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CRAMv2.1.tex
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CRAMv2.1.tex
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%&pdfLaTeX
% !TEX encoding = UTF-8 Unicode
\documentclass[a4paper]{article}
\usepackage{ifxetex}
\ifxetex
\usepackage{fontspec}
\setmainfont[Mapping=tex-text]{STIXGeneral}
\else
\usepackage[T1]{fontenc}
\usepackage[latin1]{inputenc}
\fi
\usepackage{textcomp}
\usepackage{graphicx}
\usepackage{array}
\usepackage{fixltx2e}
\usepackage{amssymb}
\usepackage{fancyhdr}
\renewcommand{\headrulewidth}{0pt}
\renewcommand{\footrulewidth}{0pt}
\setlength{\parindent}{0cm}
\setlength{\parskip}{0.18cm}
\usepackage[hmargin=2cm,vmargin=2.5cm,bindingoffset=0.0cm]{geometry}
\usepackage[pdfborder={0 0 0}]{hyperref}
\begin{document}
\input{CRAMv2.1.ver}
\title{CRAM format specification (version 2.1)}
\author{cram-dev@ebi.ac.uk}
\date{\headdate}
\maketitle
\begin{quote}\small
The master version of this document can be found at
\url{https://github.com/samtools/hts-specs}.\\
This printing is version~\commitdesc\ from that repository,
last modified on the date shown above.
\end{quote}
\begin{center}
\textit{license: Apache 2.0}
\end{center}
\vspace*{1em}
\section{\textbf{Overview}}
This specification describes the CRAM 2.1 format.
CRAM has the following major objectives:
\begin{enumerate}
\item Significantly better lossless compression than BAM
\item Full compatibility with BAM
\item Effortless transition to CRAM from using BAM files
\item Support for controlled loss of BAM data
\end{enumerate}
The first three objectives allow users to take immediate advantage of the CRAM
format while offering a smooth transition path from using BAM files. The fourth
objective supports the exploration of different lossy compression strategies and
provides a framework in which to effect these choices. Please note that the CRAM
format does not impose any rules about what data should or should not be preserved.
Instead, CRAM supports a wide range of lossless and lossy data preservation strategies
enabling users to choose which data should be preserved.
Data in CRAM is stored either as CRAM records or using one of the general purpose
compressors (gzip, bzip2). CRAM records are compressed using a number of different
encoding strategies. For example, bases are reference compressed by encoding base
differences rather than storing the bases themselves.\footnote{Markus Hsi-Yang Fritz,
Rasko Leinonen, Guy Cochrane, and Ewan Birney,
\textbf{Efficient storage of high throughput DNA sequencing data using reference-based compression},
{\sl Genome Res.}~2011~21: 734--740;
\href{http://dx.doi.org/doi:10.1101/gr.114819.110}{doi:10.1101/gr.114819.110};
{\sc pmid:}21245279.}
\section{\textbf{Data types}}
CRAM specification uses logical data types and storage data types; logical data
types are written as words (e.g. int) while physical data types are written using
single letters (e.g. i). The difference between the two is that storage data types
define how logical data types are stored in CRAM. Data in CRAM is stored either
as as bits or as bytes. Writing values as bits and bytes is described in detail
below.
\subsection{\textbf{Logical data types}}
\begin{description}
\item[Byte]\ \newline
Signed byte (8 bits).
\item[Integer]\ \newline
Signed 32-bit integer.
\item[Long]\ \newline
Signed 64-bit integer.
\item[Array]\ \newline
An array of any logical data type: \texttt{<}type\texttt{>}[ ]
\end{description}
% \begin{tabular}{ll}
% \textbf{Byte} & Signed byte (8 bits). \\
% \\
% \textbf{Integer} & Signed 32-bit integer. \\
% \\
% \textbf{Long} & Signed 64-bit integer. \\
% \\
% \textbf{Array} & An array of any logical data type: \texttt{<}type\texttt{>}[ ] \\
% \end{tabular}
\subsection{\textbf{Writing bits to a bit stream}}
A bit stream consists of a sequence of 1s and 0s. The bits are written most significant
bit first where new bits are stacked to the right and full bytes on the left are
written out. In a bit stream the last byte will be incomplete if less than 8 bits
have been written to it. In this case the bits in the last byte are shifted to
the left.
\subsubsection*{Example of writing to bit stream}
Let's consider the following example. The table below shows a sequence of write
operations:
\begin{tabular}{|l|l|l|l|l|}
\hline
\textbf{Operation order} & \textbf{Buffer state before} & \textbf{Written bits} & \textbf{Buffer state after} & \textbf{Issued bytes}\tabularnewline
\hline
1 & 0x0 & 1 & 0x1 & -\tabularnewline
\hline
2 & 0x1 & 0 & 0x2 & -\tabularnewline
\hline
3 & 0x2 & 11 & 0xB & -\tabularnewline
\hline
4 & 0xB & 0000 0111 & 0x7 & 0xB0\tabularnewline
\hline
\end{tabular}
After flushing the above bit stream the following bytes are written: 0xB0 0x70.
Please note that the last byte was 0x7 before shifting to the left and became 0x70
after that:
\texttt{> echo "obase=16; ibase=2; 00000111" \textbar{} bc\\
7\\
\\
> echo "obase=16; ibase=2; 01110000" \textbar{} bc\\
70}
And the whole bit sequence:
\texttt{> echo "obase=2; ibase=16; B070" \textbar{} bc\\
1011000001110000}
When reading the bits from the bit sequence it must be known that only 12 bits
are meaningful and the bit stream should not be read after that.
\subsubsection*{Note on writing to bit stream}
When writing to a bit stream both the value and the number of bits in the value
must be known. This is because programming languages normally operate with bytes
(8 bits) and to specify which bits are to be written requires a bit-holder, for
example an integer, and the number of bits in it. Equally, when reading a value
from a bit stream the number of bits must be known in advance. In case of prefix
codes (e.g. Huffman) all possible bit combinations are either known in advance
or it is possible to calculate how many bits will follow based on the first few
bits. Alternatively, two codes can be combined, where the first contains the number
of bits to read.
\subsection{\textbf{Writing bytes to a byte stream}}
The interpretation of byte stream is straightforward. CRAM uses \emph{little endianness}
for bytes when applicable and defines the following storage data types:
\begin{description}
\item[Boolean (bool)]\ \newline
Boolean is written as 1-byte with 0x0 being `false' and 0x1 being `true'.
\item[Integer (int32)]\ \newline
Signed 32-bit integer, written as 4 bytes in little-endian byte order.
\item[Long (int64)]\ \newline
Signed 64-bit integer, written as 8 bytes in little-endian byte order.
\item[ITF-8 integer (itf8)]\ \newline
This is an alternative way to write an integer value. The idea is similar to UTF-8
encoding and therefore this encoding is called ITF-8 (Integer Transformation Format
- 8 bit).
The most significant bits of the first byte have special meaning and are called
`prefix'. These are 0 to 4 true bits followed by a 0. The number of 1's denote
the number of bytes the follow. To accommodate 32 bits such representation requires
5 bytes with only 4 lower bits used in the last byte 5.
\item[LTF-8 long or (ltf8)]\ \newline
See ITF-8 for more details. The only difference between ITF-8 and LTF-8 is the
number of bytes used to encode a single value. To do so 64 bits are required and
this can be done with 9 byte at most with the first byte consisting of just 1s
or 0xFF value.
\item[{Array ([ ])}]\ \newline
Array length is written first as integer (itf8), followed by the elements of the
array.
\end{description}
\subsubsection*{Encoding}
Encoding is a data type that specifies how data series have been compressed. Encodings
are defined as encoding\texttt{<}type\texttt{>} where the type is a logical data
type as opposed to a storage data type.
An encoding is written as follows. The first integer (itf8) denotes the codec id
and the second integer (itf8) the number of bytes in the following encoding-specific
values.
Subexponential encoding example:
\begin{tabular}{|l|l|l|}
\hline
\textbf{Value} & \textbf{Type} & \textbf{Name}\tabularnewline
\hline
0x7 & itf8 & codec id\tabularnewline
\hline
0x2 & itf8 & number of bytes to follow\tabularnewline
\hline
0x0 & itf8 & offset\tabularnewline
\hline
0x1 & itf8 & K parameter\tabularnewline
\hline
\end{tabular}
The first byte ``0x7'' is the codec id.
The second 4 bytes ``0x0 0x0 0x0 0xD'' denote the length of the bytes to follow
(13).
The subexponential encoding has 3 parameters: integer (itf8) K, int (itf8) offset
and boolean (bool) unary bit:
K = 0x1 = 1
offset = 0x0 = 0
\subsubsection*{Map}
A map is a collection of keys and associated values. A map with N keys is written
as follows:
\begin{tabular}{|l|l|l|l|l|l|l|l|}
\hline
size in bytes & N & key 1 & value 1 & key ... & value ... & key N & value N\tabularnewline
\hline
\end{tabular}
Both the size in bytes and the number of keys are written as integer (itf8). Keys
and values are written according to their data types and are specific to each map.
\subsection{\textbf{Strings}}
Strings are represented as byte arrays using UTF-8 format. Read names, reference
sequence names and tag values with type `Z' are stored as UTF-8.
\section{\textbf{Encodings }}
Encoding is a data structure that captures information about compression details
of a data series that are required to uncompress it. This could be a set of constants
required to initialize a specific decompression algorithm or statistical properties
of a data series or, in case of data series being stored in an external block,
the block content id.
Encoding notation is defined as the keyword `encoding' followed by its data type
in angular brackets, for example `encoding\texttt{<}byte\texttt{>}' stands for
an encoding that operates on a data series of data type `byte'.
Encodings may have parameters of different data types, for example the external
encoding has only one parameter, integer id of the external block. The following
encodings are defined:
\begin{tabular}{|l|l|>{\raggedright}p{155pt}|>{\raggedright}p{160pt}|}
\hline
\textbf{Codec} & \textbf{ID} & \textbf{Parameters} & \textbf{Comment}\tabularnewline
\hline
NULL & 0 & none & series not preserved\tabularnewline
\hline
EXTERNAL & 1 & int block content id & the block content identifier used to associate
external data blocks with data series\tabularnewline
\hline
GOLOMB & 2 & int offset, int M & Golomb coding\tabularnewline
\hline
HUFFMAN\_INT & 3 & int array, int array & coding with int values\tabularnewline
\hline
BYTE\_ARRAY\_LEN & 4 & encoding\texttt{<}int\texttt{>} array length, encoding\texttt{<}byte\texttt{>}
bytes & coding of byte arrays with array length\tabularnewline
\hline
BYTE\_ARRAY\_STOP & 5 & byte stop, int external block\linebreak{}
content id & coding of byte arrays with a stop value \tabularnewline
\hline
BETA & 6 & int offset, int number of bits & binary coding\tabularnewline
\hline
SUBEXP & 7 & int offset, int K & subexponential coding\tabularnewline
\hline
GOLOMB\_RICE & 8 & int offset, int log2m & Golomb-Rice coding\tabularnewline
\hline
GAMMA & 9 & int offset & Elias gamma coding\tabularnewline
\hline
\end{tabular}
See the later \textbf{Encodings} sections for more detailed descriptions of all
the above coding algorithms and their parameters.
\section{\textbf{File structure}}
The overall CRAM file structure is described in this section. Please refer to other
sections of this document for more detailed information.
A CRAM file starts with a fixed length file definition followed by one or more
containers. The BAM header is stored in the first container.
%%\begin{figure}[htbp]
\includegraphics[width=356pt, height=31pt, keepaspectratio=true]{img/CRAMFileFormat2-1-fig001.png}
%%\caption{This should be the caption for \texttt{img/CRAMFileFormat2-1-fig001.png}.}
%%\end{figure}
Pic.1 CRAM file starts with a file definition followed by the BAM header and other
containers.
Containers consist of one or more blocks. By convention, the BAM header is stored
in the first container within a single block. This is known as the BAM header block.
%%\begin{figure}[htbp]
\includegraphics[width=354pt, height=103pt, keepaspectratio=true]{img/CRAMFileFormat2-1-fig002.png}
%%\caption{This should be the caption for \texttt{img/CRAMFileFormat2-1-fig002.png}.}
%%\end{figure}
Pic.2 The BAM header is stored in the first container.
Each container starts with a container header followed by one or more blocks. Each
block starts with a block header. All data in CRAM is stored within blocks after
the block header.
%%\begin{figure}[htbp]
\includegraphics[width=356pt, height=154pt, keepaspectratio=true]{img/CRAMFileFormat2-1-fig003.png}
%%\caption{This should be the caption for \texttt{img/CRAMFileFormat2-1-fig003.png}.}
%%\end{figure}
Pic.3 Container and block structure. All data in CRAM files is stored in blocks.
The first block in each container is the compression header block:
%%\begin{figure}[htbp]
\includegraphics[width=354pt, height=103pt, keepaspectratio=true]{img/CRAMFileFormat2-1-fig004.png}
%%\caption{This should be the caption for \texttt{img/CRAMFileFormat2-1-fig004.png}.}
%%\end{figure}
Pic.4 Compression header is the first block in the container.
The blocks after the compression header are organised logically into slices. One
slice may contain, for example, a contiguous region of alignment data. Slices begin
with a slice header block and are followed by one or more data blocks:
%%\begin{figure}[htbp]
\includegraphics[width=374pt, height=137pt, keepaspectratio=true]{img/CRAMFileFormat2-1-fig005.png}
%%\caption{This should be the caption for \texttt{img/CRAMFileFormat2-1-fig005.png}.}
%%\end{figure}
Pic.5 Containers are logically organised into slices.
Data blocks are divided into core and external data blocks. Each slice must have
at least one core data block immediately after the slice header block. The core
data block may be followed by one or more external data blocks.
%%\begin{figure}[htbp]
\includegraphics[width=392pt, height=149pt, keepaspectratio=true]{img/CRAMFileFormat2-1-fig006.png}
%%\caption{This should be the caption for \texttt{img/CRAMFileFormat2-1-fig006.png}.}
%%\end{figure}
Pic.5 Data blocks are divided into core and external data blocks.
\section{\textbf{File definition}}
Each CRAM file starts with a fixed length (26 bytes) definition with the following
fields:
\begin{tabular}{|l|l|l|}
\hline
\textbf{Data type} & \textbf{Name} & \textbf{Value}\tabularnewline
\hline
byte[4] & format magic number & CRAM (0x43 0x52 0x41 0x4d)\tabularnewline
\hline
unsigned byte & major format number & 2 (0x2)\tabularnewline
\hline
unsigned byte & minor format number & 1 (0x1)\tabularnewline
\hline
byte[20] & file id & CRAM file identifier (e.g. file name or SHA1 checksum)\tabularnewline
\hline
\end{tabular}
Valid CRAM \textit{major}.\textit{minor} version numbers are as follows:
\begin{itemize}
\item[\textit{1.0}]
The original public CRAM release.
\item[\textit{2.0}]
The first CRAM release implemented in both Java and C; tidied up
implementation vs specification differences in \textit{1.0}.
\item[\textit{2.1}]
Gained end of file markers; compatible with \textit{2.0}.
\item[\textit{3.0}]
Additional compression methods; header and data checksums;
improvements for unsorted data.
\end {itemize}
\section{\textbf{Container structure}}
The file definition is followed by one or more containers with the following header
structure where the container content is stored in the `blocks' field:
\begin{tabular}{|l|>{\raggedright}p{120pt}|>{\raggedright}p{260pt}|}
\hline
\textbf{Data type} & \textbf{Name} & \textbf{Value}
\tabularnewline
\hline
int32 & length & byte size of the container data (blocks)\tabularnewline
\hline
itf8 & reference sequence id & reference sequence identifier or\linebreak{}
-1 for unmapped reads\linebreak{}
-2 for multiple reference sequences\tabularnewline
\hline
itf8 & starting position on the reference & the alignment start position or\linebreak{}
0 for unmapped reads\tabularnewline
\hline
itf8 & alignment span & the length of the alignment or\linebreak{}
0 for unmapped reads\tabularnewline
\hline
itf8 & number of records & number of records in the container\tabularnewline
\hline
itf8 & record counter & 1-based sequential index of records in the file/stream.\tabularnewline
\hline
ltf8 & bases & number of read bases\tabularnewline
\hline
itf8 & number of blocks & the number of blocks\tabularnewline
\hline
itf8[ ] & landmarks & Each integer value of this array is a byte offset into the
blocks byte array. Landmarks are used for random access indexing.\tabularnewline
\hline
byte[ ] & blocks & The blocks contained within the container.\tabularnewline
\hline
\end{tabular}
\subsection{\textbf{CRAM header in the first container}}
The first container in the CRAM file contains the BAM header in an uncompressed
block. BAM header is terminated with \textbackslash{}0 byte and any extra bytes
in the block can be used to expand the BAM header. For example when updating @SQ
records additional space may be required for the BAM header. It is recommended
to reserve 50\% more space in the CRAM header block than it is required by the
BAM header.
\section{\textbf{Block structure}}
Containers consist of one or more blocks. Block compression is applied independently
and in addition to any encodings used to compress data within the block. The block
have the following header structure with the data stored in the `block data' field:
\begin{tabular}{|l|>{\raggedright}p{120pt}|>{\raggedright}p{260pt}|}
\hline
\textbf{Data type} & \textbf{Name} & \textbf{Value}
\tabularnewline
\hline
byte & method & the block compression method: \linebreak{}
0: raw (none)*\linebreak{}
1: gzip\linebreak{}
2: bzip2\tabularnewline
\hline
byte & block content type id & the block content type identifier\tabularnewline
\hline
itf8 & block content id & the block content identifier used to associate external
data blocks with data series\tabularnewline
\hline
itf8 & size in bytes* & size of the block data after applying block compression\tabularnewline
\hline
itf8 & raw size in bytes* & size of the block data before applying block compression\tabularnewline
\hline
byte[ ] & block data & the data stored in the block:\linebreak{}
$\bullet$ bit stream of CRAM records (core data block)\linebreak{}
$\bullet$ byte stream (external data block)\linebreak{}
$\bullet$ additional fields ( header blocks)\tabularnewline
\hline
\end{tabular}
* Note on raw method: both compressed and raw sizes must be set to the same value.
\subsection{\textbf{Block content types}}
CRAM has the following block content types:
\begin{tabular}{|>{\raggedright}p{143pt}|>{\raggedright}p{45pt}|>{\raggedright}p{116pt}|>{\raggedright}p{114pt}|}
\hline
\textbf{Block content type} & \textbf{Block content type id} & \textbf{Name} & \textbf{Contents}\tabularnewline
\hline
FILE\_HEADER & 0 & BAM header block & BAM header\tabularnewline
\hline
COMPRESSION\_HEADER & 1 & Compression header block & See specific section\tabularnewline
\hline
MAPPED\_SLICE\_HEADER & 2 & Slice header block & See specific section\tabularnewline
\hline
& 3 & & reserved\tabularnewline
\hline
EXTERNAL\_DATA & 4 & external data block & data produced by external encodings\tabularnewline
\hline
CORE\_DATA & 5 & core data block & bit stream of all encodings except for external\tabularnewline
\hline
\end{tabular}
\subsection{\textbf{Block content id}}
Block content id is used to distinguish between external blocks in the same slice.
Each external encoding has an id parameter which must be one of the external block
content ids. For external blocks the content id is a positive integer. For all
other blocks content id should be 0. Consequently, all external encodings must
not use content id less than 1.
\subsubsection*{Data blocks}
Data is stored in data blocks. There are two types of data blocks: core data blocks
and external data blocks.The difference between core and external data blocks is
that core data blocks consist of data series that are compressed using bit encodings
while the external data blocks are byte compressed. One core data block and any
number of external data blocks are associated with each slice.
Writing to and reading from core and external data blocks is organised through
CRAM records. Each data series is associated with an encoding. In case of external
encoding the block content id is used to identify the block where the data series
is stored. Please note that external blocks can have multiple data series associated
with them; in this case the values from these data series will be interleaved.
\subsection{\textbf{BAM header block}}
The BAM header is stored in a single block within the first container.
The following constraints apply to the BAM header:
\begin{itemize}
\item The SQ:MD5 checksum is required unless the reference sequence has been embedded
into the file.
\item At least one RG record is required.
\item The HD:SO sort order is always POS.
\end{itemize}
\subsection{\textbf{Compression header block}}
The compression header block consists of 3 parts: preservation map, data series
encoding map and tag encoding map.
\subsubsection*{Preservation map}
The preservation map contains information about which data was preserved in the
CRAM file. It is stored as a map with byte[2] keys:
\begin{tabular}{|l|l|>{\raggedright}p{100pt}|>{\raggedright}p{220pt}|}
\hline
\textbf{Key} & \textbf{Value data type} & \textbf{Name} & \textbf{Value}\tabularnewline
\hline
RN & bool & read names included & true if read names are preserved for all reads\tabularnewline
\hline
AP & bool & AP data series delta & true if AP data series is delta, false otherwise\tabularnewline
\hline
RR & bool & reference required & true if reference sequence is required to restore
the data completely\tabularnewline
\hline
SM & byte[5] & substitution matrix & substitution matrix\tabularnewline
\hline
TD & byte[ ] & tag ids dictionary & a list of lists of tag ids, see tag encoding
section\tabularnewline
\hline
\end{tabular}
\subsubsection*{Data series encodings}
Each data series has an encoding. These encoding are stored in a map with byte[2]
keys:
\begin{tabular}{|l|l|>{\raggedright}p{100pt}|>{\raggedright}p{220pt}|}
\hline
\textbf{Key} & \textbf{Value data type} & \textbf{Name} & \textbf{Value}\tabularnewline
\hline
BF & encoding\texttt{<}int\texttt{>} & bit flags & see separate section\tabularnewline
\hline
AP & encoding\texttt{<}int\texttt{>} & in-seq positions & 0-based alignment start
delta from previous record *\tabularnewline
\hline
FP & encoding\texttt{<}int\texttt{>} & in-read positions & positions of the read
features\tabularnewline
\hline
RL & encoding\texttt{<}int\texttt{>} & read lengths & read lengths\tabularnewline
\hline
DL & encoding\texttt{<}int\texttt{>} & deletion lengths & base-pair deletion lengths\tabularnewline
\hline
NF & encoding\texttt{<}int\texttt{>} & distance to next fragment & number of records
to the next fragment*\tabularnewline
\hline
BA & encoding\texttt{<}byte\texttt{>} & bases & bases\tabularnewline
\hline
QS & encoding\texttt{<}byte\texttt{>} & quality scores & quality scores\tabularnewline
\hline
FC & encoding\texttt{<}byte\texttt{>} & read features codes & see separate section\tabularnewline
\hline
FN & encoding\texttt{<}int\texttt{>} & number of read features & number of read
features in each record\tabularnewline
\hline
BS & encoding\texttt{<}byte\texttt{>} & base substitution codes & base substitution
codes\tabularnewline
\hline
IN & encoding\texttt{<}byte[ ]\texttt{>} & insertion & inserted bases\tabularnewline
\hline
RG & encoding\texttt{<}int\texttt{>} & read groups & read groups. Special value
`-1' stands for no group.\tabularnewline
\hline
MQ & encoding\texttt{<}int\texttt{>} & mapping qualities & mapping quality scores
\tabularnewline
\hline
TL & encoding\texttt{<}int\texttt{>} & tag ids & list of tag ids, see tag encoding
section\tabularnewline
\hline
RN & encoding\texttt{<}byte[ ]\texttt{>} & read names & read names\tabularnewline
\hline
NS & encoding\texttt{<}int\texttt{>} & next fragment reference sequence id & reference
sequence ids for the next fragment \tabularnewline
\hline
NP & encoding\texttt{<}int\texttt{>} & next mate alignment start & alignment positions
for the next fragment\tabularnewline
\hline
TS & encoding\texttt{<}int\texttt{>} & template size & template sizes\tabularnewline
\hline
MF & encoding\texttt{<}int\texttt{>} & next mate bit flags & see specific section\tabularnewline
\hline
CF & encoding\texttt{<}int\texttt{>} & compression bit flags & see specific section\tabularnewline
\hline
TM & encoding\texttt{<}int\texttt{>} & test mark & a prefix expected before every
record, for debugging purposes.\tabularnewline
\hline
RI & encoding\texttt{<}int\texttt{>} & reference id & record reference id from
the BAM file header\tabularnewline
\hline
RS & encoding\texttt{<}int\texttt{>} & reference skip length & number of skipped
bases for the `N' read feature\tabularnewline
\hline
PD & encoding\texttt{<}int\texttt{>} & padding & number of padded bases\tabularnewline
\hline
HC & encoding\texttt{<}int\texttt{>} & hard clip & number of hard clipped bases\tabularnewline
\hline
SC & encoding\texttt{<}byte[ ]\texttt{>} & soft clip & soft clipped bases\tabularnewline
\hline
\end{tabular}
* The data series is reset for each slice.
\subsubsection*{Encoding tags}
The TL (tag list) data series represents combined information about the number
of tags in a record and their ids.
Let $L_{i}=\{T_{i0}, T_{i1}, \ldots, T_{ix}\}$
be sorted list of all tag ids for a record $R_{i}$, where $i$ is the sequential
record index and $T_{ij}$ denotes $j$-th tag id in the record. We recommend
alphabetical sort order. The list of unique $L_{i}$ is assigned sequential
integer numbers starting with 0. These integer numbers represent the TL data series.
The sorted list of unique $L_{i}$ is stored as the TD value in the preservation
map. Using TD, an integer from the TL data series can be mapped back into a list
of tag ids.
The TD is written as byte array consisting of $L_{i}$ values separated
with \textbackslash{}0. Each $L_{i}$ value is written as a sequence
of 3 bytes: tag id followed by tag value type. For example AMiOQZ\textbackslash{}0OQZ\textbackslash{}0,
where the TD consists of just two values: integer 0 for tags \{AM:i,OQ:Z\} and
1 for tag \{OQ:Z\}.
\subsubsection*{Encoding tag values}
The encodings used for different tags are stored in a map. The map has integer
keys composed of the two letter tag abbreviation followed by the tag type as defined
in the SAM specification, for example `OQZ' for `OQ:Z'. The three bytes form a
big endian integer and are written as ITF8. For example, 3-byte representation
of OQ:Z is \{0x4F, 0x51, 0x5A\} and these bytes are interpreted as the integer 0x004F515A.
The integer is finally written as ITF8.
\begin{tabular}{|l|l|l|>{\raggedright}p{160pt}|}
\hline
\textbf{Key} & \textbf{Value data type} & \textbf{Name} & \textbf{Value}
\tabularnewline
\hline
TAG NAME 1:TAG TYPE 1 & encoding\texttt{<}byte[ ]\texttt{>} & read tag 1 & tag values
(names and types are available in the data series code)\tabularnewline
\hline
... & & ... & ...\tabularnewline
\hline
TAG NAME N:TAG TYPE N & encoding\texttt{<}byte[ ]\texttt{>} & read tag N & ...\tabularnewline
\hline
\end{tabular}
Note that tag values are encoded as array of bytes. The routines to convert tag
values into byte array and back are the same as in BAM with the exception of value
type being captured in the tag key rather in the value.
\subsection{\textbf{Slice header block}}
The slice header block is never compressed (block method=raw). For reference mapped
reads the slice header also defines the reference sequence context of the data
blocks associated with the slice. Mapped and unmapped reads can be stored within
the same slice similarly to BAM file. Slices with unsorted reads must not contain
any other types of reads.
The slice header block contains the following fields.
\begin{tabular}{|l|l|>{\raggedright}p{200pt}|}
\hline
\textbf{Data type} & \textbf{Name} & \textbf{Value}\tabularnewline
\hline
itf8 & reference sequence id & reference sequence identifier or -1 for unmapped
or unsorted reads\tabularnewline
\hline
itf8 & alignment start & the alignment start position or -1 for unmapped or unsorted
reads\tabularnewline
\hline
itf8 & alignment span & the length of the alignment or 0 for unmapped or unsorted
reads\tabularnewline
\hline
itf8 & number of records & the number of records in the slice\tabularnewline
\hline
ltf8 & record counter & 1-based sequential index of records in the file/stream\tabularnewline
\hline
itf8 & number of blocks & the number of blocks in the slice\tabularnewline
\hline
itf8[ ] & block content ids & block content ids of the blocks in the slice\tabularnewline
\hline
itf8 & embedded reference bases block content id & block content id for the embedded
reference sequence bases or -1 for none\tabularnewline
\hline
byte[16] & reference md5 & MD5 checksum of the reference bases within the slice
boundaries or 16 \textbackslash{}0 bytes for unmapped or unsorted reads\tabularnewline
\hline
\end{tabular}
\subsection{\textbf{Core data block}}
A core data block is a bit stream (most significant bit first) consisting of one
or more CRAM records. Please note that one byte could hold more then one CRAM record
as a minimal CRAM record could be just a few bits long. The core data block has
the following fields:
\begin{tabular}{|l|>{\raggedright}p{120pt}|>{\raggedright}p{260pt}|}
\hline
\textbf{Data type} & \textbf{Name} & \textbf{Value}
\tabularnewline
\hline
bit[ ] & CRAM record 1 & The first CRAM record\tabularnewline
\hline
... & ... & ...\tabularnewline
\hline
bit[ ] & CRAM record N & The Nth CRAM record \tabularnewline
\hline
\end{tabular}
\subsection{\textbf{External data block}}
Relationship between core data block and external data blocks is shown in the following
picture:
%%\begin{figure}[htbp]
\includegraphics[width=451pt, height=350pt, keepaspectratio=true]{img/CRAMFileFormat2-1-fig007.png}
%%\caption{This should be the caption for \texttt{img/CRAMFileFormat2-1-fig007.png}.}
%%\end{figure}
Pic.3 Relationship between core data block and external data blocks.
The picture shows how a CRAM record (on the left) is partially written to core
data block while the other fields are stored in two external data blocks. The specific
encodings are presented only for demonstration purposes, the main point here is
to distinguish between bit encodings whose output is always stored in core data
block and the external encoding which simply stored the bytes into external data
blocks.
\section{\textbf{End of file marker}}
A special container is used to mark the end of a file or stream. It is optional
in version preceding 2.1 but required in later versions. The idea is to provide
an easy and a quick way to detect that a CRAM file or stream is complete. The marker
is basically an empty container with ref seq id set to -1 (unaligned) and alignment
start set to 4542278.
Here is a complete content of the EOF container explained in detail:
\begin{tabular}{|l|l|>{\raggedright}p{150pt}|>{\raggedright}p{180pt}|}
\hline
\textbf{hex bytes} & \textbf{data type} & \textbf{decimal value} & \textbf{field
name}\tabularnewline
\hline
\multicolumn{4}{|l|}{\textit{Container header}}\tabularnewline
\hline
0b 00 00 00 & integer & 11 & size of blocks data\tabularnewline
\hline
ff ff ff ff ff & itf8 & -1 & ref seq id\tabularnewline
\hline
e0 45 4f 46 & itf8 & 4542278 & alignment start\tabularnewline
\hline
00 & itf8 & 0 & alignment span\tabularnewline
\hline
00 & itf8 & 0 & nof records\tabularnewline
\hline
00 & itf8 & 0 & global record counter\tabularnewline
\hline
00 & itf8 & 0 & bases\tabularnewline
\hline
01 & itf8 & 1 & block count\tabularnewline
\hline
00 & array & 0 & landmarks\tabularnewline
\hline
\multicolumn{4}{|l|}{\textit{Compression header block}}\tabularnewline
\hline
00 & byte & 0 (RAW) & compression method\tabularnewline
\hline
01 & byte & 1 (COMPRESSION\_HEADER) & block content type\tabularnewline
\hline
00 & itf8 & 0 & block content id\tabularnewline
\hline
06 & itf8 & 6 & compressed size\tabularnewline
\hline
06 & itf8 & 6 & uncompressed size\tabularnewline
\hline
\multicolumn{4}{|l|}{\textit{Compression header}}\tabularnewline
\hline
01 & itf8 & 1 & preservation map byte size\tabularnewline
\hline
00 & itf8 & 0 & preservation map size\tabularnewline
\hline
01 & itf8 & 1 & encoding map byte size\tabularnewline
\hline
00 & itf8 & 0 & encoding map size\tabularnewline
\hline
01 & itf8 & 1 & tag encoding byte size\tabularnewline
\hline
00 & itf8 & 0 & tag encoding map size\tabularnewline
\hline
\end{tabular}
When compiled together the EOF marker is exactly 30 bytes long and in hex representation
is:
0b 00 00 00 ff ff ff ff ff e0 45 4f 46 00 00 00 00 01 00 00 01 00 06 06 01 00
01 00 01 00
\section{\textbf{Record structure}}
CRAM record is based on the SAM record but has additional features allowing for
more efficient data storage. In contrast to BAM record CRAM record uses bits as
well as bytes for data storage. This way, for example, various coding techniques
which output variable length binary codes can be used directly in CRAM. On the
other hand, data series that do not require binary coding can be stored separately
in external blocks with some other compression applied to them independently.
\subsection{\textbf{CRAM record}}
Both mapped and unmapped reads start with the following fields. Please note that
the data series type refers to the logical data type and the data series name corresponds
to the data series encoding map.
\begin{tabular}{|>{\raggedright}p{36pt}|>{\raggedright}p{70pt}|>{\raggedright}p{75pt}|>{\raggedright}p{90pt}|>{\raggedright}p{171pt}|}
\hline
& \textbf{Data series type} & \textbf{Data series name} & \textbf{Field} & \textbf{Description}\tabularnewline
\hline
1 & int & BF & CRAM bit flags & see CRAM record bit flags\tabularnewline
\hline
2 & int & CF & compression bit flags & see compression bit flags\tabularnewline
\hline
3 & int & RI & ref id & reference sequence id, not used for single reference slices,
reserved for future multiref slices. \tabularnewline
\hline
4 & int & RL & read length & the length of the read\tabularnewline
\hline
5 & int & AP & alignment start & the alignment start position *1\tabularnewline
\hline
6 & int & RG & read group & the read group identifier\tabularnewline
\hline
7 & byte & QS & quality scores & quality scores are stored depending on the value
of the `mapped QS included' field\tabularnewline
\hline
8 & byte[ ] & RN & read name & the read names (if preserved)\tabularnewline
\hline
9 & *2 & *2 & mate record & *2 (if not the last record)\tabularnewline
\hline
10 & int & TL & tag ids & tag ids *3\tabularnewline
\hline
11 & byte[ ] & - & tag values & tag values *3\tabularnewline
\hline
\end{tabular}
*1 The AP data series is delta encoded for reads mapped to a single reference slice
and normal integer value in all other cases.
*2 See \textbf{mate record} section.
*3 See \textbf{tag encoding} section.
The CRAM record structure for mapped reads has the following additional fields:
\begin{tabular}{|>{\raggedright}p{36pt}|>{\raggedright}p{70pt}|>{\raggedright}p{74pt}|>{\raggedright}p{85pt}|>{\raggedright}p{177pt}|}
\hline
& \textbf{Data series type} & \textbf{Data series name} & \textbf{Field} & \textbf{Description}\tabularnewline
\hline
1 & *1 & *1 & read feature records & *1\tabularnewline
\hline
2 & byte & MQ & mapping quality & read mapping quality\tabularnewline
\hline
\end{tabular}
*1 See read feature record specification below.
The CRAM record structure for unmapped reads has the following additional fields:
\begin{tabular}{|>{\raggedright}p{8pt}|>{\raggedright}p{88pt}|>{\raggedright}p{83pt}|>{\raggedright}p{85pt}|>{\raggedright}p{178pt}|}
\hline
& \textbf{Data series type} & \textbf{Data series name} & \textbf{Field} & \textbf{Description}\tabularnewline
\hline
1 & byte[read length] & BA & bases & the read bases\tabularnewline
\hline
\end{tabular}
\subsection{\textbf{Read bases}}
CRAM format supports ACGTN bases only. All non-ACGTN read bases must be replaced
with N (unknown) base. In case of mismatching non-ACGTN read base and non-ACGTN
reference base a ReadBase read feature should be used to capture the fact that
the read base should be restored as N base.
\subsection{\textbf{CRAM record bit flags (BF data series)}}
The following flags are defined for each CRAM read record:
\begin{tabular}{|>{\raggedright}p{144pt}|>{\raggedright}p{144pt}|>{\raggedright}p{144pt}|}
\hline
\textbf{Bit flag} & \textbf{Comment} & \textbf{Description}\tabularnewline
\hline
0x1 & ! 0x40 \&\& ! 0x80 & template having multiple segments in sequencing\tabularnewline
\hline
0x2 & & each segment properly aligned according to the aligner\tabularnewline
\hline
0x4 & & segment unmapped\tabularnewline
\hline
0x8 & calculated* or stored in the mate's info & next segment in the template unmapped\tabularnewline
\hline
0x10 & & SEQ being reverse complemented\tabularnewline
\hline
0x20 & calculated* or stored in the mate's info & SEQ of the next segment in the
template being reverse complemented\tabularnewline
\hline
0x40 & & the first segment in the template\tabularnewline
\hline
0x80 & & the last segment in the template\tabularnewline
\hline
0x100 & & secondary alignment\tabularnewline
\hline
0x200 & & not passing quality controls\tabularnewline
\hline
0x400 & & PCR or optical duplicate\tabularnewline
\hline
\end{tabular}
* For segments within the same slice.
\subsection{\textbf{Read feature records}}
Read features are used to store read details that are expressed using read coordinates
(e.g. base differences respective to the reference sequence). The read feature
records start with the number of read features followed by the read features themselves:
\begin{tabular}{|>{\raggedright}p{36pt}|>{\raggedright}p{65pt}|>{\raggedright}p{84pt}|>{\raggedright}p{90pt}|>{\raggedright}p{168pt}|}
\hline
& \textbf{Data series type} & \textbf{Data series name} & \textbf{Field} & \textbf{Description}\tabularnewline
\hline
1 & int & FN & number of read features & the number of read features\tabularnewline
\hline
2 *1 & int & FP & in-read-position & position of the read feature\tabularnewline
\hline
3 *1 & byte & FC & read feature code & *2\tabularnewline
\hline
4 *1 & *2 & *2 & read feature data & *2\tabularnewline
\hline