Version: | 0.10.1 |
---|---|
Download: | http://pypi.python.org/pypi/kairos |
Source: | https://github.com/agoragames/kairos |
Keywords: | python, redis, mongo, sql, mysql, sqlite, postgresql, cassandra, timeseries, rrd, gevent, statistics |
Kairos provides time series storage using Redis, Mongo, SQL or Cassandra backends. Kairos is intended to replace RRD and Whisper in situations where the scale and flexibility of other data stores is required. It works with gevent and is the library on which torus is built.
Recommended for python 2.7 and later, it can work with previous versions if you install OrderedDict.
Kairos provides a consistent API for a variety of timeseries types and the
storage engines they're implemented in. Each timestamp is resolved to a
consistent bucket identifier ("interval") based on the number of whole seconds
since epoch, or a number corresponding to the Gregorian date associated with
the relative intervals [daily, weekly, monthly, yearly]
(e.g 19991231
).
Within that, data can optionally be stored at resolutions (e.g. "daily,
in 1 hour increments"). Multiple intervals can be tracked within a timeseries,
each with its own resolution and optional TTL (e.g. 60 days of daily data,
lifetime monthly data).
In data stores that support it, TTLs can be set for automatically deleting
data after a set number of intervals; other data stores expose an expire()
method for deleting data programmatically.
Within each interval (or resolution), data is stored according to the type of the timeseries and what each backend supports. The values tracked in each timeseries can be loosely typed for backends that support it, else the type will be whatever is set in the timeseries constructor. Even when loosely typed, it should be assumed that the value should be a string or number.
- series
- All data will be stored in the order in which it arrives. Uses data store list types where supported, else it will be timestamped records that come as close as possible to the order in which they were written. Queries will return list objects.
- histogram
- A hash of unique values to the number of its occurrences within an interval. Uses data store dictionaries where supported, else it will be separate records for each unique value and timestamp. Queries will return dictionary objects. Built-in transforms assume that keys are real numbers.
- count
- A simple counter will be maintained for each interval, starting at 0 for an interval. Queries will return an integer.
- gauge
- Stores the last-written value for each interval. Queries will return whatever the value type was.
- set
- Stores all the unique values within an interval. Uses data store sets where supported, else it will be separate records for each unique value. Queries will return set objects.
Kairos supports all storage engines using the same API. The constructor will return a Timeseries instance tailored for the type of data and the storage engine, and the API for updating and querying the timeseries is consistent for all combinations of data type and storage engine.
The first argument is a handle to a supported storage engine or a URL (see below), and the rest of the keyword arguments configure the timeseries. The keyword arguments supported by all storage engines are:
- type
- Required, defines the type of the timeseries. Raises a
NotImplementedError
if the backend does not support the type. - read_func
- Optional, is a function applied to all values read back from the database. Without it, values will be strings for Redis, whatever write_func defined for Mongo. Must accept a string value for Redis (empty string for no data) and can return anything.
- write_func
- Optional, is a function applied to all values when writing. Can be used for histogram resolution, converting an object into an id, etc. Must accept whatever can be inserted into a timeseries and return an object which can be saved according to the rules of the storage engine.
- intervals
Required, a dictionary of interval configurations in the form of:
{ # interval name, used in keys and should conform to best # practices according to the storage engine. minute: { # Required. The number of seconds that the interval will cover, # or a supported Gregorian interval. step: 60, # Optional. The maximum number of intervals to maintain. If supplied, # will use Redis and Mongo expiration to delete old intervals, else # intervals exist in perpetuity. If the storage engine doesn't support # expiry, will be used to implement the expire() call. steps: 240, # Optional. Defines the resolution of the data, i.e. the number of # seconds in which data is assumed to have occurred "at the same time". # So if you're tracking a month-long time series, you may only need # resolution down to the day, or resolution=86400. Defaults to same # value as "step". Can also be a Gregorian interval. resolution: 60, } }
In addition to specifying
step
andresolution
in terms of seconds, kairos also supports a simplified format for larger time intervals. For hours (h), days (d), weeks (w), months (m) and years (y), you can use the format30d
to represent 30 days, for example.As of
0.3.0
, kairos also supports the Gregorian calendar forstep
andresolution
. Either or both parameters can use the terms[daily, weekly, monthly, yearly]
to describe an interval. You can also mix these terms betweenstep
andresolution
(e.g.daily
in1h
resolutions). The expiration time for Gregorian dates is still defined in terms of seconds and may not match the varying month lengths, leap years, etc. Gregorian dates are translated intostrptime
- andstrftime
-compatible keys (as integers) and so may be easier to use in raw form or with any external tools. Theduration
parameter to transforms run on gregorian series will be seconds in whole number of days (where a day is 86400 seconds).
Each of the supported storage engines also supports a set of keyword arguments
to configure their behavior. When intializing with a URL, the keyword argument
client_config
can optionally be a dictionary which will be passed as
keyword arguments to the constructor for the client associated with the URL.
If kairos implements any custom keyword arguments from client_config
those
are documented below.
An example timeseries stored in Redis:
from kairos import Timeseries import redis client = redis.Redis('localhost', 6379) t = Timeseries(client, type='histogram', read_func=float, intervals={ 'minute':{ 'step':60, # 60 seconds 'steps':120, # last 2 hours } }) t.insert('example', 3.14159) t.insert('example', 2.71828) print t.get('example', 'minute')
Additional keyword arguments are:
prefix Optional, is a prefix for all keys in this timeseries. If supplied and it doesn't end with ":", it will be automatically appended.
Supported URL formats:
redis://localhost redis://localhost/3
All supported configuration options can be passed in client_config
.
An example timeseries stored in Mongo:
from kairos import Timeseries import pymongo client = pymongo.MongoClient('localhost') t = Timeseries(client, type='histogram', read_func=float, intervals={ 'minute':{ 'step':60, # 60 seconds 'steps':120, # last 2 hours } }) t.insert('example', 3.14159) t.insert('example', 2.71828) print t.get('example', 'minute')
Additional keyword arguments are:
escape_character Optional, defines the character used to escape periods. Defaults to the unicode character "U+FFFF".
Supported URL formats:
mongodb://localhost mongodb://localhost:27018/timeseries mongodb://guest:host@localhost/authed_db
All supported configuration arguments can be passed in client_config
, in addition to:
database The name of the database to use. Defaults to 'kairos'. Required if using an auth database. Overrides any database provided in the URL.
An example timeseries stored in a SQLite memory store:
from kairos import Timeseries from sqlalchemy import create_engine client = create_engine('sqlite:///:memory:') t = Timeseries(client, type='histogram', read_func=int, intervals={ 'minute':{ 'step':60, # 60 seconds 'steps':120, # last 2 hours } }) t.insert('example', 3.14159) t.insert('example', 2.71828) print t.get('example', 'minute')
Additional keyword arguments are:
string_length Optional, configures the length of strings (VARCHARs). Defaults to 255. All tables have at least 2 string columns, and the size of these columns may impact usability of the SQL storage engine. text_length Optional, configures the length of TEXT and BLOB columns. Defaults to 32Kbytes. Only matters if value_type is a text or blob. table_name Optional, overrides the default table name for a timeseries type. value_type Optional, defines the type of value to be stored in the timeseries. Defaults to float. Can be a string, a Python type or a SQLAlchemy type or instance. 'blob' 'bool' <type 'bool'> 'boolean' 'clob' 'date' <type 'datetime.date'> 'datetime' <type 'datetime.datetime'> 'decimal' <class 'decimal.Decimal'> 'float' <type 'float'> 'int' 'int64' 'integer' <type 'int'> 'long' <type 'long'> 'str' 'string' <type 'str'> 'text' 'time' <type 'datetime.time'> 'unicode' <type 'unicode'>
Supported URL formats are many and varied. A few examples:
sqlite:///:memory: postgresql://scott:tiger@localhost/mydatabase mysql+mysqldb://scott:tiger@localhost/foo oracle://scott:[email protected]:1521/sidname
All supported constructor arguments can be used in client_config
.
An example timeseries stored in Cassandra:
from kairos import Timeseries import cql client = cql.connect('localhost', 9160, 'keyspace', cql_version='3.0.0') t = Timeseries(client, type='histogram', read_func=int, intervals={ 'minute':{ 'step':60, # 60 seconds 'steps':120, # last 2 hours } }) t.insert('example', 3.14159) t.insert('example', 2.71828) print t.get('example', 'minute')
Additional keyword arguments are:
table_name Optional, overrides the default table name for a timeseries type. pool_size Optional, set a cap on the pool size. Defines the maximum number of connections to maintain in the pool. Defaults to 0 for no maximum. value_type Optional, defines the type of value to be stored in the timeseries. Defaults to float. Can be a string or a Python type. <type 'unicode'> string decimal <type 'long'> int double unicode float long <type 'bool'> <type 'float'> boolean int64 str text blob clob integer bool <type 'str'> <type 'int'> inet
Supported URL formats are:
cql:// cassandra://localhost:9160 cassandra://localhost/database
All supported constructor arguments can be used in client_config
.
kairos requires cql as it supports
CQL3 and gevent. This
requires that the keyspace be created before the connection, and the keyword
argument cql_version='3.0.0'
must be used.
A notable downside of this library is that it does not support a list of endpoints to connect to, so is missing key High Availability features.
It is likely that future versions of kairos will require cassandra-driver when it is ready.
Cassandra counters can only store integers, and cannot be used for a running total of floating point numbers.
Kairos implements a connection pooling mechanism on top of cql. The pool is a simple soft-cap on the number of connections maintained in the pool, but not necessarily the total number of connections at a time. An optional hard cap may be implemented in a future release.
There are two methods to insert data, Timeseries.insert
and Timeseries.bulk_insert
.
- name The name of the statistic
- value The value of the statistic (optional for count timeseries), or a list of values
- timestamp (optional) The timestamp of the statistic, defaults to
time.time()
if not supplied - intervals (optional) The number of time intervals before (<0) or after (>0)
timestamp
to copy the data - **kwargs (optional) Any additional keyword arguments supported by a backend, see below
For series
and histogram
timeseries types, value
can be whatever
you'd like, optionally processed through the write_func
method before being
written to storage. Depending on your needs, value
(or the output of
write_func
) does not have to be a number, and can be used to track such
things as unique occurances of a string or references to other objects, such
as MongoDB ObjectIds. Note that many of the aggregate functions in histogram
expect the data to be real numbers.
For the count
type, value
is optional and should be a float or integer
representing the amount by which to increment or decrement name
; it defaults
to 1
.
For the gauge
type, value
can be anything and it will be stored as-is.
For all timeseries types, if value
is one of (list,tuple,set)
, will
call bulk_insert
.
The intervals
option allows the caller to simulate the value appearing in
time periods before or after the timestamp
. This is useful for creating
fast trending (e.g. "count over last seven days"). It is important to note
that, because the time periods are simulated, resolution is lost for the
the simulated timestamps.
Redis supports an additional keyword argument, pipeline
, to give the caller
control over batches of commands. If pipeline
is supplied, the execute
method will not be called and it is up to the caller to do so.
- inserts The structure of inserts (see below)
- intervals (optional) The number of time intervals before (<0) or after (>0)
timestamp
to copy the data - **kwargs (optional) Any additional keyword arguments supported by a backend, see below
The inserts
field must take the following form:
{ timestamp : { name: [ value, ... ], ... }, ... }
The meaning of timestamp
, name
and value
are identical to those
parameters in insert
. The caller can insert any number of timestamps,
statistic names and values, and the backend will optimize the insert where
possible. See details on the different backends below. Where a backend does
not support an optimized bulk insert, the data structure will be processed
such that each value will be passed to insert
.
The inserts
structure can be a dict
or OrderedDict
. If you need
the insert order preserved, such as when inserting into a series
or
gauge
, you should use OrderedDict
.
If timestamp
is unknown, use None
for the key and it will be set to
the current value of time.time()
. Note that this may alter ordering if
inserts
is an OrderedDict
.
NOTE bulk inserts will increase memory usage of the client process.
Redis bulk inserts are implemented by using a single pipeline (without
transactions) and committing the pipeline after all bulk inserts have been
executed. The bulk insert also supports the pipeline
argument, with the
same rules as insert
.
Mongo bulk inserts are implemented by joining all of the data together into
a condensed set of queries and updates. As the configuration of a timeseries
may result in multiple timestamps resolving to the same record (e.g. per-day
data), this could result in significant performance gains when the timeseries
is a count
, histogram
or gauge
.
There is no optimization for bulk inserts in SQL due to the lack of native update-or-insert support. The generic SQL implementation requires an attempted update to be committed before kairos can determine if an insert is required. Future versions may have optimized implementations for specific SQL servers which support such a feature, at which time bulk inserts may be optimized for those specific backends.
The cql
library has no support for transactions, grouping, etc.
There are two methods to query meta data about a Timeseries.
There are no arguments. Returns a list of all of the stat names stored in the Timeseries.
Takes a single argument, the name of the timeseries. Returns a dictionary with the following fields:
{ interval : { 'first' : timestamp, 'last' : timestamp } }
interval
will be the named interval, such as "minute". For each interval,
there is a dictionary of properties. first
is the timestamp of the first
data point in the timeseries, and last
is the last data point in the
timeseries.
There are three methods to read data, Timeseries.get
, Timeseries.series
and Timeseries.iterate
. get
will return data from a single bucket,
and series
will return data from several buckets. iterate
will use
the Timeseries.properties
method to determine the date range of the data,
and return a generator that calls get
for every possible interval in
the date range.
Supports the following parameters. All optional parameters are keyword arguments.
- name The name of the statistic, or a list of names whose data will be joined together.
- interval The named interval to read from
- timestamp (optional) The timestamp to read, defaults to
time.time()
- condensed (optional) DEPRECATED Use
condense
instead. Support for this will be removed entirely in a future release. - transform (optional) Optionally process each row of data. Supports
[mean, count, min, max, sum]
, or any callable that accepts datapoints according to the type of series (e.g histograms are dictionaries, counts are integers, etc). Transforms are called afterread_func
has cast the data type and after resolution data is optionally condensed. Iftransform
is one of(list,tuple,set)
, will load the data once and run all the transforms on that data set. Iftransform
is adict
of the form{ transform_name : transform_func }
, will run all of the transform functions on the data set. See Customized Reads for more on custom transforms. - fetch (optional) Function to use instead of the built-in implementations for fetching data. See Customized Reads.
- process_row (optional) Can be a callable to implement Customized Reads.
- condense (optional) If using resolutions,
True
will collapse the resolution data into a single row. Can be a callable to implement Customized Reads. - join_rows (optional) Can be a callable to implement Customized Reads.
Returns a dictionary of { timestamp : data }
, where timestamp
is a Unix timestamp
and data
is a data structure corresponding to the type of series, or whatever
transform
returns. If not using resolutions or condense=True
, the length
of the dictionary is 1, else it will be the number of resolution buckets within
the interval that contained data. If transform
is a list, data
will be a
dictionary of { transform_func : transformed_data }
. If transform
is a dict
,
data
will be a dictionary of { transform_name : transformed_data }
.
Almost identical to get
, supports the following parameters. All optional parameters are keyword arguments.
- name The name of the statistic, or a list of names whose data will be joined together.
- interval The named interval to read from
- start (optional) The timestamp which should be in the first interval of the returned data.
- end (optional) The timestamp which should be in the last interval of the returned data.
- steps (optional) The number of steps in the interval to read, defaults to either
steps
in the configuration or 1. Ignored if bothstart
andend
are defined. If eitherstart
orend
are defined,steps
is inclusive of whatever interval that timestamp falls into. - condensed (optional) DEPRECATED Use
condense
instead. Support for this will be removed entirely in a future release. - transform (optional) Optionally process each row of data. Supports
[mean, count, min, max, sum]
, or any callable that accepts a list of datapoints according to the type of series (e.g histograms are dictionaries, counts are integers, etc). Transforms are called afterread_func
has cast the data type and after resolution data is optionally condensed. Iftransform
is one of(list,tuple,set)
, will load the data once and run all the transforms on that data set. Iftransform
is adict
of the form{ transform_name : transform_func }
, will run all of the transform functions on the data set. See Customized Reads for more on custom transforms. - fetch (optional) Function to use instead of the built-in implementations for fetching data. See Customized Reads.
- process_row (optional) Can be a callable to implement Customized Reads.
- condense (optional) If using resolutions,
True
will collapse the resolution data into a single row. Can be a callable to implement Customized Reads. - join_rows (optional) Can be a callable to implement Customized Reads.
- collapse (optional)
True
will collapse all of the data in the date range into a single result. Can be a callable to implement Customized Reads.
Returns an ordered dictionary of { interval_timestamp : { resolution_timestamp: data } }
,
where interval_timestamp
and resolution_timestamp
are Unix timestamps
and data
is a data structure corresponding to the type of series, or whatever
transform
returns. If not using resolutions or condense=True
, the dictionary
will be of the form { interval_timestamp : data }
.
All variations of transform
and the resulting format of data
are the same
as in get
.
If both start
and end
are defined, the returned data will start and end
on intervals including those timestamps. If only start
is defined, then the
return data will start with an interval that includes that timestamp, with the
total number of intervals returned defined by steps
. If only end
is
defined, then the return data will end with an interval that includes that
timestamp, with the total number of intervals preceeding it defined by steps
.
It is important to note that the interval timestamps in the returned data will
not necessarily match start
or end
. This is because of the consistent
hashing scheme that kairos uses, such that start
and end
will be
translated into the bucket in which it can be found.
Almost identical to get
except it does not accept a timestamp
argument.
- name The name of the statistic, or a list of names whose data will be joined together.
- interval The named interval to read from
- transform (optional) Optionally process each row of data. Supports
[mean, count, min, max, sum]
, or any callable that accepts datapoints according to the type of series (e.g histograms are dictionaries, counts are integers, etc). Transforms are called afterread_func
has cast the data type and after resolution data is optionally condensed. Iftransform
is one of(list,tuple,set)
, will load the data once and run all the transforms on that data set. Iftransform
is adict
of the form{ transform_name : transform_func }
, will run all of the transform functions on the data set. See Customized Reads for more on custom transforms. - fetch (optional) Function to use instead of the built-in implementations for fetching data. See Customized Reads.
- process_row (optional) Can be a callable to implement Customized Reads.
- condense (optional) If using resolutions,
True
will collapse the resolution data into a single row. Can be a callable to implement Customized Reads. - join_rows (optional) Can be a callable to implement Customized Reads.
Returns a generator which iterates over ( timestamp, data )
tuples, where
timestamp
is a Unix timestamp and data
corresponds to the rules
documented in get
. Yields a tuple for each potential timestamp in the
entire date range of the timeseries, even if there is no data.
ALPHA This feature is still being explored and the API may change significantly.
There are times when the data in a timeseries requires processing to be pushed onto the datastore.
There are times when one needs custom control over the reading and processing
of data in a timeseries. As there is no good way to do this generically,
the get
and series
API supports several keyword arguments to customize
access to the data. Common use cases are to handle large sets of data that
can be processed in the datastore, and situations where one wants to implement
cutom analysis of the dataset such as calculating variance.
The following functions can be overloaded with keyword parameters to get
and
series
(collapse
being only used for a series).
A customized database read function. The usage varies depending on the backends which are described in detail below. IMPORTANT You are welcome to change the type of the return value, but be wary that transforms, condense and collapse functionality may not work properly with the changed data types.
The function which handles the type casting of the data read from the backend
and also calling the read_func
if it has been defined for the time series.
It is required that you define this function if you overload fetch
such
that the returned data type is not the same as the time series' native format
(dict
for histogram, list
for series, etc).
The function must be in the form of process_row(data)
, where:
- data The row data generated by the native or
fetch
implementation, not including any time stamps.
The function may return any data type, but if it's not the native format of the time series, additional downstream functions may have to be overloaded.
If the condense
argument is a callable, the caller can override how resolution
data is collapsed (reduced) into a single interval. The argument will always be
in the form of:
{ 'resolution_t0' : <data_t0>, 'resolution_t1' : <data_t1>, ... 'resolution_tN' : <data_tN>, }
Where <data_tN>
is the data returned from the native or fetch
implementation and passed through the native or custom process_row
implementation.
The function should return a single value, optionally in the same format as
<data_tN>
, but this method could also be used for calculating such
things as rate of change or variance within a time interval.
If the join_rows
argument is a callable and the name
parameter to get
or series
is one of (list,tuple,set)
, this method will be called to join
the data from several named timeseries into a single result. The argument will
always be in the form of:
[ <data_series0>, <data_series1>, ... <data_seriesN> ]
Where <data_series0>
will be the data within a single timestamp window in
the series' native format or whatever was generated by custom implementations
of fetch
, process_row
and/or condense
. It is important to note
that not every series will contain data points within a given time interval.
In addition to reducing multiple time series' worth of data within an interval into a single result, this method could be used to implement cross-series analytics such as unions, intersections and differentials.
If the collapse
argument is a callable, the caller can override how interval
data is collapsed (reduced) into a single result. The native implementation is to
call the condense
function implemented by a time series. The arguments are
the same as a custom condense
function, as-is the expected return value.
It's important to note that if collapse
is defined, the series will
automatically be condensed as well, so if fetch
is overloaded to return a
custom data type, then condense
must also be defined. If collapse
is
True
, the custom condense
function will be used if defined.
In addition to collapsing the result of a time series into a single data set, this method could also be used to calculate data across a time series, such as variance.
As noted previously, transform
can be any callable, list of names or callables,
or a named map of transform names or callables. The transforms will be processed
after all previous native or custom read functions, including collapse
.
Transforms must accept 2 parameters, the data and the time interval in seconds
over which that data was captured. The data
parameter will be of a type
corresponding to the timeseries type, or whatever was generated by a custom
fetch
. For example:
def custom_rate_for_counts(data, duration): return float(data) / float(duration)
For gregorian timeseries, duration
will seconds in terms of the whole
number of days over which the data was captured, where a day is 86400 seconds.
The function must be in the form of fetch(handle, key)
, where:
- handle Either a Redis client or pipeline instance
- key The key for the timeseries data
The return value should correspond to the data type of timeseries, e.g. dict
for a histogram. One should always assume that handle
is both a pipeline
and a client, and fetch
should return the result of, e.g.
handle.hlen(...)
, but that it cannot be used to return a literal, such
as lambda: h,k: { 'foo' : h.hlen(k) }
The function must be in the form of fetch(handle, **kwargs)
, where:
- handle A PyMongo
Collection
- spec The (suggested) query specification
- sort The (suggested) sort definition for the query
- method The suggested method to use on the
handle
The required return value depends on the value of method
.
- find_one Should return a hash in the form
{ value : <data> }
, where<data>
should correspond to the data type of the timeseries, e.g.list
for a series. May directly return a result frompymongo.collection.find_one
. - find Should return an iterable in the form
[ { value: <data> }, ... ]
, where<data>
follows the same rules asfind_one
.
Re-implementing the default functionality would look like:
def mongo_fetch(handle, spec, sort, method): if method=='find': return handle.find( spec=spec, sort=sort ) elif method=='find_one': return handle.find_one( spec )
The function must be in the form
fetch(connection, table, name, interval, i_start, i_end)
, where:
- connection A SQLAlchemy
Connection
- table A SQLAlchemy
Table
- name The name of the stat to fetch
- interval The interval of the stat to fetch
- i_start The interval timestamp (starting) key
- i_end (optional) For a series, the ending timestamp key
The return value should be in the form of
{ 'interval_t0' : { 'resolution_t0t0' : <data_t0t0>, 'resolution_t0t1' : <data_t0t1>, ... 'resolution_t0tN' : <data_t0tN> }, 'interval_t1' : { ... }, ... 'interval_tN' : { ... }, }
If the series doesn't use resolutions, then resolution_tNtN
should be
None
, and so each interval will be in the form
{ 'interval_tN: { None : <data_tN> } }
. This is inherent in the way that
data is stored within the tables.
If i_end
is supplied, the query should be over the range
i_time >= i_start AND i_time <= i_end
, else the query should be for
the interval i_time = i_start
.
The function must be in the form
fetch(connection, table, name, interval, i_start, i_end)
, where:
- cursor A
cql
Connection
- table The name of the table
- name The name of the stat to fetch
- interval The interval of the stat to fetch
- intervals The list of interval timestamps
The return value should be in the form of
{ 'interval_t0' : { 'resolution_t0t0' : <data_t0t0>, 'resolution_t0t1' : <data_t0t1>, ... 'resolution_t0tN' : <data_t0tN> }, 'interval_t1' : { ... }, ... 'interval_tN' : { ... }, }
If the series doesn't use resolutions, then resolution_tNtN
should be
None
, and so each interval will be in the form
{ 'interval_tN: { None : <data_tN> } }
and can be determined when a row
has an r_time
of -1
.
If intervals
is a list of 1, it's effectively a get
query where
i_time = intervals[0]
, else it's i_time >= intervals[0] AND
i_time <= intervals[-1]
. The full list of intervals is supplied to workaround
Cassandra's lack of grouping support in situations where an aggregate per
i_time
is desired.
Takes a single argument, the name of the timeseries. Will delete all data for that timeseries in all intervals.
Deletes every timeseries for all intervals. This method may be fast in data
stores that support optimized deletes, else it will have to delete for each
timeseries returned in list
.
Takes a single argument, the name of the timeseries. For storage engines that
do not support expiry, such as SQL, will delete expired data from intervals
for which steps
is defined. All other storage engines will raise the
NotImplementedError
exception.
Kairos achieves its efficiency by using TTLs and data structures in combination with a key naming scheme that generates consistent keys based on any timestamp relative to epoch. However, just like RRDtool, changing any attribute of the timeseries means that new data will be stored differently than old data. For this reason it's best to completely delete all data in an old time series before creating or querying using a new configuration.
If you want to migrate data, there are tools in torus that can help.
Kairos is available on pypi and can be
installed using pip
pip install kairos
If installing from source:
with development requirements (e.g. testing frameworks)
pip install -r development.pip
without development requirements
pip install -r requirements.pip
Note that kairos does not install packages for any of the supported backends, and that you must do this yourself.
Use nose to run the test suite.
$ nosetests
The test suite can be controlled through several environment variables, all
defaulting to true
.
- TEST_REDIS true
- TEST_MONGO true
- TEST_SQL true
- TEST_CASSANDRA true
- TEST_SERIES true
- TEST_HISTOGRAM true
- TEST_COUNT true
- TEST_GAUGE true
- TEST_SET true
- SQL_HOST sqlite:///:memory:
- CASSANDRA_KEYSPACE kairos
- Round-robbin intervals for datastores without TTLs
- Round-robbin databases: memcache (and compatible, e.g. ElastiCache), Riak, DynamoDB, SimpleDB, GDBM, Berkeley DB, and more
- Redis optimizations
- Capped collection support for mongo
- Python 3 support
- InfluxDB support
- Bloom filters
- Joined series populate a data structure at query time
- Joined series support concurrency "runner"
This software is licensed under the New BSD License. See the LICENSE.txt
file in the top distribution directory for the full license text.