aboutsummaryrefslogtreecommitdiff
path: root/src/leveldb/doc/impl.html
diff options
context:
space:
mode:
Diffstat (limited to 'src/leveldb/doc/impl.html')
-rw-r--r--src/leveldb/doc/impl.html213
1 files changed, 213 insertions, 0 deletions
diff --git a/src/leveldb/doc/impl.html b/src/leveldb/doc/impl.html
new file mode 100644
index 000000000..e870795d2
--- /dev/null
+++ b/src/leveldb/doc/impl.html
@@ -0,0 +1,213 @@
+<!DOCTYPE html>
+<html>
+<head>
+<link rel="stylesheet" type="text/css" href="doc.css" />
+<title>Leveldb file layout and compactions</title>
+</head>
+
+<body>
+
+<h1>Files</h1>
+
+The implementation of leveldb is similar in spirit to the
+representation of a single
+<a href="http://labs.google.com/papers/bigtable.html">
+Bigtable tablet (section 5.3)</a>.
+However the organization of the files that make up the representation
+is somewhat different and is explained below.
+
+<p>
+Each database is represented by a set of files stored in a directory.
+There are several different types of files as documented below:
+<p>
+<h2>Log files</h2>
+<p>
+A log file (*.log) stores a sequence of recent updates. Each update
+is appended to the current log file. When the log file reaches a
+pre-determined size (approximately 4MB by default), it is converted
+to a sorted table (see below) and a new log file is created for future
+updates.
+<p>
+A copy of the current log file is kept in an in-memory structure (the
+<code>memtable</code>). This copy is consulted on every read so that read
+operations reflect all logged updates.
+<p>
+<h2>Sorted tables</h2>
+<p>
+A sorted table (*.sst) stores a sequence of entries sorted by key.
+Each entry is either a value for the key, or a deletion marker for the
+key. (Deletion markers are kept around to hide obsolete values
+present in older sorted tables).
+<p>
+The set of sorted tables are organized into a sequence of levels. The
+sorted table generated from a log file is placed in a special <code>young</code>
+level (also called level-0). When the number of young files exceeds a
+certain threshold (currently four), all of the young files are merged
+together with all of the overlapping level-1 files to produce a
+sequence of new level-1 files (we create a new level-1 file for every
+2MB of data.)
+<p>
+Files in the young level may contain overlapping keys. However files
+in other levels have distinct non-overlapping key ranges. Consider
+level number L where L >= 1. When the combined size of files in
+level-L exceeds (10^L) MB (i.e., 10MB for level-1, 100MB for level-2,
+...), one file in level-L, and all of the overlapping files in
+level-(L+1) are merged to form a set of new files for level-(L+1).
+These merges have the effect of gradually migrating new updates from
+the young level to the largest level using only bulk reads and writes
+(i.e., minimizing expensive seeks).
+
+<h2>Manifest</h2>
+<p>
+A MANIFEST file lists the set of sorted tables that make up each
+level, the corresponding key ranges, and other important metadata.
+A new MANIFEST file (with a new number embedded in the file name)
+is created whenever the database is reopened. The MANIFEST file is
+formatted as a log, and changes made to the serving state (as files
+are added or removed) are appended to this log.
+<p>
+<h2>Current</h2>
+<p>
+CURRENT is a simple text file that contains the name of the latest
+MANIFEST file.
+<p>
+<h2>Info logs</h2>
+<p>
+Informational messages are printed to files named LOG and LOG.old.
+<p>
+<h2>Others</h2>
+<p>
+Other files used for miscellaneous purposes may also be present
+(LOCK, *.dbtmp).
+
+<h1>Level 0</h1>
+When the log file grows above a certain size (1MB by default):
+<ul>
+<li>Create a brand new memtable and log file and direct future updates here
+<li>In the background:
+<ul>
+<li>Write the contents of the previous memtable to an sstable
+<li>Discard the memtable
+<li>Delete the old log file and the old memtable
+<li>Add the new sstable to the young (level-0) level.
+</ul>
+</ul>
+
+<h1>Compactions</h1>
+
+<p>
+When the size of level L exceeds its limit, we compact it in a
+background thread. The compaction picks a file from level L and all
+overlapping files from the next level L+1. Note that if a level-L
+file overlaps only part of a level-(L+1) file, the entire file at
+level-(L+1) is used as an input to the compaction and will be
+discarded after the compaction. Aside: because level-0 is special
+(files in it may overlap each other), we treat compactions from
+level-0 to level-1 specially: a level-0 compaction may pick more than
+one level-0 file in case some of these files overlap each other.
+
+<p>
+A compaction merges the contents of the picked files to produce a
+sequence of level-(L+1) files. We switch to producing a new
+level-(L+1) file after the current output file has reached the target
+file size (2MB). We also switch to a new output file when the key
+range of the current output file has grown enough to overlap more then
+ten level-(L+2) files. This last rule ensures that a later compaction
+of a level-(L+1) file will not pick up too much data from level-(L+2).
+
+<p>
+The old files are discarded and the new files are added to the serving
+state.
+
+<p>
+Compactions for a particular level rotate through the key space. In
+more detail, for each level L, we remember the ending key of the last
+compaction at level L. The next compaction for level L will pick the
+first file that starts after this key (wrapping around to the
+beginning of the key space if there is no such file).
+
+<p>
+Compactions drop overwritten values. They also drop deletion markers
+if there are no higher numbered levels that contain a file whose range
+overlaps the current key.
+
+<h2>Timing</h2>
+
+Level-0 compactions will read up to four 1MB files from level-0, and
+at worst all the level-1 files (10MB). I.e., we will read 14MB and
+write 14MB.
+
+<p>
+Other than the special level-0 compactions, we will pick one 2MB file
+from level L. In the worst case, this will overlap ~ 12 files from
+level L+1 (10 because level-(L+1) is ten times the size of level-L,
+and another two at the boundaries since the file ranges at level-L
+will usually not be aligned with the file ranges at level-L+1). The
+compaction will therefore read 26MB and write 26MB. Assuming a disk
+IO rate of 100MB/s (ballpark range for modern drives), the worst
+compaction cost will be approximately 0.5 second.
+
+<p>
+If we throttle the background writing to something small, say 10% of
+the full 100MB/s speed, a compaction may take up to 5 seconds. If the
+user is writing at 10MB/s, we might build up lots of level-0 files
+(~50 to hold the 5*10MB). This may signficantly increase the cost of
+reads due to the overhead of merging more files together on every
+read.
+
+<p>
+Solution 1: To reduce this problem, we might want to increase the log
+switching threshold when the number of level-0 files is large. Though
+the downside is that the larger this threshold, the more memory we will
+need to hold the corresponding memtable.
+
+<p>
+Solution 2: We might want to decrease write rate artificially when the
+number of level-0 files goes up.
+
+<p>
+Solution 3: We work on reducing the cost of very wide merges.
+Perhaps most of the level-0 files will have their blocks sitting
+uncompressed in the cache and we will only need to worry about the
+O(N) complexity in the merging iterator.
+
+<h2>Number of files</h2>
+
+Instead of always making 2MB files, we could make larger files for
+larger levels to reduce the total file count, though at the expense of
+more bursty compactions. Alternatively, we could shard the set of
+files into multiple directories.
+
+<p>
+An experiment on an <code>ext3</code> filesystem on Feb 04, 2011 shows
+the following timings to do 100K file opens in directories with
+varying number of files:
+<table class="datatable">
+<tr><th>Files in directory</th><th>Microseconds to open a file</th></tr>
+<tr><td>1000</td><td>9</td>
+<tr><td>10000</td><td>10</td>
+<tr><td>100000</td><td>16</td>
+</table>
+So maybe even the sharding is not necessary on modern filesystems?
+
+<h1>Recovery</h1>
+
+<ul>
+<li> Read CURRENT to find name of the latest committed MANIFEST
+<li> Read the named MANIFEST file
+<li> Clean up stale files
+<li> We could open all sstables here, but it is probably better to be lazy...
+<li> Convert log chunk to a new level-0 sstable
+<li> Start directing new writes to a new log file with recovered sequence#
+</ul>
+
+<h1>Garbage collection of files</h1>
+
+<code>DeleteObsoleteFiles()</code> is called at the end of every
+compaction and at the end of recovery. It finds the names of all
+files in the database. It deletes all log files that are not the
+current log file. It deletes all table files that are not referenced
+from some level and are not the output of an active compaction.
+
+</body>
+</html>