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This page is broken up into the following sections:

Keep in mind that the online version of this document will always apply to the latest release. For older releases, check the documentation included with the release package.


flac has been tuned so that the default options yield a good speed vs. compression tradeoff for many kinds of input. However, if you are looking to maximize the compression rate or speed, or want to use the full power of FLAC's metadata system, this section is for you. If not, just skip to the next section.

The basic structure of a FLAC stream is:

  • The four byte string "fLaC"
  • The STREAMINFO metadata block
  • Zero or more other metadata blocks
  • One or more audio frames

The first four bytes are to identify the FLAC stream. The metadata that follows contains all the information about the stream except for the audio data itself. After the metadata comes the encoded audio data.


FLAC defines several types of metadata blocks (see the format page for the complete list. Metadata blocks can be any length and new ones can be defined. A decoder is allowed to skip any metadata types it does not understand. Only one is mandatory: the STREAMINFO block. This block has information like the sample rate, number of channels, etc., and data that can help the decoder manage its buffers, like the minimum and maximum data rate and minimum and maximum block size. Also included in the STREAMINFO block is the MD5 signature of the unencoded audio data. This is useful for checking an entire stream for transmission errors.

Other blocks allow for padding, seek tables, and application-specific data. You can see flac options below for adding PADDING blocks or specifying seek points. FLAC does not require seek points for seeking but they can speed up seeks, or be used for cueing in editing applications.

Also, if you have a need of a custom metadata block, you can define your own and request an ID here. Then you can reserve a PADDING block of the correct size when encoding, and overwrite the padding block with your APPLICATION block after encoding. The resulting stream will be FLAC compatible; decoders that are aware of your metadata can use it and the rest will safely ignore it.


After the metadata comes the encoded audio data. Audio data and metadata are not interleaved. Like most audio codecs, FLAC splits the unencoded audio data into blocks, and encodes each block separately. The encoded block is packed into a frame and appended to the stream. The reference encoder uses a single block size for the whole stream but the FLAC format does not require it.


The block size is an important parameter to encoding. If it is too small, the frame overhead will lower the compression. If it is too large, the modeling stage of the compressor will not be able to generate an efficient model. Understanding FLAC's modeling will help you to improve compression for some kinds of input by varying the block size. In the most general case, using linear prediction on 44.1kHz audio, the optimal block size will be between 2-6 ksamples. flac defaults to a block size of 4608 in this case. Using the fast fixed predictors, a smaller block size is usually preferable because of the smaller frame header.


In the case of stereo input, once the data is blocked it is optionally passed through an inter-channel decorrelation stage. The left and right channels are converted to center and side channels through the following transformation: mid = (left + right) / 2, side = left - right. This is a lossless process, unlike joint stereo. For normal CD audio this can result in significant extra compression. flac has two options for this: -m always compresses both the left-right and mid-side versions of the block and takes the smallest frame, and -M, which adaptively switches between left-right and mid-side.


In the next stage, the encoder tries to approximate the signal with a function in such a way that when the approximation is subracted, the result (called the residual, residue, or error) requires fewer bits-per-sample to encode. The function's parameters also have to be transmitted so they should not be so complex as to eat up the savings. FLAC has two methods of forming approximations: 1) fitting a simple polynomial to the signal; and 2) general linear predictive coding (LPC). I will not go into the details here, only some generalities that involve the encoding options.

First, fixed polynomial prediction (specified with -l 0) is much faster, but less accurate than LPC. The higher the maximum LPC order, the slower, but more accurate, the model will be. However, there are diminishing returns with increasing orders. Also, at some point (usually around order 9) the part of the encoder that guesses what is the best order to use will start to get it wrong and the compression will actually decrease slightly; at that point you will have to you will have to use the exhaustive search option -e to overcome this, which is significantly slower.

Second, the parameters for the fixed predictors can be transmitted in 3 bits whereas the parameters for the LPC model depend on the bits-per-sample and LPC order. This means the frame header length varies depending on the method and order you choose and can affect the optimal block size.


Once the model is generated, the encoder subracts the approximation from the original signal to get the residual (error) signal. The error signal is then losslessly coded. To do this, FLAC takes advantage of the fact that the error signal generally has a Laplacian (two-sided geometric) distribution, and that there are a set of special Huffman codes called Rice codes that can be used to efficiently encode these kind of signals quickly and without needing a dictionary.

Rice coding involves finding a single parameter that matches a signal's distribution, then using that parameter to generate the codes. As the distribution changes, the optimal parameter changes, so FLAC supports a method that allows the parameter to change as needed. The residual can be broken into several contexts or partitions, each with it's own Rice parameter. flac allows you to specify how the partitioning is done with the -r option. The residual can be broken into 2^n partitions, by using the option -r n,n. The parameter n is called the partition order. Furthermore, the encoder can be made to search through m to n partition orders, taking the best one, by specifying -r m,n. Generally, the choice of n does not affect encoding speed but m,n does. The larger the difference between m and n, the more time it will take the encoder to search for the best order. The block size will also affect the optimal order.


An audio frame is preceded by a frame header and trailed by a frame footer. The header starts with a sync code, and contains the minimum information necessary for a decoder to play the stream, like sample rate, bits per sample, etc. It also contains the block or sample number and an 8-bit CRC of the frame header. The sync code, frame header CRC, and block/sample number allow resynchronization and seeking even in the absence of seek points. The frame footer contains a 16-bit CRC of the entire encoded frame for error detection. If the reference decoder detects a CRC error it will generate a silent block.


In order to support come common types of metadata, the reference decoder knows how to skip ID3V1 and ID3V2 tags so it is safe to tag FLAC files in this way. ID3V2 tags must come at the beginning of the file (before the "fLaC" marker) and ID3V1 tags must come at the end of the file.

flac has a verify option -V that verifies the output while encoding. With this option, a decoder is run in parallel to the encoder and its output is compared against the original input. If a difference is found flac will stop with an error.


flac is the command-line file encoder/decoder. The input to the encoder and the output to the decoder must either be RIFF WAVE format, AIFF, or raw interleaved sample data. flac only supports linear PCM samples (in other words, no A-LAW, uLAW, etc.). Another restriction (hopefully short-term) is that the input must be 8, 16, or 24 bits per sample. This is not a limitation of the FLAC format, just the reference encoder/decoder.

flac assumes that files ending in ".wav" or that have the RIFF WAVE header present are WAVE files, and files ending in ".aif" or ".aiff" or have the AIFF header present are in AIFF files. This may be overridden with a command-line option. It also assumes that files ending in ".ogg" are Ogg-FLAC files. Other than this, flac makes no assumptions about file extensions, though the convention is that FLAC files have the extension ".flac" (or ".fla" on ancient file systems like FAT-16).

Before going into the full command-line description, a few other things help to sort it out: 1) flac encodes by default, so you must use -d to decode; 2) the options -0 .. -8 (or --fast and --best) that control the compression level actually are just synonyms for different groups of specific encoding options (described later) and you can get the same effect by using the same options; 3) flac behaves similarly to gzip in the way it handles input and output files.

flac will be invoked one of four ways, depending on whether you are encoding, decoding, testing, or analyzing:

In any case, if no inputfile is specified, stdin is assumed. If only one inputfile is specified, it may be "-" for stdin. When stdin is used as input, flac will write to stdout. Otherwise flac will perform the desired operation on each input file to similarly named output files (meaning for encoding, the extension will be replaced with ".flac", or appended with ".flac" if the input file has no extension, and for decoding, the extension will be ".wav" for WAVE output and ".raw" for raw output). The original file is not deleted unless --delete-input-file is specified.

If you are encoding/decoding from stdin to a file, you should use the -o option like so:

  • flac [options] -o outputfile
  • flac -d [options] -o outputfile
which are better than:
  • flac [options] > outputfile
  • flac -d [options] > outputfile
since the former allows flac to seek backwards to write the STREAMINFO or RIFF WAVE header contents when necessary.

Also, you can force output data to go to stdout using -c.

The encoding options affect the compression ratio and encoding speed. The format options are used to tell flac the arrangement of samples if the input file (or output file when decoding) is a raw file. If it is a RIFF WAVE or AIFF file the format options are not needed since they are read from the AIFF/WAVE header.

In test mode, flac acts just like in decode mode, except no output file is written. Both decode and test modes detect errors in the stream, but they also detect when the MD5 signature of the decoded audio does not match the stored MD5 signature, even when the bitstream is valid.

General Options
-v, --version Show the flac version number.
-h, --help Show basic usage and a list of all options. Running flac without arguments shows the short help screen by default.
-H, --explain Show detailed explanation of usage and all options. Running flac without arguments shows the short help screen by default.
-d, --decode Decode (flac encodes by default). flac will exit with an exit code of 1 (and print a message, even in silent mode) if there were any errors during decoding, including when the MD5 checksum does not match the decoded output. Otherwise the exit code will be 0.
-t, --test Test (same as -d except no decoded file is written). The exit codes are the same as in decode mode.
-a, --analyze Analyze (same as -d except an analysis file is written). The exit codes are the same as in decode mode. This option is mainly for developers; the output will be a text file that has data about each frame and subframe.
-c, --stdout Write output to stdout.
-s, --silent Silent: do not show encoding/decoding statistics.
-o filename,
Force the output file name (usually flac just changes the extension). May only be used when encoding a single file. May not be used in conjunction with --output-prefix.
--output-prefix=string Prefix each output file name with the given string. This can be useful for encoding/decoding files to a different directory. Make sure if your string is a path name that it ends with a trailing '/' slash.
--delete-input-file Automatically delete the input file after a successful encode or decode. If there was an error (including a verify error) the input file is left intact.
--skip=# Skip over the first # of samples of the input. This works for both encoding and decoding, but not testing.
--ogg When encoding, generate Ogg-FLAC output instead of native-FLAC. Ogg-FLAC streams are FLAC streams wrapped in an Ogg transport layer. The resulting file should have an '.ogg' extension and will still be decodable by flac.

When decoding, force the input to be treated as Ogg-FLAC. This is useful when piping input from stdin or when the filename does not end in '.ogg'.

--serial-number=# When used with --ogg, specifies the serial number to use the for the FLAC stream. When encoding and no serial number is given, flac uses '0'. When decoding and no number is given, flac uses the serial number of the first page.

Analysis Options
--residual-text Includes the residual signal in the analysis file. This will make the file very big, much larger than even the decoded file.
--residual-gnuplot Generates a gnuplot file for every subframe; each file will contain the residual distribution of the subframe. This will create a lot of files.

Decoding Options
By default flac stops decoding with an error and removes the partially decoded file if it encounters a bitstream error. With -F, errors are still printed but flac will continue decoding to completion. Note that errors may cause the decoded audio to be missing some samples or have silent sections.

Encoding Options
-V, --verify Verify the encoding process. With this option, flac will create a parallel decoder that decodes the output of the encoder and compares the result against the original. It will abort immediately with an error if a mismatch occurs. -V increases the total encoding time but is guaranteed to catch any unforseen bug in the encoding process.
--lax Allow encoder to generate non-Subset files. The resulting FLAC file may not be streamable, so you should only use this option in combination with custom encoding options meant for archival. File decoders will still be able play (and seek in) such files.
--sector-align Align encoding of multiple CD format WAVE files on sector boundaries. This option is only allowed when encoding WAVE files, all of which have a 44.1kHz sample rate and 2 channels. With --sector-align, the encoder will align the resulting .flac streams so that their lengths are even multiples of a CD sector (1/75th of a second, or 588 samples). It does this by carrying over any partial sector at the end of each WAVE file to the next stream. The last stream will be padded to alignment with zeroes.

This option will have no effect if the files are already aligned (as is the normally the case with WAVE files ripped from a CD). flac can only align a set of files given in one invocation of flac.

WARNING: The ordering of files is important! If you give a command like 'flac --sector-align *.wav' the shell may not expand the wildcard to the order you expect. To be safe you should 'echo *.wav' first to confirm the order, or be explicit like 'flac --sector-align 8.wav 9.wav 10.wav'.

-S {#|X|#x},
Include a point or points in a SEEKTABLE:
  • : a specific sample number for a seek point
  • : a placeholder point (always goes at the end of the SEEKTABLE)
  • #x : # evenly spaced seekpoints, the first being at sample 0
You may use many -S options; the resulting SEEKTABLE will be the unique-ified union of all such values.
With no -S options, flac defaults to '-S 100x'. Use -S- for no SEEKTABLE.
NOTE: -S #x will not work if the encoder can't determine the input size before starting.
NOTE: if you use -S # and # is >= samples in the input, there will be either no seek point entered (if the input size is determinable before encoding starts) or a placeholder point (if input size is not determinable).
-P #, --padding=# Tell the encoder to write a PADDING metadata block of the given length (in bytes) after the STREAMINFO block. This is useful if you plan to tag the file later with an APPLICATION block; instead of having to rewrite the entire file later just to insert your block, you can write directly over the PADDING block. Note that the total length of the PADDING block will be 4 bytes longer than the length given because of the 4 metadata block header bytes. You can force no PADDING block at all to be written with -P-, which is the default.
-T FIELD=VALUE, --tag=FIELD=VALUE Add a Vorbis comment. The comment must adhere to the Vorbis comment spec; i.e. the FIELD must contain only legal characters, terminated by an 'equals' sign. Make sure to quote the comment if necessary. This option may appear more than once to add several comments. NOTE: all tags will be added to all encoded files.
-b #, --blocksize=# Specify the block size in samples. The default is 1152 for -l 0, otherwise 4608. Subset streams must use one of 192/576/1152/2304/4608/256/512/1024/2048/4096/8192/16384/32768. The reference encoder uses the same block size for the entire stream.
-m, --mid-side Enable mid-side coding (only for stereo streams). Tends to increase compression by a few percent on average. For each block both the stereo pair and mid-side versions of the block will be encoded, and smallest resulting frame will be stored. Currently mid-side encoding is only available when bits-per-sample <= 16.
-M, --adaptive-mid-side Enable adaptive mid-side coding (only for stereo streams). Like -m but the encoder adaptively switches between independent and mid-side coding, which is faster but yields less compression than -m (which does an exhaustive search).
-0 .. -8 Fastest compression .. highest compression. The default is -5.
-0, --compression-level-0 Synonymous with -l 0 -b 1152 -r 2,2
-1, --compression-level-1 Synonymous with -l 0 -b 1152 -M -r 2,2
-2, --compression-level-2 Synonymous with -l 0 -b 1152 -m -r 3
-3, --compression-level-3 Synonymous with -l 6 -b 4608 -r 3,3
-4, --compression-level-4 Synonymous with -l 8 -b 4608 -M -r 3,3
-5, --compression-level-5 Synonymous with -l 8 -b 4608 -m -r 3,3
-6, --compression-level-6 Synonymous with -l 8 -b 4608 -m -r 4
-7, --compression-level-7 Synonymous with -l 8 -b 4608 -m -e -r 6
-8, --compression-level-8 Synonymous with -l 12 -b 4608 -m -e -r 6
--fast Fastest compression. Currently synonymous with -0
--best Highest compression. Currently synonymous with -8
Exhaustive model search (expensive!). Normally the encoder estimates the best model to use and encodes once based on the estimate. With an exhaustive model search, the encoder will generate subframes for every order and use the smallest. If the max LPC order is high this can significantly increase the encode time but can shave off another 0.5%.
-l #, --max-lpc-order=# Specifies the maximum LPC order. This number must be <= 32. If 0, the encoder will not attempt generic linear prediction, and use only fixed predictors. Using fixed predictors is faster but usually results in files being 5-10% larger.
-q #,
Specifies the precision of the quantized LP coefficients, in bits. The default is -q 0, which means let the encoder decide based on the signal. Unless you really know your input file it's best to leave this up to the encoder.
Do exhaustive LP coefficient quantization optimization. This option overrides any -q option. It is expensive and typically will only improve the compression a tiny fraction of a percent. -q has no effect when -l 0 is used.
-r [#,]#,
Set the [min,]max residual partition order. The min value defaults to 0 if unspecified.

By default the encoder uses a single Rice parameter for the subframe's entire residual. With this option, the residual is iteratively partitioned into 2^min# .. 2^max# pieces, each with its own Rice parameter. Higher values of max# yield diminishing returns. The most bang for the buck is usually with -r 2,2 (more for higher block sizes). This usually shaves off about 1.5%. The technique tends to peak out about when blocksize/(2^n)=128. Use -r 0,16 to force the highest degree of optimization.

Format Options
--endian={big|little} Specify big-endian or little-endian byte order in the raw file.
--channels=# Specify the number of channels in the raw file.
--bps=# Specify the number of bits per sample in the raw file.
--sample-rate=# Specify the sample rate of the raw file.
--sign={signed|unsigned} Specify that the samples in the raw file are signed or unsigned (the default is signed).
--force-raw-format Treat the input file (or output file if decoding) as a raw file, regardless of the extension.

Negative Options
can all be used to turn off a particular option.


metaflac is the command-line .flac file metadata editor. You can use it to list the contents of blocks, delete or insert blocks, and manage padding.

The documentation for metaflac is currently being rewritten, but the usage screen should explain it pretty well. Do metaflac --help to see the full usage.

xmms plugin

All that is necessary is to copy libxmms-flac.so to the directory where XMMS looks for input plugins (usually /usr/lib/xmms/Input). There is nothing else to configure. Make sure to restart XMMS before trying to play any .flac files.

winamp2 plugin

There are two Winamp plugins; one for Winamp versions 2.x and one for Winamp versions 3.x. If you are using Winamp 2.x, all that is necessary is to copy in_flac.dll to the Plugins/ directory of your Winamp installation. There is nothing else to configure. Make sure to restart Winamp before trying to play any .flac files.

winamp3 plugin

There are two Winamp plugins; one for Winamp versions 2.x and one for Winamp versions 3.x. If you are using Winamp 3.x, all that is necessary is to copy cnv_flacpcm.wac to the Wacs/ directory of your Winamp installation. There is nothing else to configure. Make sure to restart Winamp before trying to play any .flac files.

known bugs

Bug tracking is done on the Sourceforge project page here. If you submit a bug, make sure and provide an email contact or use the Monitor feature.

The following are major known bugs in the current (1.0.4) release:

  • None.


Monkey's Audio comes with a nice GUI that many people are familiar with. It supports some external encoders, but not FLAC. However, the FLAC Windows distribution comes with a utility that allows you to replace one the of the supported lossless external codecs with FLAC. Here's how:

  • Copy flac.exe and flac_ren.exe to the External/ directory of the Monkey's Audio installation.
  • Choose a supported encoder to replace:
    • Shorten - copy flac_mac.exe on top of External/shortn32.exe
    • WavPack - copy flac_mac.exe on top of both External/wavpack.exe and External/wvunpack.exe
    • RKAU - copy flac_mac.exe on top of External/rkau.exe
    If you choose WavPack you will also be able to use the WavPack Configuration menu to add flac options.
  • Now you can encode FLAC files as if you were using the replaced encoder. The renamed flac_mac.exe utility will call flac.exe and afterwards, flac_ren.exe will rename the resulting file to have the .flac extension.

Other front-ends may be wedged in the same way; if you have one in mind, post it to the flac-dev mailing list.

 Copyright (c) 2000,2001,2002 Josh Coalson