode_samples_with_residual__unencoded ( bs , bitsPerSample , samplesInPartition , unencodedBitsPerSample , lpcOrder , lpcShift , lpcPrecision , coefficients , pDecodedSamples ) ) {
return DRFLAC_FALSE ;
}
}
pDecodedSamples + = samplesInPartition ;
if ( partitionsRemaining = = 1 ) {
break ;
}
partitionsRemaining - = 1 ;
if ( partitionOrder ! = 0 ) {
samplesInPartition = blockSize / ( 1 < < partitionOrder ) ;
}
}
return DRFLAC_TRUE ;
}
/*
Reads and seeks past the residual for the sub - frame the decoder is currently sitting on . This function should be called
when the decoder is sitting at the very start of the RESIDUAL block . The first < order > residuals will be set to 0. The
< blockSize > and < order > parameters are used to determine how many residual values need to be decoded .
*/
static drflac_bool32 drflac__read_and_seek_residual ( drflac_bs * bs , drflac_uint32 blockSize , drflac_uint32 order )
{
drflac_uint8 residualMethod ;
drflac_uint8 partitionOrder ;
drflac_uint32 samplesInPartition ;
drflac_uint32 partitionsRemaining ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( blockSize ! = 0 ) ;
if ( ! drflac__read_uint8 ( bs , 2 , & residualMethod ) ) {
return DRFLAC_FALSE ;
}
if ( residualMethod ! = DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE & & residualMethod ! = DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE2 ) {
return DRFLAC_FALSE ; /* Unknown or unsupported residual coding method. */
}
if ( ! drflac__read_uint8 ( bs , 4 , & partitionOrder ) ) {
return DRFLAC_FALSE ;
}
/*
From the FLAC spec :
The Rice partition order in a Rice - coded residual section must be less than or equal to 8.
*/
if ( partitionOrder > 8 ) {
return DRFLAC_FALSE ;
}
/* Validation check. */
if ( ( blockSize / ( 1 < < partitionOrder ) ) < = order ) {
return DRFLAC_FALSE ;
}
samplesInPartition = ( blockSize / ( 1 < < partitionOrder ) ) - order ;
partitionsRemaining = ( 1 < < partitionOrder ) ;
for ( ; ; )
{
drflac_uint8 riceParam = 0 ;
if ( residualMethod = = DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE ) {
if ( ! drflac__read_uint8 ( bs , 4 , & riceParam ) ) {
return DRFLAC_FALSE ;
}
if ( riceParam = = 15 ) {
riceParam = 0xFF ;
}
} else if ( residualMethod = = DRFLAC_RESIDUAL_CODING_METHOD_PARTITIONED_RICE2 ) {
if ( ! drflac__read_uint8 ( bs , 5 , & riceParam ) ) {
return DRFLAC_FALSE ;
}
if ( riceParam = = 31 ) {
riceParam = 0xFF ;
}
}
if ( riceParam ! = 0xFF ) {
if ( ! drflac__read_and_seek_residual__rice ( bs , samplesInPartition , riceParam ) ) {
return DRFLAC_FALSE ;
}
} else {
drflac_uint8 unencodedBitsPerSample = 0 ;
if ( ! drflac__read_uint8 ( bs , 5 , & unencodedBitsPerSample ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac__seek_bits ( bs , unencodedBitsPerSample * samplesInPartition ) ) {
return DRFLAC_FALSE ;
}
}
if ( partitionsRemaining = = 1 ) {
break ;
}
partitionsRemaining - = 1 ;
samplesInPartition = blockSize / ( 1 < < partitionOrder ) ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples__constant ( drflac_bs * bs , drflac_uint32 blockSize , drflac_uint32 subframeBitsPerSample , drflac_int32 * pDecodedSamples )
{
drflac_uint32 i ;
/* Only a single sample needs to be decoded here. */
drflac_int32 sample ;
if ( ! drflac__read_int32 ( bs , subframeBitsPerSample , & sample ) ) {
return DRFLAC_FALSE ;
}
/*
We don ' t really need to expand this , but it does simplify the process of reading samples . If this becomes a performance issue ( unlikely )
we ' ll want to look at a more efficient way .
*/
for ( i = 0 ; i < blockSize ; + + i ) {
pDecodedSamples [ i ] = sample ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples__verbatim ( drflac_bs * bs , drflac_uint32 blockSize , drflac_uint32 subframeBitsPerSample , drflac_int32 * pDecodedSamples )
{
drflac_uint32 i ;
for ( i = 0 ; i < blockSize ; + + i ) {
drflac_int32 sample ;
if ( ! drflac__read_int32 ( bs , subframeBitsPerSample , & sample ) ) {
return DRFLAC_FALSE ;
}
pDecodedSamples [ i ] = sample ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples__fixed ( drflac_bs * bs , drflac_uint32 blockSize , drflac_uint32 subframeBitsPerSample , drflac_uint8 lpcOrder , drflac_int32 * pDecodedSamples )
{
drflac_uint32 i ;
static drflac_int32 lpcCoefficientsTable [ 5 ] [ 4 ] = {
{ 0 , 0 , 0 , 0 } ,
{ 1 , 0 , 0 , 0 } ,
{ 2 , - 1 , 0 , 0 } ,
{ 3 , - 3 , 1 , 0 } ,
{ 4 , - 6 , 4 , - 1 }
} ;
/* Warm up samples and coefficients. */
for ( i = 0 ; i < lpcOrder ; + + i ) {
drflac_int32 sample ;
if ( ! drflac__read_int32 ( bs , subframeBitsPerSample , & sample ) ) {
return DRFLAC_FALSE ;
}
pDecodedSamples [ i ] = sample ;
}
if ( ! drflac__decode_samples_with_residual ( bs , subframeBitsPerSample , blockSize , lpcOrder , 0 , 4 , lpcCoefficientsTable [ lpcOrder ] , pDecodedSamples ) ) {
return DRFLAC_FALSE ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_samples__lpc ( drflac_bs * bs , drflac_uint32 blockSize , drflac_uint32 bitsPerSample , drflac_uint8 lpcOrder , drflac_int32 * pDecodedSamples )
{
drflac_uint8 i ;
drflac_uint8 lpcPrecision ;
drflac_int8 lpcShift ;
drflac_int32 coefficients [ 32 ] ;
/* Warm up samples. */
for ( i = 0 ; i < lpcOrder ; + + i ) {
drflac_int32 sample ;
if ( ! drflac__read_int32 ( bs , bitsPerSample , & sample ) ) {
return DRFLAC_FALSE ;
}
pDecodedSamples [ i ] = sample ;
}
if ( ! drflac__read_uint8 ( bs , 4 , & lpcPrecision ) ) {
return DRFLAC_FALSE ;
}
if ( lpcPrecision = = 15 ) {
return DRFLAC_FALSE ; /* Invalid. */
}
lpcPrecision + = 1 ;
if ( ! drflac__read_int8 ( bs , 5 , & lpcShift ) ) {
return DRFLAC_FALSE ;
}
/*
From the FLAC specification :
Quantized linear predictor coefficient shift needed in bits ( NOTE : this number is signed two ' s - complement )
Emphasis on the " signed two's-complement " . In practice there does not seem to be any encoders nor decoders supporting negative shifts . For now dr_flac is
not going to support negative shifts as I don ' t have any reference files . However , when a reference file comes through I will consider adding support .
*/
if ( lpcShift < 0 ) {
return DRFLAC_FALSE ;
}
DRFLAC_ZERO_MEMORY ( coefficients , sizeof ( coefficients ) ) ;
for ( i = 0 ; i < lpcOrder ; + + i ) {
if ( ! drflac__read_int32 ( bs , lpcPrecision , coefficients + i ) ) {
return DRFLAC_FALSE ;
}
}
if ( ! drflac__decode_samples_with_residual ( bs , bitsPerSample , blockSize , lpcOrder , lpcShift , lpcPrecision , coefficients , pDecodedSamples ) ) {
return DRFLAC_FALSE ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__read_next_flac_frame_header ( drflac_bs * bs , drflac_uint8 streaminfoBitsPerSample , drflac_frame_header * header )
{
const drflac_uint32 sampleRateTable [ 12 ] = { 0 , 88200 , 176400 , 192000 , 8000 , 16000 , 22050 , 24000 , 32000 , 44100 , 48000 , 96000 } ;
const drflac_uint8 bitsPerSampleTable [ 8 ] = { 0 , 8 , 12 , ( drflac_uint8 ) - 1 , 16 , 20 , 24 , ( drflac_uint8 ) - 1 } ; /* -1 = reserved. */
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( header ! = NULL ) ;
/* Keep looping until we find a valid sync code. */
for ( ; ; ) {
drflac_uint8 crc8 = 0xCE ; /* 0xCE = drflac_crc8(0, 0x3FFE, 14); */
drflac_uint8 reserved = 0 ;
drflac_uint8 blockingStrategy = 0 ;
drflac_uint8 blockSize = 0 ;
drflac_uint8 sampleRate = 0 ;
drflac_uint8 channelAssignment = 0 ;
drflac_uint8 bitsPerSample = 0 ;
drflac_bool32 isVariableBlockSize ;
if ( ! drflac__find_and_seek_to_next_sync_code ( bs ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac__read_uint8 ( bs , 1 , & reserved ) ) {
return DRFLAC_FALSE ;
}
if ( reserved = = 1 ) {
continue ;
}
crc8 = drflac_crc8 ( crc8 , reserved , 1 ) ;
if ( ! drflac__read_uint8 ( bs , 1 , & blockingStrategy ) ) {
return DRFLAC_FALSE ;
}
crc8 = drflac_crc8 ( crc8 , blockingStrategy , 1 ) ;
if ( ! drflac__read_uint8 ( bs , 4 , & blockSize ) ) {
return DRFLAC_FALSE ;
}
if ( blockSize = = 0 ) {
continue ;
}
crc8 = drflac_crc8 ( crc8 , blockSize , 4 ) ;
if ( ! drflac__read_uint8 ( bs , 4 , & sampleRate ) ) {
return DRFLAC_FALSE ;
}
crc8 = drflac_crc8 ( crc8 , sampleRate , 4 ) ;
if ( ! drflac__read_uint8 ( bs , 4 , & channelAssignment ) ) {
return DRFLAC_FALSE ;
}
if ( channelAssignment > 10 ) {
continue ;
}
crc8 = drflac_crc8 ( crc8 , channelAssignment , 4 ) ;
if ( ! drflac__read_uint8 ( bs , 3 , & bitsPerSample ) ) {
return DRFLAC_FALSE ;
}
if ( bitsPerSample = = 3 | | bitsPerSample = = 7 ) {
continue ;
}
crc8 = drflac_crc8 ( crc8 , bitsPerSample , 3 ) ;
if ( ! drflac__read_uint8 ( bs , 1 , & reserved ) ) {
return DRFLAC_FALSE ;
}
if ( reserved = = 1 ) {
continue ;
}
crc8 = drflac_crc8 ( crc8 , reserved , 1 ) ;
isVariableBlockSize = blockingStrategy = = 1 ;
if ( isVariableBlockSize ) {
drflac_uint64 pcmFrameNumber ;
drflac_result result = drflac__read_utf8_coded_number ( bs , & pcmFrameNumber , & crc8 ) ;
if ( result ! = DRFLAC_SUCCESS ) {
if ( result = = DRFLAC_AT_END ) {
return DRFLAC_FALSE ;
} else {
continue ;
}
}
header - > flacFrameNumber = 0 ;
header - > pcmFrameNumber = pcmFrameNumber ;
} else {
drflac_uint64 flacFrameNumber = 0 ;
drflac_result result = drflac__read_utf8_coded_number ( bs , & flacFrameNumber , & crc8 ) ;
if ( result ! = DRFLAC_SUCCESS ) {
if ( result = = DRFLAC_AT_END ) {
return DRFLAC_FALSE ;
} else {
continue ;
}
}
header - > flacFrameNumber = ( drflac_uint32 ) flacFrameNumber ; /* <-- Safe cast. */
header - > pcmFrameNumber = 0 ;
}
DRFLAC_ASSERT ( blockSize > 0 ) ;
if ( blockSize = = 1 ) {
header - > blockSizeInPCMFrames = 192 ;
} else if ( blockSize < = 5 ) {
DRFLAC_ASSERT ( blockSize > = 2 ) ;
header - > blockSizeInPCMFrames = 576 * ( 1 < < ( blockSize - 2 ) ) ;
} else if ( blockSize = = 6 ) {
if ( ! drflac__read_uint16 ( bs , 8 , & header - > blockSizeInPCMFrames ) ) {
return DRFLAC_FALSE ;
}
crc8 = drflac_crc8 ( crc8 , header - > blockSizeInPCMFrames , 8 ) ;
header - > blockSizeInPCMFrames + = 1 ;
} else if ( blockSize = = 7 ) {
if ( ! drflac__read_uint16 ( bs , 16 , & header - > blockSizeInPCMFrames ) ) {
return DRFLAC_FALSE ;
}
crc8 = drflac_crc8 ( crc8 , header - > blockSizeInPCMFrames , 16 ) ;
if ( header - > blockSizeInPCMFrames = = 0xFFFF ) {
return DRFLAC_FALSE ; /* Frame is too big. This is the size of the frame minus 1. The STREAMINFO block defines the max block size which is 16-bits. Adding one will make it 17 bits and therefore too big. */
}
header - > blockSizeInPCMFrames + = 1 ;
} else {
DRFLAC_ASSERT ( blockSize > = 8 ) ;
header - > blockSizeInPCMFrames = 256 * ( 1 < < ( blockSize - 8 ) ) ;
}
if ( sampleRate < = 11 ) {
header - > sampleRate = sampleRateTable [ sampleRate ] ;
} else if ( sampleRate = = 12 ) {
if ( ! drflac__read_uint32 ( bs , 8 , & header - > sampleRate ) ) {
return DRFLAC_FALSE ;
}
crc8 = drflac_crc8 ( crc8 , header - > sampleRate , 8 ) ;
header - > sampleRate * = 1000 ;
} else if ( sampleRate = = 13 ) {
if ( ! drflac__read_uint32 ( bs , 16 , & header - > sampleRate ) ) {
return DRFLAC_FALSE ;
}
crc8 = drflac_crc8 ( crc8 , header - > sampleRate , 16 ) ;
} else if ( sampleRate = = 14 ) {
if ( ! drflac__read_uint32 ( bs , 16 , & header - > sampleRate ) ) {
return DRFLAC_FALSE ;
}
crc8 = drflac_crc8 ( crc8 , header - > sampleRate , 16 ) ;
header - > sampleRate * = 10 ;
} else {
continue ; /* Invalid. Assume an invalid block. */
}
header - > channelAssignment = channelAssignment ;
header - > bitsPerSample = bitsPerSampleTable [ bitsPerSample ] ;
if ( header - > bitsPerSample = = 0 ) {
header - > bitsPerSample = streaminfoBitsPerSample ;
}
if ( header - > bitsPerSample ! = streaminfoBitsPerSample ) {
/* If this subframe has a different bitsPerSample then streaminfo or the first frame, reject it */
return DRFLAC_FALSE ;
}
if ( ! drflac__read_uint8 ( bs , 8 , & header - > crc8 ) ) {
return DRFLAC_FALSE ;
}
# ifndef DR_FLAC_NO_CRC
if ( header - > crc8 ! = crc8 ) {
continue ; /* CRC mismatch. Loop back to the top and find the next sync code. */
}
# endif
return DRFLAC_TRUE ;
}
}
static drflac_bool32 drflac__read_subframe_header ( drflac_bs * bs , drflac_subframe * pSubframe )
{
drflac_uint8 header ;
int type ;
if ( ! drflac__read_uint8 ( bs , 8 , & header ) ) {
return DRFLAC_FALSE ;
}
/* First bit should always be 0. */
if ( ( header & 0x80 ) ! = 0 ) {
return DRFLAC_FALSE ;
}
type = ( header & 0x7E ) > > 1 ;
if ( type = = 0 ) {
pSubframe - > subframeType = DRFLAC_SUBFRAME_CONSTANT ;
} else if ( type = = 1 ) {
pSubframe - > subframeType = DRFLAC_SUBFRAME_VERBATIM ;
} else {
if ( ( type & 0x20 ) ! = 0 ) {
pSubframe - > subframeType = DRFLAC_SUBFRAME_LPC ;
pSubframe - > lpcOrder = ( drflac_uint8 ) ( type & 0x1F ) + 1 ;
} else if ( ( type & 0x08 ) ! = 0 ) {
pSubframe - > subframeType = DRFLAC_SUBFRAME_FIXED ;
pSubframe - > lpcOrder = ( drflac_uint8 ) ( type & 0x07 ) ;
if ( pSubframe - > lpcOrder > 4 ) {
pSubframe - > subframeType = DRFLAC_SUBFRAME_RESERVED ;
pSubframe - > lpcOrder = 0 ;
}
} else {
pSubframe - > subframeType = DRFLAC_SUBFRAME_RESERVED ;
}
}
if ( pSubframe - > subframeType = = DRFLAC_SUBFRAME_RESERVED ) {
return DRFLAC_FALSE ;
}
/* Wasted bits per sample. */
pSubframe - > wastedBitsPerSample = 0 ;
if ( ( header & 0x01 ) = = 1 ) {
unsigned int wastedBitsPerSample ;
if ( ! drflac__seek_past_next_set_bit ( bs , & wastedBitsPerSample ) ) {
return DRFLAC_FALSE ;
}
pSubframe - > wastedBitsPerSample = ( drflac_uint8 ) wastedBitsPerSample + 1 ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_subframe ( drflac_bs * bs , drflac_frame * frame , int subframeIndex , drflac_int32 * pDecodedSamplesOut )
{
drflac_subframe * pSubframe ;
drflac_uint32 subframeBitsPerSample ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( frame ! = NULL ) ;
pSubframe = frame - > subframes + subframeIndex ;
if ( ! drflac__read_subframe_header ( bs , pSubframe ) ) {
return DRFLAC_FALSE ;
}
/* Side channels require an extra bit per sample. Took a while to figure that one out... */
subframeBitsPerSample = frame - > header . bitsPerSample ;
if ( ( frame - > header . channelAssignment = = DRFLAC_CHANNEL_ASSIGNMENT_LEFT_SIDE | | frame - > header . channelAssignment = = DRFLAC_CHANNEL_ASSIGNMENT_MID_SIDE ) & & subframeIndex = = 1 ) {
subframeBitsPerSample + = 1 ;
} else if ( frame - > header . channelAssignment = = DRFLAC_CHANNEL_ASSIGNMENT_RIGHT_SIDE & & subframeIndex = = 0 ) {
subframeBitsPerSample + = 1 ;
}
if ( subframeBitsPerSample > 32 ) {
/* libFLAC and ffmpeg reject 33-bit subframes as well */
return DRFLAC_FALSE ;
}
/* Need to handle wasted bits per sample. */
if ( pSubframe - > wastedBitsPerSample > = subframeBitsPerSample ) {
return DRFLAC_FALSE ;
}
subframeBitsPerSample - = pSubframe - > wastedBitsPerSample ;
pSubframe - > pSamplesS32 = pDecodedSamplesOut ;
switch ( pSubframe - > subframeType )
{
case DRFLAC_SUBFRAME_CONSTANT :
{
drflac__decode_samples__constant ( bs , frame - > header . blockSizeInPCMFrames , subframeBitsPerSample , pSubframe - > pSamplesS32 ) ;
} break ;
case DRFLAC_SUBFRAME_VERBATIM :
{
drflac__decode_samples__verbatim ( bs , frame - > header . blockSizeInPCMFrames , subframeBitsPerSample , pSubframe - > pSamplesS32 ) ;
} break ;
case DRFLAC_SUBFRAME_FIXED :
{
drflac__decode_samples__fixed ( bs , frame - > header . blockSizeInPCMFrames , subframeBitsPerSample , pSubframe - > lpcOrder , pSubframe - > pSamplesS32 ) ;
} break ;
case DRFLAC_SUBFRAME_LPC :
{
drflac__decode_samples__lpc ( bs , frame - > header . blockSizeInPCMFrames , subframeBitsPerSample , pSubframe - > lpcOrder , pSubframe - > pSamplesS32 ) ;
} break ;
default : return DRFLAC_FALSE ;
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__seek_subframe ( drflac_bs * bs , drflac_frame * frame , int subframeIndex )
{
drflac_subframe * pSubframe ;
drflac_uint32 subframeBitsPerSample ;
DRFLAC_ASSERT ( bs ! = NULL ) ;
DRFLAC_ASSERT ( frame ! = NULL ) ;
pSubframe = frame - > subframes + subframeIndex ;
if ( ! drflac__read_subframe_header ( bs , pSubframe ) ) {
return DRFLAC_FALSE ;
}
/* Side channels require an extra bit per sample. Took a while to figure that one out... */
subframeBitsPerSample = frame - > header . bitsPerSample ;
if ( ( frame - > header . channelAssignment = = DRFLAC_CHANNEL_ASSIGNMENT_LEFT_SIDE | | frame - > header . channelAssignment = = DRFLAC_CHANNEL_ASSIGNMENT_MID_SIDE ) & & subframeIndex = = 1 ) {
subframeBitsPerSample + = 1 ;
} else if ( frame - > header . channelAssignment = = DRFLAC_CHANNEL_ASSIGNMENT_RIGHT_SIDE & & subframeIndex = = 0 ) {
subframeBitsPerSample + = 1 ;
}
/* Need to handle wasted bits per sample. */
if ( pSubframe - > wastedBitsPerSample > = subframeBitsPerSample ) {
return DRFLAC_FALSE ;
}
subframeBitsPerSample - = pSubframe - > wastedBitsPerSample ;
pSubframe - > pSamplesS32 = NULL ;
switch ( pSubframe - > subframeType )
{
case DRFLAC_SUBFRAME_CONSTANT :
{
if ( ! drflac__seek_bits ( bs , subframeBitsPerSample ) ) {
return DRFLAC_FALSE ;
}
} break ;
case DRFLAC_SUBFRAME_VERBATIM :
{
unsigned int bitsToSeek = frame - > header . blockSizeInPCMFrames * subframeBitsPerSample ;
if ( ! drflac__seek_bits ( bs , bitsToSeek ) ) {
return DRFLAC_FALSE ;
}
} break ;
case DRFLAC_SUBFRAME_FIXED :
{
unsigned int bitsToSeek = pSubframe - > lpcOrder * subframeBitsPerSample ;
if ( ! drflac__seek_bits ( bs , bitsToSeek ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac__read_and_seek_residual ( bs , frame - > header . blockSizeInPCMFrames , pSubframe - > lpcOrder ) ) {
return DRFLAC_FALSE ;
}
} break ;
case DRFLAC_SUBFRAME_LPC :
{
drflac_uint8 lpcPrecision ;
unsigned int bitsToSeek = pSubframe - > lpcOrder * subframeBitsPerSample ;
if ( ! drflac__seek_bits ( bs , bitsToSeek ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac__read_uint8 ( bs , 4 , & lpcPrecision ) ) {
return DRFLAC_FALSE ;
}
if ( lpcPrecision = = 15 ) {
return DRFLAC_FALSE ; /* Invalid. */
}
lpcPrecision + = 1 ;
bitsToSeek = ( pSubframe - > lpcOrder * lpcPrecision ) + 5 ; /* +5 for shift. */
if ( ! drflac__seek_bits ( bs , bitsToSeek ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac__read_and_seek_residual ( bs , frame - > header . blockSizeInPCMFrames , pSubframe - > lpcOrder ) ) {
return DRFLAC_FALSE ;
}
} break ;
default : return DRFLAC_FALSE ;
}
return DRFLAC_TRUE ;
}
static DRFLAC_INLINE drflac_uint8 drflac__get_channel_count_from_channel_assignment ( drflac_int8 channelAssignment )
{
drflac_uint8 lookup [ ] = { 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 2 , 2 , 2 } ;
DRFLAC_ASSERT ( channelAssignment < = 10 ) ;
return lookup [ channelAssignment ] ;
}
static drflac_result drflac__decode_flac_frame ( drflac * pFlac )
{
int channelCount ;
int i ;
drflac_uint8 paddingSizeInBits ;
drflac_uint16 desiredCRC16 ;
# ifndef DR_FLAC_NO_CRC
drflac_uint16 actualCRC16 ;
# endif
/* This function should be called while the stream is sitting on the first byte after the frame header. */
DRFLAC_ZERO_MEMORY ( pFlac - > currentFLACFrame . subframes , sizeof ( pFlac - > currentFLACFrame . subframes ) ) ;
/* The frame block size must never be larger than the maximum block size defined by the FLAC stream. */
if ( pFlac - > currentFLACFrame . header . blockSizeInPCMFrames > pFlac - > maxBlockSizeInPCMFrames ) {
return DRFLAC_ERROR ;
}
/* The number of channels in the frame must match the channel count from the STREAMINFO block. */
channelCount = drflac__get_channel_count_from_channel_assignment ( pFlac - > currentFLACFrame . header . channelAssignment ) ;
if ( channelCount ! = ( int ) pFlac - > channels ) {
return DRFLAC_ERROR ;
}
for ( i = 0 ; i < channelCount ; + + i ) {
if ( ! drflac__decode_subframe ( & pFlac - > bs , & pFlac - > currentFLACFrame , i , pFlac - > pDecodedSamples + ( pFlac - > currentFLACFrame . header . blockSizeInPCMFrames * i ) ) ) {
return DRFLAC_ERROR ;
}
}
paddingSizeInBits = ( drflac_uint8 ) ( DRFLAC_CACHE_L1_BITS_REMAINING ( & pFlac - > bs ) & 7 ) ;
if ( paddingSizeInBits > 0 ) {
drflac_uint8 padding = 0 ;
if ( ! drflac__read_uint8 ( & pFlac - > bs , paddingSizeInBits , & padding ) ) {
return DRFLAC_AT_END ;
}
}
# ifndef DR_FLAC_NO_CRC
actualCRC16 = drflac__flush_crc16 ( & pFlac - > bs ) ;
# endif
if ( ! drflac__read_uint16 ( & pFlac - > bs , 16 , & desiredCRC16 ) ) {
return DRFLAC_AT_END ;
}
# ifndef DR_FLAC_NO_CRC
if ( actualCRC16 ! = desiredCRC16 ) {
return DRFLAC_CRC_MISMATCH ; /* CRC mismatch. */
}
# endif
pFlac - > currentFLACFrame . pcmFramesRemaining = pFlac - > currentFLACFrame . header . blockSizeInPCMFrames ;
return DRFLAC_SUCCESS ;
}
static drflac_result drflac__seek_flac_frame ( drflac * pFlac )
{
int channelCount ;
int i ;
drflac_uint16 desiredCRC16 ;
# ifndef DR_FLAC_NO_CRC
drflac_uint16 actualCRC16 ;
# endif
channelCount = drflac__get_channel_count_from_channel_assignment ( pFlac - > currentFLACFrame . header . channelAssignment ) ;
for ( i = 0 ; i < channelCount ; + + i ) {
if ( ! drflac__seek_subframe ( & pFlac - > bs , & pFlac - > currentFLACFrame , i ) ) {
return DRFLAC_ERROR ;
}
}
/* Padding. */
if ( ! drflac__seek_bits ( & pFlac - > bs , DRFLAC_CACHE_L1_BITS_REMAINING ( & pFlac - > bs ) & 7 ) ) {
return DRFLAC_ERROR ;
}
/* CRC. */
# ifndef DR_FLAC_NO_CRC
actualCRC16 = drflac__flush_crc16 ( & pFlac - > bs ) ;
# endif
if ( ! drflac__read_uint16 ( & pFlac - > bs , 16 , & desiredCRC16 ) ) {
return DRFLAC_AT_END ;
}
# ifndef DR_FLAC_NO_CRC
if ( actualCRC16 ! = desiredCRC16 ) {
return DRFLAC_CRC_MISMATCH ; /* CRC mismatch. */
}
# endif
return DRFLAC_SUCCESS ;
}
static drflac_bool32 drflac__read_and_decode_next_flac_frame ( drflac * pFlac )
{
DRFLAC_ASSERT ( pFlac ! = NULL ) ;
for ( ; ; ) {
drflac_result result ;
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
return DRFLAC_FALSE ;
}
result = drflac__decode_flac_frame ( pFlac ) ;
if ( result ! = DRFLAC_SUCCESS ) {
if ( result = = DRFLAC_CRC_MISMATCH ) {
continue ; /* CRC mismatch. Skip to the next frame. */
} else {
return DRFLAC_FALSE ;
}
}
return DRFLAC_TRUE ;
}
}
static void drflac__get_pcm_frame_range_of_current_flac_frame ( drflac * pFlac , drflac_uint64 * pFirstPCMFrame , drflac_uint64 * pLastPCMFrame )
{
drflac_uint64 firstPCMFrame ;
drflac_uint64 lastPCMFrame ;
DRFLAC_ASSERT ( pFlac ! = NULL ) ;
firstPCMFrame = pFlac - > currentFLACFrame . header . pcmFrameNumber ;
if ( firstPCMFrame = = 0 ) {
firstPCMFrame = ( ( drflac_uint64 ) pFlac - > currentFLACFrame . header . flacFrameNumber ) * pFlac - > maxBlockSizeInPCMFrames ;
}
lastPCMFrame = firstPCMFrame + pFlac - > currentFLACFrame . header . blockSizeInPCMFrames ;
if ( lastPCMFrame > 0 ) {
lastPCMFrame - = 1 ; /* Needs to be zero based. */
}
if ( pFirstPCMFrame ) {
* pFirstPCMFrame = firstPCMFrame ;
}
if ( pLastPCMFrame ) {
* pLastPCMFrame = lastPCMFrame ;
}
}
static drflac_bool32 drflac__seek_to_first_frame ( drflac * pFlac )
{
drflac_bool32 result ;
DRFLAC_ASSERT ( pFlac ! = NULL ) ;
result = drflac__seek_to_byte ( & pFlac - > bs , pFlac - > firstFLACFramePosInBytes ) ;
DRFLAC_ZERO_MEMORY ( & pFlac - > currentFLACFrame , sizeof ( pFlac - > currentFLACFrame ) ) ;
pFlac - > currentPCMFrame = 0 ;
return result ;
}
static DRFLAC_INLINE drflac_result drflac__seek_to_next_flac_frame ( drflac * pFlac )
{
/* This function should only ever be called while the decoder is sitting on the first byte past the FRAME_HEADER section. */
DRFLAC_ASSERT ( pFlac ! = NULL ) ;
return drflac__seek_flac_frame ( pFlac ) ;
}
static drflac_uint64 drflac__seek_forward_by_pcm_frames ( drflac * pFlac , drflac_uint64 pcmFramesToSeek )
{
drflac_uint64 pcmFramesRead = 0 ;
while ( pcmFramesToSeek > 0 ) {
if ( pFlac - > currentFLACFrame . pcmFramesRemaining = = 0 ) {
if ( ! drflac__read_and_decode_next_flac_frame ( pFlac ) ) {
break ; /* Couldn't read the next frame, so just break from the loop and return. */
}
} else {
if ( pFlac - > currentFLACFrame . pcmFramesRemaining > pcmFramesToSeek ) {
pcmFramesRead + = pcmFramesToSeek ;
pFlac - > currentFLACFrame . pcmFramesRemaining - = ( drflac_uint32 ) pcmFramesToSeek ; /* <-- Safe cast. Will always be < currentFrame.pcmFramesRemaining < 65536. */
pcmFramesToSeek = 0 ;
} else {
pcmFramesRead + = pFlac - > currentFLACFrame . pcmFramesRemaining ;
pcmFramesToSeek - = pFlac - > currentFLACFrame . pcmFramesRemaining ;
pFlac - > currentFLACFrame . pcmFramesRemaining = 0 ;
}
}
}
pFlac - > currentPCMFrame + = pcmFramesRead ;
return pcmFramesRead ;
}
static drflac_bool32 drflac__seek_to_pcm_frame__brute_force ( drflac * pFlac , drflac_uint64 pcmFrameIndex )
{
drflac_bool32 isMidFrame = DRFLAC_FALSE ;
drflac_uint64 runningPCMFrameCount ;
DRFLAC_ASSERT ( pFlac ! = NULL ) ;
/* If we are seeking forward we start from the current position. Otherwise we need to start all the way from the start of the file. */
if ( pcmFrameIndex > = pFlac - > currentPCMFrame ) {
/* Seeking forward. Need to seek from the current position. */
runningPCMFrameCount = pFlac - > currentPCMFrame ;
/* The frame header for the first frame may not yet have been read. We need to do that if necessary. */
if ( pFlac - > currentPCMFrame = = 0 & & pFlac - > currentFLACFrame . pcmFramesRemaining = = 0 ) {
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
return DRFLAC_FALSE ;
}
} else {
isMidFrame = DRFLAC_TRUE ;
}
} else {
/* Seeking backwards. Need to seek from the start of the file. */
runningPCMFrameCount = 0 ;
/* Move back to the start. */
if ( ! drflac__seek_to_first_frame ( pFlac ) ) {
return DRFLAC_FALSE ;
}
/* Decode the first frame in preparation for sample-exact seeking below. */
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
return DRFLAC_FALSE ;
}
}
/*
We need to as quickly as possible find the frame that contains the target sample . To do this , we iterate over each frame and inspect its
header . If based on the header we can determine that the frame contains the sample , we do a full decode of that frame .
*/
for ( ; ; ) {
drflac_uint64 pcmFrameCountInThisFLACFrame ;
drflac_uint64 firstPCMFrameInFLACFrame = 0 ;
drflac_uint64 lastPCMFrameInFLACFrame = 0 ;
drflac__get_pcm_frame_range_of_current_flac_frame ( pFlac , & firstPCMFrameInFLACFrame , & lastPCMFrameInFLACFrame ) ;
pcmFrameCountInThisFLACFrame = ( lastPCMFrameInFLACFrame - firstPCMFrameInFLACFrame ) + 1 ;
if ( pcmFrameIndex < ( runningPCMFrameCount + pcmFrameCountInThisFLACFrame ) ) {
/*
The sample should be in this frame . We need to fully decode it , however if it ' s an invalid frame ( a CRC mismatch ) , we need to pretend
it never existed and keep iterating .
*/
drflac_uint64 pcmFramesToDecode = pcmFrameIndex - runningPCMFrameCount ;
if ( ! isMidFrame ) {
drflac_result result = drflac__decode_flac_frame ( pFlac ) ;
if ( result = = DRFLAC_SUCCESS ) {
/* The frame is valid. We just need to skip over some samples to ensure it's sample-exact. */
return drflac__seek_forward_by_pcm_frames ( pFlac , pcmFramesToDecode ) = = pcmFramesToDecode ; /* <-- If this fails, something bad has happened (it should never fail). */
} else {
if ( result = = DRFLAC_CRC_MISMATCH ) {
goto next_iteration ; /* CRC mismatch. Pretend this frame never existed. */
} else {
return DRFLAC_FALSE ;
}
}
} else {
/* We started seeking mid-frame which means we need to skip the frame decoding part. */
return drflac__seek_forward_by_pcm_frames ( pFlac , pcmFramesToDecode ) = = pcmFramesToDecode ;
}
} else {
/*
It ' s not in this frame . We need to seek past the frame , but check if there was a CRC mismatch . If so , we pretend this
frame never existed and leave the running sample count untouched .
*/
if ( ! isMidFrame ) {
drflac_result result = drflac__seek_to_next_flac_frame ( pFlac ) ;
if ( result = = DRFLAC_SUCCESS ) {
runningPCMFrameCount + = pcmFrameCountInThisFLACFrame ;
} else {
if ( result = = DRFLAC_CRC_MISMATCH ) {
goto next_iteration ; /* CRC mismatch. Pretend this frame never existed. */
} else {
return DRFLAC_FALSE ;
}
}
} else {
/*
We started seeking mid - frame which means we need to seek by reading to the end of the frame instead of with
drflac__seek_to_next_flac_frame ( ) which only works if the decoder is sitting on the byte just after the frame header .
*/
runningPCMFrameCount + = pFlac - > currentFLACFrame . pcmFramesRemaining ;
pFlac - > currentFLACFrame . pcmFramesRemaining = 0 ;
isMidFrame = DRFLAC_FALSE ;
}
/* If we are seeking to the end of the file and we've just hit it, we're done. */
if ( pcmFrameIndex = = pFlac - > totalPCMFrameCount & & runningPCMFrameCount = = pFlac - > totalPCMFrameCount ) {
return DRFLAC_TRUE ;
}
}
next_iteration :
/* Grab the next frame in preparation for the next iteration. */
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
return DRFLAC_FALSE ;
}
}
}
# if !defined(DR_FLAC_NO_CRC)
/*
We use an average compression ratio to determine our approximate start location . FLAC files are generally about 50 % - 70 % the size of their
uncompressed counterparts so we ' ll use this as a basis . I ' m going to split the middle and use a factor of 0.6 to determine the starting
location .
*/
# define DRFLAC_BINARY_SEARCH_APPROX_COMPRESSION_RATIO 0.6f
static drflac_bool32 drflac__seek_to_approximate_flac_frame_to_byte ( drflac * pFlac , drflac_uint64 targetByte , drflac_uint64 rangeLo , drflac_uint64 rangeHi , drflac_uint64 * pLastSuccessfulSeekOffset )
{
DRFLAC_ASSERT ( pFlac ! = NULL ) ;
DRFLAC_ASSERT ( pLastSuccessfulSeekOffset ! = NULL ) ;
DRFLAC_ASSERT ( targetByte > = rangeLo ) ;
DRFLAC_ASSERT ( targetByte < = rangeHi ) ;
* pLastSuccessfulSeekOffset = pFlac - > firstFLACFramePosInBytes ;
for ( ; ; ) {
/* After rangeLo == rangeHi == targetByte fails, we need to break out. */
drflac_uint64 lastTargetByte = targetByte ;
/* When seeking to a byte, failure probably means we've attempted to seek beyond the end of the stream. To counter this we just halve it each attempt. */
if ( ! drflac__seek_to_byte ( & pFlac - > bs , targetByte ) ) {
/* If we couldn't even seek to the first byte in the stream we have a problem. Just abandon the whole thing. */
if ( targetByte = = 0 ) {
drflac__seek_to_first_frame ( pFlac ) ; /* Try to recover. */
return DRFLAC_FALSE ;
}
/* Halve the byte location and continue. */
targetByte = rangeLo + ( ( rangeHi - rangeLo ) / 2 ) ;
rangeHi = targetByte ;
} else {
/* Getting here should mean that we have seeked to an appropriate byte. */
/* Clear the details of the FLAC frame so we don't misreport data. */
DRFLAC_ZERO_MEMORY ( & pFlac - > currentFLACFrame , sizeof ( pFlac - > currentFLACFrame ) ) ;
/*
Now seek to the next FLAC frame . We need to decode the entire frame ( not just the header ) because it ' s possible for the header to incorrectly pass the
CRC check and return bad data . We need to decode the entire frame to be more certain . Although this seems unlikely , this has happened to me in testing
so it needs to stay this way for now .
*/
# if 1
if ( ! drflac__read_and_decode_next_flac_frame ( pFlac ) ) {
/* Halve the byte location and continue. */
targetByte = rangeLo + ( ( rangeHi - rangeLo ) / 2 ) ;
rangeHi = targetByte ;
} else {
break ;
}
# else
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
/* Halve the byte location and continue. */
targetByte = rangeLo + ( ( rangeHi - rangeLo ) / 2 ) ;
rangeHi = targetByte ;
} else {
break ;
}
# endif
}
/* We already tried this byte and there are no more to try, break out. */
if ( targetByte = = lastTargetByte ) {
return DRFLAC_FALSE ;
}
}
/* The current PCM frame needs to be updated based on the frame we just seeked to. */
drflac__get_pcm_frame_range_of_current_flac_frame ( pFlac , & pFlac - > currentPCMFrame , NULL ) ;
DRFLAC_ASSERT ( targetByte < = rangeHi ) ;
* pLastSuccessfulSeekOffset = targetByte ;
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__decode_flac_frame_and_seek_forward_by_pcm_frames ( drflac * pFlac , drflac_uint64 offset )
{
/* This section of code would be used if we were only decoding the FLAC frame header when calling drflac__seek_to_approximate_flac_frame_to_byte(). */
#if 0
if ( drflac__decode_flac_frame ( pFlac ) ! = DRFLAC_SUCCESS ) {
/* We failed to decode this frame which may be due to it being corrupt. We'll just use the next valid FLAC frame. */
if ( drflac__read_and_decode_next_flac_frame ( pFlac ) = = DRFLAC_FALSE ) {
return DRFLAC_FALSE ;
}
}
# endif
return drflac__seek_forward_by_pcm_frames ( pFlac , offset ) = = offset ;
}
static drflac_bool32 drflac__seek_to_pcm_frame__binary_search_internal ( drflac * pFlac , drflac_uint64 pcmFrameIndex , drflac_uint64 byteRangeLo , drflac_uint64 byteRangeHi )
{
/* This assumes pFlac->currentPCMFrame is sitting on byteRangeLo upon entry. */
drflac_uint64 targetByte ;
drflac_uint64 pcmRangeLo = pFlac - > totalPCMFrameCount ;
drflac_uint64 pcmRangeHi = 0 ;
drflac_uint64 lastSuccessfulSeekOffset = ( drflac_uint64 ) - 1 ;
drflac_uint64 closestSeekOffsetBeforeTargetPCMFrame = byteRangeLo ;
drflac_uint32 seekForwardThreshold = ( pFlac - > maxBlockSizeInPCMFrames ! = 0 ) ? pFlac - > maxBlockSizeInPCMFrames * 2 : 4096 ;
targetByte = byteRangeLo + ( drflac_uint64 ) ( ( ( drflac_int64 ) ( ( pcmFrameIndex - pFlac - > currentPCMFrame ) * pFlac - > channels * pFlac - > bitsPerSample ) / 8.0f ) * DRFLAC_BINARY_SEARCH_APPROX_COMPRESSION_RATIO ) ;
if ( targetByte > byteRangeHi ) {
targetByte = byteRangeHi ;
}
for ( ; ; ) {
if ( drflac__seek_to_approximate_flac_frame_to_byte ( pFlac , targetByte , byteRangeLo , byteRangeHi , & lastSuccessfulSeekOffset ) ) {
/* We found a FLAC frame. We need to check if it contains the sample we're looking for. */
drflac_uint64 newPCMRangeLo ;
drflac_uint64 newPCMRangeHi ;
drflac__get_pcm_frame_range_of_current_flac_frame ( pFlac , & newPCMRangeLo , & newPCMRangeHi ) ;
/* If we selected the same frame, it means we should be pretty close. Just decode the rest. */
if ( pcmRangeLo = = newPCMRangeLo ) {
if ( ! drflac__seek_to_approximate_flac_frame_to_byte ( pFlac , closestSeekOffsetBeforeTargetPCMFrame , closestSeekOffsetBeforeTargetPCMFrame , byteRangeHi , & lastSuccessfulSeekOffset ) ) {
break ; /* Failed to seek to closest frame. */
}
if ( drflac__decode_flac_frame_and_seek_forward_by_pcm_frames ( pFlac , pcmFrameIndex - pFlac - > currentPCMFrame ) ) {
return DRFLAC_TRUE ;
} else {
break ; /* Failed to seek forward. */
}
}
pcmRangeLo = newPCMRangeLo ;
pcmRangeHi = newPCMRangeHi ;
if ( pcmRangeLo < = pcmFrameIndex & & pcmRangeHi > = pcmFrameIndex ) {
/* The target PCM frame is in this FLAC frame. */
if ( drflac__decode_flac_frame_and_seek_forward_by_pcm_frames ( pFlac , pcmFrameIndex - pFlac - > currentPCMFrame ) ) {
return DRFLAC_TRUE ;
} else {
break ; /* Failed to seek to FLAC frame. */
}
} else {
const float approxCompressionRatio = ( drflac_int64 ) ( lastSuccessfulSeekOffset - pFlac - > firstFLACFramePosInBytes ) / ( ( drflac_int64 ) ( pcmRangeLo * pFlac - > channels * pFlac - > bitsPerSample ) / 8.0f ) ;
if ( pcmRangeLo > pcmFrameIndex ) {
/* We seeked too far forward. We need to move our target byte backward and try again. */
byteRangeHi = lastSuccessfulSeekOffset ;
if ( byteRangeLo > byteRangeHi ) {
byteRangeLo = byteRangeHi ;
}
targetByte = byteRangeLo + ( ( byteRangeHi - byteRangeLo ) / 2 ) ;
if ( targetByte < byteRangeLo ) {
targetByte = byteRangeLo ;
}
} else /*if (pcmRangeHi < pcmFrameIndex)*/ {
/* We didn't seek far enough. We need to move our target byte forward and try again. */
/* If we're close enough we can just seek forward. */
if ( ( pcmFrameIndex - pcmRangeLo ) < seekForwardThreshold ) {
if ( drflac__decode_flac_frame_and_seek_forward_by_pcm_frames ( pFlac , pcmFrameIndex - pFlac - > currentPCMFrame ) ) {
return DRFLAC_TRUE ;
} else {
break ; /* Failed to seek to FLAC frame. */
}
} else {
byteRangeLo = lastSuccessfulSeekOffset ;
if ( byteRangeHi < byteRangeLo ) {
byteRangeHi = byteRangeLo ;
}
targetByte = lastSuccessfulSeekOffset + ( drflac_uint64 ) ( ( ( drflac_int64 ) ( ( pcmFrameIndex - pcmRangeLo ) * pFlac - > channels * pFlac - > bitsPerSample ) / 8.0f ) * approxCompressionRatio ) ;
if ( targetByte > byteRangeHi ) {
targetByte = byteRangeHi ;
}
if ( closestSeekOffsetBeforeTargetPCMFrame < lastSuccessfulSeekOffset ) {
closestSeekOffsetBeforeTargetPCMFrame = lastSuccessfulSeekOffset ;
}
}
}
}
} else {
/* Getting here is really bad. We just recover as best we can, but moving to the first frame in the stream, and then abort. */
break ;
}
}
drflac__seek_to_first_frame ( pFlac ) ; /* <-- Try to recover. */
return DRFLAC_FALSE ;
}
static drflac_bool32 drflac__seek_to_pcm_frame__binary_search ( drflac * pFlac , drflac_uint64 pcmFrameIndex )
{
drflac_uint64 byteRangeLo ;
drflac_uint64 byteRangeHi ;
drflac_uint32 seekForwardThreshold = ( pFlac - > maxBlockSizeInPCMFrames ! = 0 ) ? pFlac - > maxBlockSizeInPCMFrames * 2 : 4096 ;
/* Our algorithm currently assumes the FLAC stream is currently sitting at the start. */
if ( drflac__seek_to_first_frame ( pFlac ) = = DRFLAC_FALSE ) {
return DRFLAC_FALSE ;
}
/* If we're close enough to the start, just move to the start and seek forward. */
if ( pcmFrameIndex < seekForwardThreshold ) {
return drflac__seek_forward_by_pcm_frames ( pFlac , pcmFrameIndex ) = = pcmFrameIndex ;
}
/*
Our starting byte range is the byte position of the first FLAC frame and the approximate end of the file as if it were completely uncompressed . This ensures
the entire file is included , even though most of the time it ' ll exceed the end of the actual stream . This is OK as the frame searching logic will handle it .
*/
byteRangeLo = pFlac - > firstFLACFramePosInBytes ;
byteRangeHi = pFlac - > firstFLACFramePosInBytes + ( drflac_uint64 ) ( ( drflac_int64 ) ( pFlac - > totalPCMFrameCount * pFlac - > channels * pFlac - > bitsPerSample ) / 8.0f ) ;
return drflac__seek_to_pcm_frame__binary_search_internal ( pFlac , pcmFrameIndex , byteRangeLo , byteRangeHi ) ;
}
# endif /* !DR_FLAC_NO_CRC */
static drflac_bool32 drflac__seek_to_pcm_frame__seek_table ( drflac * pFlac , drflac_uint64 pcmFrameIndex )
{
drflac_uint32 iClosestSeekpoint = 0 ;
drflac_bool32 isMidFrame = DRFLAC_FALSE ;
drflac_uint64 runningPCMFrameCount ;
drflac_uint32 iSeekpoint ;
DRFLAC_ASSERT ( pFlac ! = NULL ) ;
if ( pFlac - > pSeekpoints = = NULL | | pFlac - > seekpointCount = = 0 ) {
return DRFLAC_FALSE ;
}
/* Do not use the seektable if pcmFramIndex is not coverd by it. */
if ( pFlac - > pSeekpoints [ 0 ] . firstPCMFrame > pcmFrameIndex ) {
return DRFLAC_FALSE ;
}
for ( iSeekpoint = 0 ; iSeekpoint < pFlac - > seekpointCount ; + + iSeekpoint ) {
if ( pFlac - > pSeekpoints [ iSeekpoint ] . firstPCMFrame > = pcmFrameIndex ) {
break ;
}
iClosestSeekpoint = iSeekpoint ;
}
/* There's been cases where the seek table contains only zeros. We need to do some basic validation on the closest seekpoint. */
if ( pFlac - > pSeekpoints [ iClosestSeekpoint ] . pcmFrameCount = = 0 | | pFlac - > pSeekpoints [ iClosestSeekpoint ] . pcmFrameCount > pFlac - > maxBlockSizeInPCMFrames ) {
return DRFLAC_FALSE ;
}
if ( pFlac - > pSeekpoints [ iClosestSeekpoint ] . firstPCMFrame > pFlac - > totalPCMFrameCount & & pFlac - > totalPCMFrameCount > 0 ) {
return DRFLAC_FALSE ;
}
# if !defined(DR_FLAC_NO_CRC)
/* At this point we should know the closest seek point. We can use a binary search for this. We need to know the total sample count for this. */
if ( pFlac - > totalPCMFrameCount > 0 ) {
drflac_uint64 byteRangeLo ;
drflac_uint64 byteRangeHi ;
byteRangeHi = pFlac - > firstFLACFramePosInBytes + ( drflac_uint64 ) ( ( drflac_int64 ) ( pFlac - > totalPCMFrameCount * pFlac - > channels * pFlac - > bitsPerSample ) / 8.0f ) ;
byteRangeLo = pFlac - > firstFLACFramePosInBytes + pFlac - > pSeekpoints [ iClosestSeekpoint ] . flacFrameOffset ;
/*
If our closest seek point is not the last one , we only need to search between it and the next one . The section below calculates an appropriate starting
value for byteRangeHi which will clamp it appropriately .
Note that the next seekpoint must have an offset greater than the closest seekpoint because otherwise our binary search algorithm will break down . There
have been cases where a seektable consists of seek points where every byte offset is set to 0 which causes problems . If this happens we need to abort .
*/
if ( iClosestSeekpoint < pFlac - > seekpointCount - 1 ) {
drflac_uint32 iNextSeekpoint = iClosestSeekpoint + 1 ;
/* Basic validation on the seekpoints to ensure they're usable. */
if ( pFlac - > pSeekpoints [ iClosestSeekpoint ] . flacFrameOffset > = pFlac - > pSeekpoints [ iNextSeekpoint ] . flacFrameOffset | | pFlac - > pSeekpoints [ iNextSeekpoint ] . pcmFrameCount = = 0 ) {
return DRFLAC_FALSE ; /* The next seekpoint doesn't look right. The seek table cannot be trusted from here. Abort. */
}
if ( pFlac - > pSeekpoints [ iNextSeekpoint ] . firstPCMFrame ! = ( ( ( drflac_uint64 ) 0xFFFFFFFF < < 32 ) | 0xFFFFFFFF ) ) { /* Make sure it's not a placeholder seekpoint. */
byteRangeHi = pFlac - > firstFLACFramePosInBytes + pFlac - > pSeekpoints [ iNextSeekpoint ] . flacFrameOffset - 1 ; /* byteRangeHi must be zero based. */
}
}
if ( drflac__seek_to_byte ( & pFlac - > bs , pFlac - > firstFLACFramePosInBytes + pFlac - > pSeekpoints [ iClosestSeekpoint ] . flacFrameOffset ) ) {
if ( drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
drflac__get_pcm_frame_range_of_current_flac_frame ( pFlac , & pFlac - > currentPCMFrame , NULL ) ;
if ( drflac__seek_to_pcm_frame__binary_search_internal ( pFlac , pcmFrameIndex , byteRangeLo , byteRangeHi ) ) {
return DRFLAC_TRUE ;
}
}
}
}
# endif /* !DR_FLAC_NO_CRC */
/* Getting here means we need to use a slower algorithm because the binary search method failed or cannot be used. */
/*
If we are seeking forward and the closest seekpoint is _before_ the current sample , we just seek forward from where we are . Otherwise we start seeking
from the seekpoint ' s first sample .
*/
if ( pcmFrameIndex > = pFlac - > currentPCMFrame & & pFlac - > pSeekpoints [ iClosestSeekpoint ] . firstPCMFrame < = pFlac - > currentPCMFrame ) {
/* Optimized case. Just seek forward from where we are. */
runningPCMFrameCount = pFlac - > currentPCMFrame ;
/* The frame header for the first frame may not yet have been read. We need to do that if necessary. */
if ( pFlac - > currentPCMFrame = = 0 & & pFlac - > currentFLACFrame . pcmFramesRemaining = = 0 ) {
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
return DRFLAC_FALSE ;
}
} else {
isMidFrame = DRFLAC_TRUE ;
}
} else {
/* Slower case. Seek to the start of the seekpoint and then seek forward from there. */
runningPCMFrameCount = pFlac - > pSeekpoints [ iClosestSeekpoint ] . firstPCMFrame ;
if ( ! drflac__seek_to_byte ( & pFlac - > bs , pFlac - > firstFLACFramePosInBytes + pFlac - > pSeekpoints [ iClosestSeekpoint ] . flacFrameOffset ) ) {
return DRFLAC_FALSE ;
}
/* Grab the frame the seekpoint is sitting on in preparation for the sample-exact seeking below. */
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
return DRFLAC_FALSE ;
}
}
for ( ; ; ) {
drflac_uint64 pcmFrameCountInThisFLACFrame ;
drflac_uint64 firstPCMFrameInFLACFrame = 0 ;
drflac_uint64 lastPCMFrameInFLACFrame = 0 ;
drflac__get_pcm_frame_range_of_current_flac_frame ( pFlac , & firstPCMFrameInFLACFrame , & lastPCMFrameInFLACFrame ) ;
pcmFrameCountInThisFLACFrame = ( lastPCMFrameInFLACFrame - firstPCMFrameInFLACFrame ) + 1 ;
if ( pcmFrameIndex < ( runningPCMFrameCount + pcmFrameCountInThisFLACFrame ) ) {
/*
The sample should be in this frame . We need to fully decode it , but if it ' s an invalid frame ( a CRC mismatch ) we need to pretend
it never existed and keep iterating .
*/
drflac_uint64 pcmFramesToDecode = pcmFrameIndex - runningPCMFrameCount ;
if ( ! isMidFrame ) {
drflac_result result = drflac__decode_flac_frame ( pFlac ) ;
if ( result = = DRFLAC_SUCCESS ) {
/* The frame is valid. We just need to skip over some samples to ensure it's sample-exact. */
return drflac__seek_forward_by_pcm_frames ( pFlac , pcmFramesToDecode ) = = pcmFramesToDecode ; /* <-- If this fails, something bad has happened (it should never fail). */
} else {
if ( result = = DRFLAC_CRC_MISMATCH ) {
goto next_iteration ; /* CRC mismatch. Pretend this frame never existed. */
} else {
return DRFLAC_FALSE ;
}
}
} else {
/* We started seeking mid-frame which means we need to skip the frame decoding part. */
return drflac__seek_forward_by_pcm_frames ( pFlac , pcmFramesToDecode ) = = pcmFramesToDecode ;
}
} else {
/*
It ' s not in this frame . We need to seek past the frame , but check if there was a CRC mismatch . If so , we pretend this
frame never existed and leave the running sample count untouched .
*/
if ( ! isMidFrame ) {
drflac_result result = drflac__seek_to_next_flac_frame ( pFlac ) ;
if ( result = = DRFLAC_SUCCESS ) {
runningPCMFrameCount + = pcmFrameCountInThisFLACFrame ;
} else {
if ( result = = DRFLAC_CRC_MISMATCH ) {
goto next_iteration ; /* CRC mismatch. Pretend this frame never existed. */
} else {
return DRFLAC_FALSE ;
}
}
} else {
/*
We started seeking mid - frame which means we need to seek by reading to the end of the frame instead of with
drflac__seek_to_next_flac_frame ( ) which only works if the decoder is sitting on the byte just after the frame header .
*/
runningPCMFrameCount + = pFlac - > currentFLACFrame . pcmFramesRemaining ;
pFlac - > currentFLACFrame . pcmFramesRemaining = 0 ;
isMidFrame = DRFLAC_FALSE ;
}
/* If we are seeking to the end of the file and we've just hit it, we're done. */
if ( pcmFrameIndex = = pFlac - > totalPCMFrameCount & & runningPCMFrameCount = = pFlac - > totalPCMFrameCount ) {
return DRFLAC_TRUE ;
}
}
next_iteration :
/* Grab the next frame in preparation for the next iteration. */
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
return DRFLAC_FALSE ;
}
}
}
# ifndef DR_FLAC_NO_OGG
typedef struct
{
drflac_uint8 capturePattern [ 4 ] ; /* Should be "OggS" */
drflac_uint8 structureVersion ; /* Always 0. */
drflac_uint8 headerType ;
drflac_uint64 granulePosition ;
drflac_uint32 serialNumber ;
drflac_uint32 sequenceNumber ;
drflac_uint32 checksum ;
drflac_uint8 segmentCount ;
drflac_uint8 segmentTable [ 255 ] ;
} drflac_ogg_page_header ;
# endif
typedef struct
{
drflac_read_proc onRead ;
drflac_seek_proc onSeek ;
drflac_meta_proc onMeta ;
drflac_container container ;
void * pUserData ;
void * pUserDataMD ;
drflac_uint32 sampleRate ;
drflac_uint8 channels ;
drflac_uint8 bitsPerSample ;
drflac_uint64 totalPCMFrameCount ;
drflac_uint16 maxBlockSizeInPCMFrames ;
drflac_uint64 runningFilePos ;
drflac_bool32 hasStreamInfoBlock ;
drflac_bool32 hasMetadataBlocks ;
drflac_bs bs ; /* <-- A bit streamer is required for loading data during initialization. */
drflac_frame_header firstFrameHeader ; /* <-- The header of the first frame that was read during relaxed initalization. Only set if there is no STREAMINFO block. */
# ifndef DR_FLAC_NO_OGG
drflac_uint32 oggSerial ;
drflac_uint64 oggFirstBytePos ;
drflac_ogg_page_header oggBosHeader ;
# endif
} drflac_init_info ;
static DRFLAC_INLINE void drflac__decode_block_header ( drflac_uint32 blockHeader , drflac_uint8 * isLastBlock , drflac_uint8 * blockType , drflac_uint32 * blockSize )
{
blockHeader = drflac__be2host_32 ( blockHeader ) ;
* isLastBlock = ( drflac_uint8 ) ( ( blockHeader & 0x80000000UL ) > > 31 ) ;
* blockType = ( drflac_uint8 ) ( ( blockHeader & 0x7F000000UL ) > > 24 ) ;
* blockSize = ( blockHeader & 0x00FFFFFFUL ) ;
}
static DRFLAC_INLINE drflac_bool32 drflac__read_and_decode_block_header ( drflac_read_proc onRead , void * pUserData , drflac_uint8 * isLastBlock , drflac_uint8 * blockType , drflac_uint32 * blockSize )
{
drflac_uint32 blockHeader ;
* blockSize = 0 ;
if ( onRead ( pUserData , & blockHeader , 4 ) ! = 4 ) {
return DRFLAC_FALSE ;
}
drflac__decode_block_header ( blockHeader , isLastBlock , blockType , blockSize ) ;
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__read_streaminfo ( drflac_read_proc onRead , void * pUserData , drflac_streaminfo * pStreamInfo )
{
drflac_uint32 blockSizes ;
drflac_uint64 frameSizes = 0 ;
drflac_uint64 importantProps ;
drflac_uint8 md5 [ 16 ] ;
/* min/max block size. */
if ( onRead ( pUserData , & blockSizes , 4 ) ! = 4 ) {
return DRFLAC_FALSE ;
}
/* min/max frame size. */
if ( onRead ( pUserData , & frameSizes , 6 ) ! = 6 ) {
return DRFLAC_FALSE ;
}
/* Sample rate, channels, bits per sample and total sample count. */
if ( onRead ( pUserData , & importantProps , 8 ) ! = 8 ) {
return DRFLAC_FALSE ;
}
/* MD5 */
if ( onRead ( pUserData , md5 , sizeof ( md5 ) ) ! = sizeof ( md5 ) ) {
return DRFLAC_FALSE ;
}
blockSizes = drflac__be2host_32 ( blockSizes ) ;
frameSizes = drflac__be2host_64 ( frameSizes ) ;
importantProps = drflac__be2host_64 ( importantProps ) ;
pStreamInfo - > minBlockSizeInPCMFrames = ( drflac_uint16 ) ( ( blockSizes & 0xFFFF0000 ) > > 16 ) ;
pStreamInfo - > maxBlockSizeInPCMFrames = ( drflac_uint16 ) ( blockSizes & 0x0000FFFF ) ;
pStreamInfo - > minFrameSizeInPCMFrames = ( drflac_uint32 ) ( ( frameSizes & ( ( ( drflac_uint64 ) 0x00FFFFFF < < 16 ) < < 24 ) ) > > 40 ) ;
pStreamInfo - > maxFrameSizeInPCMFrames = ( drflac_uint32 ) ( ( frameSizes & ( ( ( drflac_uint64 ) 0x00FFFFFF < < 16 ) < < 0 ) ) > > 16 ) ;
pStreamInfo - > sampleRate = ( drflac_uint32 ) ( ( importantProps & ( ( ( drflac_uint64 ) 0x000FFFFF < < 16 ) < < 28 ) ) > > 44 ) ;
pStreamInfo - > channels = ( drflac_uint8 ) ( ( importantProps & ( ( ( drflac_uint64 ) 0x0000000E < < 16 ) < < 24 ) ) > > 41 ) + 1 ;
pStreamInfo - > bitsPerSample = ( drflac_uint8 ) ( ( importantProps & ( ( ( drflac_uint64 ) 0x0000001F < < 16 ) < < 20 ) ) > > 36 ) + 1 ;
pStreamInfo - > totalPCMFrameCount = ( ( importantProps & ( ( ( ( drflac_uint64 ) 0x0000000F < < 16 ) < < 16 ) | 0xFFFFFFFF ) ) ) ;
DRFLAC_COPY_MEMORY ( pStreamInfo - > md5 , md5 , sizeof ( md5 ) ) ;
return DRFLAC_TRUE ;
}
static void * drflac__malloc_default ( size_t sz , void * pUserData )
{
( void ) pUserData ;
return DRFLAC_MALLOC ( sz ) ;
}
static void * drflac__realloc_default ( void * p , size_t sz , void * pUserData )
{
( void ) pUserData ;
return DRFLAC_REALLOC ( p , sz ) ;
}
static void drflac__free_default ( void * p , void * pUserData )
{
( void ) pUserData ;
DRFLAC_FREE ( p ) ;
}
static void * drflac__malloc_from_callbacks ( size_t sz , const drflac_allocation_callbacks * pAllocationCallbacks )
{
if ( pAllocationCallbacks = = NULL ) {
return NULL ;
}
if ( pAllocationCallbacks - > onMalloc ! = NULL ) {
return pAllocationCallbacks - > onMalloc ( sz , pAllocationCallbacks - > pUserData ) ;
}
/* Try using realloc(). */
if ( pAllocationCallbacks - > onRealloc ! = NULL ) {
return pAllocationCallbacks - > onRealloc ( NULL , sz , pAllocationCallbacks - > pUserData ) ;
}
return NULL ;
}
static void * drflac__realloc_from_callbacks ( void * p , size_t szNew , size_t szOld , const drflac_allocation_callbacks * pAllocationCallbacks )
{
if ( pAllocationCallbacks = = NULL ) {
return NULL ;
}
if ( pAllocationCallbacks - > onRealloc ! = NULL ) {
return pAllocationCallbacks - > onRealloc ( p , szNew , pAllocationCallbacks - > pUserData ) ;
}
/* Try emulating realloc() in terms of malloc()/free(). */
if ( pAllocationCallbacks - > onMalloc ! = NULL & & pAllocationCallbacks - > onFree ! = NULL ) {
void * p2 ;
p2 = pAllocationCallbacks - > onMalloc ( szNew , pAllocationCallbacks - > pUserData ) ;
if ( p2 = = NULL ) {
return NULL ;
}
if ( p ! = NULL ) {
DRFLAC_COPY_MEMORY ( p2 , p , szOld ) ;
pAllocationCallbacks - > onFree ( p , pAllocationCallbacks - > pUserData ) ;
}
return p2 ;
}
return NULL ;
}
static void drflac__free_from_callbacks ( void * p , const drflac_allocation_callbacks * pAllocationCallbacks )
{
if ( p = = NULL | | pAllocationCallbacks = = NULL ) {
return ;
}
if ( pAllocationCallbacks - > onFree ! = NULL ) {
pAllocationCallbacks - > onFree ( p , pAllocationCallbacks - > pUserData ) ;
}
}
static drflac_bool32 drflac__read_and_decode_metadata ( drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , void * pUserData , void * pUserDataMD , drflac_uint64 * pFirstFramePos , drflac_uint64 * pSeektablePos , drflac_uint32 * pSeektableSize , drflac_allocation_callbacks * pAllocationCallbacks )
{
/*
We want to keep track of the byte position in the stream of the seektable . At the time of calling this function we know that
we ' ll be sitting on byte 42.
*/
drflac_uint64 runningFilePos = 42 ;
drflac_uint64 seektablePos = 0 ;
drflac_uint32 seektableSize = 0 ;
for ( ; ; ) {
drflac_metadata metadata ;
drflac_uint8 isLastBlock = 0 ;
drflac_uint8 blockType ;
drflac_uint32 blockSize ;
if ( drflac__read_and_decode_block_header ( onRead , pUserData , & isLastBlock , & blockType , & blockSize ) = = DRFLAC_FALSE ) {
return DRFLAC_FALSE ;
}
runningFilePos + = 4 ;
metadata . type = blockType ;
metadata . pRawData = NULL ;
metadata . rawDataSize = 0 ;
switch ( blockType )
{
case DRFLAC_METADATA_BLOCK_TYPE_APPLICATION :
{
if ( blockSize < 4 ) {
return DRFLAC_FALSE ;
}
if ( onMeta ) {
void * pRawData = drflac__malloc_from_callbacks ( blockSize , pAllocationCallbacks ) ;
if ( pRawData = = NULL ) {
return DRFLAC_FALSE ;
}
if ( onRead ( pUserData , pRawData , blockSize ) ! = blockSize ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . pRawData = pRawData ;
metadata . rawDataSize = blockSize ;
metadata . data . application . id = drflac__be2host_32 ( * ( drflac_uint32 * ) pRawData ) ;
metadata . data . application . pData = ( const void * ) ( ( drflac_uint8 * ) pRawData + sizeof ( drflac_uint32 ) ) ;
metadata . data . application . dataSize = blockSize - sizeof ( drflac_uint32 ) ;
onMeta ( pUserDataMD , & metadata ) ;
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
}
} break ;
case DRFLAC_METADATA_BLOCK_TYPE_SEEKTABLE :
{
seektablePos = runningFilePos ;
seektableSize = blockSize ;
if ( onMeta ) {
drflac_uint32 iSeekpoint ;
void * pRawData ;
pRawData = drflac__malloc_from_callbacks ( blockSize , pAllocationCallbacks ) ;
if ( pRawData = = NULL ) {
return DRFLAC_FALSE ;
}
if ( onRead ( pUserData , pRawData , blockSize ) ! = blockSize ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . pRawData = pRawData ;
metadata . rawDataSize = blockSize ;
metadata . data . seektable . seekpointCount = blockSize / sizeof ( drflac_seekpoint ) ;
metadata . data . seektable . pSeekpoints = ( const drflac_seekpoint * ) pRawData ;
/* Endian swap. */
for ( iSeekpoint = 0 ; iSeekpoint < metadata . data . seektable . seekpointCount ; + + iSeekpoint ) {
drflac_seekpoint * pSeekpoint = ( drflac_seekpoint * ) pRawData + iSeekpoint ;
pSeekpoint - > firstPCMFrame = drflac__be2host_64 ( pSeekpoint - > firstPCMFrame ) ;
pSeekpoint - > flacFrameOffset = drflac__be2host_64 ( pSeekpoint - > flacFrameOffset ) ;
pSeekpoint - > pcmFrameCount = drflac__be2host_16 ( pSeekpoint - > pcmFrameCount ) ;
}
onMeta ( pUserDataMD , & metadata ) ;
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
}
} break ;
case DRFLAC_METADATA_BLOCK_TYPE_VORBIS_COMMENT :
{
if ( blockSize < 8 ) {
return DRFLAC_FALSE ;
}
if ( onMeta ) {
void * pRawData ;
const char * pRunningData ;
const char * pRunningDataEnd ;
drflac_uint32 i ;
pRawData = drflac__malloc_from_callbacks ( blockSize , pAllocationCallbacks ) ;
if ( pRawData = = NULL ) {
return DRFLAC_FALSE ;
}
if ( onRead ( pUserData , pRawData , blockSize ) ! = blockSize ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . pRawData = pRawData ;
metadata . rawDataSize = blockSize ;
pRunningData = ( const char * ) pRawData ;
pRunningDataEnd = ( const char * ) pRawData + blockSize ;
metadata . data . vorbis_comment . vendorLength = drflac__le2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
/* Need space for the rest of the block */
if ( ( pRunningDataEnd - pRunningData ) - 4 < ( drflac_int64 ) metadata . data . vorbis_comment . vendorLength ) { /* <-- Note the order of operations to avoid overflow to a valid value */
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . data . vorbis_comment . vendor = pRunningData ; pRunningData + = metadata . data . vorbis_comment . vendorLength ;
metadata . data . vorbis_comment . commentCount = drflac__le2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
/* Need space for 'commentCount' comments after the block, which at minimum is a drflac_uint32 per comment */
if ( ( pRunningDataEnd - pRunningData ) / sizeof ( drflac_uint32 ) < metadata . data . vorbis_comment . commentCount ) { /* <-- Note the order of operations to avoid overflow to a valid value */
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . data . vorbis_comment . pComments = pRunningData ;
/* Check that the comments section is valid before passing it to the callback */
for ( i = 0 ; i < metadata . data . vorbis_comment . commentCount ; + + i ) {
drflac_uint32 commentLength ;
if ( pRunningDataEnd - pRunningData < 4 ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
commentLength = drflac__le2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
if ( pRunningDataEnd - pRunningData < ( drflac_int64 ) commentLength ) { /* <-- Note the order of operations to avoid overflow to a valid value */
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
pRunningData + = commentLength ;
}
onMeta ( pUserDataMD , & metadata ) ;
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
}
} break ;
case DRFLAC_METADATA_BLOCK_TYPE_CUESHEET :
{
if ( blockSize < 396 ) {
return DRFLAC_FALSE ;
}
if ( onMeta ) {
void * pRawData ;
const char * pRunningData ;
const char * pRunningDataEnd ;
drflac_uint8 iTrack ;
drflac_uint8 iIndex ;
pRawData = drflac__malloc_from_callbacks ( blockSize , pAllocationCallbacks ) ;
if ( pRawData = = NULL ) {
return DRFLAC_FALSE ;
}
if ( onRead ( pUserData , pRawData , blockSize ) ! = blockSize ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . pRawData = pRawData ;
metadata . rawDataSize = blockSize ;
pRunningData = ( const char * ) pRawData ;
pRunningDataEnd = ( const char * ) pRawData + blockSize ;
DRFLAC_COPY_MEMORY ( metadata . data . cuesheet . catalog , pRunningData , 128 ) ; pRunningData + = 128 ;
metadata . data . cuesheet . leadInSampleCount = drflac__be2host_64 ( * ( const drflac_uint64 * ) pRunningData ) ; pRunningData + = 8 ;
metadata . data . cuesheet . isCD = ( pRunningData [ 0 ] & 0x80 ) ! = 0 ; pRunningData + = 259 ;
metadata . data . cuesheet . trackCount = pRunningData [ 0 ] ; pRunningData + = 1 ;
metadata . data . cuesheet . pTrackData = pRunningData ;
/* Check that the cuesheet tracks are valid before passing it to the callback */
for ( iTrack = 0 ; iTrack < metadata . data . cuesheet . trackCount ; + + iTrack ) {
drflac_uint8 indexCount ;
drflac_uint32 indexPointSize ;
if ( pRunningDataEnd - pRunningData < 36 ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
/* Skip to the index point count */
pRunningData + = 35 ;
indexCount = pRunningData [ 0 ] ; pRunningData + = 1 ;
indexPointSize = indexCount * sizeof ( drflac_cuesheet_track_index ) ;
if ( pRunningDataEnd - pRunningData < ( drflac_int64 ) indexPointSize ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
/* Endian swap. */
for ( iIndex = 0 ; iIndex < indexCount ; + + iIndex ) {
drflac_cuesheet_track_index * pTrack = ( drflac_cuesheet_track_index * ) pRunningData ;
pRunningData + = sizeof ( drflac_cuesheet_track_index ) ;
pTrack - > offset = drflac__be2host_64 ( pTrack - > offset ) ;
}
}
onMeta ( pUserDataMD , & metadata ) ;
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
}
} break ;
case DRFLAC_METADATA_BLOCK_TYPE_PICTURE :
{
if ( blockSize < 32 ) {
return DRFLAC_FALSE ;
}
if ( onMeta ) {
void * pRawData ;
const char * pRunningData ;
const char * pRunningDataEnd ;
pRawData = drflac__malloc_from_callbacks ( blockSize , pAllocationCallbacks ) ;
if ( pRawData = = NULL ) {
return DRFLAC_FALSE ;
}
if ( onRead ( pUserData , pRawData , blockSize ) ! = blockSize ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . pRawData = pRawData ;
metadata . rawDataSize = blockSize ;
pRunningData = ( const char * ) pRawData ;
pRunningDataEnd = ( const char * ) pRawData + blockSize ;
metadata . data . picture . type = drflac__be2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
metadata . data . picture . mimeLength = drflac__be2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
/* Need space for the rest of the block */
if ( ( pRunningDataEnd - pRunningData ) - 24 < ( drflac_int64 ) metadata . data . picture . mimeLength ) { /* <-- Note the order of operations to avoid overflow to a valid value */
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . data . picture . mime = pRunningData ; pRunningData + = metadata . data . picture . mimeLength ;
metadata . data . picture . descriptionLength = drflac__be2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
/* Need space for the rest of the block */
if ( ( pRunningDataEnd - pRunningData ) - 20 < ( drflac_int64 ) metadata . data . picture . descriptionLength ) { /* <-- Note the order of operations to avoid overflow to a valid value */
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . data . picture . description = pRunningData ; pRunningData + = metadata . data . picture . descriptionLength ;
metadata . data . picture . width = drflac__be2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
metadata . data . picture . height = drflac__be2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
metadata . data . picture . colorDepth = drflac__be2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
metadata . data . picture . indexColorCount = drflac__be2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
metadata . data . picture . pictureDataSize = drflac__be2host_32_ptr_unaligned ( pRunningData ) ; pRunningData + = 4 ;
metadata . data . picture . pPictureData = ( const drflac_uint8 * ) pRunningData ;
/* Need space for the picture after the block */
if ( pRunningDataEnd - pRunningData < ( drflac_int64 ) metadata . data . picture . pictureDataSize ) { /* <-- Note the order of operations to avoid overflow to a valid value */
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
onMeta ( pUserDataMD , & metadata ) ;
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
}
} break ;
case DRFLAC_METADATA_BLOCK_TYPE_PADDING :
{
if ( onMeta ) {
metadata . data . padding . unused = 0 ;
/* Padding doesn't have anything meaningful in it, so just skip over it, but make sure the caller is aware of it by firing the callback. */
if ( ! onSeek ( pUserData , blockSize , drflac_seek_origin_current ) ) {
isLastBlock = DRFLAC_TRUE ; /* An error occurred while seeking. Attempt to recover by treating this as the last block which will in turn terminate the loop. */
} else {
onMeta ( pUserDataMD , & metadata ) ;
}
}
} break ;
case DRFLAC_METADATA_BLOCK_TYPE_INVALID :
{
/* Invalid chunk. Just skip over this one. */
if ( onMeta ) {
if ( ! onSeek ( pUserData , blockSize , drflac_seek_origin_current ) ) {
isLastBlock = DRFLAC_TRUE ; /* An error occurred while seeking. Attempt to recover by treating this as the last block which will in turn terminate the loop. */
}
}
} break ;
default :
{
/*
It ' s an unknown chunk , but not necessarily invalid . There ' s a chance more metadata blocks might be defined later on , so we
can at the very least report the chunk to the application and let it look at the raw data .
*/
if ( onMeta ) {
void * pRawData = drflac__malloc_from_callbacks ( blockSize , pAllocationCallbacks ) ;
if ( pRawData = = NULL ) {
return DRFLAC_FALSE ;
}
if ( onRead ( pUserData , pRawData , blockSize ) ! = blockSize ) {
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
return DRFLAC_FALSE ;
}
metadata . pRawData = pRawData ;
metadata . rawDataSize = blockSize ;
onMeta ( pUserDataMD , & metadata ) ;
drflac__free_from_callbacks ( pRawData , pAllocationCallbacks ) ;
}
} break ;
}
/* If we're not handling metadata, just skip over the block. If we are, it will have been handled earlier in the switch statement above. */
if ( onMeta = = NULL & & blockSize > 0 ) {
if ( ! onSeek ( pUserData , blockSize , drflac_seek_origin_current ) ) {
isLastBlock = DRFLAC_TRUE ;
}
}
runningFilePos + = blockSize ;
if ( isLastBlock ) {
break ;
}
}
* pSeektablePos = seektablePos ;
* pSeektableSize = seektableSize ;
* pFirstFramePos = runningFilePos ;
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac__init_private__native ( drflac_init_info * pInit , drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , void * pUserData , void * pUserDataMD , drflac_bool32 relaxed )
{
/* Pre Condition: The bit stream should be sitting just past the 4-byte id header. */
drflac_uint8 isLastBlock ;
drflac_uint8 blockType ;
drflac_uint32 blockSize ;
( void ) onSeek ;
pInit - > container = drflac_container_native ;
/* The first metadata block should be the STREAMINFO block. */
if ( ! drflac__read_and_decode_block_header ( onRead , pUserData , & isLastBlock , & blockType , & blockSize ) ) {
return DRFLAC_FALSE ;
}
if ( blockType ! = DRFLAC_METADATA_BLOCK_TYPE_STREAMINFO | | blockSize ! = 34 ) {
if ( ! relaxed ) {
/* We're opening in strict mode and the first block is not the STREAMINFO block. Error. */
return DRFLAC_FALSE ;
} else {
/*
Relaxed mode . To open from here we need to just find the first frame and set the sample rate , etc . to whatever is defined
for that frame .
*/
pInit - > hasStreamInfoBlock = DRFLAC_FALSE ;
pInit - > hasMetadataBlocks = DRFLAC_FALSE ;
if ( ! drflac__read_next_flac_frame_header ( & pInit - > bs , 0 , & pInit - > firstFrameHeader ) ) {
return DRFLAC_FALSE ; /* Couldn't find a frame. */
}
if ( pInit - > firstFrameHeader . bitsPerSample = = 0 ) {
return DRFLAC_FALSE ; /* Failed to initialize because the first frame depends on the STREAMINFO block, which does not exist. */
}
pInit - > sampleRate = pInit - > firstFrameHeader . sampleRate ;
pInit - > channels = drflac__get_channel_count_from_channel_assignment ( pInit - > firstFrameHeader . channelAssignment ) ;
pInit - > bitsPerSample = pInit - > firstFrameHeader . bitsPerSample ;
pInit - > maxBlockSizeInPCMFrames = 65535 ; /* <-- See notes here: https://xiph.org/flac/format.html#metadata_block_streaminfo */
return DRFLAC_TRUE ;
}
} else {
drflac_streaminfo streaminfo ;
if ( ! drflac__read_streaminfo ( onRead , pUserData , & streaminfo ) ) {
return DRFLAC_FALSE ;
}
pInit - > hasStreamInfoBlock = DRFLAC_TRUE ;
pInit - > sampleRate = streaminfo . sampleRate ;
pInit - > channels = streaminfo . channels ;
pInit - > bitsPerSample = streaminfo . bitsPerSample ;
pInit - > totalPCMFrameCount = streaminfo . totalPCMFrameCount ;
pInit - > maxBlockSizeInPCMFrames = streaminfo . maxBlockSizeInPCMFrames ; /* Don't care about the min block size - only the max (used for determining the size of the memory allocation). */
pInit - > hasMetadataBlocks = ! isLastBlock ;
if ( onMeta ) {
drflac_metadata metadata ;
metadata . type = DRFLAC_METADATA_BLOCK_TYPE_STREAMINFO ;
metadata . pRawData = NULL ;
metadata . rawDataSize = 0 ;
metadata . data . streaminfo = streaminfo ;
onMeta ( pUserDataMD , & metadata ) ;
}
return DRFLAC_TRUE ;
}
}
# ifndef DR_FLAC_NO_OGG
# define DRFLAC_OGG_MAX_PAGE_SIZE 65307
# define DRFLAC_OGG_CAPTURE_PATTERN_CRC32 1605413199 /* CRC-32 of "OggS". */
typedef enum
{
drflac_ogg_recover_on_crc_mismatch ,
drflac_ogg_fail_on_crc_mismatch
} drflac_ogg_crc_mismatch_recovery ;
# ifndef DR_FLAC_NO_CRC
static drflac_uint32 drflac__crc32_table [ ] = {
0x00000000L , 0x04C11DB7L , 0x09823B6EL , 0x0D4326D9L ,
0x130476DCL , 0x17C56B6BL , 0x1A864DB2L , 0x1E475005L ,
0x2608EDB8L , 0x22C9F00FL , 0x2F8AD6D6L , 0x2B4BCB61L ,
0x350C9B64L , 0x31CD86D3L , 0x3C8EA00AL , 0x384FBDBDL ,
0x4C11DB70L , 0x48D0C6C7L , 0x4593E01EL , 0x4152FDA9L ,
0x5F15ADACL , 0x5BD4B01BL , 0x569796C2L , 0x52568B75L ,
0x6A1936C8L , 0x6ED82B7FL , 0x639B0DA6L , 0x675A1011L ,
0x791D4014L , 0x7DDC5DA3L , 0x709F7B7AL , 0x745E66CDL ,
0x9823B6E0L , 0x9CE2AB57L , 0x91A18D8EL , 0x95609039L ,
0x8B27C03CL , 0x8FE6DD8BL , 0x82A5FB52L , 0x8664E6E5L ,
0xBE2B5B58L , 0xBAEA46EFL , 0xB7A96036L , 0xB3687D81L ,
0xAD2F2D84L , 0xA9EE3033L , 0xA4AD16EAL , 0xA06C0B5DL ,
0xD4326D90L , 0xD0F37027L , 0xDDB056FEL , 0xD9714B49L ,
0xC7361B4CL , 0xC3F706FBL , 0xCEB42022L , 0xCA753D95L ,
0xF23A8028L , 0xF6FB9D9FL , 0xFBB8BB46L , 0xFF79A6F1L ,
0xE13EF6F4L , 0xE5FFEB43L , 0xE8BCCD9AL , 0xEC7DD02DL ,
0x34867077L , 0x30476DC0L , 0x3D044B19L , 0x39C556AEL ,
0x278206ABL , 0x23431B1CL , 0x2E003DC5L , 0x2AC12072L ,
0x128E9DCFL , 0x164F8078L , 0x1B0CA6A1L , 0x1FCDBB16L ,
0x018AEB13L , 0x054BF6A4L , 0x0808D07DL , 0x0CC9CDCAL ,
0x7897AB07L , 0x7C56B6B0L , 0x71159069L , 0x75D48DDEL ,
0x6B93DDDBL , 0x6F52C06CL , 0x6211E6B5L , 0x66D0FB02L ,
0x5E9F46BFL , 0x5A5E5B08L , 0x571D7DD1L , 0x53DC6066L ,
0x4D9B3063L , 0x495A2DD4L , 0x44190B0DL , 0x40D816BAL ,
0xACA5C697L , 0xA864DB20L , 0xA527FDF9L , 0xA1E6E04EL ,
0xBFA1B04BL , 0xBB60ADFCL , 0xB6238B25L , 0xB2E29692L ,
0x8AAD2B2FL , 0x8E6C3698L , 0x832F1041L , 0x87EE0DF6L ,
0x99A95DF3L , 0x9D684044L , 0x902B669DL , 0x94EA7B2AL ,
0xE0B41DE7L , 0xE4750050L , 0xE9362689L , 0xEDF73B3EL ,
0xF3B06B3BL , 0xF771768CL , 0xFA325055L , 0xFEF34DE2L ,
0xC6BCF05FL , 0xC27DEDE8L , 0xCF3ECB31L , 0xCBFFD686L ,
0xD5B88683L , 0xD1799B34L , 0xDC3ABDEDL , 0xD8FBA05AL ,
0x690CE0EEL , 0x6DCDFD59L , 0x608EDB80L , 0x644FC637L ,
0x7A089632L , 0x7EC98B85L , 0x738AAD5CL , 0x774BB0EBL ,
0x4F040D56L , 0x4BC510E1L , 0x46863638L , 0x42472B8FL ,
0x5C007B8AL , 0x58C1663DL , 0x558240E4L , 0x51435D53L ,
0x251D3B9EL , 0x21DC2629L , 0x2C9F00F0L , 0x285E1D47L ,
0x36194D42L , 0x32D850F5L , 0x3F9B762CL , 0x3B5A6B9BL ,
0x0315D626L , 0x07D4CB91L , 0x0A97ED48L , 0x0E56F0FFL ,
0x1011A0FAL , 0x14D0BD4DL , 0x19939B94L , 0x1D528623L ,
0xF12F560EL , 0xF5EE4BB9L , 0xF8AD6D60L , 0xFC6C70D7L ,
0xE22B20D2L , 0xE6EA3D65L , 0xEBA91BBCL , 0xEF68060BL ,
0xD727BBB6L , 0xD3E6A601L , 0xDEA580D8L , 0xDA649D6FL ,
0xC423CD6AL , 0xC0E2D0DDL , 0xCDA1F604L , 0xC960EBB3L ,
0xBD3E8D7EL , 0xB9FF90C9L , 0xB4BCB610L , 0xB07DABA7L ,
0xAE3AFBA2L , 0xAAFBE615L , 0xA7B8C0CCL , 0xA379DD7BL ,
0x9B3660C6L , 0x9FF77D71L , 0x92B45BA8L , 0x9675461FL ,
0x8832161AL , 0x8CF30BADL , 0x81B02D74L , 0x857130C3L ,
0x5D8A9099L , 0x594B8D2EL , 0x5408ABF7L , 0x50C9B640L ,
0x4E8EE645L , 0x4A4FFBF2L , 0x470CDD2BL , 0x43CDC09CL ,
0x7B827D21L , 0x7F436096L , 0x7200464FL , 0x76C15BF8L ,
0x68860BFDL , 0x6C47164AL , 0x61043093L , 0x65C52D24L ,
0x119B4BE9L , 0x155A565EL , 0x18197087L , 0x1CD86D30L ,
0x029F3D35L , 0x065E2082L , 0x0B1D065BL , 0x0FDC1BECL ,
0x3793A651L , 0x3352BBE6L , 0x3E119D3FL , 0x3AD08088L ,
0x2497D08DL , 0x2056CD3AL , 0x2D15EBE3L , 0x29D4F654L ,
0xC5A92679L , 0xC1683BCEL , 0xCC2B1D17L , 0xC8EA00A0L ,
0xD6AD50A5L , 0xD26C4D12L , 0xDF2F6BCBL , 0xDBEE767CL ,
0xE3A1CBC1L , 0xE760D676L , 0xEA23F0AFL , 0xEEE2ED18L ,
0xF0A5BD1DL , 0xF464A0AAL , 0xF9278673L , 0xFDE69BC4L ,
0x89B8FD09L , 0x8D79E0BEL , 0x803AC667L , 0x84FBDBD0L ,
0x9ABC8BD5L , 0x9E7D9662L , 0x933EB0BBL , 0x97FFAD0CL ,
0xAFB010B1L , 0xAB710D06L , 0xA6322BDFL , 0xA2F33668L ,
0xBCB4666DL , 0xB8757BDAL , 0xB5365D03L , 0xB1F740B4L
} ;
# endif
static DRFLAC_INLINE drflac_uint32 drflac_crc32_byte ( drflac_uint32 crc32 , drflac_uint8 data )
{
# ifndef DR_FLAC_NO_CRC
return ( crc32 < < 8 ) ^ drflac__crc32_table [ ( drflac_uint8 ) ( ( crc32 > > 24 ) & 0xFF ) ^ data ] ;
# else
( void ) data ;
return crc32 ;
# endif
}
#if 0
static DRFLAC_INLINE drflac_uint32 drflac_crc32_uint32 ( drflac_uint32 crc32 , drflac_uint32 data )
{
crc32 = drflac_crc32_byte ( crc32 , ( drflac_uint8 ) ( ( data > > 24 ) & 0xFF ) ) ;
crc32 = drflac_crc32_byte ( crc32 , ( drflac_uint8 ) ( ( data > > 16 ) & 0xFF ) ) ;
crc32 = drflac_crc32_byte ( crc32 , ( drflac_uint8 ) ( ( data > > 8 ) & 0xFF ) ) ;
crc32 = drflac_crc32_byte ( crc32 , ( drflac_uint8 ) ( ( data > > 0 ) & 0xFF ) ) ;
return crc32 ;
}
static DRFLAC_INLINE drflac_uint32 drflac_crc32_uint64 ( drflac_uint32 crc32 , drflac_uint64 data )
{
crc32 = drflac_crc32_uint32 ( crc32 , ( drflac_uint32 ) ( ( data > > 32 ) & 0xFFFFFFFF ) ) ;
crc32 = drflac_crc32_uint32 ( crc32 , ( drflac_uint32 ) ( ( data > > 0 ) & 0xFFFFFFFF ) ) ;
return crc32 ;
}
# endif
static DRFLAC_INLINE drflac_uint32 drflac_crc32_buffer ( drflac_uint32 crc32 , drflac_uint8 * pData , drflac_uint32 dataSize )
{
/* This can be optimized. */
drflac_uint32 i ;
for ( i = 0 ; i < dataSize ; + + i ) {
crc32 = drflac_crc32_byte ( crc32 , pData [ i ] ) ;
}
return crc32 ;
}
static DRFLAC_INLINE drflac_bool32 drflac_ogg__is_capture_pattern ( drflac_uint8 pattern [ 4 ] )
{
return pattern [ 0 ] = = ' O ' & & pattern [ 1 ] = = ' g ' & & pattern [ 2 ] = = ' g ' & & pattern [ 3 ] = = ' S ' ;
}
static DRFLAC_INLINE drflac_uint32 drflac_ogg__get_page_header_size ( drflac_ogg_page_header * pHeader )
{
return 27 + pHeader - > segmentCount ;
}
static DRFLAC_INLINE drflac_uint32 drflac_ogg__get_page_body_size ( drflac_ogg_page_header * pHeader )
{
drflac_uint32 pageBodySize = 0 ;
int i ;
for ( i = 0 ; i < pHeader - > segmentCount ; + + i ) {
pageBodySize + = pHeader - > segmentTable [ i ] ;
}
return pageBodySize ;
}
static drflac_result drflac_ogg__read_page_header_after_capture_pattern ( drflac_read_proc onRead , void * pUserData , drflac_ogg_page_header * pHeader , drflac_uint32 * pBytesRead , drflac_uint32 * pCRC32 )
{
drflac_uint8 data [ 23 ] ;
drflac_uint32 i ;
DRFLAC_ASSERT ( * pCRC32 = = DRFLAC_OGG_CAPTURE_PATTERN_CRC32 ) ;
if ( onRead ( pUserData , data , 23 ) ! = 23 ) {
return DRFLAC_AT_END ;
}
* pBytesRead + = 23 ;
/*
It ' s not actually used , but set the capture pattern to ' OggS ' for completeness . Not doing this will cause static analysers to complain about
us trying to access uninitialized data . We could alternatively just comment out this member of the drflac_ogg_page_header structure , but I
like to have it map to the structure of the underlying data .
*/
pHeader - > capturePattern [ 0 ] = ' O ' ;
pHeader - > capturePattern [ 1 ] = ' g ' ;
pHeader - > capturePattern [ 2 ] = ' g ' ;
pHeader - > capturePattern [ 3 ] = ' S ' ;
pHeader - > structureVersion = data [ 0 ] ;
pHeader - > headerType = data [ 1 ] ;
DRFLAC_COPY_MEMORY ( & pHeader - > granulePosition , & data [ 2 ] , 8 ) ;
DRFLAC_COPY_MEMORY ( & pHeader - > serialNumber , & data [ 10 ] , 4 ) ;
DRFLAC_COPY_MEMORY ( & pHeader - > sequenceNumber , & data [ 14 ] , 4 ) ;
DRFLAC_COPY_MEMORY ( & pHeader - > checksum , & data [ 18 ] , 4 ) ;
pHeader - > segmentCount = data [ 22 ] ;
/* Calculate the CRC. Note that for the calculation the checksum part of the page needs to be set to 0. */
data [ 18 ] = 0 ;
data [ 19 ] = 0 ;
data [ 20 ] = 0 ;
data [ 21 ] = 0 ;
for ( i = 0 ; i < 23 ; + + i ) {
* pCRC32 = drflac_crc32_byte ( * pCRC32 , data [ i ] ) ;
}
if ( onRead ( pUserData , pHeader - > segmentTable , pHeader - > segmentCount ) ! = pHeader - > segmentCount ) {
return DRFLAC_AT_END ;
}
* pBytesRead + = pHeader - > segmentCount ;
for ( i = 0 ; i < pHeader - > segmentCount ; + + i ) {
* pCRC32 = drflac_crc32_byte ( * pCRC32 , pHeader - > segmentTable [ i ] ) ;
}
return DRFLAC_SUCCESS ;
}
static drflac_result drflac_ogg__read_page_header ( drflac_read_proc onRead , void * pUserData , drflac_ogg_page_header * pHeader , drflac_uint32 * pBytesRead , drflac_uint32 * pCRC32 )
{
drflac_uint8 id [ 4 ] ;
* pBytesRead = 0 ;
if ( onRead ( pUserData , id , 4 ) ! = 4 ) {
return DRFLAC_AT_END ;
}
* pBytesRead + = 4 ;
/* We need to read byte-by-byte until we find the OggS capture pattern. */
for ( ; ; ) {
if ( drflac_ogg__is_capture_pattern ( id ) ) {
drflac_result result ;
* pCRC32 = DRFLAC_OGG_CAPTURE_PATTERN_CRC32 ;
result = drflac_ogg__read_page_header_after_capture_pattern ( onRead , pUserData , pHeader , pBytesRead , pCRC32 ) ;
if ( result = = DRFLAC_SUCCESS ) {
return DRFLAC_SUCCESS ;
} else {
if ( result = = DRFLAC_CRC_MISMATCH ) {
continue ;
} else {
return result ;
}
}
} else {
/* The first 4 bytes did not equal the capture pattern. Read the next byte and try again. */
id [ 0 ] = id [ 1 ] ;
id [ 1 ] = id [ 2 ] ;
id [ 2 ] = id [ 3 ] ;
if ( onRead ( pUserData , & id [ 3 ] , 1 ) ! = 1 ) {
return DRFLAC_AT_END ;
}
* pBytesRead + = 1 ;
}
}
}
/*
The main part of the Ogg encapsulation is the conversion from the physical Ogg bitstream to the native FLAC bitstream . It works
in three general stages : Ogg Physical Bitstream - > Ogg / FLAC Logical Bitstream - > FLAC Native Bitstream . dr_flac is designed
in such a way that the core sections assume everything is delivered in native format . Therefore , for each encapsulation type
dr_flac is supporting there needs to be a layer sitting on top of the onRead and onSeek callbacks that ensures the bits read from
the physical Ogg bitstream are converted and delivered in native FLAC format .
*/
typedef struct
{
drflac_read_proc onRead ; /* The original onRead callback from drflac_open() and family. */
drflac_seek_proc onSeek ; /* The original onSeek callback from drflac_open() and family. */
void * pUserData ; /* The user data passed on onRead and onSeek. This is the user data that was passed on drflac_open() and family. */
drflac_uint64 currentBytePos ; /* The position of the byte we are sitting on in the physical byte stream. Used for efficient seeking. */
drflac_uint64 firstBytePos ; /* The position of the first byte in the physical bitstream. Points to the start of the "OggS" identifier of the FLAC bos page. */
drflac_uint32 serialNumber ; /* The serial number of the FLAC audio pages. This is determined by the initial header page that was read during initialization. */
drflac_ogg_page_header bosPageHeader ; /* Used for seeking. */
drflac_ogg_page_header currentPageHeader ;
drflac_uint32 bytesRemainingInPage ;
drflac_uint32 pageDataSize ;
drflac_uint8 pageData [ DRFLAC_OGG_MAX_PAGE_SIZE ] ;
} drflac_oggbs ; /* oggbs = Ogg Bitstream */
static size_t drflac_oggbs__read_physical ( drflac_oggbs * oggbs , void * bufferOut , size_t bytesToRead )
{
size_t bytesActuallyRead = oggbs - > onRead ( oggbs - > pUserData , bufferOut , bytesToRead ) ;
oggbs - > currentBytePos + = bytesActuallyRead ;
return bytesActuallyRead ;
}
static drflac_bool32 drflac_oggbs__seek_physical ( drflac_oggbs * oggbs , drflac_uint64 offset , drflac_seek_origin origin )
{
if ( origin = = drflac_seek_origin_start ) {
if ( offset < = 0x7FFFFFFF ) {
if ( ! oggbs - > onSeek ( oggbs - > pUserData , ( int ) offset , drflac_seek_origin_start ) ) {
return DRFLAC_FALSE ;
}
oggbs - > currentBytePos = offset ;
return DRFLAC_TRUE ;
} else {
if ( ! oggbs - > onSeek ( oggbs - > pUserData , 0x7FFFFFFF , drflac_seek_origin_start ) ) {
return DRFLAC_FALSE ;
}
oggbs - > currentBytePos = offset ;
return drflac_oggbs__seek_physical ( oggbs , offset - 0x7FFFFFFF , drflac_seek_origin_current ) ;
}
} else {
while ( offset > 0x7FFFFFFF ) {
if ( ! oggbs - > onSeek ( oggbs - > pUserData , 0x7FFFFFFF , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ;
}
oggbs - > currentBytePos + = 0x7FFFFFFF ;
offset - = 0x7FFFFFFF ;
}
if ( ! oggbs - > onSeek ( oggbs - > pUserData , ( int ) offset , drflac_seek_origin_current ) ) { /* <-- Safe cast thanks to the loop above. */
return DRFLAC_FALSE ;
}
oggbs - > currentBytePos + = offset ;
return DRFLAC_TRUE ;
}
}
static drflac_bool32 drflac_oggbs__goto_next_page ( drflac_oggbs * oggbs , drflac_ogg_crc_mismatch_recovery recoveryMethod )
{
drflac_ogg_page_header header ;
for ( ; ; ) {
drflac_uint32 crc32 = 0 ;
drflac_uint32 bytesRead ;
drflac_uint32 pageBodySize ;
# ifndef DR_FLAC_NO_CRC
drflac_uint32 actualCRC32 ;
# endif
if ( drflac_ogg__read_page_header ( oggbs - > onRead , oggbs - > pUserData , & header , & bytesRead , & crc32 ) ! = DRFLAC_SUCCESS ) {
return DRFLAC_FALSE ;
}
oggbs - > currentBytePos + = bytesRead ;
pageBodySize = drflac_ogg__get_page_body_size ( & header ) ;
if ( pageBodySize > DRFLAC_OGG_MAX_PAGE_SIZE ) {
continue ; /* Invalid page size. Assume it's corrupted and just move to the next page. */
}
if ( header . serialNumber ! = oggbs - > serialNumber ) {
/* It's not a FLAC page. Skip it. */
if ( pageBodySize > 0 & & ! drflac_oggbs__seek_physical ( oggbs , pageBodySize , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ;
}
continue ;
}
/* We need to read the entire page and then do a CRC check on it. If there's a CRC mismatch we need to skip this page. */
if ( drflac_oggbs__read_physical ( oggbs , oggbs - > pageData , pageBodySize ) ! = pageBodySize ) {
return DRFLAC_FALSE ;
}
oggbs - > pageDataSize = pageBodySize ;
# ifndef DR_FLAC_NO_CRC
actualCRC32 = drflac_crc32_buffer ( crc32 , oggbs - > pageData , oggbs - > pageDataSize ) ;
if ( actualCRC32 ! = header . checksum ) {
if ( recoveryMethod = = drflac_ogg_recover_on_crc_mismatch ) {
continue ; /* CRC mismatch. Skip this page. */
} else {
/*
Even though we are failing on a CRC mismatch , we still want our stream to be in a good state . Therefore we
go to the next valid page to ensure we ' re in a good state , but return false to let the caller know that the
seek did not fully complete .
*/
drflac_oggbs__goto_next_page ( oggbs , drflac_ogg_recover_on_crc_mismatch ) ;
return DRFLAC_FALSE ;
}
}
# else
( void ) recoveryMethod ; /* <-- Silence a warning. */
# endif
oggbs - > currentPageHeader = header ;
oggbs - > bytesRemainingInPage = pageBodySize ;
return DRFLAC_TRUE ;
}
}
/* Function below is unused at the moment, but I might be re-adding it later. */
#if 0
static drflac_uint8 drflac_oggbs__get_current_segment_index ( drflac_oggbs * oggbs , drflac_uint8 * pBytesRemainingInSeg )
{
drflac_uint32 bytesConsumedInPage = drflac_ogg__get_page_body_size ( & oggbs - > currentPageHeader ) - oggbs - > bytesRemainingInPage ;
drflac_uint8 iSeg = 0 ;
drflac_uint32 iByte = 0 ;
while ( iByte < bytesConsumedInPage ) {
drflac_uint8 segmentSize = oggbs - > currentPageHeader . segmentTable [ iSeg ] ;
if ( iByte + segmentSize > bytesConsumedInPage ) {
break ;
} else {
iSeg + = 1 ;
iByte + = segmentSize ;
}
}
* pBytesRemainingInSeg = oggbs - > currentPageHeader . segmentTable [ iSeg ] - ( drflac_uint8 ) ( bytesConsumedInPage - iByte ) ;
return iSeg ;
}
static drflac_bool32 drflac_oggbs__seek_to_next_packet ( drflac_oggbs * oggbs )
{
/* The current packet ends when we get to the segment with a lacing value of < 255 which is not at the end of a page. */
for ( ; ; ) {
drflac_bool32 atEndOfPage = DRFLAC_FALSE ;
drflac_uint8 bytesRemainingInSeg ;
drflac_uint8 iFirstSeg = drflac_oggbs__get_current_segment_index ( oggbs , & bytesRemainingInSeg ) ;
drflac_uint32 bytesToEndOfPacketOrPage = bytesRemainingInSeg ;
for ( drflac_uint8 iSeg = iFirstSeg ; iSeg < oggbs - > currentPageHeader . segmentCount ; + + iSeg ) {
drflac_uint8 segmentSize = oggbs - > currentPageHeader . segmentTable [ iSeg ] ;
if ( segmentSize < 255 ) {
if ( iSeg = = oggbs - > currentPageHeader . segmentCount - 1 ) {
atEndOfPage = DRFLAC_TRUE ;
}
break ;
}
bytesToEndOfPacketOrPage + = segmentSize ;
}
/*
At this point we will have found either the packet or the end of the page . If were at the end of the page we ' ll
want to load the next page and keep searching for the end of the packet .
*/
drflac_oggbs__seek_physical ( oggbs , bytesToEndOfPacketOrPage , drflac_seek_origin_current ) ;
oggbs - > bytesRemainingInPage - = bytesToEndOfPacketOrPage ;
if ( atEndOfPage ) {
/*
We ' re potentially at the next packet , but we need to check the next page first to be sure because the packet may
straddle pages .
*/
if ( ! drflac_oggbs__goto_next_page ( oggbs ) ) {
return DRFLAC_FALSE ;
}
/* If it's a fresh packet it most likely means we're at the next packet. */
if ( ( oggbs - > currentPageHeader . headerType & 0x01 ) = = 0 ) {
return DRFLAC_TRUE ;
}
} else {
/* We're at the next packet. */
return DRFLAC_TRUE ;
}
}
}
static drflac_bool32 drflac_oggbs__seek_to_next_frame ( drflac_oggbs * oggbs )
{
/* The bitstream should be sitting on the first byte just after the header of the frame. */
/* What we're actually doing here is seeking to the start of the next packet. */
return drflac_oggbs__seek_to_next_packet ( oggbs ) ;
}
# endif
static size_t drflac__on_read_ogg ( void * pUserData , void * bufferOut , size_t bytesToRead )
{
drflac_oggbs * oggbs = ( drflac_oggbs * ) pUserData ;
drflac_uint8 * pRunningBufferOut = ( drflac_uint8 * ) bufferOut ;
size_t bytesRead = 0 ;
DRFLAC_ASSERT ( oggbs ! = NULL ) ;
DRFLAC_ASSERT ( pRunningBufferOut ! = NULL ) ;
/* Reading is done page-by-page. If we've run out of bytes in the page we need to move to the next one. */
while ( bytesRead < bytesToRead ) {
size_t bytesRemainingToRead = bytesToRead - bytesRead ;
if ( oggbs - > bytesRemainingInPage > = bytesRemainingToRead ) {
DRFLAC_COPY_MEMORY ( pRunningBufferOut , oggbs - > pageData + ( oggbs - > pageDataSize - oggbs - > bytesRemainingInPage ) , bytesRemainingToRead ) ;
bytesRead + = bytesRemainingToRead ;
oggbs - > bytesRemainingInPage - = ( drflac_uint32 ) bytesRemainingToRead ;
break ;
}
/* If we get here it means some of the requested data is contained in the next pages. */
if ( oggbs - > bytesRemainingInPage > 0 ) {
DRFLAC_COPY_MEMORY ( pRunningBufferOut , oggbs - > pageData + ( oggbs - > pageDataSize - oggbs - > bytesRemainingInPage ) , oggbs - > bytesRemainingInPage ) ;
bytesRead + = oggbs - > bytesRemainingInPage ;
pRunningBufferOut + = oggbs - > bytesRemainingInPage ;
oggbs - > bytesRemainingInPage = 0 ;
}
DRFLAC_ASSERT ( bytesRemainingToRead > 0 ) ;
if ( ! drflac_oggbs__goto_next_page ( oggbs , drflac_ogg_recover_on_crc_mismatch ) ) {
break ; /* Failed to go to the next page. Might have simply hit the end of the stream. */
}
}
return bytesRead ;
}
static drflac_bool32 drflac__on_seek_ogg ( void * pUserData , int offset , drflac_seek_origin origin )
{
drflac_oggbs * oggbs = ( drflac_oggbs * ) pUserData ;
int bytesSeeked = 0 ;
DRFLAC_ASSERT ( oggbs ! = NULL ) ;
DRFLAC_ASSERT ( offset > = 0 ) ; /* <-- Never seek backwards. */
/* Seeking is always forward which makes things a lot simpler. */
if ( origin = = drflac_seek_origin_start ) {
if ( ! drflac_oggbs__seek_physical ( oggbs , ( int ) oggbs - > firstBytePos , drflac_seek_origin_start ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac_oggbs__goto_next_page ( oggbs , drflac_ogg_fail_on_crc_mismatch ) ) {
return DRFLAC_FALSE ;
}
return drflac__on_seek_ogg ( pUserData , offset , drflac_seek_origin_current ) ;
}
DRFLAC_ASSERT ( origin = = drflac_seek_origin_current ) ;
while ( bytesSeeked < offset ) {
int bytesRemainingToSeek = offset - bytesSeeked ;
DRFLAC_ASSERT ( bytesRemainingToSeek > = 0 ) ;
if ( oggbs - > bytesRemainingInPage > = ( size_t ) bytesRemainingToSeek ) {
bytesSeeked + = bytesRemainingToSeek ;
( void ) bytesSeeked ; /* <-- Silence a dead store warning emitted by Clang Static Analyzer. */
oggbs - > bytesRemainingInPage - = bytesRemainingToSeek ;
break ;
}
/* If we get here it means some of the requested data is contained in the next pages. */
if ( oggbs - > bytesRemainingInPage > 0 ) {
bytesSeeked + = ( int ) oggbs - > bytesRemainingInPage ;
oggbs - > bytesRemainingInPage = 0 ;
}
DRFLAC_ASSERT ( bytesRemainingToSeek > 0 ) ;
if ( ! drflac_oggbs__goto_next_page ( oggbs , drflac_ogg_fail_on_crc_mismatch ) ) {
/* Failed to go to the next page. We either hit the end of the stream or had a CRC mismatch. */
return DRFLAC_FALSE ;
}
}
return DRFLAC_TRUE ;
}
static drflac_bool32 drflac_ogg__seek_to_pcm_frame ( drflac * pFlac , drflac_uint64 pcmFrameIndex )
{
drflac_oggbs * oggbs = ( drflac_oggbs * ) pFlac - > _oggbs ;
drflac_uint64 originalBytePos ;
drflac_uint64 runningGranulePosition ;
drflac_uint64 runningFrameBytePos ;
drflac_uint64 runningPCMFrameCount ;
DRFLAC_ASSERT ( oggbs ! = NULL ) ;
originalBytePos = oggbs - > currentBytePos ; /* For recovery. Points to the OggS identifier. */
/* First seek to the first frame. */
if ( ! drflac__seek_to_byte ( & pFlac - > bs , pFlac - > firstFLACFramePosInBytes ) ) {
return DRFLAC_FALSE ;
}
oggbs - > bytesRemainingInPage = 0 ;
runningGranulePosition = 0 ;
for ( ; ; ) {
if ( ! drflac_oggbs__goto_next_page ( oggbs , drflac_ogg_recover_on_crc_mismatch ) ) {
drflac_oggbs__seek_physical ( oggbs , originalBytePos , drflac_seek_origin_start ) ;
return DRFLAC_FALSE ; /* Never did find that sample... */
}
runningFrameBytePos = oggbs - > currentBytePos - drflac_ogg__get_page_header_size ( & oggbs - > currentPageHeader ) - oggbs - > pageDataSize ;
if ( oggbs - > currentPageHeader . granulePosition > = pcmFrameIndex ) {
break ; /* The sample is somewhere in the previous page. */
}
/*
At this point we know the sample is not in the previous page . It could possibly be in this page . For simplicity we
disregard any pages that do not begin a fresh packet .
*/
if ( ( oggbs - > currentPageHeader . headerType & 0x01 ) = = 0 ) { /* <-- Is it a fresh page? */
if ( oggbs - > currentPageHeader . segmentTable [ 0 ] > = 2 ) {
drflac_uint8 firstBytesInPage [ 2 ] ;
firstBytesInPage [ 0 ] = oggbs - > pageData [ 0 ] ;
firstBytesInPage [ 1 ] = oggbs - > pageData [ 1 ] ;
if ( ( firstBytesInPage [ 0 ] = = 0xFF ) & & ( firstBytesInPage [ 1 ] & 0xFC ) = = 0xF8 ) { /* <-- Does the page begin with a frame's sync code? */
runningGranulePosition = oggbs - > currentPageHeader . granulePosition ;
}
continue ;
}
}
}
/*
We found the page that that is closest to the sample , so now we need to find it . The first thing to do is seek to the
start of that page . In the loop above we checked that it was a fresh page which means this page is also the start of
a new frame . This property means that after we ' ve seeked to the page we can immediately start looping over frames until
we find the one containing the target sample .
*/
if ( ! drflac_oggbs__seek_physical ( oggbs , runningFrameBytePos , drflac_seek_origin_start ) ) {
return DRFLAC_FALSE ;
}
if ( ! drflac_oggbs__goto_next_page ( oggbs , drflac_ogg_recover_on_crc_mismatch ) ) {
return DRFLAC_FALSE ;
}
/*
At this point we ' ll be sitting on the first byte of the frame header of the first frame in the page . We just keep
looping over these frames until we find the one containing the sample we ' re after .
*/
runningPCMFrameCount = runningGranulePosition ;
for ( ; ; ) {
/*
There are two ways to find the sample and seek past irrelevant frames :
1 ) Use the native FLAC decoder .
2 ) Use Ogg ' s framing system .
Both of these options have their own pros and cons . Using the native FLAC decoder is slower because it needs to
do a full decode of the frame . Using Ogg ' s framing system is faster , but more complicated and involves some code
duplication for the decoding of frame headers .
Another thing to consider is that using the Ogg framing system will perform direct seeking of the physical Ogg
bitstream . This is important to consider because it means we cannot read data from the drflac_bs object using the
standard drflac__ * ( ) APIs because that will read in extra data for its own internal caching which in turn breaks
the positioning of the read pointer of the physical Ogg bitstream . Therefore , anything that would normally be read
using the native FLAC decoding APIs , such as drflac__read_next_flac_frame_header ( ) , need to be re - implemented so as to
avoid the use of the drflac_bs object .
Considering these issues , I have decided to use the slower native FLAC decoding method for the following reasons :
1 ) Seeking is already partially accelerated using Ogg ' s paging system in the code block above .
2 ) Seeking in an Ogg encapsulated FLAC stream is probably quite uncommon .
3 ) Simplicity .
*/
drflac_uint64 firstPCMFrameInFLACFrame = 0 ;
drflac_uint64 lastPCMFrameInFLACFrame = 0 ;
drflac_uint64 pcmFrameCountInThisFrame ;
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
return DRFLAC_FALSE ;
}
drflac__get_pcm_frame_range_of_current_flac_frame ( pFlac , & firstPCMFrameInFLACFrame , & lastPCMFrameInFLACFrame ) ;
pcmFrameCountInThisFrame = ( lastPCMFrameInFLACFrame - firstPCMFrameInFLACFrame ) + 1 ;
/* If we are seeking to the end of the file and we've just hit it, we're done. */
if ( pcmFrameIndex = = pFlac - > totalPCMFrameCount & & ( runningPCMFrameCount + pcmFrameCountInThisFrame ) = = pFlac - > totalPCMFrameCount ) {
drflac_result result = drflac__decode_flac_frame ( pFlac ) ;
if ( result = = DRFLAC_SUCCESS ) {
pFlac - > currentPCMFrame = pcmFrameIndex ;
pFlac - > currentFLACFrame . pcmFramesRemaining = 0 ;
return DRFLAC_TRUE ;
} else {
return DRFLAC_FALSE ;
}
}
if ( pcmFrameIndex < ( runningPCMFrameCount + pcmFrameCountInThisFrame ) ) {
/*
The sample should be in this FLAC frame . We need to fully decode it , however if it ' s an invalid frame ( a CRC mismatch ) , we need to pretend
it never existed and keep iterating .
*/
drflac_result result = drflac__decode_flac_frame ( pFlac ) ;
if ( result = = DRFLAC_SUCCESS ) {
/* The frame is valid. We just need to skip over some samples to ensure it's sample-exact. */
drflac_uint64 pcmFramesToDecode = ( size_t ) ( pcmFrameIndex - runningPCMFrameCount ) ; /* <-- Safe cast because the maximum number of samples in a frame is 65535. */
if ( pcmFramesToDecode = = 0 ) {
return DRFLAC_TRUE ;
}
pFlac - > currentPCMFrame = runningPCMFrameCount ;
return drflac__seek_forward_by_pcm_frames ( pFlac , pcmFramesToDecode ) = = pcmFramesToDecode ; /* <-- If this fails, something bad has happened (it should never fail). */
} else {
if ( result = = DRFLAC_CRC_MISMATCH ) {
continue ; /* CRC mismatch. Pretend this frame never existed. */
} else {
return DRFLAC_FALSE ;
}
}
} else {
/*
It ' s not in this frame . We need to seek past the frame , but check if there was a CRC mismatch . If so , we pretend this
frame never existed and leave the running sample count untouched .
*/
drflac_result result = drflac__seek_to_next_flac_frame ( pFlac ) ;
if ( result = = DRFLAC_SUCCESS ) {
runningPCMFrameCount + = pcmFrameCountInThisFrame ;
} else {
if ( result = = DRFLAC_CRC_MISMATCH ) {
continue ; /* CRC mismatch. Pretend this frame never existed. */
} else {
return DRFLAC_FALSE ;
}
}
}
}
}
static drflac_bool32 drflac__init_private__ogg ( drflac_init_info * pInit , drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , void * pUserData , void * pUserDataMD , drflac_bool32 relaxed )
{
drflac_ogg_page_header header ;
drflac_uint32 crc32 = DRFLAC_OGG_CAPTURE_PATTERN_CRC32 ;
drflac_uint32 bytesRead = 0 ;
/* Pre Condition: The bit stream should be sitting just past the 4-byte OggS capture pattern. */
( void ) relaxed ;
pInit - > container = drflac_container_ogg ;
pInit - > oggFirstBytePos = 0 ;
/*
We ' ll get here if the first 4 bytes of the stream were the OggS capture pattern , however it doesn ' t necessarily mean the
stream includes FLAC encoded audio . To check for this we need to scan the beginning - of - stream page markers and check if
any match the FLAC specification . Important to keep in mind that the stream may be multiplexed .
*/
if ( drflac_ogg__read_page_header_after_capture_pattern ( onRead , pUserData , & header , & bytesRead , & crc32 ) ! = DRFLAC_SUCCESS ) {
return DRFLAC_FALSE ;
}
pInit - > runningFilePos + = bytesRead ;
for ( ; ; ) {
int pageBodySize ;
/* Break if we're past the beginning of stream page. */
if ( ( header . headerType & 0x02 ) = = 0 ) {
return DRFLAC_FALSE ;
}
/* Check if it's a FLAC header. */
pageBodySize = drflac_ogg__get_page_body_size ( & header ) ;
if ( pageBodySize = = 51 ) { /* 51 = the lacing value of the FLAC header packet. */
/* It could be a FLAC page... */
drflac_uint32 bytesRemainingInPage = pageBodySize ;
drflac_uint8 packetType ;
if ( onRead ( pUserData , & packetType , 1 ) ! = 1 ) {
return DRFLAC_FALSE ;
}
bytesRemainingInPage - = 1 ;
if ( packetType = = 0x7F ) {
/* Increasingly more likely to be a FLAC page... */
drflac_uint8 sig [ 4 ] ;
if ( onRead ( pUserData , sig , 4 ) ! = 4 ) {
return DRFLAC_FALSE ;
}
bytesRemainingInPage - = 4 ;
if ( sig [ 0 ] = = ' F ' & & sig [ 1 ] = = ' L ' & & sig [ 2 ] = = ' A ' & & sig [ 3 ] = = ' C ' ) {
/* Almost certainly a FLAC page... */
drflac_uint8 mappingVersion [ 2 ] ;
if ( onRead ( pUserData , mappingVersion , 2 ) ! = 2 ) {
return DRFLAC_FALSE ;
}
if ( mappingVersion [ 0 ] ! = 1 ) {
return DRFLAC_FALSE ; /* Only supporting version 1.x of the Ogg mapping. */
}
/*
The next 2 bytes are the non - audio packets , not including this one . We don ' t care about this because we ' re going to
be handling it in a generic way based on the serial number and packet types .
*/
if ( ! onSeek ( pUserData , 2 , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ;
}
/* Expecting the native FLAC signature "fLaC". */
if ( onRead ( pUserData , sig , 4 ) ! = 4 ) {
return DRFLAC_FALSE ;
}
if ( sig [ 0 ] = = ' f ' & & sig [ 1 ] = = ' L ' & & sig [ 2 ] = = ' a ' & & sig [ 3 ] = = ' C ' ) {
/* The remaining data in the page should be the STREAMINFO block. */
drflac_streaminfo streaminfo ;
drflac_uint8 isLastBlock ;
drflac_uint8 blockType ;
drflac_uint32 blockSize ;
if ( ! drflac__read_and_decode_block_header ( onRead , pUserData , & isLastBlock , & blockType , & blockSize ) ) {
return DRFLAC_FALSE ;
}
if ( blockType ! = DRFLAC_METADATA_BLOCK_TYPE_STREAMINFO | | blockSize ! = 34 ) {
return DRFLAC_FALSE ; /* Invalid block type. First block must be the STREAMINFO block. */
}
if ( drflac__read_streaminfo ( onRead , pUserData , & streaminfo ) ) {
/* Success! */
pInit - > hasStreamInfoBlock = DRFLAC_TRUE ;
pInit - > sampleRate = streaminfo . sampleRate ;
pInit - > channels = streaminfo . channels ;
pInit - > bitsPerSample = streaminfo . bitsPerSample ;
pInit - > totalPCMFrameCount = streaminfo . totalPCMFrameCount ;
pInit - > maxBlockSizeInPCMFrames = streaminfo . maxBlockSizeInPCMFrames ;
pInit - > hasMetadataBlocks = ! isLastBlock ;
if ( onMeta ) {
drflac_metadata metadata ;
metadata . type = DRFLAC_METADATA_BLOCK_TYPE_STREAMINFO ;
metadata . pRawData = NULL ;
metadata . rawDataSize = 0 ;
metadata . data . streaminfo = streaminfo ;
onMeta ( pUserDataMD , & metadata ) ;
}
pInit - > runningFilePos + = pageBodySize ;
pInit - > oggFirstBytePos = pInit - > runningFilePos - 79 ; /* Subtracting 79 will place us right on top of the "OggS" identifier of the FLAC bos page. */
pInit - > oggSerial = header . serialNumber ;
pInit - > oggBosHeader = header ;
break ;
} else {
/* Failed to read STREAMINFO block. Aww, so close... */
return DRFLAC_FALSE ;
}
} else {
/* Invalid file. */
return DRFLAC_FALSE ;
}
} else {
/* Not a FLAC header. Skip it. */
if ( ! onSeek ( pUserData , bytesRemainingInPage , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ;
}
}
} else {
/* Not a FLAC header. Seek past the entire page and move on to the next. */
if ( ! onSeek ( pUserData , bytesRemainingInPage , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ;
}
}
} else {
if ( ! onSeek ( pUserData , pageBodySize , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ;
}
}
pInit - > runningFilePos + = pageBodySize ;
/* Read the header of the next page. */
if ( drflac_ogg__read_page_header ( onRead , pUserData , & header , & bytesRead , & crc32 ) ! = DRFLAC_SUCCESS ) {
return DRFLAC_FALSE ;
}
pInit - > runningFilePos + = bytesRead ;
}
/*
If we get here it means we found a FLAC audio stream . We should be sitting on the first byte of the header of the next page . The next
packets in the FLAC logical stream contain the metadata . The only thing left to do in the initialization phase for Ogg is to create the
Ogg bistream object .
*/
pInit - > hasMetadataBlocks = DRFLAC_TRUE ; /* <-- Always have at least VORBIS_COMMENT metadata block. */
return DRFLAC_TRUE ;
}
# endif
static drflac_bool32 drflac__init_private ( drflac_init_info * pInit , drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , drflac_container container , void * pUserData , void * pUserDataMD )
{
drflac_bool32 relaxed ;
drflac_uint8 id [ 4 ] ;
if ( pInit = = NULL | | onRead = = NULL | | onSeek = = NULL ) {
return DRFLAC_FALSE ;
}
DRFLAC_ZERO_MEMORY ( pInit , sizeof ( * pInit ) ) ;
pInit - > onRead = onRead ;
pInit - > onSeek = onSeek ;
pInit - > onMeta = onMeta ;
pInit - > container = container ;
pInit - > pUserData = pUserData ;
pInit - > pUserDataMD = pUserDataMD ;
pInit - > bs . onRead = onRead ;
pInit - > bs . onSeek = onSeek ;
pInit - > bs . pUserData = pUserData ;
drflac__reset_cache ( & pInit - > bs ) ;
/* If the container is explicitly defined then we can try opening in relaxed mode. */
relaxed = container ! = drflac_container_unknown ;
/* Skip over any ID3 tags. */
for ( ; ; ) {
if ( onRead ( pUserData , id , 4 ) ! = 4 ) {
return DRFLAC_FALSE ; /* Ran out of data. */
}
pInit - > runningFilePos + = 4 ;
if ( id [ 0 ] = = ' I ' & & id [ 1 ] = = ' D ' & & id [ 2 ] = = ' 3 ' ) {
drflac_uint8 header [ 6 ] ;
drflac_uint8 flags ;
drflac_uint32 headerSize ;
if ( onRead ( pUserData , header , 6 ) ! = 6 ) {
return DRFLAC_FALSE ; /* Ran out of data. */
}
pInit - > runningFilePos + = 6 ;
flags = header [ 1 ] ;
DRFLAC_COPY_MEMORY ( & headerSize , header + 2 , 4 ) ;
headerSize = drflac__unsynchsafe_32 ( drflac__be2host_32 ( headerSize ) ) ;
if ( flags & 0x10 ) {
headerSize + = 10 ;
}
if ( ! onSeek ( pUserData , headerSize , drflac_seek_origin_current ) ) {
return DRFLAC_FALSE ; /* Failed to seek past the tag. */
}
pInit - > runningFilePos + = headerSize ;
} else {
break ;
}
}
if ( id [ 0 ] = = ' f ' & & id [ 1 ] = = ' L ' & & id [ 2 ] = = ' a ' & & id [ 3 ] = = ' C ' ) {
return drflac__init_private__native ( pInit , onRead , onSeek , onMeta , pUserData , pUserDataMD , relaxed ) ;
}
# ifndef DR_FLAC_NO_OGG
if ( id [ 0 ] = = ' O ' & & id [ 1 ] = = ' g ' & & id [ 2 ] = = ' g ' & & id [ 3 ] = = ' S ' ) {
return drflac__init_private__ogg ( pInit , onRead , onSeek , onMeta , pUserData , pUserDataMD , relaxed ) ;
}
# endif
/* If we get here it means we likely don't have a header. Try opening in relaxed mode, if applicable. */
if ( relaxed ) {
if ( container = = drflac_container_native ) {
return drflac__init_private__native ( pInit , onRead , onSeek , onMeta , pUserData , pUserDataMD , relaxed ) ;
}
# ifndef DR_FLAC_NO_OGG
if ( container = = drflac_container_ogg ) {
return drflac__init_private__ogg ( pInit , onRead , onSeek , onMeta , pUserData , pUserDataMD , relaxed ) ;
}
# endif
}
/* Unsupported container. */
return DRFLAC_FALSE ;
}
static void drflac__init_from_info ( drflac * pFlac , const drflac_init_info * pInit )
{
DRFLAC_ASSERT ( pFlac ! = NULL ) ;
DRFLAC_ASSERT ( pInit ! = NULL ) ;
DRFLAC_ZERO_MEMORY ( pFlac , sizeof ( * pFlac ) ) ;
pFlac - > bs = pInit - > bs ;
pFlac - > onMeta = pInit - > onMeta ;
pFlac - > pUserDataMD = pInit - > pUserDataMD ;
pFlac - > maxBlockSizeInPCMFrames = pInit - > maxBlockSizeInPCMFrames ;
pFlac - > sampleRate = pInit - > sampleRate ;
pFlac - > channels = ( drflac_uint8 ) pInit - > channels ;
pFlac - > bitsPerSample = ( drflac_uint8 ) pInit - > bitsPerSample ;
pFlac - > totalPCMFrameCount = pInit - > totalPCMFrameCount ;
pFlac - > container = pInit - > container ;
}
static drflac * drflac_open_with_metadata_private ( drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , drflac_container container , void * pUserData , void * pUserDataMD , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac_init_info init ;
drflac_uint32 allocationSize ;
drflac_uint32 wholeSIMDVectorCountPerChannel ;
drflac_uint32 decodedSamplesAllocationSize ;
# ifndef DR_FLAC_NO_OGG
drflac_oggbs oggbs ;
# endif
drflac_uint64 firstFramePos ;
drflac_uint64 seektablePos ;
drflac_uint32 seektableSize ;
drflac_allocation_callbacks allocationCallbacks ;
drflac * pFlac ;
/* CPU support first. */
drflac__init_cpu_caps ( ) ;
if ( ! drflac__init_private ( & init , onRead , onSeek , onMeta , container , pUserData , pUserDataMD ) ) {
return NULL ;
}
if ( pAllocationCallbacks ! = NULL ) {
allocationCallbacks = * pAllocationCallbacks ;
if ( allocationCallbacks . onFree = = NULL | | ( allocationCallbacks . onMalloc = = NULL & & allocationCallbacks . onRealloc = = NULL ) ) {
return NULL ; /* Invalid allocation callbacks. */
}
} else {
allocationCallbacks . pUserData = NULL ;
allocationCallbacks . onMalloc = drflac__malloc_default ;
allocationCallbacks . onRealloc = drflac__realloc_default ;
allocationCallbacks . onFree = drflac__free_default ;
}
/*
The size of the allocation for the drflac object needs to be large enough to fit the following :
1 ) The main members of the drflac structure
2 ) A block of memory large enough to store the decoded samples of the largest frame in the stream
3 ) If the container is Ogg , a drflac_oggbs object
The complicated part of the allocation is making sure there ' s enough room the decoded samples , taking into consideration
the different SIMD instruction sets .
*/
allocationSize = sizeof ( drflac ) ;
/*
The allocation size for decoded frames depends on the number of 32 - bit integers that fit inside the largest SIMD vector
we are supporting .
*/
if ( ( init . maxBlockSizeInPCMFrames % ( DRFLAC_MAX_SIMD_VECTOR_SIZE / sizeof ( drflac_int32 ) ) ) = = 0 ) {
wholeSIMDVectorCountPerChannel = ( init . maxBlockSizeInPCMFrames / ( DRFLAC_MAX_SIMD_VECTOR_SIZE / sizeof ( drflac_int32 ) ) ) ;
} else {
wholeSIMDVectorCountPerChannel = ( init . maxBlockSizeInPCMFrames / ( DRFLAC_MAX_SIMD_VECTOR_SIZE / sizeof ( drflac_int32 ) ) ) + 1 ;
}
decodedSamplesAllocationSize = wholeSIMDVectorCountPerChannel * DRFLAC_MAX_SIMD_VECTOR_SIZE * init . channels ;
allocationSize + = decodedSamplesAllocationSize ;
allocationSize + = DRFLAC_MAX_SIMD_VECTOR_SIZE ; /* Allocate extra bytes to ensure we have enough for alignment. */
# ifndef DR_FLAC_NO_OGG
/* There's additional data required for Ogg streams. */
if ( init . container = = drflac_container_ogg ) {
allocationSize + = sizeof ( drflac_oggbs ) ;
}
DRFLAC_ZERO_MEMORY ( & oggbs , sizeof ( oggbs ) ) ;
if ( init . container = = drflac_container_ogg ) {
oggbs . onRead = onRead ;
oggbs . onSeek = onSeek ;
oggbs . pUserData = pUserData ;
oggbs . currentBytePos = init . oggFirstBytePos ;
oggbs . firstBytePos = init . oggFirstBytePos ;
oggbs . serialNumber = init . oggSerial ;
oggbs . bosPageHeader = init . oggBosHeader ;
oggbs . bytesRemainingInPage = 0 ;
}
# endif
/*
This part is a bit awkward . We need to load the seektable so that it can be referenced in - memory , but I want the drflac object to
consist of only a single heap allocation . To this , the size of the seek table needs to be known , which we determine when reading
and decoding the metadata .
*/
firstFramePos = 42 ; /* <-- We know we are at byte 42 at this point. */
seektablePos = 0 ;
seektableSize = 0 ;
if ( init . hasMetadataBlocks ) {
drflac_read_proc onReadOverride = onRead ;
drflac_seek_proc onSeekOverride = onSeek ;
void * pUserDataOverride = pUserData ;
# ifndef DR_FLAC_NO_OGG
if ( init . container = = drflac_container_ogg ) {
onReadOverride = drflac__on_read_ogg ;
onSeekOverride = drflac__on_seek_ogg ;
pUserDataOverride = ( void * ) & oggbs ;
}
# endif
if ( ! drflac__read_and_decode_metadata ( onReadOverride , onSeekOverride , onMeta , pUserDataOverride , pUserDataMD , & firstFramePos , & seektablePos , & seektableSize , & allocationCallbacks ) ) {
return NULL ;
}
allocationSize + = seektableSize ;
}
pFlac = ( drflac * ) drflac__malloc_from_callbacks ( allocationSize , & allocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
drflac__init_from_info ( pFlac , & init ) ;
pFlac - > allocationCallbacks = allocationCallbacks ;
pFlac - > pDecodedSamples = ( drflac_int32 * ) drflac_align ( ( size_t ) pFlac - > pExtraData , DRFLAC_MAX_SIMD_VECTOR_SIZE ) ;
# ifndef DR_FLAC_NO_OGG
if ( init . container = = drflac_container_ogg ) {
drflac_oggbs * pInternalOggbs = ( drflac_oggbs * ) ( ( drflac_uint8 * ) pFlac - > pDecodedSamples + decodedSamplesAllocationSize + seektableSize ) ;
* pInternalOggbs = oggbs ;
/* The Ogg bistream needs to be layered on top of the original bitstream. */
pFlac - > bs . onRead = drflac__on_read_ogg ;
pFlac - > bs . onSeek = drflac__on_seek_ogg ;
pFlac - > bs . pUserData = ( void * ) pInternalOggbs ;
pFlac - > _oggbs = ( void * ) pInternalOggbs ;
}
# endif
pFlac - > firstFLACFramePosInBytes = firstFramePos ;
/* NOTE: Seektables are not currently compatible with Ogg encapsulation (Ogg has its own accelerated seeking system). I may change this later, so I'm leaving this here for now. */
# ifndef DR_FLAC_NO_OGG
if ( init . container = = drflac_container_ogg )
{
pFlac - > pSeekpoints = NULL ;
pFlac - > seekpointCount = 0 ;
}
else
# endif
{
/* If we have a seektable we need to load it now, making sure we move back to where we were previously. */
if ( seektablePos ! = 0 ) {
pFlac - > seekpointCount = seektableSize / sizeof ( * pFlac - > pSeekpoints ) ;
pFlac - > pSeekpoints = ( drflac_seekpoint * ) ( ( drflac_uint8 * ) pFlac - > pDecodedSamples + decodedSamplesAllocationSize ) ;
DRFLAC_ASSERT ( pFlac - > bs . onSeek ! = NULL ) ;
DRFLAC_ASSERT ( pFlac - > bs . onRead ! = NULL ) ;
/* Seek to the seektable, then just read directly into our seektable buffer. */
if ( pFlac - > bs . onSeek ( pFlac - > bs . pUserData , ( int ) seektablePos , drflac_seek_origin_start ) ) {
if ( pFlac - > bs . onRead ( pFlac - > bs . pUserData , pFlac - > pSeekpoints , seektableSize ) = = seektableSize ) {
/* Endian swap. */
drflac_uint32 iSeekpoint ;
for ( iSeekpoint = 0 ; iSeekpoint < pFlac - > seekpointCount ; + + iSeekpoint ) {
pFlac - > pSeekpoints [ iSeekpoint ] . firstPCMFrame = drflac__be2host_64 ( pFlac - > pSeekpoints [ iSeekpoint ] . firstPCMFrame ) ;
pFlac - > pSeekpoints [ iSeekpoint ] . flacFrameOffset = drflac__be2host_64 ( pFlac - > pSeekpoints [ iSeekpoint ] . flacFrameOffset ) ;
pFlac - > pSeekpoints [ iSeekpoint ] . pcmFrameCount = drflac__be2host_16 ( pFlac - > pSeekpoints [ iSeekpoint ] . pcmFrameCount ) ;
}
} else {
/* Failed to read the seektable. Pretend we don't have one. */
pFlac - > pSeekpoints = NULL ;
pFlac - > seekpointCount = 0 ;
}
/* We need to seek back to where we were. If this fails it's a critical error. */
if ( ! pFlac - > bs . onSeek ( pFlac - > bs . pUserData , ( int ) pFlac - > firstFLACFramePosInBytes , drflac_seek_origin_start ) ) {
drflac__free_from_callbacks ( pFlac , & allocationCallbacks ) ;
return NULL ;
}
} else {
/* Failed to seek to the seektable. Ominous sign, but for now we can just pretend we don't have one. */
pFlac - > pSeekpoints = NULL ;
pFlac - > seekpointCount = 0 ;
}
}
}
/*
If we get here , but don ' t have a STREAMINFO block , it means we ' ve opened the stream in relaxed mode and need to decode
the first frame .
*/
if ( ! init . hasStreamInfoBlock ) {
pFlac - > currentFLACFrame . header = init . firstFrameHeader ;
for ( ; ; ) {
drflac_result result = drflac__decode_flac_frame ( pFlac ) ;
if ( result = = DRFLAC_SUCCESS ) {
break ;
} else {
if ( result = = DRFLAC_CRC_MISMATCH ) {
if ( ! drflac__read_next_flac_frame_header ( & pFlac - > bs , pFlac - > bitsPerSample , & pFlac - > currentFLACFrame . header ) ) {
drflac__free_from_callbacks ( pFlac , & allocationCallbacks ) ;
return NULL ;
}
continue ;
} else {
drflac__free_from_callbacks ( pFlac , & allocationCallbacks ) ;
return NULL ;
}
}
}
}
return pFlac ;
}
# ifndef DR_FLAC_NO_STDIO
# include <stdio.h>
# include <wchar.h> /* For wcslen(), wcsrtombs() */
/* drflac_result_from_errno() is only used for fopen() and wfopen() so putting it inside DR_WAV_NO_STDIO for now. If something else needs this later we can move it out. */
# include <errno.h>
static drflac_result drflac_result_from_errno ( int e )
{
switch ( e )
{
case 0 : return DRFLAC_SUCCESS ;
# ifdef EPERM
case EPERM : return DRFLAC_INVALID_OPERATION ;
# endif
# ifdef ENOENT
case ENOENT : return DRFLAC_DOES_NOT_EXIST ;
# endif
# ifdef ESRCH
case ESRCH : return DRFLAC_DOES_NOT_EXIST ;
# endif
# ifdef EINTR
case EINTR : return DRFLAC_INTERRUPT ;
# endif
# ifdef EIO
case EIO : return DRFLAC_IO_ERROR ;
# endif
# ifdef ENXIO
case ENXIO : return DRFLAC_DOES_NOT_EXIST ;
# endif
# ifdef E2BIG
case E2BIG : return DRFLAC_INVALID_ARGS ;
# endif
# ifdef ENOEXEC
case ENOEXEC : return DRFLAC_INVALID_FILE ;
# endif
# ifdef EBADF
case EBADF : return DRFLAC_INVALID_FILE ;
# endif
# ifdef ECHILD
case ECHILD : return DRFLAC_ERROR ;
# endif
# ifdef EAGAIN
case EAGAIN : return DRFLAC_UNAVAILABLE ;
# endif
# ifdef ENOMEM
case ENOMEM : return DRFLAC_OUT_OF_MEMORY ;
# endif
# ifdef EACCES
case EACCES : return DRFLAC_ACCESS_DENIED ;
# endif
# ifdef EFAULT
case EFAULT : return DRFLAC_BAD_ADDRESS ;
# endif
# ifdef ENOTBLK
case ENOTBLK : return DRFLAC_ERROR ;
# endif
# ifdef EBUSY
case EBUSY : return DRFLAC_BUSY ;
# endif
# ifdef EEXIST
case EEXIST : return DRFLAC_ALREADY_EXISTS ;
# endif
# ifdef EXDEV
case EXDEV : return DRFLAC_ERROR ;
# endif
# ifdef ENODEV
case ENODEV : return DRFLAC_DOES_NOT_EXIST ;
# endif
# ifdef ENOTDIR
case ENOTDIR : return DRFLAC_NOT_DIRECTORY ;
# endif
# ifdef EISDIR
case EISDIR : return DRFLAC_IS_DIRECTORY ;
# endif
# ifdef EINVAL
case EINVAL : return DRFLAC_INVALID_ARGS ;
# endif
# ifdef ENFILE
case ENFILE : return DRFLAC_TOO_MANY_OPEN_FILES ;
# endif
# ifdef EMFILE
case EMFILE : return DRFLAC_TOO_MANY_OPEN_FILES ;
# endif
# ifdef ENOTTY
case ENOTTY : return DRFLAC_INVALID_OPERATION ;
# endif
# ifdef ETXTBSY
case ETXTBSY : return DRFLAC_BUSY ;
# endif
# ifdef EFBIG
case EFBIG : return DRFLAC_TOO_BIG ;
# endif
# ifdef ENOSPC
case ENOSPC : return DRFLAC_NO_SPACE ;
# endif
# ifdef ESPIPE
case ESPIPE : return DRFLAC_BAD_SEEK ;
# endif
# ifdef EROFS
case EROFS : return DRFLAC_ACCESS_DENIED ;
# endif
# ifdef EMLINK
case EMLINK : return DRFLAC_TOO_MANY_LINKS ;
# endif
# ifdef EPIPE
case EPIPE : return DRFLAC_BAD_PIPE ;
# endif
# ifdef EDOM
case EDOM : return DRFLAC_OUT_OF_RANGE ;
# endif
# ifdef ERANGE
case ERANGE : return DRFLAC_OUT_OF_RANGE ;
# endif
# ifdef EDEADLK
case EDEADLK : return DRFLAC_DEADLOCK ;
# endif
# ifdef ENAMETOOLONG
case ENAMETOOLONG : return DRFLAC_PATH_TOO_LONG ;
# endif
# ifdef ENOLCK
case ENOLCK : return DRFLAC_ERROR ;
# endif
# ifdef ENOSYS
case ENOSYS : return DRFLAC_NOT_IMPLEMENTED ;
# endif
# ifdef ENOTEMPTY
case ENOTEMPTY : return DRFLAC_DIRECTORY_NOT_EMPTY ;
# endif
# ifdef ELOOP
case ELOOP : return DRFLAC_TOO_MANY_LINKS ;
# endif
# ifdef ENOMSG
case ENOMSG : return DRFLAC_NO_MESSAGE ;
# endif
# ifdef EIDRM
case EIDRM : return DRFLAC_ERROR ;
# endif
# ifdef ECHRNG
case ECHRNG : return DRFLAC_ERROR ;
# endif
# ifdef EL2NSYNC
case EL2NSYNC : return DRFLAC_ERROR ;
# endif
# ifdef EL3HLT
case EL3HLT : return DRFLAC_ERROR ;
# endif
# ifdef EL3RST
case EL3RST : return DRFLAC_ERROR ;
# endif
# ifdef ELNRNG
case ELNRNG : return DRFLAC_OUT_OF_RANGE ;
# endif
# ifdef EUNATCH
case EUNATCH : return DRFLAC_ERROR ;
# endif
# ifdef ENOCSI
case ENOCSI : return DRFLAC_ERROR ;
# endif
# ifdef EL2HLT
case EL2HLT : return DRFLAC_ERROR ;
# endif
# ifdef EBADE
case EBADE : return DRFLAC_ERROR ;
# endif
# ifdef EBADR
case EBADR : return DRFLAC_ERROR ;
# endif
# ifdef EXFULL
case EXFULL : return DRFLAC_ERROR ;
# endif
# ifdef ENOANO
case ENOANO : return DRFLAC_ERROR ;
# endif
# ifdef EBADRQC
case EBADRQC : return DRFLAC_ERROR ;
# endif
# ifdef EBADSLT
case EBADSLT : return DRFLAC_ERROR ;
# endif
# ifdef EBFONT
case EBFONT : return DRFLAC_INVALID_FILE ;
# endif
# ifdef ENOSTR
case ENOSTR : return DRFLAC_ERROR ;
# endif
# ifdef ENODATA
case ENODATA : return DRFLAC_NO_DATA_AVAILABLE ;
# endif
# ifdef ETIME
case ETIME : return DRFLAC_TIMEOUT ;
# endif
# ifdef ENOSR
case ENOSR : return DRFLAC_NO_DATA_AVAILABLE ;
# endif
# ifdef ENONET
case ENONET : return DRFLAC_NO_NETWORK ;
# endif
# ifdef ENOPKG
case ENOPKG : return DRFLAC_ERROR ;
# endif
# ifdef EREMOTE
case EREMOTE : return DRFLAC_ERROR ;
# endif
# ifdef ENOLINK
case ENOLINK : return DRFLAC_ERROR ;
# endif
# ifdef EADV
case EADV : return DRFLAC_ERROR ;
# endif
# ifdef ESRMNT
case ESRMNT : return DRFLAC_ERROR ;
# endif
# ifdef ECOMM
case ECOMM : return DRFLAC_ERROR ;
# endif
# ifdef EPROTO
case EPROTO : return DRFLAC_ERROR ;
# endif
# ifdef EMULTIHOP
case EMULTIHOP : return DRFLAC_ERROR ;
# endif
# ifdef EDOTDOT
case EDOTDOT : return DRFLAC_ERROR ;
# endif
# ifdef EBADMSG
case EBADMSG : return DRFLAC_BAD_MESSAGE ;
# endif
# ifdef EOVERFLOW
case EOVERFLOW : return DRFLAC_TOO_BIG ;
# endif
# ifdef ENOTUNIQ
case ENOTUNIQ : return DRFLAC_NOT_UNIQUE ;
# endif
# ifdef EBADFD
case EBADFD : return DRFLAC_ERROR ;
# endif
# ifdef EREMCHG
case EREMCHG : return DRFLAC_ERROR ;
# endif
# ifdef ELIBACC
case ELIBACC : return DRFLAC_ACCESS_DENIED ;
# endif
# ifdef ELIBBAD
case ELIBBAD : return DRFLAC_INVALID_FILE ;
# endif
# ifdef ELIBSCN
case ELIBSCN : return DRFLAC_INVALID_FILE ;
# endif
# ifdef ELIBMAX
case ELIBMAX : return DRFLAC_ERROR ;
# endif
# ifdef ELIBEXEC
case ELIBEXEC : return DRFLAC_ERROR ;
# endif
# ifdef EILSEQ
case EILSEQ : return DRFLAC_INVALID_DATA ;
# endif
# ifdef ERESTART
case ERESTART : return DRFLAC_ERROR ;
# endif
# ifdef ESTRPIPE
case ESTRPIPE : return DRFLAC_ERROR ;
# endif
# ifdef EUSERS
case EUSERS : return DRFLAC_ERROR ;
# endif
# ifdef ENOTSOCK
case ENOTSOCK : return DRFLAC_NOT_SOCKET ;
# endif
# ifdef EDESTADDRREQ
case EDESTADDRREQ : return DRFLAC_NO_ADDRESS ;
# endif
# ifdef EMSGSIZE
case EMSGSIZE : return DRFLAC_TOO_BIG ;
# endif
# ifdef EPROTOTYPE
case EPROTOTYPE : return DRFLAC_BAD_PROTOCOL ;
# endif
# ifdef ENOPROTOOPT
case ENOPROTOOPT : return DRFLAC_PROTOCOL_UNAVAILABLE ;
# endif
# ifdef EPROTONOSUPPORT
case EPROTONOSUPPORT : return DRFLAC_PROTOCOL_NOT_SUPPORTED ;
# endif
# ifdef ESOCKTNOSUPPORT
case ESOCKTNOSUPPORT : return DRFLAC_SOCKET_NOT_SUPPORTED ;
# endif
# ifdef EOPNOTSUPP
case EOPNOTSUPP : return DRFLAC_INVALID_OPERATION ;
# endif
# ifdef EPFNOSUPPORT
case EPFNOSUPPORT : return DRFLAC_PROTOCOL_FAMILY_NOT_SUPPORTED ;
# endif
# ifdef EAFNOSUPPORT
case EAFNOSUPPORT : return DRFLAC_ADDRESS_FAMILY_NOT_SUPPORTED ;
# endif
# ifdef EADDRINUSE
case EADDRINUSE : return DRFLAC_ALREADY_IN_USE ;
# endif
# ifdef EADDRNOTAVAIL
case EADDRNOTAVAIL : return DRFLAC_ERROR ;
# endif
# ifdef ENETDOWN
case ENETDOWN : return DRFLAC_NO_NETWORK ;
# endif
# ifdef ENETUNREACH
case ENETUNREACH : return DRFLAC_NO_NETWORK ;
# endif
# ifdef ENETRESET
case ENETRESET : return DRFLAC_NO_NETWORK ;
# endif
# ifdef ECONNABORTED
case ECONNABORTED : return DRFLAC_NO_NETWORK ;
# endif
# ifdef ECONNRESET
case ECONNRESET : return DRFLAC_CONNECTION_RESET ;
# endif
# ifdef ENOBUFS
case ENOBUFS : return DRFLAC_NO_SPACE ;
# endif
# ifdef EISCONN
case EISCONN : return DRFLAC_ALREADY_CONNECTED ;
# endif
# ifdef ENOTCONN
case ENOTCONN : return DRFLAC_NOT_CONNECTED ;
# endif
# ifdef ESHUTDOWN
case ESHUTDOWN : return DRFLAC_ERROR ;
# endif
# ifdef ETOOMANYREFS
case ETOOMANYREFS : return DRFLAC_ERROR ;
# endif
# ifdef ETIMEDOUT
case ETIMEDOUT : return DRFLAC_TIMEOUT ;
# endif
# ifdef ECONNREFUSED
case ECONNREFUSED : return DRFLAC_CONNECTION_REFUSED ;
# endif
# ifdef EHOSTDOWN
case EHOSTDOWN : return DRFLAC_NO_HOST ;
# endif
# ifdef EHOSTUNREACH
case EHOSTUNREACH : return DRFLAC_NO_HOST ;
# endif
# ifdef EALREADY
case EALREADY : return DRFLAC_IN_PROGRESS ;
# endif
# ifdef EINPROGRESS
case EINPROGRESS : return DRFLAC_IN_PROGRESS ;
# endif
# ifdef ESTALE
case ESTALE : return DRFLAC_INVALID_FILE ;
# endif
# ifdef EUCLEAN
case EUCLEAN : return DRFLAC_ERROR ;
# endif
# ifdef ENOTNAM
case ENOTNAM : return DRFLAC_ERROR ;
# endif
# ifdef ENAVAIL
case ENAVAIL : return DRFLAC_ERROR ;
# endif
# ifdef EISNAM
case EISNAM : return DRFLAC_ERROR ;
# endif
# ifdef EREMOTEIO
case EREMOTEIO : return DRFLAC_IO_ERROR ;
# endif
# ifdef EDQUOT
case EDQUOT : return DRFLAC_NO_SPACE ;
# endif
# ifdef ENOMEDIUM
case ENOMEDIUM : return DRFLAC_DOES_NOT_EXIST ;
# endif
# ifdef EMEDIUMTYPE
case EMEDIUMTYPE : return DRFLAC_ERROR ;
# endif
# ifdef ECANCELED
case ECANCELED : return DRFLAC_CANCELLED ;
# endif
# ifdef ENOKEY
case ENOKEY : return DRFLAC_ERROR ;
# endif
# ifdef EKEYEXPIRED
case EKEYEXPIRED : return DRFLAC_ERROR ;
# endif
# ifdef EKEYREVOKED
case EKEYREVOKED : return DRFLAC_ERROR ;
# endif
# ifdef EKEYREJECTED
case EKEYREJECTED : return DRFLAC_ERROR ;
# endif
# ifdef EOWNERDEAD
case EOWNERDEAD : return DRFLAC_ERROR ;
# endif
# ifdef ENOTRECOVERABLE
case ENOTRECOVERABLE : return DRFLAC_ERROR ;
# endif
# ifdef ERFKILL
case ERFKILL : return DRFLAC_ERROR ;
# endif
# ifdef EHWPOISON
case EHWPOISON : return DRFLAC_ERROR ;
# endif
default : return DRFLAC_ERROR ;
}
}
static drflac_result drflac_fopen ( FILE * * ppFile , const char * pFilePath , const char * pOpenMode )
{
# if defined(_MSC_VER) && _MSC_VER >= 1400
errno_t err ;
# endif
if ( ppFile ! = NULL ) {
* ppFile = NULL ; /* Safety. */
}
if ( pFilePath = = NULL | | pOpenMode = = NULL | | ppFile = = NULL ) {
return DRFLAC_INVALID_ARGS ;
}
# if defined(_MSC_VER) && _MSC_VER >= 1400
err = fopen_s ( ppFile , pFilePath , pOpenMode ) ;
if ( err ! = 0 ) {
return drflac_result_from_errno ( err ) ;
}
# else
# if defined(_WIN32) || defined(__APPLE__)
* ppFile = fopen ( pFilePath , pOpenMode ) ;
# else
# if defined(_FILE_OFFSET_BITS) && _FILE_OFFSET_BITS == 64 && defined(_LARGEFILE64_SOURCE)
* ppFile = fopen64 ( pFilePath , pOpenMode ) ;
# else
* ppFile = fopen ( pFilePath , pOpenMode ) ;
# endif
# endif
if ( * ppFile = = NULL ) {
drflac_result result = drflac_result_from_errno ( errno ) ;
if ( result = = DRFLAC_SUCCESS ) {
result = DRFLAC_ERROR ; /* Just a safety check to make sure we never ever return success when pFile == NULL. */
}
return result ;
}
# endif
return DRFLAC_SUCCESS ;
}
/*
_wfopen ( ) isn ' t always available in all compilation environments .
* Windows only .
* MSVC seems to support it universally as far back as VC6 from what I can tell ( haven ' t checked further back ) .
* MinGW - 64 ( both 32 - and 64 - bit ) seems to support it .
* MinGW wraps it in ! defined ( __STRICT_ANSI__ ) .
* OpenWatcom wraps it in ! defined ( _NO_EXT_KEYS ) .
This can be reviewed as compatibility issues arise . The preference is to use _wfopen_s ( ) and _wfopen ( ) as opposed to the wcsrtombs ( )
fallback , so if you notice your compiler not detecting this properly I ' m happy to look at adding support .
*/
# if defined(_WIN32)
# if defined(_MSC_VER) || defined(__MINGW64__) || (!defined(__STRICT_ANSI__) && !defined(_NO_EXT_KEYS))
# define DRFLAC_HAS_WFOPEN
# endif
# endif
static drflac_result drflac_wfopen ( FILE * * ppFile , const wchar_t * pFilePath , const wchar_t * pOpenMode , const drflac_allocation_callbacks * pAllocationCallbacks )
{
if ( ppFile ! = NULL ) {
* ppFile = NULL ; /* Safety. */
}
if ( pFilePath = = NULL | | pOpenMode = = NULL | | ppFile = = NULL ) {
return DRFLAC_INVALID_ARGS ;
}
# if defined(DRFLAC_HAS_WFOPEN)
{
/* Use _wfopen() on Windows. */
# if defined(_MSC_VER) && _MSC_VER >= 1400
errno_t err = _wfopen_s ( ppFile , pFilePath , pOpenMode ) ;
if ( err ! = 0 ) {
return drflac_result_from_errno ( err ) ;
}
# else
* ppFile = _wfopen ( pFilePath , pOpenMode ) ;
if ( * ppFile = = NULL ) {
return drflac_result_from_errno ( errno ) ;
}
# endif
( void ) pAllocationCallbacks ;
}
# else
/*
Use fopen ( ) on anything other than Windows . Requires a conversion . This is annoying because fopen ( ) is locale specific . The only real way I can
think of to do this is with wcsrtombs ( ) . Note that wcstombs ( ) is apparently not thread - safe because it uses a static global mbstate_t object for
maintaining state . I ' ve checked this with - std = c89 and it works , but if somebody get ' s a compiler error I ' ll look into improving compatibility .
*/
{
mbstate_t mbs ;
size_t lenMB ;
const wchar_t * pFilePathTemp = pFilePath ;
char * pFilePathMB = NULL ;
char pOpenModeMB [ 32 ] = { 0 } ;
/* Get the length first. */
DRFLAC_ZERO_OBJECT ( & mbs ) ;
lenMB = wcsrtombs ( NULL , & pFilePathTemp , 0 , & mbs ) ;
if ( lenMB = = ( size_t ) - 1 ) {
return drflac_result_from_errno ( errno ) ;
}
pFilePathMB = ( char * ) drflac__malloc_from_callbacks ( lenMB + 1 , pAllocationCallbacks ) ;
if ( pFilePathMB = = NULL ) {
return DRFLAC_OUT_OF_MEMORY ;
}
pFilePathTemp = pFilePath ;
DRFLAC_ZERO_OBJECT ( & mbs ) ;
wcsrtombs ( pFilePathMB , & pFilePathTemp , lenMB + 1 , & mbs ) ;
/* The open mode should always consist of ASCII characters so we should be able to do a trivial conversion. */
{
size_t i = 0 ;
for ( ; ; ) {
if ( pOpenMode [ i ] = = 0 ) {
pOpenModeMB [ i ] = ' \0 ' ;
break ;
}
pOpenModeMB [ i ] = ( char ) pOpenMode [ i ] ;
i + = 1 ;
}
}
* ppFile = fopen ( pFilePathMB , pOpenModeMB ) ;
drflac__free_from_callbacks ( pFilePathMB , pAllocationCallbacks ) ;
}
if ( * ppFile = = NULL ) {
return DRFLAC_ERROR ;
}
# endif
return DRFLAC_SUCCESS ;
}
static size_t drflac__on_read_stdio ( void * pUserData , void * bufferOut , size_t bytesToRead )
{
return fread ( bufferOut , 1 , bytesToRead , ( FILE * ) pUserData ) ;
}
static drflac_bool32 drflac__on_seek_stdio ( void * pUserData , int offset , drflac_seek_origin origin )
{
DRFLAC_ASSERT ( offset > = 0 ) ; /* <-- Never seek backwards. */
return fseek ( ( FILE * ) pUserData , offset , ( origin = = drflac_seek_origin_current ) ? SEEK_CUR : SEEK_SET ) = = 0 ;
}
DRFLAC_API drflac * drflac_open_file ( const char * pFileName , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
FILE * pFile ;
if ( drflac_fopen ( & pFile , pFileName , " rb " ) ! = DRFLAC_SUCCESS ) {
return NULL ;
}
pFlac = drflac_open ( drflac__on_read_stdio , drflac__on_seek_stdio , ( void * ) pFile , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
fclose ( pFile ) ;
return NULL ;
}
return pFlac ;
}
DRFLAC_API drflac * drflac_open_file_w ( const wchar_t * pFileName , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
FILE * pFile ;
if ( drflac_wfopen ( & pFile , pFileName , L " rb " , pAllocationCallbacks ) ! = DRFLAC_SUCCESS ) {
return NULL ;
}
pFlac = drflac_open ( drflac__on_read_stdio , drflac__on_seek_stdio , ( void * ) pFile , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
fclose ( pFile ) ;
return NULL ;
}
return pFlac ;
}
DRFLAC_API drflac * drflac_open_file_with_metadata ( const char * pFileName , drflac_meta_proc onMeta , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
FILE * pFile ;
if ( drflac_fopen ( & pFile , pFileName , " rb " ) ! = DRFLAC_SUCCESS ) {
return NULL ;
}
pFlac = drflac_open_with_metadata_private ( drflac__on_read_stdio , drflac__on_seek_stdio , onMeta , drflac_container_unknown , ( void * ) pFile , pUserData , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
fclose ( pFile ) ;
return pFlac ;
}
return pFlac ;
}
DRFLAC_API drflac * drflac_open_file_with_metadata_w ( const wchar_t * pFileName , drflac_meta_proc onMeta , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
FILE * pFile ;
if ( drflac_wfopen ( & pFile , pFileName , L " rb " , pAllocationCallbacks ) ! = DRFLAC_SUCCESS ) {
return NULL ;
}
pFlac = drflac_open_with_metadata_private ( drflac__on_read_stdio , drflac__on_seek_stdio , onMeta , drflac_container_unknown , ( void * ) pFile , pUserData , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
fclose ( pFile ) ;
return pFlac ;
}
return pFlac ;
}
# endif /* DR_FLAC_NO_STDIO */
static size_t drflac__on_read_memory ( void * pUserData , void * bufferOut , size_t bytesToRead )
{
drflac__memory_stream * memoryStream = ( drflac__memory_stream * ) pUserData ;
size_t bytesRemaining ;
DRFLAC_ASSERT ( memoryStream ! = NULL ) ;
DRFLAC_ASSERT ( memoryStream - > dataSize > = memoryStream - > currentReadPos ) ;
bytesRemaining = memoryStream - > dataSize - memoryStream - > currentReadPos ;
if ( bytesToRead > bytesRemaining ) {
bytesToRead = bytesRemaining ;
}
if ( bytesToRead > 0 ) {
DRFLAC_COPY_MEMORY ( bufferOut , memoryStream - > data + memoryStream - > currentReadPos , bytesToRead ) ;
memoryStream - > currentReadPos + = bytesToRead ;
}
return bytesToRead ;
}
static drflac_bool32 drflac__on_seek_memory ( void * pUserData , int offset , drflac_seek_origin origin )
{
drflac__memory_stream * memoryStream = ( drflac__memory_stream * ) pUserData ;
DRFLAC_ASSERT ( memoryStream ! = NULL ) ;
DRFLAC_ASSERT ( offset > = 0 ) ; /* <-- Never seek backwards. */
if ( offset > ( drflac_int64 ) memoryStream - > dataSize ) {
return DRFLAC_FALSE ;
}
if ( origin = = drflac_seek_origin_current ) {
if ( memoryStream - > currentReadPos + offset < = memoryStream - > dataSize ) {
memoryStream - > currentReadPos + = offset ;
} else {
return DRFLAC_FALSE ; /* Trying to seek too far forward. */
}
} else {
if ( ( drflac_uint32 ) offset < = memoryStream - > dataSize ) {
memoryStream - > currentReadPos = offset ;
} else {
return DRFLAC_FALSE ; /* Trying to seek too far forward. */
}
}
return DRFLAC_TRUE ;
}
DRFLAC_API drflac * drflac_open_memory ( const void * pData , size_t dataSize , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac__memory_stream memoryStream ;
drflac * pFlac ;
memoryStream . data = ( const drflac_uint8 * ) pData ;
memoryStream . dataSize = dataSize ;
memoryStream . currentReadPos = 0 ;
pFlac = drflac_open ( drflac__on_read_memory , drflac__on_seek_memory , & memoryStream , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
pFlac - > memoryStream = memoryStream ;
/* This is an awful hack... */
# ifndef DR_FLAC_NO_OGG
if ( pFlac - > container = = drflac_container_ogg )
{
drflac_oggbs * oggbs = ( drflac_oggbs * ) pFlac - > _oggbs ;
oggbs - > pUserData = & pFlac - > memoryStream ;
}
else
# endif
{
pFlac - > bs . pUserData = & pFlac - > memoryStream ;
}
return pFlac ;
}
DRFLAC_API drflac * drflac_open_memory_with_metadata ( const void * pData , size_t dataSize , drflac_meta_proc onMeta , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac__memory_stream memoryStream ;
drflac * pFlac ;
memoryStream . data = ( const drflac_uint8 * ) pData ;
memoryStream . dataSize = dataSize ;
memoryStream . currentReadPos = 0 ;
pFlac = drflac_open_with_metadata_private ( drflac__on_read_memory , drflac__on_seek_memory , onMeta , drflac_container_unknown , & memoryStream , pUserData , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
pFlac - > memoryStream = memoryStream ;
/* This is an awful hack... */
# ifndef DR_FLAC_NO_OGG
if ( pFlac - > container = = drflac_container_ogg )
{
drflac_oggbs * oggbs = ( drflac_oggbs * ) pFlac - > _oggbs ;
oggbs - > pUserData = & pFlac - > memoryStream ;
}
else
# endif
{
pFlac - > bs . pUserData = & pFlac - > memoryStream ;
}
return pFlac ;
}
DRFLAC_API drflac * drflac_open ( drflac_read_proc onRead , drflac_seek_proc onSeek , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks )
{
return drflac_open_with_metadata_private ( onRead , onSeek , NULL , drflac_container_unknown , pUserData , pUserData , pAllocationCallbacks ) ;
}
DRFLAC_API drflac * drflac_open_relaxed ( drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_container container , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks )
{
return drflac_open_with_metadata_private ( onRead , onSeek , NULL , container , pUserData , pUserData , pAllocationCallbacks ) ;
}
DRFLAC_API drflac * drflac_open_with_metadata ( drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks )
{
return drflac_open_with_metadata_private ( onRead , onSeek , onMeta , drflac_container_unknown , pUserData , pUserData , pAllocationCallbacks ) ;
}
DRFLAC_API drflac * drflac_open_with_metadata_relaxed ( drflac_read_proc onRead , drflac_seek_proc onSeek , drflac_meta_proc onMeta , drflac_container container , void * pUserData , const drflac_allocation_callbacks * pAllocationCallbacks )
{
return drflac_open_with_metadata_private ( onRead , onSeek , onMeta , container , pUserData , pUserData , pAllocationCallbacks ) ;
}
DRFLAC_API void drflac_close ( drflac * pFlac )
{
if ( pFlac = = NULL ) {
return ;
}
# ifndef DR_FLAC_NO_STDIO
/*
If we opened the file with drflac_open_file ( ) we will want to close the file handle . We can know whether or not drflac_open_file ( )
was used by looking at the callbacks .
*/
if ( pFlac - > bs . onRead = = drflac__on_read_stdio ) {
fclose ( ( FILE * ) pFlac - > bs . pUserData ) ;
}
# ifndef DR_FLAC_NO_OGG
/* Need to clean up Ogg streams a bit differently due to the way the bit streaming is chained. */
if ( pFlac - > container = = drflac_container_ogg ) {
drflac_oggbs * oggbs = ( drflac_oggbs * ) pFlac - > _oggbs ;
DRFLAC_ASSERT ( pFlac - > bs . onRead = = drflac__on_read_ogg ) ;
if ( oggbs - > onRead = = drflac__on_read_stdio ) {
fclose ( ( FILE * ) oggbs - > pUserData ) ;
}
}
# endif
# endif
drflac__free_from_callbacks ( pFlac , & pFlac - > allocationCallbacks ) ;
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_left_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
for ( i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 left = ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
drflac_uint32 side = ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
drflac_uint32 right = left - side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_left_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 left0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 left1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 left2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 left3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
drflac_uint32 right0 = left0 - side0 ;
drflac_uint32 right1 = left1 - side1 ;
drflac_uint32 right2 = left2 - side2 ;
drflac_uint32 right3 = left3 - side3 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) left0 ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) right0 ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) left1 ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) right1 ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) left2 ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) right2 ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) left3 ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) right3 ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_left_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i left = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
__m128i side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
__m128i right = _mm_sub_epi32 ( left , side ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 0 ) , _mm_unpacklo_epi32 ( left , right ) ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 4 ) , _mm_unpackhi_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_left_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
int32x4_t shift0_4 ;
int32x4_t shift1_4 ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
shift0_4 = vdupq_n_s32 ( shift0 ) ;
shift1_4 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t left ;
uint32x4_t side ;
uint32x4_t right ;
left = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift0_4 ) ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift1_4 ) ;
right = vsubq_u32 ( left , side ) ;
drflac__vst2q_u32 ( ( drflac_uint32 * ) pOutputSamples + i * 8 , vzipq_u32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_left_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s32__decode_left_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s32__decode_left_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_s32__decode_left_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_s32__decode_left_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_right_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
for ( i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 side = ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
drflac_uint32 right = ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
drflac_uint32 left = right + side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_right_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 side0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 side1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 side2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 side3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 right0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 right1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 right2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 right3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
drflac_uint32 left0 = right0 + side0 ;
drflac_uint32 left1 = right1 + side1 ;
drflac_uint32 left2 = right2 + side2 ;
drflac_uint32 left3 = right3 + side3 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) left0 ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) right0 ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) left1 ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) right1 ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) left2 ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) right2 ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) left3 ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) right3 ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_right_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
__m128i right = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
__m128i left = _mm_add_epi32 ( right , side ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 0 ) , _mm_unpacklo_epi32 ( left , right ) ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 4 ) , _mm_unpackhi_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_right_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
int32x4_t shift0_4 ;
int32x4_t shift1_4 ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
shift0_4 = vdupq_n_s32 ( shift0 ) ;
shift1_4 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t side ;
uint32x4_t right ;
uint32x4_t left ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift0_4 ) ;
right = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift1_4 ) ;
left = vaddq_u32 ( right , side ) ;
drflac__vst2q_u32 ( ( drflac_uint32 * ) pOutputSamples + i * 8 , vzipq_u32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_right_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s32__decode_right_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s32__decode_right_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_s32__decode_right_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_s32__decode_right_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_mid_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
for ( drflac_uint64 i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid + side ) > > 1 ) < < unusedBitsPerSample ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid - side ) > > 1 ) < < unusedBitsPerSample ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_mid_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_int32 shift = unusedBitsPerSample ;
if ( shift > 0 ) {
shift - = 1 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 temp0L ;
drflac_uint32 temp1L ;
drflac_uint32 temp2L ;
drflac_uint32 temp3L ;
drflac_uint32 temp0R ;
drflac_uint32 temp1R ;
drflac_uint32 temp2R ;
drflac_uint32 temp3R ;
drflac_uint32 mid0 = pInputSamples0U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid1 = pInputSamples0U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid2 = pInputSamples0U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid3 = pInputSamples0U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid0 = ( mid0 < < 1 ) | ( side0 & 0x01 ) ;
mid1 = ( mid1 < < 1 ) | ( side1 & 0x01 ) ;
mid2 = ( mid2 < < 1 ) | ( side2 & 0x01 ) ;
mid3 = ( mid3 < < 1 ) | ( side3 & 0x01 ) ;
temp0L = ( mid0 + side0 ) < < shift ;
temp1L = ( mid1 + side1 ) < < shift ;
temp2L = ( mid2 + side2 ) < < shift ;
temp3L = ( mid3 + side3 ) < < shift ;
temp0R = ( mid0 - side0 ) < < shift ;
temp1R = ( mid1 - side1 ) < < shift ;
temp2R = ( mid2 - side2 ) < < shift ;
temp3R = ( mid3 - side3 ) < < shift ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) temp0L ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) temp0R ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) temp1L ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) temp1R ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) temp2L ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) temp2R ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) temp3L ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) temp3R ;
}
} else {
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 temp0L ;
drflac_uint32 temp1L ;
drflac_uint32 temp2L ;
drflac_uint32 temp3L ;
drflac_uint32 temp0R ;
drflac_uint32 temp1R ;
drflac_uint32 temp2R ;
drflac_uint32 temp3R ;
drflac_uint32 mid0 = pInputSamples0U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid1 = pInputSamples0U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid2 = pInputSamples0U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid3 = pInputSamples0U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid0 = ( mid0 < < 1 ) | ( side0 & 0x01 ) ;
mid1 = ( mid1 < < 1 ) | ( side1 & 0x01 ) ;
mid2 = ( mid2 < < 1 ) | ( side2 & 0x01 ) ;
mid3 = ( mid3 < < 1 ) | ( side3 & 0x01 ) ;
temp0L = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid0 + side0 ) > > 1 ) ;
temp1L = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid1 + side1 ) > > 1 ) ;
temp2L = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid2 + side2 ) > > 1 ) ;
temp3L = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid3 + side3 ) > > 1 ) ;
temp0R = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid0 - side0 ) > > 1 ) ;
temp1R = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid1 - side1 ) > > 1 ) ;
temp2R = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid2 - side2 ) > > 1 ) ;
temp3R = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid3 - side3 ) > > 1 ) ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) temp0L ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) temp0R ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) temp1L ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) temp1R ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) temp2L ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) temp2R ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) temp3L ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) temp3R ;
}
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid + side ) > > 1 ) < < unusedBitsPerSample ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid - side ) > > 1 ) < < unusedBitsPerSample ) ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_mid_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_int32 shift = unusedBitsPerSample ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
if ( shift = = 0 ) {
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i mid ;
__m128i side ;
__m128i left ;
__m128i right ;
mid = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
mid = _mm_or_si128 ( _mm_slli_epi32 ( mid , 1 ) , _mm_and_si128 ( side , _mm_set1_epi32 ( 0x01 ) ) ) ;
left = _mm_srai_epi32 ( _mm_add_epi32 ( mid , side ) , 1 ) ;
right = _mm_srai_epi32 ( _mm_sub_epi32 ( mid , side ) , 1 ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 0 ) , _mm_unpacklo_epi32 ( left , right ) ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 4 ) , _mm_unpackhi_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( mid + side ) > > 1 ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( mid - side ) > > 1 ;
}
} else {
shift - = 1 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i mid ;
__m128i side ;
__m128i left ;
__m128i right ;
mid = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
mid = _mm_or_si128 ( _mm_slli_epi32 ( mid , 1 ) , _mm_and_si128 ( side , _mm_set1_epi32 ( 0x01 ) ) ) ;
left = _mm_slli_epi32 ( _mm_add_epi32 ( mid , side ) , shift ) ;
right = _mm_slli_epi32 ( _mm_sub_epi32 ( mid , side ) , shift ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 0 ) , _mm_unpacklo_epi32 ( left , right ) ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 4 ) , _mm_unpackhi_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( ( mid + side ) < < shift ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( ( mid - side ) < < shift ) ;
}
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_mid_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_int32 shift = unusedBitsPerSample ;
int32x4_t wbpsShift0_4 ; /* wbps = Wasted Bits Per Sample */
int32x4_t wbpsShift1_4 ; /* wbps = Wasted Bits Per Sample */
uint32x4_t one4 ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
wbpsShift0_4 = vdupq_n_s32 ( pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
wbpsShift1_4 = vdupq_n_s32 ( pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
one4 = vdupq_n_u32 ( 1 ) ;
if ( shift = = 0 ) {
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t mid ;
uint32x4_t side ;
int32x4_t left ;
int32x4_t right ;
mid = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , wbpsShift0_4 ) ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , wbpsShift1_4 ) ;
mid = vorrq_u32 ( vshlq_n_u32 ( mid , 1 ) , vandq_u32 ( side , one4 ) ) ;
left = vshrq_n_s32 ( vreinterpretq_s32_u32 ( vaddq_u32 ( mid , side ) ) , 1 ) ;
right = vshrq_n_s32 ( vreinterpretq_s32_u32 ( vsubq_u32 ( mid , side ) ) , 1 ) ;
drflac__vst2q_s32 ( pOutputSamples + i * 8 , vzipq_s32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( mid + side ) > > 1 ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( mid - side ) > > 1 ;
}
} else {
int32x4_t shift4 ;
shift - = 1 ;
shift4 = vdupq_n_s32 ( shift ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t mid ;
uint32x4_t side ;
int32x4_t left ;
int32x4_t right ;
mid = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , wbpsShift0_4 ) ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , wbpsShift1_4 ) ;
mid = vorrq_u32 ( vshlq_n_u32 ( mid , 1 ) , vandq_u32 ( side , one4 ) ) ;
left = vreinterpretq_s32_u32 ( vshlq_u32 ( vaddq_u32 ( mid , side ) , shift4 ) ) ;
right = vreinterpretq_s32_u32 ( vshlq_u32 ( vsubq_u32 ( mid , side ) , shift4 ) ) ;
drflac__vst2q_s32 ( pOutputSamples + i * 8 , vzipq_s32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( ( mid + side ) < < shift ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( ( mid - side ) < < shift ) ;
}
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_mid_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s32__decode_mid_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s32__decode_mid_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_s32__decode_mid_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_s32__decode_mid_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_independent_stereo__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
for ( drflac_uint64 i = 0 ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_independent_stereo__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 tempL0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 tempL1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 tempL2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 tempL3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 tempR0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 tempR1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 tempR2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 tempR3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) tempL0 ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) tempR0 ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) tempL1 ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) tempR1 ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) tempL2 ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) tempR2 ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) tempL3 ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) tempR3 ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( pInputSamples0U32 [ i ] < < shift0 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( pInputSamples1U32 [ i ] < < shift1 ) ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_independent_stereo__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i left = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
__m128i right = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 0 ) , _mm_unpacklo_epi32 ( left , right ) ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 + 4 ) , _mm_unpackhi_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( pInputSamples0U32 [ i ] < < shift0 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( pInputSamples1U32 [ i ] < < shift1 ) ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_independent_stereo__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
int32x4_t shift4_0 = vdupq_n_s32 ( shift0 ) ;
int32x4_t shift4_1 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
int32x4_t left ;
int32x4_t right ;
left = vreinterpretq_s32_u32 ( vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift4_0 ) ) ;
right = vreinterpretq_s32_u32 ( vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift4_1 ) ) ;
drflac__vst2q_s32 ( pOutputSamples + i * 8 , vzipq_s32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( pInputSamples0U32 [ i ] < < shift0 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( pInputSamples1U32 [ i ] < < shift1 ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s32__decode_independent_stereo ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int32 * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s32__decode_independent_stereo__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s32__decode_independent_stereo__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_s32__decode_independent_stereo__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_s32__decode_independent_stereo__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
DRFLAC_API drflac_uint64 drflac_read_pcm_frames_s32 ( drflac * pFlac , drflac_uint64 framesToRead , drflac_int32 * pBufferOut )
{
drflac_uint64 framesRead ;
drflac_uint32 unusedBitsPerSample ;
if ( pFlac = = NULL | | framesToRead = = 0 ) {
return 0 ;
}
if ( pBufferOut = = NULL ) {
return drflac__seek_forward_by_pcm_frames ( pFlac , framesToRead ) ;
}
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 32 ) ;
unusedBitsPerSample = 32 - pFlac - > bitsPerSample ;
framesRead = 0 ;
while ( framesToRead > 0 ) {
/* If we've run out of samples in this frame, go to the next. */
if ( pFlac - > currentFLACFrame . pcmFramesRemaining = = 0 ) {
if ( ! drflac__read_and_decode_next_flac_frame ( pFlac ) ) {
break ; /* Couldn't read the next frame, so just break from the loop and return. */
}
} else {
unsigned int channelCount = drflac__get_channel_count_from_channel_assignment ( pFlac - > currentFLACFrame . header . channelAssignment ) ;
drflac_uint64 iFirstPCMFrame = pFlac - > currentFLACFrame . header . blockSizeInPCMFrames - pFlac - > currentFLACFrame . pcmFramesRemaining ;
drflac_uint64 frameCountThisIteration = framesToRead ;
if ( frameCountThisIteration > pFlac - > currentFLACFrame . pcmFramesRemaining ) {
frameCountThisIteration = pFlac - > currentFLACFrame . pcmFramesRemaining ;
}
if ( channelCount = = 2 ) {
const drflac_int32 * pDecodedSamples0 = pFlac - > currentFLACFrame . subframes [ 0 ] . pSamplesS32 + iFirstPCMFrame ;
const drflac_int32 * pDecodedSamples1 = pFlac - > currentFLACFrame . subframes [ 1 ] . pSamplesS32 + iFirstPCMFrame ;
switch ( pFlac - > currentFLACFrame . header . channelAssignment )
{
case DRFLAC_CHANNEL_ASSIGNMENT_LEFT_SIDE :
{
drflac_read_pcm_frames_s32__decode_left_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_RIGHT_SIDE :
{
drflac_read_pcm_frames_s32__decode_right_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_MID_SIDE :
{
drflac_read_pcm_frames_s32__decode_mid_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_INDEPENDENT :
default :
{
drflac_read_pcm_frames_s32__decode_independent_stereo ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
}
} else {
/* Generic interleaving. */
drflac_uint64 i ;
for ( i = 0 ; i < frameCountThisIteration ; + + i ) {
unsigned int j ;
for ( j = 0 ; j < channelCount ; + + j ) {
pBufferOut [ ( i * channelCount ) + j ] = ( drflac_int32 ) ( ( drflac_uint32 ) ( pFlac - > currentFLACFrame . subframes [ j ] . pSamplesS32 [ iFirstPCMFrame + i ] ) < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ j ] . wastedBitsPerSample ) ) ;
}
}
}
framesRead + = frameCountThisIteration ;
pBufferOut + = frameCountThisIteration * channelCount ;
framesToRead - = frameCountThisIteration ;
pFlac - > currentPCMFrame + = frameCountThisIteration ;
pFlac - > currentFLACFrame . pcmFramesRemaining - = ( drflac_uint32 ) frameCountThisIteration ;
}
}
return framesRead ;
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_left_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
for ( i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 left = ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
drflac_uint32 side = ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
drflac_uint32 right = left - side ;
left > > = 16 ;
right > > = 16 ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) right ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_left_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 left0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 left1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 left2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 left3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
drflac_uint32 right0 = left0 - side0 ;
drflac_uint32 right1 = left1 - side1 ;
drflac_uint32 right2 = left2 - side2 ;
drflac_uint32 right3 = left3 - side3 ;
left0 > > = 16 ;
left1 > > = 16 ;
left2 > > = 16 ;
left3 > > = 16 ;
right0 > > = 16 ;
right1 > > = 16 ;
right2 > > = 16 ;
right3 > > = 16 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int16 ) left0 ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int16 ) right0 ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int16 ) left1 ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int16 ) right1 ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int16 ) left2 ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int16 ) right2 ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int16 ) left3 ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int16 ) right3 ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
left > > = 16 ;
right > > = 16 ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) right ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_left_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i left = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
__m128i side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
__m128i right = _mm_sub_epi32 ( left , side ) ;
left = _mm_srai_epi32 ( left , 16 ) ;
right = _mm_srai_epi32 ( right , 16 ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 ) , drflac__mm_packs_interleaved_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
left > > = 16 ;
right > > = 16 ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) right ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_left_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
int32x4_t shift0_4 ;
int32x4_t shift1_4 ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
shift0_4 = vdupq_n_s32 ( shift0 ) ;
shift1_4 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t left ;
uint32x4_t side ;
uint32x4_t right ;
left = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift0_4 ) ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift1_4 ) ;
right = vsubq_u32 ( left , side ) ;
left = vshrq_n_u32 ( left , 16 ) ;
right = vshrq_n_u32 ( right , 16 ) ;
drflac__vst2q_u16 ( ( drflac_uint16 * ) pOutputSamples + i * 8 , vzip_u16 ( vmovn_u32 ( left ) , vmovn_u32 ( right ) ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
left > > = 16 ;
right > > = 16 ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) right ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_left_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s16__decode_left_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s16__decode_left_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_s16__decode_left_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_s16__decode_left_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_right_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
for ( i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 side = ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
drflac_uint32 right = ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
drflac_uint32 left = right + side ;
left > > = 16 ;
right > > = 16 ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) right ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_right_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 side0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 side1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 side2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 side3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 right0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 right1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 right2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 right3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
drflac_uint32 left0 = right0 + side0 ;
drflac_uint32 left1 = right1 + side1 ;
drflac_uint32 left2 = right2 + side2 ;
drflac_uint32 left3 = right3 + side3 ;
left0 > > = 16 ;
left1 > > = 16 ;
left2 > > = 16 ;
left3 > > = 16 ;
right0 > > = 16 ;
right1 > > = 16 ;
right2 > > = 16 ;
right3 > > = 16 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int16 ) left0 ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int16 ) right0 ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int16 ) left1 ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int16 ) right1 ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int16 ) left2 ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int16 ) right2 ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int16 ) left3 ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int16 ) right3 ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
left > > = 16 ;
right > > = 16 ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) right ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_right_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
__m128i right = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
__m128i left = _mm_add_epi32 ( right , side ) ;
left = _mm_srai_epi32 ( left , 16 ) ;
right = _mm_srai_epi32 ( right , 16 ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 ) , drflac__mm_packs_interleaved_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
left > > = 16 ;
right > > = 16 ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) right ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_right_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
int32x4_t shift0_4 ;
int32x4_t shift1_4 ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
shift0_4 = vdupq_n_s32 ( shift0 ) ;
shift1_4 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t side ;
uint32x4_t right ;
uint32x4_t left ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift0_4 ) ;
right = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift1_4 ) ;
left = vaddq_u32 ( right , side ) ;
left = vshrq_n_u32 ( left , 16 ) ;
right = vshrq_n_u32 ( right , 16 ) ;
drflac__vst2q_u16 ( ( drflac_uint16 * ) pOutputSamples + i * 8 , vzip_u16 ( vmovn_u32 ( left ) , vmovn_u32 ( right ) ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
left > > = 16 ;
right > > = 16 ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) left ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) right ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_right_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s16__decode_right_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s16__decode_right_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_s16__decode_right_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_s16__decode_right_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_mid_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
for ( drflac_uint64 i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 mid = ( drflac_uint32 ) pInputSamples0 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = ( drflac_uint32 ) pInputSamples1 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid + side ) > > 1 ) < < unusedBitsPerSample ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid - side ) > > 1 ) < < unusedBitsPerSample ) > > 16 ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_mid_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift = unusedBitsPerSample ;
if ( shift > 0 ) {
shift - = 1 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 temp0L ;
drflac_uint32 temp1L ;
drflac_uint32 temp2L ;
drflac_uint32 temp3L ;
drflac_uint32 temp0R ;
drflac_uint32 temp1R ;
drflac_uint32 temp2R ;
drflac_uint32 temp3R ;
drflac_uint32 mid0 = pInputSamples0U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid1 = pInputSamples0U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid2 = pInputSamples0U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid3 = pInputSamples0U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid0 = ( mid0 < < 1 ) | ( side0 & 0x01 ) ;
mid1 = ( mid1 < < 1 ) | ( side1 & 0x01 ) ;
mid2 = ( mid2 < < 1 ) | ( side2 & 0x01 ) ;
mid3 = ( mid3 < < 1 ) | ( side3 & 0x01 ) ;
temp0L = ( mid0 + side0 ) < < shift ;
temp1L = ( mid1 + side1 ) < < shift ;
temp2L = ( mid2 + side2 ) < < shift ;
temp3L = ( mid3 + side3 ) < < shift ;
temp0R = ( mid0 - side0 ) < < shift ;
temp1R = ( mid1 - side1 ) < < shift ;
temp2R = ( mid2 - side2 ) < < shift ;
temp3R = ( mid3 - side3 ) < < shift ;
temp0L > > = 16 ;
temp1L > > = 16 ;
temp2L > > = 16 ;
temp3L > > = 16 ;
temp0R > > = 16 ;
temp1R > > = 16 ;
temp2R > > = 16 ;
temp3R > > = 16 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int16 ) temp0L ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int16 ) temp0R ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int16 ) temp1L ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int16 ) temp1R ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int16 ) temp2L ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int16 ) temp2R ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int16 ) temp3L ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int16 ) temp3R ;
}
} else {
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 temp0L ;
drflac_uint32 temp1L ;
drflac_uint32 temp2L ;
drflac_uint32 temp3L ;
drflac_uint32 temp0R ;
drflac_uint32 temp1R ;
drflac_uint32 temp2R ;
drflac_uint32 temp3R ;
drflac_uint32 mid0 = pInputSamples0U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid1 = pInputSamples0U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid2 = pInputSamples0U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid3 = pInputSamples0U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid0 = ( mid0 < < 1 ) | ( side0 & 0x01 ) ;
mid1 = ( mid1 < < 1 ) | ( side1 & 0x01 ) ;
mid2 = ( mid2 < < 1 ) | ( side2 & 0x01 ) ;
mid3 = ( mid3 < < 1 ) | ( side3 & 0x01 ) ;
temp0L = ( ( drflac_int32 ) ( mid0 + side0 ) > > 1 ) ;
temp1L = ( ( drflac_int32 ) ( mid1 + side1 ) > > 1 ) ;
temp2L = ( ( drflac_int32 ) ( mid2 + side2 ) > > 1 ) ;
temp3L = ( ( drflac_int32 ) ( mid3 + side3 ) > > 1 ) ;
temp0R = ( ( drflac_int32 ) ( mid0 - side0 ) > > 1 ) ;
temp1R = ( ( drflac_int32 ) ( mid1 - side1 ) > > 1 ) ;
temp2R = ( ( drflac_int32 ) ( mid2 - side2 ) > > 1 ) ;
temp3R = ( ( drflac_int32 ) ( mid3 - side3 ) > > 1 ) ;
temp0L > > = 16 ;
temp1L > > = 16 ;
temp2L > > = 16 ;
temp3L > > = 16 ;
temp0R > > = 16 ;
temp1R > > = 16 ;
temp2R > > = 16 ;
temp3R > > = 16 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int16 ) temp0L ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int16 ) temp0R ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int16 ) temp1L ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int16 ) temp1R ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int16 ) temp2L ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int16 ) temp2R ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int16 ) temp3L ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int16 ) temp3R ;
}
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid + side ) > > 1 ) < < unusedBitsPerSample ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid - side ) > > 1 ) < < unusedBitsPerSample ) > > 16 ) ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_mid_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift = unusedBitsPerSample ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
if ( shift = = 0 ) {
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i mid ;
__m128i side ;
__m128i left ;
__m128i right ;
mid = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
mid = _mm_or_si128 ( _mm_slli_epi32 ( mid , 1 ) , _mm_and_si128 ( side , _mm_set1_epi32 ( 0x01 ) ) ) ;
left = _mm_srai_epi32 ( _mm_add_epi32 ( mid , side ) , 1 ) ;
right = _mm_srai_epi32 ( _mm_sub_epi32 ( mid , side ) , 1 ) ;
left = _mm_srai_epi32 ( left , 16 ) ;
right = _mm_srai_epi32 ( right , 16 ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 ) , drflac__mm_packs_interleaved_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( ( drflac_int32 ) ( mid + side ) > > 1 ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( ( drflac_int32 ) ( mid - side ) > > 1 ) > > 16 ) ;
}
} else {
shift - = 1 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i mid ;
__m128i side ;
__m128i left ;
__m128i right ;
mid = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
mid = _mm_or_si128 ( _mm_slli_epi32 ( mid , 1 ) , _mm_and_si128 ( side , _mm_set1_epi32 ( 0x01 ) ) ) ;
left = _mm_slli_epi32 ( _mm_add_epi32 ( mid , side ) , shift ) ;
right = _mm_slli_epi32 ( _mm_sub_epi32 ( mid , side ) , shift ) ;
left = _mm_srai_epi32 ( left , 16 ) ;
right = _mm_srai_epi32 ( right , 16 ) ;
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 ) , drflac__mm_packs_interleaved_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( ( mid + side ) < < shift ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( ( mid - side ) < < shift ) > > 16 ) ;
}
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_mid_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift = unusedBitsPerSample ;
int32x4_t wbpsShift0_4 ; /* wbps = Wasted Bits Per Sample */
int32x4_t wbpsShift1_4 ; /* wbps = Wasted Bits Per Sample */
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
wbpsShift0_4 = vdupq_n_s32 ( pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
wbpsShift1_4 = vdupq_n_s32 ( pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
if ( shift = = 0 ) {
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t mid ;
uint32x4_t side ;
int32x4_t left ;
int32x4_t right ;
mid = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , wbpsShift0_4 ) ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , wbpsShift1_4 ) ;
mid = vorrq_u32 ( vshlq_n_u32 ( mid , 1 ) , vandq_u32 ( side , vdupq_n_u32 ( 1 ) ) ) ;
left = vshrq_n_s32 ( vreinterpretq_s32_u32 ( vaddq_u32 ( mid , side ) ) , 1 ) ;
right = vshrq_n_s32 ( vreinterpretq_s32_u32 ( vsubq_u32 ( mid , side ) ) , 1 ) ;
left = vshrq_n_s32 ( left , 16 ) ;
right = vshrq_n_s32 ( right , 16 ) ;
drflac__vst2q_s16 ( pOutputSamples + i * 8 , vzip_s16 ( vmovn_s32 ( left ) , vmovn_s32 ( right ) ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( ( drflac_int32 ) ( mid + side ) > > 1 ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( ( drflac_int32 ) ( mid - side ) > > 1 ) > > 16 ) ;
}
} else {
int32x4_t shift4 ;
shift - = 1 ;
shift4 = vdupq_n_s32 ( shift ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t mid ;
uint32x4_t side ;
int32x4_t left ;
int32x4_t right ;
mid = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , wbpsShift0_4 ) ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , wbpsShift1_4 ) ;
mid = vorrq_u32 ( vshlq_n_u32 ( mid , 1 ) , vandq_u32 ( side , vdupq_n_u32 ( 1 ) ) ) ;
left = vreinterpretq_s32_u32 ( vshlq_u32 ( vaddq_u32 ( mid , side ) , shift4 ) ) ;
right = vreinterpretq_s32_u32 ( vshlq_u32 ( vsubq_u32 ( mid , side ) , shift4 ) ) ;
left = vshrq_n_s32 ( left , 16 ) ;
right = vshrq_n_s32 ( right , 16 ) ;
drflac__vst2q_s16 ( pOutputSamples + i * 8 , vzip_s16 ( vmovn_s32 ( left ) , vmovn_s32 ( right ) ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( ( mid + side ) < < shift ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( ( mid - side ) < < shift ) > > 16 ) ;
}
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_mid_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s16__decode_mid_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s16__decode_mid_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_s16__decode_mid_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_s16__decode_mid_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_independent_stereo__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
for ( drflac_uint64 i = 0 ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( drflac_int32 ) ( ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( drflac_int32 ) ( ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ) > > 16 ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_independent_stereo__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 tempL0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 tempL1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 tempL2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 tempL3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 tempR0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 tempR1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 tempR2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 tempR3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
tempL0 > > = 16 ;
tempL1 > > = 16 ;
tempL2 > > = 16 ;
tempL3 > > = 16 ;
tempR0 > > = 16 ;
tempR1 > > = 16 ;
tempR2 > > = 16 ;
tempR3 > > = 16 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int16 ) tempL0 ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int16 ) tempR0 ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int16 ) tempL1 ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int16 ) tempR1 ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int16 ) tempL2 ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int16 ) tempR2 ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int16 ) tempL3 ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int16 ) tempR3 ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( pInputSamples0U32 [ i ] < < shift0 ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( pInputSamples1U32 [ i ] < < shift1 ) > > 16 ) ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_independent_stereo__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i left = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
__m128i right = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
left = _mm_srai_epi32 ( left , 16 ) ;
right = _mm_srai_epi32 ( right , 16 ) ;
/* At this point we have results. We can now pack and interleave these into a single __m128i object and then store the in the output buffer. */
_mm_storeu_si128 ( ( __m128i * ) ( pOutputSamples + i * 8 ) , drflac__mm_packs_interleaved_epi32 ( left , right ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( pInputSamples0U32 [ i ] < < shift0 ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( pInputSamples1U32 [ i ] < < shift1 ) > > 16 ) ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_independent_stereo__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
int32x4_t shift0_4 = vdupq_n_s32 ( shift0 ) ;
int32x4_t shift1_4 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
int32x4_t left ;
int32x4_t right ;
left = vreinterpretq_s32_u32 ( vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift0_4 ) ) ;
right = vreinterpretq_s32_u32 ( vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift1_4 ) ) ;
left = vshrq_n_s32 ( left , 16 ) ;
right = vshrq_n_s32 ( right , 16 ) ;
drflac__vst2q_s16 ( pOutputSamples + i * 8 , vzip_s16 ( vmovn_s32 ( left ) , vmovn_s32 ( right ) ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int16 ) ( ( pInputSamples0U32 [ i ] < < shift0 ) > > 16 ) ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int16 ) ( ( pInputSamples1U32 [ i ] < < shift1 ) > > 16 ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_s16__decode_independent_stereo ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , drflac_int16 * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s16__decode_independent_stereo__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_s16__decode_independent_stereo__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_s16__decode_independent_stereo__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_s16__decode_independent_stereo__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
DRFLAC_API drflac_uint64 drflac_read_pcm_frames_s16 ( drflac * pFlac , drflac_uint64 framesToRead , drflac_int16 * pBufferOut )
{
drflac_uint64 framesRead ;
drflac_uint32 unusedBitsPerSample ;
if ( pFlac = = NULL | | framesToRead = = 0 ) {
return 0 ;
}
if ( pBufferOut = = NULL ) {
return drflac__seek_forward_by_pcm_frames ( pFlac , framesToRead ) ;
}
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 32 ) ;
unusedBitsPerSample = 32 - pFlac - > bitsPerSample ;
framesRead = 0 ;
while ( framesToRead > 0 ) {
/* If we've run out of samples in this frame, go to the next. */
if ( pFlac - > currentFLACFrame . pcmFramesRemaining = = 0 ) {
if ( ! drflac__read_and_decode_next_flac_frame ( pFlac ) ) {
break ; /* Couldn't read the next frame, so just break from the loop and return. */
}
} else {
unsigned int channelCount = drflac__get_channel_count_from_channel_assignment ( pFlac - > currentFLACFrame . header . channelAssignment ) ;
drflac_uint64 iFirstPCMFrame = pFlac - > currentFLACFrame . header . blockSizeInPCMFrames - pFlac - > currentFLACFrame . pcmFramesRemaining ;
drflac_uint64 frameCountThisIteration = framesToRead ;
if ( frameCountThisIteration > pFlac - > currentFLACFrame . pcmFramesRemaining ) {
frameCountThisIteration = pFlac - > currentFLACFrame . pcmFramesRemaining ;
}
if ( channelCount = = 2 ) {
const drflac_int32 * pDecodedSamples0 = pFlac - > currentFLACFrame . subframes [ 0 ] . pSamplesS32 + iFirstPCMFrame ;
const drflac_int32 * pDecodedSamples1 = pFlac - > currentFLACFrame . subframes [ 1 ] . pSamplesS32 + iFirstPCMFrame ;
switch ( pFlac - > currentFLACFrame . header . channelAssignment )
{
case DRFLAC_CHANNEL_ASSIGNMENT_LEFT_SIDE :
{
drflac_read_pcm_frames_s16__decode_left_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_RIGHT_SIDE :
{
drflac_read_pcm_frames_s16__decode_right_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_MID_SIDE :
{
drflac_read_pcm_frames_s16__decode_mid_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_INDEPENDENT :
default :
{
drflac_read_pcm_frames_s16__decode_independent_stereo ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
}
} else {
/* Generic interleaving. */
drflac_uint64 i ;
for ( i = 0 ; i < frameCountThisIteration ; + + i ) {
unsigned int j ;
for ( j = 0 ; j < channelCount ; + + j ) {
drflac_int32 sampleS32 = ( drflac_int32 ) ( ( drflac_uint32 ) ( pFlac - > currentFLACFrame . subframes [ j ] . pSamplesS32 [ iFirstPCMFrame + i ] ) < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ j ] . wastedBitsPerSample ) ) ;
pBufferOut [ ( i * channelCount ) + j ] = ( drflac_int16 ) ( sampleS32 > > 16 ) ;
}
}
}
framesRead + = frameCountThisIteration ;
pBufferOut + = frameCountThisIteration * channelCount ;
framesToRead - = frameCountThisIteration ;
pFlac - > currentPCMFrame + = frameCountThisIteration ;
pFlac - > currentFLACFrame . pcmFramesRemaining - = ( drflac_uint32 ) frameCountThisIteration ;
}
}
return framesRead ;
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_left_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
for ( i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 left = ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
drflac_uint32 side = ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
drflac_uint32 right = left - side ;
pOutputSamples [ i * 2 + 0 ] = ( float ) ( ( drflac_int32 ) left / 2147483648.0 ) ;
pOutputSamples [ i * 2 + 1 ] = ( float ) ( ( drflac_int32 ) right / 2147483648.0 ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_left_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
float factor = 1 / 2147483648.0 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 left0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 left1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 left2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 left3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
drflac_uint32 right0 = left0 - side0 ;
drflac_uint32 right1 = left1 - side1 ;
drflac_uint32 right2 = left2 - side2 ;
drflac_uint32 right3 = left3 - side3 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) left0 * factor ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) right0 * factor ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) left1 * factor ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) right1 * factor ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) left2 * factor ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) right2 * factor ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) left3 * factor ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) right3 * factor ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left * factor ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right * factor ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_left_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) - 8 ;
drflac_uint32 shift1 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) - 8 ;
__m128 factor ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
factor = _mm_set1_ps ( 1.0f / 8388608.0f ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i left = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
__m128i side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
__m128i right = _mm_sub_epi32 ( left , side ) ;
__m128 leftf = _mm_mul_ps ( _mm_cvtepi32_ps ( left ) , factor ) ;
__m128 rightf = _mm_mul_ps ( _mm_cvtepi32_ps ( right ) , factor ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 0 , _mm_unpacklo_ps ( leftf , rightf ) ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 4 , _mm_unpackhi_ps ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left / 8388608.0f ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right / 8388608.0f ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_left_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) - 8 ;
drflac_uint32 shift1 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) - 8 ;
float32x4_t factor4 ;
int32x4_t shift0_4 ;
int32x4_t shift1_4 ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
factor4 = vdupq_n_f32 ( 1.0f / 8388608.0f ) ;
shift0_4 = vdupq_n_s32 ( shift0 ) ;
shift1_4 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t left ;
uint32x4_t side ;
uint32x4_t right ;
float32x4_t leftf ;
float32x4_t rightf ;
left = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift0_4 ) ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift1_4 ) ;
right = vsubq_u32 ( left , side ) ;
leftf = vmulq_f32 ( vcvtq_f32_s32 ( vreinterpretq_s32_u32 ( left ) ) , factor4 ) ;
rightf = vmulq_f32 ( vcvtq_f32_s32 ( vreinterpretq_s32_u32 ( right ) ) , factor4 ) ;
drflac__vst2q_f32 ( pOutputSamples + i * 8 , vzipq_f32 ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 left = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 right = left - side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left / 8388608.0f ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right / 8388608.0f ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_left_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_f32__decode_left_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_f32__decode_left_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_f32__decode_left_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_f32__decode_left_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_right_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
for ( i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 side = ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
drflac_uint32 right = ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
drflac_uint32 left = right + side ;
pOutputSamples [ i * 2 + 0 ] = ( float ) ( ( drflac_int32 ) left / 2147483648.0 ) ;
pOutputSamples [ i * 2 + 1 ] = ( float ) ( ( drflac_int32 ) right / 2147483648.0 ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_right_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
float factor = 1 / 2147483648.0 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 side0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 side1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 side2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 side3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 right0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 right1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 right2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 right3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
drflac_uint32 left0 = right0 + side0 ;
drflac_uint32 left1 = right1 + side1 ;
drflac_uint32 left2 = right2 + side2 ;
drflac_uint32 left3 = right3 + side3 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) left0 * factor ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) right0 * factor ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) left1 * factor ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) right1 * factor ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) left2 * factor ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) right2 * factor ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) left3 * factor ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) right3 * factor ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left * factor ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right * factor ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_right_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) - 8 ;
drflac_uint32 shift1 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) - 8 ;
__m128 factor ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
factor = _mm_set1_ps ( 1.0f / 8388608.0f ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
__m128i right = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
__m128i left = _mm_add_epi32 ( right , side ) ;
__m128 leftf = _mm_mul_ps ( _mm_cvtepi32_ps ( left ) , factor ) ;
__m128 rightf = _mm_mul_ps ( _mm_cvtepi32_ps ( right ) , factor ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 0 , _mm_unpacklo_ps ( leftf , rightf ) ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 4 , _mm_unpackhi_ps ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left / 8388608.0f ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right / 8388608.0f ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_right_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) - 8 ;
drflac_uint32 shift1 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) - 8 ;
float32x4_t factor4 ;
int32x4_t shift0_4 ;
int32x4_t shift1_4 ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
factor4 = vdupq_n_f32 ( 1.0f / 8388608.0f ) ;
shift0_4 = vdupq_n_s32 ( shift0 ) ;
shift1_4 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t side ;
uint32x4_t right ;
uint32x4_t left ;
float32x4_t leftf ;
float32x4_t rightf ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift0_4 ) ;
right = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift1_4 ) ;
left = vaddq_u32 ( right , side ) ;
leftf = vmulq_f32 ( vcvtq_f32_s32 ( vreinterpretq_s32_u32 ( left ) ) , factor4 ) ;
rightf = vmulq_f32 ( vcvtq_f32_s32 ( vreinterpretq_s32_u32 ( right ) ) , factor4 ) ;
drflac__vst2q_f32 ( pOutputSamples + i * 8 , vzipq_f32 ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 side = pInputSamples0U32 [ i ] < < shift0 ;
drflac_uint32 right = pInputSamples1U32 [ i ] < < shift1 ;
drflac_uint32 left = right + side ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) left / 8388608.0f ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) right / 8388608.0f ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_right_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_f32__decode_right_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_f32__decode_right_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_f32__decode_right_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_f32__decode_right_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_mid_side__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
for ( drflac_uint64 i = 0 ; i < frameCount ; + + i ) {
drflac_uint32 mid = ( drflac_uint32 ) pInputSamples0 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = ( drflac_uint32 ) pInputSamples1 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( float ) ( ( ( ( drflac_int32 ) ( mid + side ) > > 1 ) < < ( unusedBitsPerSample ) ) / 2147483648.0 ) ;
pOutputSamples [ i * 2 + 1 ] = ( float ) ( ( ( ( drflac_int32 ) ( mid - side ) > > 1 ) < < ( unusedBitsPerSample ) ) / 2147483648.0 ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_mid_side__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift = unusedBitsPerSample ;
float factor = 1 / 2147483648.0 ;
if ( shift > 0 ) {
shift - = 1 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 temp0L ;
drflac_uint32 temp1L ;
drflac_uint32 temp2L ;
drflac_uint32 temp3L ;
drflac_uint32 temp0R ;
drflac_uint32 temp1R ;
drflac_uint32 temp2R ;
drflac_uint32 temp3R ;
drflac_uint32 mid0 = pInputSamples0U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid1 = pInputSamples0U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid2 = pInputSamples0U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid3 = pInputSamples0U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid0 = ( mid0 < < 1 ) | ( side0 & 0x01 ) ;
mid1 = ( mid1 < < 1 ) | ( side1 & 0x01 ) ;
mid2 = ( mid2 < < 1 ) | ( side2 & 0x01 ) ;
mid3 = ( mid3 < < 1 ) | ( side3 & 0x01 ) ;
temp0L = ( mid0 + side0 ) < < shift ;
temp1L = ( mid1 + side1 ) < < shift ;
temp2L = ( mid2 + side2 ) < < shift ;
temp3L = ( mid3 + side3 ) < < shift ;
temp0R = ( mid0 - side0 ) < < shift ;
temp1R = ( mid1 - side1 ) < < shift ;
temp2R = ( mid2 - side2 ) < < shift ;
temp3R = ( mid3 - side3 ) < < shift ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) temp0L * factor ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) temp0R * factor ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) temp1L * factor ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) temp1R * factor ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) temp2L * factor ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) temp2R * factor ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) temp3L * factor ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) temp3R * factor ;
}
} else {
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 temp0L ;
drflac_uint32 temp1L ;
drflac_uint32 temp2L ;
drflac_uint32 temp3L ;
drflac_uint32 temp0R ;
drflac_uint32 temp1R ;
drflac_uint32 temp2R ;
drflac_uint32 temp3R ;
drflac_uint32 mid0 = pInputSamples0U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid1 = pInputSamples0U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid2 = pInputSamples0U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 mid3 = pInputSamples0U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side0 = pInputSamples1U32 [ i * 4 + 0 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side1 = pInputSamples1U32 [ i * 4 + 1 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side2 = pInputSamples1U32 [ i * 4 + 2 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
drflac_uint32 side3 = pInputSamples1U32 [ i * 4 + 3 ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid0 = ( mid0 < < 1 ) | ( side0 & 0x01 ) ;
mid1 = ( mid1 < < 1 ) | ( side1 & 0x01 ) ;
mid2 = ( mid2 < < 1 ) | ( side2 & 0x01 ) ;
mid3 = ( mid3 < < 1 ) | ( side3 & 0x01 ) ;
temp0L = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid0 + side0 ) > > 1 ) ;
temp1L = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid1 + side1 ) > > 1 ) ;
temp2L = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid2 + side2 ) > > 1 ) ;
temp3L = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid3 + side3 ) > > 1 ) ;
temp0R = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid0 - side0 ) > > 1 ) ;
temp1R = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid1 - side1 ) > > 1 ) ;
temp2R = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid2 - side2 ) > > 1 ) ;
temp3R = ( drflac_uint32 ) ( ( drflac_int32 ) ( mid3 - side3 ) > > 1 ) ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) temp0L * factor ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) temp0R * factor ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) temp1L * factor ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) temp1R * factor ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) temp2L * factor ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) temp2R * factor ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) temp3L * factor ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) temp3R * factor ;
}
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid + side ) > > 1 ) < < unusedBitsPerSample ) * factor ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( ( drflac_uint32 ) ( ( drflac_int32 ) ( mid - side ) > > 1 ) < < unusedBitsPerSample ) * factor ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_mid_side__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift = unusedBitsPerSample - 8 ;
float factor ;
__m128 factor128 ;
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
factor = 1.0f / 8388608.0f ;
factor128 = _mm_set1_ps ( factor ) ;
if ( shift = = 0 ) {
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i mid ;
__m128i side ;
__m128i tempL ;
__m128i tempR ;
__m128 leftf ;
__m128 rightf ;
mid = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
mid = _mm_or_si128 ( _mm_slli_epi32 ( mid , 1 ) , _mm_and_si128 ( side , _mm_set1_epi32 ( 0x01 ) ) ) ;
tempL = _mm_srai_epi32 ( _mm_add_epi32 ( mid , side ) , 1 ) ;
tempR = _mm_srai_epi32 ( _mm_sub_epi32 ( mid , side ) , 1 ) ;
leftf = _mm_mul_ps ( _mm_cvtepi32_ps ( tempL ) , factor128 ) ;
rightf = _mm_mul_ps ( _mm_cvtepi32_ps ( tempR ) , factor128 ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 0 , _mm_unpacklo_ps ( leftf , rightf ) ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 4 , _mm_unpackhi_ps ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( ( drflac_int32 ) ( mid + side ) > > 1 ) * factor ;
pOutputSamples [ i * 2 + 1 ] = ( ( drflac_int32 ) ( mid - side ) > > 1 ) * factor ;
}
} else {
shift - = 1 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i mid ;
__m128i side ;
__m128i tempL ;
__m128i tempR ;
__m128 leftf ;
__m128 rightf ;
mid = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
side = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
mid = _mm_or_si128 ( _mm_slli_epi32 ( mid , 1 ) , _mm_and_si128 ( side , _mm_set1_epi32 ( 0x01 ) ) ) ;
tempL = _mm_slli_epi32 ( _mm_add_epi32 ( mid , side ) , shift ) ;
tempR = _mm_slli_epi32 ( _mm_sub_epi32 ( mid , side ) , shift ) ;
leftf = _mm_mul_ps ( _mm_cvtepi32_ps ( tempL ) , factor128 ) ;
rightf = _mm_mul_ps ( _mm_cvtepi32_ps ( tempR ) , factor128 ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 0 , _mm_unpacklo_ps ( leftf , rightf ) ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 4 , _mm_unpackhi_ps ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( ( mid + side ) < < shift ) * factor ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( ( mid - side ) < < shift ) * factor ;
}
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_mid_side__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift = unusedBitsPerSample - 8 ;
float factor ;
float32x4_t factor4 ;
int32x4_t shift4 ;
int32x4_t wbps0_4 ; /* Wasted Bits Per Sample */
int32x4_t wbps1_4 ; /* Wasted Bits Per Sample */
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 24 ) ;
factor = 1.0f / 8388608.0f ;
factor4 = vdupq_n_f32 ( factor ) ;
wbps0_4 = vdupq_n_s32 ( pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ;
wbps1_4 = vdupq_n_s32 ( pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ;
if ( shift = = 0 ) {
for ( i = 0 ; i < frameCount4 ; + + i ) {
int32x4_t lefti ;
int32x4_t righti ;
float32x4_t leftf ;
float32x4_t rightf ;
uint32x4_t mid = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , wbps0_4 ) ;
uint32x4_t side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , wbps1_4 ) ;
mid = vorrq_u32 ( vshlq_n_u32 ( mid , 1 ) , vandq_u32 ( side , vdupq_n_u32 ( 1 ) ) ) ;
lefti = vshrq_n_s32 ( vreinterpretq_s32_u32 ( vaddq_u32 ( mid , side ) ) , 1 ) ;
righti = vshrq_n_s32 ( vreinterpretq_s32_u32 ( vsubq_u32 ( mid , side ) ) , 1 ) ;
leftf = vmulq_f32 ( vcvtq_f32_s32 ( lefti ) , factor4 ) ;
rightf = vmulq_f32 ( vcvtq_f32_s32 ( righti ) , factor4 ) ;
drflac__vst2q_f32 ( pOutputSamples + i * 8 , vzipq_f32 ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( ( drflac_int32 ) ( mid + side ) > > 1 ) * factor ;
pOutputSamples [ i * 2 + 1 ] = ( ( drflac_int32 ) ( mid - side ) > > 1 ) * factor ;
}
} else {
shift - = 1 ;
shift4 = vdupq_n_s32 ( shift ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
uint32x4_t mid ;
uint32x4_t side ;
int32x4_t lefti ;
int32x4_t righti ;
float32x4_t leftf ;
float32x4_t rightf ;
mid = vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , wbps0_4 ) ;
side = vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , wbps1_4 ) ;
mid = vorrq_u32 ( vshlq_n_u32 ( mid , 1 ) , vandq_u32 ( side , vdupq_n_u32 ( 1 ) ) ) ;
lefti = vreinterpretq_s32_u32 ( vshlq_u32 ( vaddq_u32 ( mid , side ) , shift4 ) ) ;
righti = vreinterpretq_s32_u32 ( vshlq_u32 ( vsubq_u32 ( mid , side ) , shift4 ) ) ;
leftf = vmulq_f32 ( vcvtq_f32_s32 ( lefti ) , factor4 ) ;
rightf = vmulq_f32 ( vcvtq_f32_s32 ( righti ) , factor4 ) ;
drflac__vst2q_f32 ( pOutputSamples + i * 8 , vzipq_f32 ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
drflac_uint32 mid = pInputSamples0U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 side = pInputSamples1U32 [ i ] < < pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
mid = ( mid < < 1 ) | ( side & 0x01 ) ;
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( ( mid + side ) < < shift ) * factor ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( ( mid - side ) < < shift ) * factor ;
}
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_mid_side ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_f32__decode_mid_side__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_f32__decode_mid_side__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_f32__decode_mid_side__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_f32__decode_mid_side__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
#if 0
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_independent_stereo__reference ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
for ( drflac_uint64 i = 0 ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( float ) ( ( drflac_int32 ) ( ( drflac_uint32 ) pInputSamples0 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) ) / 2147483648.0 ) ;
pOutputSamples [ i * 2 + 1 ] = ( float ) ( ( drflac_int32 ) ( ( drflac_uint32 ) pInputSamples1 [ i ] < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) ) / 2147483648.0 ) ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_independent_stereo__scalar ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ;
drflac_uint32 shift1 = unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ;
float factor = 1 / 2147483648.0 ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
drflac_uint32 tempL0 = pInputSamples0U32 [ i * 4 + 0 ] < < shift0 ;
drflac_uint32 tempL1 = pInputSamples0U32 [ i * 4 + 1 ] < < shift0 ;
drflac_uint32 tempL2 = pInputSamples0U32 [ i * 4 + 2 ] < < shift0 ;
drflac_uint32 tempL3 = pInputSamples0U32 [ i * 4 + 3 ] < < shift0 ;
drflac_uint32 tempR0 = pInputSamples1U32 [ i * 4 + 0 ] < < shift1 ;
drflac_uint32 tempR1 = pInputSamples1U32 [ i * 4 + 1 ] < < shift1 ;
drflac_uint32 tempR2 = pInputSamples1U32 [ i * 4 + 2 ] < < shift1 ;
drflac_uint32 tempR3 = pInputSamples1U32 [ i * 4 + 3 ] < < shift1 ;
pOutputSamples [ i * 8 + 0 ] = ( drflac_int32 ) tempL0 * factor ;
pOutputSamples [ i * 8 + 1 ] = ( drflac_int32 ) tempR0 * factor ;
pOutputSamples [ i * 8 + 2 ] = ( drflac_int32 ) tempL1 * factor ;
pOutputSamples [ i * 8 + 3 ] = ( drflac_int32 ) tempR1 * factor ;
pOutputSamples [ i * 8 + 4 ] = ( drflac_int32 ) tempL2 * factor ;
pOutputSamples [ i * 8 + 5 ] = ( drflac_int32 ) tempR2 * factor ;
pOutputSamples [ i * 8 + 6 ] = ( drflac_int32 ) tempL3 * factor ;
pOutputSamples [ i * 8 + 7 ] = ( drflac_int32 ) tempR3 * factor ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( pInputSamples0U32 [ i ] < < shift0 ) * factor ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( pInputSamples1U32 [ i ] < < shift1 ) * factor ;
}
}
# if defined(DRFLAC_SUPPORT_SSE2)
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_independent_stereo__sse2 ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) - 8 ;
drflac_uint32 shift1 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) - 8 ;
float factor = 1.0f / 8388608.0f ;
__m128 factor128 = _mm_set1_ps ( factor ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
__m128i lefti ;
__m128i righti ;
__m128 leftf ;
__m128 rightf ;
lefti = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples0 + i ) , shift0 ) ;
righti = _mm_slli_epi32 ( _mm_loadu_si128 ( ( const __m128i * ) pInputSamples1 + i ) , shift1 ) ;
leftf = _mm_mul_ps ( _mm_cvtepi32_ps ( lefti ) , factor128 ) ;
rightf = _mm_mul_ps ( _mm_cvtepi32_ps ( righti ) , factor128 ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 0 , _mm_unpacklo_ps ( leftf , rightf ) ) ;
_mm_storeu_ps ( pOutputSamples + i * 8 + 4 , _mm_unpackhi_ps ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( pInputSamples0U32 [ i ] < < shift0 ) * factor ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( pInputSamples1U32 [ i ] < < shift1 ) * factor ;
}
}
# endif
# if defined(DRFLAC_SUPPORT_NEON)
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_independent_stereo__neon ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
drflac_uint64 i ;
drflac_uint64 frameCount4 = frameCount > > 2 ;
const drflac_uint32 * pInputSamples0U32 = ( const drflac_uint32 * ) pInputSamples0 ;
const drflac_uint32 * pInputSamples1U32 = ( const drflac_uint32 * ) pInputSamples1 ;
drflac_uint32 shift0 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 0 ] . wastedBitsPerSample ) - 8 ;
drflac_uint32 shift1 = ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ 1 ] . wastedBitsPerSample ) - 8 ;
float factor = 1.0f / 8388608.0f ;
float32x4_t factor4 = vdupq_n_f32 ( factor ) ;
int32x4_t shift0_4 = vdupq_n_s32 ( shift0 ) ;
int32x4_t shift1_4 = vdupq_n_s32 ( shift1 ) ;
for ( i = 0 ; i < frameCount4 ; + + i ) {
int32x4_t lefti ;
int32x4_t righti ;
float32x4_t leftf ;
float32x4_t rightf ;
lefti = vreinterpretq_s32_u32 ( vshlq_u32 ( vld1q_u32 ( pInputSamples0U32 + i * 4 ) , shift0_4 ) ) ;
righti = vreinterpretq_s32_u32 ( vshlq_u32 ( vld1q_u32 ( pInputSamples1U32 + i * 4 ) , shift1_4 ) ) ;
leftf = vmulq_f32 ( vcvtq_f32_s32 ( lefti ) , factor4 ) ;
rightf = vmulq_f32 ( vcvtq_f32_s32 ( righti ) , factor4 ) ;
drflac__vst2q_f32 ( pOutputSamples + i * 8 , vzipq_f32 ( leftf , rightf ) ) ;
}
for ( i = ( frameCount4 < < 2 ) ; i < frameCount ; + + i ) {
pOutputSamples [ i * 2 + 0 ] = ( drflac_int32 ) ( pInputSamples0U32 [ i ] < < shift0 ) * factor ;
pOutputSamples [ i * 2 + 1 ] = ( drflac_int32 ) ( pInputSamples1U32 [ i ] < < shift1 ) * factor ;
}
}
# endif
static DRFLAC_INLINE void drflac_read_pcm_frames_f32__decode_independent_stereo ( drflac * pFlac , drflac_uint64 frameCount , drflac_uint32 unusedBitsPerSample , const drflac_int32 * pInputSamples0 , const drflac_int32 * pInputSamples1 , float * pOutputSamples )
{
# if defined(DRFLAC_SUPPORT_SSE2)
if ( drflac__gIsSSE2Supported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_f32__decode_independent_stereo__sse2 ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# elif defined(DRFLAC_SUPPORT_NEON)
if ( drflac__gIsNEONSupported & & pFlac - > bitsPerSample < = 24 ) {
drflac_read_pcm_frames_f32__decode_independent_stereo__neon ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
} else
# endif
{
/* Scalar fallback. */
#if 0
drflac_read_pcm_frames_f32__decode_independent_stereo__reference ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# else
drflac_read_pcm_frames_f32__decode_independent_stereo__scalar ( pFlac , frameCount , unusedBitsPerSample , pInputSamples0 , pInputSamples1 , pOutputSamples ) ;
# endif
}
}
DRFLAC_API drflac_uint64 drflac_read_pcm_frames_f32 ( drflac * pFlac , drflac_uint64 framesToRead , float * pBufferOut )
{
drflac_uint64 framesRead ;
drflac_uint32 unusedBitsPerSample ;
if ( pFlac = = NULL | | framesToRead = = 0 ) {
return 0 ;
}
if ( pBufferOut = = NULL ) {
return drflac__seek_forward_by_pcm_frames ( pFlac , framesToRead ) ;
}
DRFLAC_ASSERT ( pFlac - > bitsPerSample < = 32 ) ;
unusedBitsPerSample = 32 - pFlac - > bitsPerSample ;
framesRead = 0 ;
while ( framesToRead > 0 ) {
/* If we've run out of samples in this frame, go to the next. */
if ( pFlac - > currentFLACFrame . pcmFramesRemaining = = 0 ) {
if ( ! drflac__read_and_decode_next_flac_frame ( pFlac ) ) {
break ; /* Couldn't read the next frame, so just break from the loop and return. */
}
} else {
unsigned int channelCount = drflac__get_channel_count_from_channel_assignment ( pFlac - > currentFLACFrame . header . channelAssignment ) ;
drflac_uint64 iFirstPCMFrame = pFlac - > currentFLACFrame . header . blockSizeInPCMFrames - pFlac - > currentFLACFrame . pcmFramesRemaining ;
drflac_uint64 frameCountThisIteration = framesToRead ;
if ( frameCountThisIteration > pFlac - > currentFLACFrame . pcmFramesRemaining ) {
frameCountThisIteration = pFlac - > currentFLACFrame . pcmFramesRemaining ;
}
if ( channelCount = = 2 ) {
const drflac_int32 * pDecodedSamples0 = pFlac - > currentFLACFrame . subframes [ 0 ] . pSamplesS32 + iFirstPCMFrame ;
const drflac_int32 * pDecodedSamples1 = pFlac - > currentFLACFrame . subframes [ 1 ] . pSamplesS32 + iFirstPCMFrame ;
switch ( pFlac - > currentFLACFrame . header . channelAssignment )
{
case DRFLAC_CHANNEL_ASSIGNMENT_LEFT_SIDE :
{
drflac_read_pcm_frames_f32__decode_left_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_RIGHT_SIDE :
{
drflac_read_pcm_frames_f32__decode_right_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_MID_SIDE :
{
drflac_read_pcm_frames_f32__decode_mid_side ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
case DRFLAC_CHANNEL_ASSIGNMENT_INDEPENDENT :
default :
{
drflac_read_pcm_frames_f32__decode_independent_stereo ( pFlac , frameCountThisIteration , unusedBitsPerSample , pDecodedSamples0 , pDecodedSamples1 , pBufferOut ) ;
} break ;
}
} else {
/* Generic interleaving. */
drflac_uint64 i ;
for ( i = 0 ; i < frameCountThisIteration ; + + i ) {
unsigned int j ;
for ( j = 0 ; j < channelCount ; + + j ) {
drflac_int32 sampleS32 = ( drflac_int32 ) ( ( drflac_uint32 ) ( pFlac - > currentFLACFrame . subframes [ j ] . pSamplesS32 [ iFirstPCMFrame + i ] ) < < ( unusedBitsPerSample + pFlac - > currentFLACFrame . subframes [ j ] . wastedBitsPerSample ) ) ;
pBufferOut [ ( i * channelCount ) + j ] = ( float ) ( sampleS32 / 2147483648.0 ) ;
}
}
}
framesRead + = frameCountThisIteration ;
pBufferOut + = frameCountThisIteration * channelCount ;
framesToRead - = frameCountThisIteration ;
pFlac - > currentPCMFrame + = frameCountThisIteration ;
pFlac - > currentFLACFrame . pcmFramesRemaining - = ( unsigned int ) frameCountThisIteration ;
}
}
return framesRead ;
}
DRFLAC_API drflac_bool32 drflac_seek_to_pcm_frame ( drflac * pFlac , drflac_uint64 pcmFrameIndex )
{
if ( pFlac = = NULL ) {
return DRFLAC_FALSE ;
}
/* Don't do anything if we're already on the seek point. */
if ( pFlac - > currentPCMFrame = = pcmFrameIndex ) {
return DRFLAC_TRUE ;
}
/*
If we don ' t know where the first frame begins then we can ' t seek . This will happen when the STREAMINFO block was not present
when the decoder was opened .
*/
if ( pFlac - > firstFLACFramePosInBytes = = 0 ) {
return DRFLAC_FALSE ;
}
if ( pcmFrameIndex = = 0 ) {
pFlac - > currentPCMFrame = 0 ;
return drflac__seek_to_first_frame ( pFlac ) ;
} else {
drflac_bool32 wasSuccessful = DRFLAC_FALSE ;
drflac_uint64 originalPCMFrame = pFlac - > currentPCMFrame ;
/* Clamp the sample to the end. */
if ( pcmFrameIndex > pFlac - > totalPCMFrameCount ) {
pcmFrameIndex = pFlac - > totalPCMFrameCount ;
}
/* If the target sample and the current sample are in the same frame we just move the position forward. */
if ( pcmFrameIndex > pFlac - > currentPCMFrame ) {
/* Forward. */
drflac_uint32 offset = ( drflac_uint32 ) ( pcmFrameIndex - pFlac - > currentPCMFrame ) ;
if ( pFlac - > currentFLACFrame . pcmFramesRemaining > offset ) {
pFlac - > currentFLACFrame . pcmFramesRemaining - = offset ;
pFlac - > currentPCMFrame = pcmFrameIndex ;
return DRFLAC_TRUE ;
}
} else {
/* Backward. */
drflac_uint32 offsetAbs = ( drflac_uint32 ) ( pFlac - > currentPCMFrame - pcmFrameIndex ) ;
drflac_uint32 currentFLACFramePCMFrameCount = pFlac - > currentFLACFrame . header . blockSizeInPCMFrames ;
drflac_uint32 currentFLACFramePCMFramesConsumed = currentFLACFramePCMFrameCount - pFlac - > currentFLACFrame . pcmFramesRemaining ;
if ( currentFLACFramePCMFramesConsumed > offsetAbs ) {
pFlac - > currentFLACFrame . pcmFramesRemaining + = offsetAbs ;
pFlac - > currentPCMFrame = pcmFrameIndex ;
return DRFLAC_TRUE ;
}
}
/*
Different techniques depending on encapsulation . Using the native FLAC seektable with Ogg encapsulation is a bit awkward so
we ' ll instead use Ogg ' s natural seeking facility .
*/
# ifndef DR_FLAC_NO_OGG
if ( pFlac - > container = = drflac_container_ogg )
{
wasSuccessful = drflac_ogg__seek_to_pcm_frame ( pFlac , pcmFrameIndex ) ;
}
else
# endif
{
/* First try seeking via the seek table. If this fails, fall back to a brute force seek which is much slower. */
if ( /*!wasSuccessful && */ ! pFlac - > _noSeekTableSeek ) {
wasSuccessful = drflac__seek_to_pcm_frame__seek_table ( pFlac , pcmFrameIndex ) ;
}
# if !defined(DR_FLAC_NO_CRC)
/* Fall back to binary search if seek table seeking fails. This requires the length of the stream to be known. */
if ( ! wasSuccessful & & ! pFlac - > _noBinarySearchSeek & & pFlac - > totalPCMFrameCount > 0 ) {
wasSuccessful = drflac__seek_to_pcm_frame__binary_search ( pFlac , pcmFrameIndex ) ;
}
# endif
/* Fall back to brute force if all else fails. */
if ( ! wasSuccessful & & ! pFlac - > _noBruteForceSeek ) {
wasSuccessful = drflac__seek_to_pcm_frame__brute_force ( pFlac , pcmFrameIndex ) ;
}
}
if ( wasSuccessful ) {
pFlac - > currentPCMFrame = pcmFrameIndex ;
} else {
/* Seek failed. Try putting the decoder back to it's original state. */
if ( drflac_seek_to_pcm_frame ( pFlac , originalPCMFrame ) = = DRFLAC_FALSE ) {
/* Failed to seek back to the original PCM frame. Fall back to 0. */
drflac_seek_to_pcm_frame ( pFlac , 0 ) ;
}
}
return wasSuccessful ;
}
}
/* High Level APIs */
# if defined(SIZE_MAX)
# define DRFLAC_SIZE_MAX SIZE_MAX
# else
# if defined(DRFLAC_64BIT)
# define DRFLAC_SIZE_MAX ((drflac_uint64)0xFFFFFFFFFFFFFFFF)
# else
# define DRFLAC_SIZE_MAX 0xFFFFFFFF
# endif
# endif
/* Using a macro as the definition of the drflac__full_decode_and_close_*() API family. Sue me. */
# define DRFLAC_DEFINE_FULL_READ_AND_CLOSE(extension, type) \
static type * drflac__full_read_and_close_ # # extension ( drflac * pFlac , unsigned int * channelsOut , unsigned int * sampleRateOut , drflac_uint64 * totalPCMFrameCountOut ) \
{ \
type * pSampleData = NULL ; \
drflac_uint64 totalPCMFrameCount ; \
\
DRFLAC_ASSERT ( pFlac ! = NULL ) ; \
\
totalPCMFrameCount = pFlac - > totalPCMFrameCount ; \
\
if ( totalPCMFrameCount = = 0 ) { \
type buffer [ 4096 ] ; \
drflac_uint64 pcmFramesRead ; \
size_t sampleDataBufferSize = sizeof ( buffer ) ; \
\
pSampleData = ( type * ) drflac__malloc_from_callbacks ( sampleDataBufferSize , & pFlac - > allocationCallbacks ) ; \
if ( pSampleData = = NULL ) { \
goto on_error ; \
} \
\
while ( ( pcmFramesRead = ( drflac_uint64 ) drflac_read_pcm_frames_ # # extension ( pFlac , sizeof ( buffer ) / sizeof ( buffer [ 0 ] ) / pFlac - > channels , buffer ) ) > 0 ) { \
if ( ( ( totalPCMFrameCount + pcmFramesRead ) * pFlac - > channels * sizeof ( type ) ) > sampleDataBufferSize ) { \
type * pNewSampleData ; \
size_t newSampleDataBufferSize ; \
\
newSampleDataBufferSize = sampleDataBufferSize * 2 ; \
pNewSampleData = ( type * ) drflac__realloc_from_callbacks ( pSampleData , newSampleDataBufferSize , sampleDataBufferSize , & pFlac - > allocationCallbacks ) ; \
if ( pNewSampleData = = NULL ) { \
drflac__free_from_callbacks ( pSampleData , & pFlac - > allocationCallbacks ) ; \
goto on_error ; \
} \
\
sampleDataBufferSize = newSampleDataBufferSize ; \
pSampleData = pNewSampleData ; \
} \
\
DRFLAC_COPY_MEMORY ( pSampleData + ( totalPCMFrameCount * pFlac - > channels ) , buffer , ( size_t ) ( pcmFramesRead * pFlac - > channels * sizeof ( type ) ) ) ; \
totalPCMFrameCount + = pcmFramesRead ; \
} \
\
/* At this point everything should be decoded, but we just want to fill the unused part buffer with silence - need to \
protect those ears from random noise ! */ \
DRFLAC_ZERO_MEMORY ( pSampleData + ( totalPCMFrameCount * pFlac - > channels ) , ( size_t ) ( sampleDataBufferSize - totalPCMFrameCount * pFlac - > channels * sizeof ( type ) ) ) ; \
} else { \
drflac_uint64 dataSize = totalPCMFrameCount * pFlac - > channels * sizeof ( type ) ; \
if ( dataSize > ( drflac_uint64 ) DRFLAC_SIZE_MAX ) { \
goto on_error ; /* The decoded data is too big. */ \
} \
\
pSampleData = ( type * ) drflac__malloc_from_callbacks ( ( size_t ) dataSize , & pFlac - > allocationCallbacks ) ; /* <-- Safe cast as per the check above. */ \
if ( pSampleData = = NULL ) { \
goto on_error ; \
} \
\
totalPCMFrameCount = drflac_read_pcm_frames_ # # extension ( pFlac , pFlac - > totalPCMFrameCount , pSampleData ) ; \
} \
\
if ( sampleRateOut ) * sampleRateOut = pFlac - > sampleRate ; \
if ( channelsOut ) * channelsOut = pFlac - > channels ; \
if ( totalPCMFrameCountOut ) * totalPCMFrameCountOut = totalPCMFrameCount ; \
\
drflac_close ( pFlac ) ; \
return pSampleData ; \
\
on_error : \
drflac_close ( pFlac ) ; \
return NULL ; \
}
DRFLAC_DEFINE_FULL_READ_AND_CLOSE ( s32 , drflac_int32 )
DRFLAC_DEFINE_FULL_READ_AND_CLOSE ( s16 , drflac_int16 )
DRFLAC_DEFINE_FULL_READ_AND_CLOSE ( f32 , float )
DRFLAC_API drflac_int32 * drflac_open_and_read_pcm_frames_s32 ( drflac_read_proc onRead , drflac_seek_proc onSeek , void * pUserData , unsigned int * channelsOut , unsigned int * sampleRateOut , drflac_uint64 * totalPCMFrameCountOut , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( channelsOut ) {
* channelsOut = 0 ;
}
if ( sampleRateOut ) {
* sampleRateOut = 0 ;
}
if ( totalPCMFrameCountOut ) {
* totalPCMFrameCountOut = 0 ;
}
pFlac = drflac_open ( onRead , onSeek , pUserData , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_s32 ( pFlac , channelsOut , sampleRateOut , totalPCMFrameCountOut ) ;
}
DRFLAC_API drflac_int16 * drflac_open_and_read_pcm_frames_s16 ( drflac_read_proc onRead , drflac_seek_proc onSeek , void * pUserData , unsigned int * channelsOut , unsigned int * sampleRateOut , drflac_uint64 * totalPCMFrameCountOut , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( channelsOut ) {
* channelsOut = 0 ;
}
if ( sampleRateOut ) {
* sampleRateOut = 0 ;
}
if ( totalPCMFrameCountOut ) {
* totalPCMFrameCountOut = 0 ;
}
pFlac = drflac_open ( onRead , onSeek , pUserData , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_s16 ( pFlac , channelsOut , sampleRateOut , totalPCMFrameCountOut ) ;
}
DRFLAC_API float * drflac_open_and_read_pcm_frames_f32 ( drflac_read_proc onRead , drflac_seek_proc onSeek , void * pUserData , unsigned int * channelsOut , unsigned int * sampleRateOut , drflac_uint64 * totalPCMFrameCountOut , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( channelsOut ) {
* channelsOut = 0 ;
}
if ( sampleRateOut ) {
* sampleRateOut = 0 ;
}
if ( totalPCMFrameCountOut ) {
* totalPCMFrameCountOut = 0 ;
}
pFlac = drflac_open ( onRead , onSeek , pUserData , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_f32 ( pFlac , channelsOut , sampleRateOut , totalPCMFrameCountOut ) ;
}
# ifndef DR_FLAC_NO_STDIO
DRFLAC_API drflac_int32 * drflac_open_file_and_read_pcm_frames_s32 ( const char * filename , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( sampleRate ) {
* sampleRate = 0 ;
}
if ( channels ) {
* channels = 0 ;
}
if ( totalPCMFrameCount ) {
* totalPCMFrameCount = 0 ;
}
pFlac = drflac_open_file ( filename , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_s32 ( pFlac , channels , sampleRate , totalPCMFrameCount ) ;
}
DRFLAC_API drflac_int16 * drflac_open_file_and_read_pcm_frames_s16 ( const char * filename , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( sampleRate ) {
* sampleRate = 0 ;
}
if ( channels ) {
* channels = 0 ;
}
if ( totalPCMFrameCount ) {
* totalPCMFrameCount = 0 ;
}
pFlac = drflac_open_file ( filename , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_s16 ( pFlac , channels , sampleRate , totalPCMFrameCount ) ;
}
DRFLAC_API float * drflac_open_file_and_read_pcm_frames_f32 ( const char * filename , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( sampleRate ) {
* sampleRate = 0 ;
}
if ( channels ) {
* channels = 0 ;
}
if ( totalPCMFrameCount ) {
* totalPCMFrameCount = 0 ;
}
pFlac = drflac_open_file ( filename , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_f32 ( pFlac , channels , sampleRate , totalPCMFrameCount ) ;
}
# endif
DRFLAC_API drflac_int32 * drflac_open_memory_and_read_pcm_frames_s32 ( const void * data , size_t dataSize , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( sampleRate ) {
* sampleRate = 0 ;
}
if ( channels ) {
* channels = 0 ;
}
if ( totalPCMFrameCount ) {
* totalPCMFrameCount = 0 ;
}
pFlac = drflac_open_memory ( data , dataSize , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_s32 ( pFlac , channels , sampleRate , totalPCMFrameCount ) ;
}
DRFLAC_API drflac_int16 * drflac_open_memory_and_read_pcm_frames_s16 ( const void * data , size_t dataSize , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( sampleRate ) {
* sampleRate = 0 ;
}
if ( channels ) {
* channels = 0 ;
}
if ( totalPCMFrameCount ) {
* totalPCMFrameCount = 0 ;
}
pFlac = drflac_open_memory ( data , dataSize , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_s16 ( pFlac , channels , sampleRate , totalPCMFrameCount ) ;
}
DRFLAC_API float * drflac_open_memory_and_read_pcm_frames_f32 ( const void * data , size_t dataSize , unsigned int * channels , unsigned int * sampleRate , drflac_uint64 * totalPCMFrameCount , const drflac_allocation_callbacks * pAllocationCallbacks )
{
drflac * pFlac ;
if ( sampleRate ) {
* sampleRate = 0 ;
}
if ( channels ) {
* channels = 0 ;
}
if ( totalPCMFrameCount ) {
* totalPCMFrameCount = 0 ;
}
pFlac = drflac_open_memory ( data , dataSize , pAllocationCallbacks ) ;
if ( pFlac = = NULL ) {
return NULL ;
}
return drflac__full_read_and_close_f32 ( pFlac , channels , sampleRate , totalPCMFrameCount ) ;
}
DRFLAC_API void drflac_free ( void * p , const drflac_allocation_callbacks * pAllocationCallbacks )
{
if ( pAllocationCallbacks ! = NULL ) {
drflac__free_from_callbacks ( p , pAllocationCallbacks ) ;
} else {
drflac__free_default ( p , NULL ) ;
}
}
DRFLAC_API void drflac_init_vorbis_comment_iterator ( drflac_vorbis_comment_iterator * pIter , drflac_uint32 commentCount , const void * pComments )
{
if ( pIter = = NULL ) {
return ;
}
pIter - > countRemaining = commentCount ;
pIter - > pRunningData = ( const char * ) pComments ;
}
DRFLAC_API const char * drflac_next_vorbis_comment ( drflac_vorbis_comment_iterator * pIter , drflac_uint32 * pCommentLengthOut )
{
drflac_int32 length ;
const char * pComment ;
/* Safety. */
if ( pCommentLengthOut ) {
* pCommentLengthOut = 0 ;
}
if ( pIter = = NULL | | pIter - > countRemaining = = 0 | | pIter - > pRunningData = = NULL ) {
return NULL ;
}
length = drflac__le2host_32_ptr_unaligned ( pIter - > pRunningData ) ;
pIter - > pRunningData + = 4 ;
pComment = pIter - > pRunningData ;
pIter - > pRunningData + = length ;
pIter - > countRemaining - = 1 ;
if ( pCommentLengthOut ) {
* pCommentLengthOut = length ;
}
return pComment ;
}
DRFLAC_API void drflac_init_cuesheet_track_iterator ( drflac_cuesheet_track_iterator * pIter , drflac_uint32 trackCount , const void * pTrackData )
{
if ( pIter = = NULL ) {
return ;
}
pIter - > countRemaining = trackCount ;
pIter - > pRunningData = ( const char * ) pTrackData ;
}
DRFLAC_API drflac_bool32 drflac_next_cuesheet_track ( drflac_cuesheet_track_iterator * pIter , drflac_cuesheet_track * pCuesheetTrack )
{
drflac_cuesheet_track cuesheetTrack ;
const char * pRunningData ;
drflac_uint64 offsetHi ;
drflac_uint64 offsetLo ;
if ( pIter = = NULL | | pIter - > countRemaining = = 0 | | pIter - > pRunningData = = NULL ) {
return DRFLAC_FALSE ;
}
pRunningData = pIter - > pRunningData ;
offsetHi = drflac__be2host_32 ( * ( const drflac_uint32 * ) pRunningData ) ; pRunningData + = 4 ;
offsetLo = drflac__be2host_32 ( * ( const drflac_uint32 * ) pRunningData ) ; pRunningData + = 4 ;
cuesheetTrack . offset = offsetLo | ( offsetHi < < 32 ) ;
cuesheetTrack . trackNumber = pRunningData [ 0 ] ; pRunningData + = 1 ;
DRFLAC_COPY_MEMORY ( cuesheetTrack . ISRC , pRunningData , sizeof ( cuesheetTrack . ISRC ) ) ; pRunningData + = 12 ;
cuesheetTrack . isAudio = ( pRunningData [ 0 ] & 0x80 ) ! = 0 ;
cuesheetTrack . preEmphasis = ( pRunningData [ 0 ] & 0x40 ) ! = 0 ; pRunningData + = 14 ;
cuesheetTrack . indexCount = pRunningData [ 0 ] ; pRunningData + = 1 ;
cuesheetTrack . pIndexPoints = ( const drflac_cuesheet_track_index * ) pRunningData ; pRunningData + = cuesheetTrack . indexCount * sizeof ( drflac_cuesheet_track_index ) ;
pIter - > pRunningData = pRunningData ;
pIter - > countRemaining - = 1 ;
if ( pCuesheetTrack ) {
* pCuesheetTrack = cuesheetTrack ;
}
return DRFLAC_TRUE ;
}
# if defined(__clang__) || (defined(__GNUC__) && (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 6)))
# pragma GCC diagnostic pop
# endif
# endif /* dr_flac_c */
# endif /* DR_FLAC_IMPLEMENTATION */
/*
REVISION HISTORY
= = = = = = = = = = = = = = = =
v0 .12 .37 - 2022 - 02 - 12
- Improve ARM detection .
v0 .12 .36 - 2022 - 02 - 07
- Fix a compilation error with the ARM build .
v0 .12 .35 - 2022 - 02 - 06
- Fix a bug due to underestimating the amount of precision required for the prediction stage .
- Fix some bugs found from fuzz testing .
v0 .12 .34 - 2022 - 01 - 07
- Fix some misalignment bugs when reading metadata .
v0 .12 .33 - 2021 - 12 - 22
- Fix a bug with seeking when the seek table does not start at PCM frame 0.
v0 .12 .32 - 2021 - 12 - 11
- Fix a warning with Clang .
v0 .12 .31 - 2021 - 08 - 16
- Silence some warnings .
v0 .12 .30 - 2021 - 07 - 31
- Fix platform detection for ARM64 .
v0 .12 .29 - 2021 - 04 - 02
- Fix a bug where the running PCM frame index is set to an invalid value when over - seeking .
- Fix a decoding error due to an incorrect validation check .
v0 .12 .28 - 2021 - 02 - 21
- Fix a warning due to referencing _MSC_VER when it is undefined .
v0 .12 .27 - 2021 - 01 - 31
- Fix a static analysis warning .
v0 .12 .26 - 2021 - 01 - 17
- Fix a compilation warning due to _BSD_SOURCE being deprecated .
v0 .12 .25 - 2020 - 12 - 26
- Update documentation .
v0 .12 .24 - 2020 - 11 - 29
- Fix ARM64 / NEON detection when compiling with MSVC .
v0 .12 .23 - 2020 - 11 - 21
- Fix compilation with OpenWatcom .
v0 .12 .22 - 2020 - 11 - 01
- Fix an error with the previous release .
v0 .12 .21 - 2020 - 11 - 01
- Fix a possible deadlock when seeking .
- Improve compiler support for older versions of GCC .
v0 .12 .20 - 2020 - 09 - 08
- Fix a compilation error on older compilers .
v0 .12 .19 - 2020 - 08 - 30
- Fix a bug due to an undefined 32 - bit shift .
v0 .12 .18 - 2020 - 08 - 14
- Fix a crash when compiling with clang - cl .
v0 .12 .17 - 2020 - 08 - 02
- Simplify sized types .
v0 .12 .16 - 2020 - 07 - 25
- Fix a compilation warning .
v0 .12 .15 - 2020 - 07 - 06
- Check for negative LPC shifts and return an error .
v0 .12 .14 - 2020 - 06 - 23
- Add include guard for the implementation section .
v0 .12 .13 - 2020 - 05 - 16
- Add compile - time and run - time version querying .
- DRFLAC_VERSION_MINOR
- DRFLAC_VERSION_MAJOR
- DRFLAC_VERSION_REVISION
- DRFLAC_VERSION_STRING
- drflac_version ( )
- drflac_version_string ( )
v0 .12 .12 - 2020 - 04 - 30
- Fix compilation errors with VC6 .
v0 .12 .11 - 2020 - 04 - 19
- Fix some pedantic warnings .
- Fix some undefined behaviour warnings .
v0 .12 .10 - 2020 - 04 - 10
- Fix some bugs when trying to seek with an invalid seek table .
v0 .12 .9 - 2020 - 04 - 05
- Fix warnings .
v0 .12 .8 - 2020 - 04 - 04
- Add drflac_open_file_w ( ) and drflac_open_file_with_metadata_w ( ) .
- Fix some static analysis warnings .
- Minor documentation updates .
v0 .12 .7 - 2020 - 03 - 14
- Fix compilation errors with VC6 .
v0 .12 .6 - 2020 - 03 - 07
- Fix compilation error with Visual Studio . NET 2003.
v0 .12 .5 - 2020 - 01 - 30
- Silence some static analysis warnings .
v0 .12 .4 - 2020 - 01 - 29
- Silence some static analysis warnings .
v0 .12 .3 - 2019 - 12 - 02
- Fix some warnings when compiling with GCC and the - Og flag .
- Fix a crash in out - of - memory situations .
- Fix potential integer overflow bug .
- Fix some static analysis warnings .
- Fix a possible crash when using custom memory allocators without a custom realloc ( ) implementation .
- Fix a bug with binary search seeking where the bits per sample is not a multiple of 8.
v0 .12 .2 - 2019 - 10 - 07
- Internal code clean up .
v0 .12 .1 - 2019 - 09 - 29
- Fix some Clang Static Analyzer warnings .
- Fix an unused variable warning .
v0 .12 .0 - 2019 - 09 - 23
- API CHANGE : Add support for user defined memory allocation routines . This system allows the program to specify their own memory allocation
routines with a user data pointer for client - specific contextual data . This adds an extra parameter to the end of the following APIs :
- drflac_open ( )
- drflac_open_relaxed ( )
- drflac_open_with_metadata ( )
- drflac_open_with_metadata_relaxed ( )
- drflac_open_file ( )
- drflac_open_file_with_metadata ( )
- drflac_open_memory ( )
- drflac_open_memory_with_metadata ( )
- drflac_open_and_read_pcm_frames_s32 ( )
- drflac_open_and_read_pcm_frames_s16 ( )
- drflac_open_and_read_pcm_frames_f32 ( )
- drflac_open_file_and_read_pcm_frames_s32 ( )
- drflac_open_file_and_read_pcm_frames_s16 ( )
- drflac_open_file_and_read_pcm_frames_f32 ( )
- drflac_open_memory_and_read_pcm_frames_s32 ( )
- drflac_open_memory_and_read_pcm_frames_s16 ( )
- drflac_open_memory_and_read_pcm_frames_f32 ( )
Set this extra parameter to NULL to use defaults which is the same as the previous behaviour . Setting this NULL will use
DRFLAC_MALLOC , DRFLAC_REALLOC and DRFLAC_FREE .
- Remove deprecated APIs :
- drflac_read_s32 ( )
- drflac_read_s16 ( )
- drflac_read_f32 ( )
- drflac_seek_to_sample ( )
- drflac_open_and_decode_s32 ( )
- drflac_open_and_decode_s16 ( )
- drflac_open_and_decode_f32 ( )
- drflac_open_and_decode_file_s32 ( )
- drflac_open_and_decode_file_s16 ( )
- drflac_open_and_decode_file_f32 ( )
- drflac_open_and_decode_memory_s32 ( )
- drflac_open_and_decode_memory_s16 ( )
- drflac_open_and_decode_memory_f32 ( )
- Remove drflac . totalSampleCount which is now replaced with drflac . totalPCMFrameCount . You can emulate drflac . totalSampleCount
by doing pFlac - > totalPCMFrameCount * pFlac - > channels .
- Rename drflac . currentFrame to drflac . currentFLACFrame to remove ambiguity with PCM frames .
- Fix errors when seeking to the end of a stream .
- Optimizations to seeking .
- SSE improvements and optimizations .
- ARM NEON optimizations .
- Optimizations to drflac_read_pcm_frames_s16 ( ) .
- Optimizations to drflac_read_pcm_frames_s32 ( ) .
v0 .11 .10 - 2019 - 06 - 26
- Fix a compiler error .
v0 .11 .9 - 2019 - 06 - 16
- Silence some ThreadSanitizer warnings .
v0 .11 .8 - 2019 - 05 - 21
- Fix warnings .
v0 .11 .7 - 2019 - 05 - 06
- C89 fixes .
v0 .11 .6 - 2019 - 05 - 05
- Add support for C89 .
- Fix a compiler warning when CRC is disabled .
- Change license to choice of public domain or MIT - 0.
v0 .11 .5 - 2019 - 04 - 19
- Fix a compiler error with GCC .
v0 .11 .4 - 2019 - 04 - 17
- Fix some warnings with GCC when compiling with - std = c99 .
v0 .11 .3 - 2019 - 04 - 07
- Silence warnings with GCC .
v0 .11 .2 - 2019 - 03 - 10
- Fix a warning .
v0 .11 .1 - 2019 - 02 - 17
- Fix a potential bug with seeking .
v0 .11 .0 - 2018 - 12 - 16
- API CHANGE : Deprecated drflac_read_s32 ( ) , drflac_read_s16 ( ) and drflac_read_f32 ( ) and replaced them with
drflac_read_pcm_frames_s32 ( ) , drflac_read_pcm_frames_s16 ( ) and drflac_read_pcm_frames_f32 ( ) . The new APIs take
and return PCM frame counts instead of sample counts . To upgrade you will need to change the input count by
dividing it by the channel count , and then do the same with the return value .
- API_CHANGE : Deprecated drflac_seek_to_sample ( ) and replaced with drflac_seek_to_pcm_frame ( ) . Same rules as
the changes to drflac_read_ * ( ) apply .
- API CHANGE : Deprecated drflac_open_and_decode_ * ( ) and replaced with drflac_open_ * _and_read_ * ( ) . Same rules as
the changes to drflac_read_ * ( ) apply .
- Optimizations .
v0 .10 .0 - 2018 - 09 - 11
- Remove the DR_FLAC_NO_WIN32_IO option and the Win32 file IO functionality . If you need to use Win32 file IO you
need to do it yourself via the callback API .
- Fix the clang build .
- Fix undefined behavior .
- Fix errors with CUESHEET metdata blocks .
- Add an API for iterating over each cuesheet track in the CUESHEET metadata block . This works the same way as the
Vorbis comment API .
- Other miscellaneous bug fixes , mostly relating to invalid FLAC streams .
- Minor optimizations .
v0 .9 .11 - 2018 - 08 - 29
- Fix a bug with sample reconstruction .
v0 .9 .10 - 2018 - 08 - 07
- Improve 64 - bit detection .
v0 .9 .9 - 2018 - 08 - 05
- Fix C + + build on older versions of GCC .
v0 .9 .8 - 2018 - 07 - 24
- Fix compilation errors .
v0 .9 .7 - 2018 - 07 - 05
- Fix a warning .
v0 .9 .6 - 2018 - 06 - 29
- Fix some typos .
v0 .9 .5 - 2018 - 06 - 23
- Fix some warnings .
v0 .9 .4 - 2018 - 06 - 14
- Optimizations to seeking .
- Clean up .
v0 .9 .3 - 2018 - 05 - 22
- Bug fix .
v0 .9 .2 - 2018 - 05 - 12
- Fix a compilation error due to a missing break statement .
v0 .9 .1 - 2018 - 04 - 29
- Fix compilation error with Clang .
v0 .9 - 2018 - 04 - 24
- Fix Clang build .
- Start using major . minor . revision versioning .
v0 .8 g - 2018 - 04 - 19
- Fix build on non - x86 / x64 architectures .
v0 .8f - 2018 - 02 - 02
- Stop pretending to support changing rate / channels mid stream .
v0 .8 e - 2018 - 02 - 01
- Fix a crash when the block size of a frame is larger than the maximum block size defined by the FLAC stream .
- Fix a crash the the Rice partition order is invalid .
v0 .8 d - 2017 - 09 - 22
- Add support for decoding streams with ID3 tags . ID3 tags are just skipped .
v0 .8 c - 2017 - 09 - 07
- Fix warning on non - x86 / x64 architectures .
v0 .8 b - 2017 - 08 - 19
- Fix build on non - x86 / x64 architectures .
v0 .8 a - 2017 - 08 - 13
- A small optimization for the Clang build .
v0 .8 - 2017 - 08 - 12
- API CHANGE : Rename dr_ * types to drflac_ * .
- Optimizations . This brings dr_flac back to about the same class of efficiency as the reference implementation .
- Add support for custom implementations of malloc ( ) , realloc ( ) , etc .
- Add CRC checking to Ogg encapsulated streams .
- Fix VC + + 6 build . This is only for the C + + compiler . The C compiler is not currently supported .
- Bug fixes .
v0 .7 - 2017 - 07 - 23
- Add support for opening a stream without a header block . To do this , use drflac_open_relaxed ( ) / drflac_open_with_metadata_relaxed ( ) .
v0 .6 - 2017 - 07 - 22
- Add support for recovering from invalid frames . With this change , dr_flac will simply skip over invalid frames as if they
never existed . Frames are checked against their sync code , the CRC - 8 of the frame header and the CRC - 16 of the whole frame .
v0 .5 - 2017 - 07 - 16
- Fix typos .
- Change drflac_bool * types to unsigned .
- Add CRC checking . This makes dr_flac slower , but can be disabled with # define DR_FLAC_NO_CRC .
v0 .4f - 2017 - 03 - 10
- Fix a couple of bugs with the bitstreaming code .
v0 .4 e - 2017 - 02 - 17
- Fix some warnings .
v0 .4 d - 2016 - 12 - 26
- Add support for 32 - bit floating - point PCM decoding .
- Use drflac_int * and drflac_uint * sized types to improve compiler support .
- Minor improvements to documentation .
v0 .4 c - 2016 - 12 - 26
- Add support for signed 16 - bit integer PCM decoding .
v0 .4 b - 2016 - 10 - 23
- A minor change to drflac_bool8 and drflac_bool32 types .
v0 .4 a - 2016 - 10 - 11
- Rename drBool32 to drflac_bool32 for styling consistency .
v0 .4 - 2016 - 09 - 29
- API / ABI CHANGE : Use fixed size 32 - bit booleans instead of the built - in bool type .
- API CHANGE : Rename drflac_open_and_decode * ( ) to drflac_open_and_decode * _s32 ( ) .
- API CHANGE : Swap the order of " channels " and " sampleRate " parameters in drflac_open_and_decode * ( ) . Rationale for this is to
keep it consistent with drflac_audio .
v0 .3f - 2016 - 09 - 21
- Fix a warning with GCC .
v0 .3 e - 2016 - 09 - 18
- Fixed a bug where GCC 4.3 + was not getting properly identified .
- Fixed a few typos .
- Changed date formats to ISO 8601 ( YYYY - MM - DD ) .
v0 .3 d - 2016 - 06 - 11
- Minor clean up .
v0 .3 c - 2016 - 05 - 28
- Fixed compilation error .
v0 .3 b - 2016 - 05 - 16
- Fixed Linux / GCC build .
- Updated documentation .
v0 .3 a - 2016 - 05 - 15
- Minor fixes to documentation .
v0 .3 - 2016 - 05 - 11
- Optimizations . Now at about parity with the reference implementation on 32 - bit builds .
- Lots of clean up .
v0 .2 b - 2016 - 05 - 10
- Bug fixes .
v0 .2 a - 2016 - 05 - 10
- Made drflac_open_and_decode ( ) more robust .
- Removed an unused debugging variable
v0 .2 - 2016 - 05 - 09
- Added support for Ogg encapsulation .
- API CHANGE . Have the onSeek callback take a third argument which specifies whether or not the seek
should be relative to the start or the current position . Also changes the seeking rules such that
seeking offsets will never be negative .
- Have drflac_open_and_decode ( ) fail gracefully if the stream has an unknown total sample count .
v0 .1 b - 2016 - 05 - 07
- Properly close the file handle in drflac_open_file ( ) and family when the decoder fails to initialize .
- Removed a stale comment .
v0 .1 a - 2016 - 05 - 05
- Minor formatting changes .
- Fixed a warning on the GCC build .
v0 .1 - 2016 - 05 - 03
- Initial versioned release .
*/
/*
This software is available as a choice of the following licenses . Choose
whichever you prefer .
= = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = =
ALTERNATIVE 1 - Public Domain ( www . unlicense . org )
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This is free and unencumbered software released into the public domain .
Anyone is free to copy , modify , publish , use , compile , sell , or distribute this
software , either in source code form or as a compiled binary , for any purpose ,
commercial or non - commercial , and by any means .
In jurisdictions that recognize copyright laws , the author or authors of this
software dedicate any and all copyright interest in the software to the public
domain . We make this dedication for the benefit of the public at large and to
the detriment of our heirs and successors . We intend this dedication to be an
overt act of relinquishment in perpetuity of all present and future rights to
this software under copyright law .
THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL THE
AUTHORS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER LIABILITY , WHETHER IN AN
ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING FROM , OUT OF OR IN CONNECTION
WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE .
For more information , please refer to < http : //unlicense.org/>
= = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = =
ALTERNATIVE 2 - MIT No Attribution
= = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = =
Copyright 2020 David Reid
Permission is hereby granted , free of charge , to any person obtaining a copy of
this software and associated documentation files ( the " Software " ) , to deal in
the Software without restriction , including without limitation the rights to
use , copy , modify , merge , publish , distribute , sublicense , and / or sell copies
of the Software , and to permit persons to whom the Software is furnished to do
so .
THE SOFTWARE IS PROVIDED " AS IS " , WITHOUT WARRANTY OF ANY KIND , EXPRESS OR
IMPLIED , INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY ,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT . IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM , DAMAGES OR OTHER
LIABILITY , WHETHER IN AN ACTION OF CONTRACT , TORT OR OTHERWISE , ARISING FROM ,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE
SOFTWARE .
*/