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Diffstat (limited to 'source/dr_libs/dr_flac.h')
-rw-r--r-- | source/dr_libs/dr_flac.h | 12536 |
1 files changed, 0 insertions, 12536 deletions
diff --git a/source/dr_libs/dr_flac.h b/source/dr_libs/dr_flac.h deleted file mode 100644 index 14324cf..0000000 --- a/source/dr_libs/dr_flac.h +++ /dev/null @@ -1,12536 +0,0 @@ -/* -FLAC audio decoder. Choice of public domain or MIT-0. See license statements at the end of this file. -dr_flac - v0.12.42 - 2023-11-02 - -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 4KB (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. - -#define DR_FLAC_NO_WCHAR - Disables all functions ending with `_w`. Use this if your compiler does not provide wchar.h. Not required if DR_FLAC_NO_STDIO is also defined. - - - -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 42 -#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 -/* End Sized Types */ - -/* Decorations */ -#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 -/* End Decorations */ - -#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); - -/* Allocation Callbacks */ -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; -/* End Allocation Callbacks */ - -/* -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 4KB, 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 - - -/* Architecture Detection */ -#if defined(_WIN64) || defined(_LP64) || defined(__LP64__) -#define DRFLAC_64BIT -#endif - -#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 -/* End Architecture Detection */ - - -#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; - -/* The order of members in this structure is important because we map this directly to the raw data within the SEEKTABLE metadata block. */ -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; - -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); - - -/* 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; - -/* The order of members here is important because we map this directly to the raw data within the CUESHEET metadata block. */ -typedef struct -{ - drflac_uint64 offset; - drflac_uint8 index; - drflac_uint8 reserved[3]; -} drflac_cuesheet_track_index; - -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> - -/* Inline */ -#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_GNUC_INLINE_HINT __inline__ - #else - #define DRFLAC_GNUC_INLINE_HINT inline - #endif - - #if (__GNUC__ > 3 || (__GNUC__ == 3 && __GNUC_MINOR__ >= 2)) || defined(__clang__) - #define DRFLAC_INLINE DRFLAC_GNUC_INLINE_HINT __attribute__((always_inline)) - #else - #define DRFLAC_INLINE DRFLAC_GNUC_INLINE_HINT - #endif -#elif defined(__WATCOMC__) - #define DRFLAC_INLINE __inline -#else - #define DRFLAC_INLINE -#endif -/* End Inline */ - -/* -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(__SSE4_1__) || defined(__AVX__) - 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] \ - value [ax] \ - modify nomemory; -#pragma aux _watcom_bswap32 = \ - "bswap eax" \ - parm [eax] \ - value [eax] \ - modify nomemory; -#pragma aux _watcom_bswap64 = \ - "bswap eax" \ - "bswap edx" \ - "xchg eax,edx" \ - parm [eax edx] \ - value [eax edx] \ - modify nomemory; -#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. */ - -/* Result Codes */ -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 -100 -/* End Result Codes */ - - -#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_SEEKPOINT_SIZE_IN_BYTES 18 -#define DRFLAC_CUESHEET_TRACK_SIZE_IN_BYTES 36 -#define DRFLAC_CUESHEET_TRACK_INDEX_SIZE_IN_BYTES 12 - -#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(__ARM_ARCH_6M__) && !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 4KB 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 -#ifdef __MRC__ -#include <intrinsics.h> -#define DRFLAC_IMPLEMENT_CLZ_MRC -#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; -#elif defined(__MRC__) - 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(__ARM_ARCH_6M__) && !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); -#ifdef DRFLAC_IMPLEMENT_CLZ_WATCOM_LZCNT -/* Use the LZCNT instruction (only available on some processors since the 2010s). */ -#pragma aux drflac__clz_watcom_lzcnt = \ - "db 0F3h, 0Fh, 0BDh, 0C0h" /* lzcnt eax, eax */ \ - parm [eax] \ - value [eax] \ - modify nomemory; -#else -/* Use the 386+-compatible implementation. */ -#pragma aux drflac__clz_watcom = \ - "bsr eax, eax" \ - "xor eax, 31" \ - parm [eax] nomemory \ - value [eax] \ - modify exact [eax] nomemory; -#endif -#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_LZCNT) - return drflac__clz_watcom_lzcnt(x); -#elif defined(DRFLAC_IMPLEMENT_CLZ_WATCOM) - return (x == 0) ? sizeof(x)*8 : drflac__clz_watcom(x); -#elif defined(__MRC__) - return __cntlzw(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 = (drflac_uint32)~((~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; - int64x2_t prediction128 = { 0 }; - uint32x4_t zeroCountPart128; - uint32x4_t riceParamPart128; - - const drflac_uint32 t[2] = {0x00000000, 0xFFFFFFFF}; - - riceParamMask = (drflac_uint32)~((~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) { - 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* pSeekpointCount, 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 = 0; - 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 seekpointCount; - drflac_uint32 iSeekpoint; - void* pRawData; - - seekpointCount = blockSize/DRFLAC_SEEKPOINT_SIZE_IN_BYTES; - - pRawData = drflac__malloc_from_callbacks(seekpointCount * sizeof(drflac_seekpoint), pAllocationCallbacks); - if (pRawData == NULL) { - return DRFLAC_FALSE; - } - - /* We need to read seekpoint by seekpoint and do some processing. */ - for (iSeekpoint = 0; iSeekpoint < seekpointCount; ++iSeekpoint) { - drflac_seekpoint* pSeekpoint = (drflac_seekpoint*)pRawData + iSeekpoint; - - if (onRead(pUserData, pSeekpoint, DRFLAC_SEEKPOINT_SIZE_IN_BYTES) != DRFLAC_SEEKPOINT_SIZE_IN_BYTES) { - drflac__free_from_callbacks(pRawData, pAllocationCallbacks); - return DRFLAC_FALSE; - } - - /* Endian swap. */ - pSeekpoint->firstPCMFrame = drflac__be2host_64(pSeekpoint->firstPCMFrame); - pSeekpoint->flacFrameOffset = drflac__be2host_64(pSeekpoint->flacFrameOffset); - pSeekpoint->pcmFrameCount = drflac__be2host_16(pSeekpoint->pcmFrameCount); - } - - metadata.pRawData = pRawData; - metadata.rawDataSize = blockSize; - metadata.data.seektable.seekpointCount = seekpointCount; - metadata.data.seektable.pSeekpoints = (const drflac_seekpoint*)pRawData; - - 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; - size_t bufferSize; - drflac_uint8 iTrack; - drflac_uint8 iIndex; - void* pTrackData; - - /* - This needs to be loaded in two passes. The first pass is used to calculate the size of the memory allocation - we need for storing the necessary data. The second pass will fill that buffer with usable data. - */ - 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 = NULL; /* Will be filled later. */ - - /* Pass 1: Calculate the size of the buffer for the track data. */ - { - const char* pRunningDataSaved = pRunningData; /* Will be restored at the end in preparation for the second pass. */ - - bufferSize = metadata.data.cuesheet.trackCount * DRFLAC_CUESHEET_TRACK_SIZE_IN_BYTES; - - for (iTrack = 0; iTrack < metadata.data.cuesheet.trackCount; ++iTrack) { - drflac_uint8 indexCount; - drflac_uint32 indexPointSize; - - if (pRunningDataEnd - pRunningData < DRFLAC_CUESHEET_TRACK_SIZE_IN_BYTES) { - drflac__free_from_callbacks(pRawData, pAllocationCallbacks); - return DRFLAC_FALSE; - } - - /* Skip to the index point count */ - pRunningData += 35; - - indexCount = pRunningData[0]; - pRunningData += 1; - - bufferSize += indexCount * sizeof(drflac_cuesheet_track_index); - - /* Quick validation check. */ - indexPointSize = indexCount * DRFLAC_CUESHEET_TRACK_INDEX_SIZE_IN_BYTES; - if (pRunningDataEnd - pRunningData < (drflac_int64)indexPointSize) { - drflac__free_from_callbacks(pRawData, pAllocationCallbacks); - return DRFLAC_FALSE; - } - - pRunningData += indexPointSize; - } - - pRunningData = pRunningDataSaved; - } - - /* Pass 2: Allocate a buffer and fill the data. Validation was done in the step above so can be skipped. */ - { - char* pRunningTrackData; - - pTrackData = drflac__malloc_from_callbacks(bufferSize, pAllocationCallbacks); - if (pTrackData == NULL) { - drflac__free_from_callbacks(pRawData, pAllocationCallbacks); - return DRFLAC_FALSE; - } - - pRunningTrackData = (char*)pTrackData; - - for (iTrack = 0; iTrack < metadata.data.cuesheet.trackCount; ++iTrack) { - drflac_uint8 indexCount; - - DRFLAC_COPY_MEMORY(pRunningTrackData, pRunningData, DRFLAC_CUESHEET_TRACK_SIZE_IN_BYTES); - pRunningData += DRFLAC_CUESHEET_TRACK_SIZE_IN_BYTES-1; /* Skip forward, but not beyond the last byte in the CUESHEET_TRACK block which is the index count. */ - pRunningTrackData += DRFLAC_CUESHEET_TRACK_SIZE_IN_BYTES-1; - - /* Grab the index count for the next part. */ - indexCount = pRunningData[0]; - pRunningData += 1; - pRunningTrackData += 1; - - /* Extract each track index. */ - for (iIndex = 0; iIndex < indexCount; ++iIndex) { - drflac_cuesheet_track_index* pTrackIndex = (drflac_cuesheet_track_index*)pRunningTrackData; - - DRFLAC_COPY_MEMORY(pRunningTrackData, pRunningData, DRFLAC_CUESHEET_TRACK_INDEX_SIZE_IN_BYTES); - pRunningData += DRFLAC_CUESHEET_TRACK_INDEX_SIZE_IN_BYTES; - pRunningTrackData += sizeof(drflac_cuesheet_track_index); - - pTrackIndex->offset = drflac__be2host_64(pTrackIndex->offset); - } - } - - metadata.data.cuesheet.pTrackData = pTrackData; - } - - /* The original data is no longer needed. */ - drflac__free_from_callbacks(pRawData, pAllocationCallbacks); - pRawData = NULL; - - onMeta(pUserDataMD, &metadata); - - drflac__free_from_callbacks(pTrackData, pAllocationCallbacks); - pTrackData = NULL; - } - } 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; - *pSeekpointCount = seektableSize / DRFLAC_SEEKPOINT_SIZE_IN_BYTES; - *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* pOggbs = NULL; -#endif - drflac_uint64 firstFramePos; - drflac_uint64 seektablePos; - drflac_uint32 seekpointCount; - 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); - - pOggbs = (drflac_oggbs*)drflac__malloc_from_callbacks(sizeof(*pOggbs), &allocationCallbacks); - if (pOggbs == NULL) { - return NULL; /*DRFLAC_OUT_OF_MEMORY;*/ - } - - DRFLAC_ZERO_MEMORY(pOggbs, sizeof(*pOggbs)); - pOggbs->onRead = onRead; - pOggbs->onSeek = onSeek; - pOggbs->pUserData = pUserData; - pOggbs->currentBytePos = init.oggFirstBytePos; - pOggbs->firstBytePos = init.oggFirstBytePos; - pOggbs->serialNumber = init.oggSerial; - pOggbs->bosPageHeader = init.oggBosHeader; - pOggbs->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; - seekpointCount = 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*)pOggbs; - } -#endif - - if (!drflac__read_and_decode_metadata(onReadOverride, onSeekOverride, onMeta, pUserDataOverride, pUserDataMD, &firstFramePos, &seektablePos, &seekpointCount, &allocationCallbacks)) { - #ifndef DR_FLAC_NO_OGG - drflac__free_from_callbacks(pOggbs, &allocationCallbacks); - #endif - return NULL; - } - - allocationSize += seekpointCount * sizeof(drflac_seekpoint); - } - - - pFlac = (drflac*)drflac__malloc_from_callbacks(allocationSize, &allocationCallbacks); - if (pFlac == NULL) { - #ifndef DR_FLAC_NO_OGG - drflac__free_from_callbacks(pOggbs, &allocationCallbacks); - #endif - 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 + (seekpointCount * sizeof(drflac_seekpoint))); - DRFLAC_COPY_MEMORY(pInternalOggbs, pOggbs, sizeof(*pOggbs)); - - /* At this point the pOggbs object has been handed over to pInternalOggbs and can be freed. */ - drflac__free_from_callbacks(pOggbs, &allocationCallbacks); - pOggbs = NULL; - - /* 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 = seekpointCount; - 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)) { - drflac_uint32 iSeekpoint; - - for (iSeekpoint = 0; iSeekpoint < seekpointCount; iSeekpoint += 1) { - if (pFlac->bs.onRead(pFlac->bs.pUserData, pFlac->pSeekpoints + iSeekpoint, DRFLAC_SEEKPOINT_SIZE_IN_BYTES) == DRFLAC_SEEKPOINT_SIZE_IN_BYTES) { - /* Endian swap. */ - 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; - break; - } - } - - /* 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> -#ifndef DR_FLAC_NO_WCHAR -#include <wchar.h> /* For wcslen(), wcsrtombs() */ -#endif - -/* Errno */ -/* 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; - } -} -/* End Errno */ - -/* fopen */ -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 - -#ifndef DR_FLAC_NO_WCHAR -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. - */ - - /* - Some compilers don't support wchar_t or wcsrtombs() which we're using below. In this case we just - need to abort with an error. If you encounter a compiler lacking such support, add it to this list - and submit a bug report and it'll be added to the library upstream. - */ - #if defined(__DJGPP__) - { - /* Nothing to do here. This will fall through to the error check below. */ - } - #else - { - 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); - } - #endif - - if (*ppFile == NULL) { - return DRFLAC_ERROR; - } -#endif - - return DRFLAC_SUCCESS; -} -#endif -/* End fopen */ - -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; -} - -#ifndef DR_FLAC_NO_WCHAR -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; -} -#endif - -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; -} - -#ifndef DR_FLAC_NO_WCHAR -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 -#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 */ - -/* SIZE_MAX */ -#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 -/* End SIZE_MAX */ - - -/* 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 -================ -v0.12.42 - 2023-11-02 - - Fix build for ARMv6-M. - - Fix a compilation warning with GCC. - -v0.12.41 - 2023-06-17 - - Fix an incorrect date in revision history. No functional change. - -v0.12.40 - 2023-05-22 - - Minor code restructure. No functional change. - -v0.12.39 - 2022-09-17 - - Fix compilation with DJGPP. - - Fix compilation error with Visual Studio 2019 and the ARM build. - - Fix an error with SSE 4.1 detection. - - Add support for disabling wchar_t with DR_WAV_NO_WCHAR. - - Improve compatibility with compilers which lack support for explicit struct packing. - - Improve compatibility with low-end and embedded hardware by reducing the amount of stack - allocation when loading an Ogg encapsulated file. - -v0.12.38 - 2022-04-10 - - Fix compilation error on older versions of GCC. - -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. - -v0.8g - 2018-04-19 - - Fix build on non-x86/x64 architectures. - -v0.8f - 2018-02-02 - - Stop pretending to support changing rate/channels mid stream. - -v0.8e - 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. - -v0.8d - 2017-09-22 - - Add support for decoding streams with ID3 tags. ID3 tags are just skipped. - -v0.8c - 2017-09-07 - - Fix warning on non-x86/x64 architectures. - -v0.8b - 2017-08-19 - - Fix build on non-x86/x64 architectures. - -v0.8a - 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. - -v0.4e - 2017-02-17 - - Fix some warnings. - -v0.4d - 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. - -v0.4c - 2016-12-26 - - Add support for signed 16-bit integer PCM decoding. - -v0.4b - 2016-10-23 - - A minor change to drflac_bool8 and drflac_bool32 types. - -v0.4a - 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. - -v0.3e - 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). - -v0.3d - 2016-06-11 - - Minor clean up. - -v0.3c - 2016-05-28 - - Fixed compilation error. - -v0.3b - 2016-05-16 - - Fixed Linux/GCC build. - - Updated documentation. - -v0.3a - 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. - -v0.2b - 2016-05-10 - - Bug fixes. - -v0.2a - 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. - -v0.1b - 2016-05-07 - - Properly close the file handle in drflac_open_file() and family when the decoder fails to initialize. - - Removed a stale comment. - -v0.1a - 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) -=============================================================================== -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 2023 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. -*/ |