PyEpics Overview¶
The python epics
package provides several function, modules, and
classes to interact with EPICS Channel Access. The simplest approach uses
the functions caget()
, caput()
, and cainfo()
within the
top-level epics module to get and put values of Epics Process Variables.
These functions are similar to the standard command line utilities and the
EZCA library interface, and are described in more detail below.
To use the epics
package, import it with:
import epics
The main components of this module include
functions
caget()
,caput()
,cainfo()
and others described in more detail below.a
ca
module, providing the low-level library as a set of functions, meant to be very close to the C library for Channel Access.a
PV
object, representing a Process Variable (PV) and giving a higher-level interface to Epics Channel Access.a
Device
object: a collection of related PVs, similar to an Epics Record.a
Motor
object: a Device that represents an Epics Motor.an
Alarm
object, which can be used to set up notifications when a PV’s values goes outside an acceptable bounds.an
epics.wx
module that provides wxPython classes designed for use with Epics PVs.
If you’re looking to write quick scripts or a simple introduction to using
Channel Access, the caget()
and caput()
functions are probably
where you want to start.
If you’re building larger scripts and programs, using PV
objects
is recommended. The PV
class provides a Process Variable (PV)
object that has methods (including get()
and put()
) to read and
change the PV, and attributes that are kept automatically synchronized with
the remote channel. For larger applications where you find yourself
working with sets of related PVs, you may find the Device
class
helpful.
The lowest-level CA functionality is exposed in the ca
module, and
companion dbr
module. While not necessary recommended for most use
cases, this module does provide a fairly complete wrapping of the basic
EPICS CA library. For people who have used CA from C or other languages,
this module should be familiar and seem quite usable, if a little more
verbose and C-like than using PV objects.
In addition, the epics package contains more specialized modules for alarms, Epics motors, and several other devices (collections of PVs), and a set of wxPython widget classes for using EPICS PVs with wxPython.
The epics package is supported and well-tested on Linux, Mac OS X, and Windows with Python versions 2.7, and 3.5 and above.
Quick Start¶
Whether you’re familiar with Epics Channel Access or not, start here. You’ll then be able to use Python’s introspection tools and built-in help system, and the rest of this document as a reference and for detailed discussions.
Procedural Approach: caget(), caput()¶
To get values from PVs, you can use the caget()
function:
>>> from epics import caget, caput, cainfo
>>> m1 = caget('XXX:m1.VAL')
>>> print(m1)
1.2001
To set PV values, you can use the caput()
function:
>>> caput('XXX:m1.VAL', 1.90)
>>> print(caget('XXX:m1.VAL'))
1.9000
To see more detailed information about a PV, use the cainfo()
function:
>>> cainfo('XXX:m1.VAL')
== XXX:m1.VAL (time_double) ==
value = 1.9
char_value = '1.9000'
count = 1
nelm = 1
type = time_double
units = mm
precision = 4
host = somehost.aps.anl.gov:5064
access = read/write
status = 0
severity = 0
timestamp = 1513352940.872 (2017-12-15 09:49:00.87179)
posixseconds = 1513352940.0
nanoseconds= 871788105
upper_ctrl_limit = 50.0
lower_ctrl_limit = -48.0
upper_disp_limit = 50.0
lower_disp_limit = -48.0
upper_alarm_limit = 0.0
lower_alarm_limit = 0.0
upper_warning_limit = 0.0
lower_warning_limit = 0.0
PV is internally monitored, with 0 user-defined callbacks:
=============================
The simplicity and clarity of these functions make them ideal for many uses.
Creating and Using PV Objects¶
If you are repeatedly referencing the same PV, you may find it more convenient to create a PV object and use it in a more object-oriented manner.
>>> from epics import PV
>>> pv1 = PV('XXX:m1.VAL')
PV objects have several methods and attributes. The most important methods
are get()
and put()
to receive and send the PV’s value, and
the value
attribute which stores the current value. In analogy to
the caget()
and caput()
examples above, the value of a PV can
be fetched either with
>>> print(pv1.get())
1.90
or
>>> print(pv1.value)
1.90
To set a PV’s value, you can either use
>>> pv1.put(1.9)
or assign the value
attribute
>>> pv1.value = 1.9
You can see a few of the most important properties of a PV by simply printing it:
>>> print(pv1)
<PV 'XXX:m1.VAL', count=1, type=time_double, access=read/write>
More complete information can be seen by printing the PVs info
attribute:
>>> print(pv1.info)
== XXX:m1.VAL (time_double) ==
value = 1.9
char_value = '1.9000'
count = 1
nelm = 1
type = time_double
units = mm
precision = 4
host = somehost.aps.anl.gov:5064
access = read/write
status = 0
severity = 0
timestamp = 1513352940.872 (2017-12-15 09:49:00.87179)
posixseconds = 1513352940.0
nanoseconds= 871788105
upper_ctrl_limit = 50.0
lower_ctrl_limit = -48.0
upper_disp_limit = 50.0
lower_disp_limit = -48.0
upper_alarm_limit = 0.0
lower_alarm_limit = 0.0
upper_warning_limit = 0.0
lower_warning_limit = 0.0
PV is internally monitored, with 0 user-defined callbacks:
=============================
PV objects have several additional methods related to monitoring changes to
the PV values or connection state including user-defined functions to be
run when the value changes. There are also attributes associated with a
PVs Control Attributes, like those shown above in the info
attribute. Further details are at PV: Epics Process Variables.
Simple epics
functions: caget(), caput(), etc.¶
As shown above, the simplest interface to EPICS Channel Access is found
with the functions caget()
, caput()
, and cainfo()
. There
are also functions camonitor()
and camonitor_clear()
to setup
and clear a simple monitoring of changes to a PV. These functions all take
the name of an Epics Process Variable (PV) as the first argument and are
similar to the EPICS command line utilities of the same names.
Internally, these functions keeps a cache of connected PV (in this case,
using PV objects) so that repeated use of a PV name will not actually
result in a new connection to the PV – see The get_pv() function and _PVcache_ cache of PVs for more
details. Thus, though the functionality is simple and straightforward, the
performance of using thes simple function can be quite good. In addition,
there are also functions caget_many()
and caput_many()
for
getting and putting values for multiple PVs at a time.
caget()
¶
-
epics.
caget
(pvname[, as_string=False[, count=None[, as_numpy=True[, timeout=None[, use_monitor=True]]]]])¶ retrieves and returns the value of the named PV.
- Parameters
pvname – name of Epics Process Variable.
as_string (
True
/False
) – whether to return string representation of the PV value.count (integer or
None
) – number of elements to return for array data.as_numpy (
True
/False
) – whether to return the Numerical Python representation for array data.timeout (float or
None
) – maximum time to wait (in seconds) for value before returning None.use_monitor (
True
/False
) – whether to rely on monitor callbacks or explicitly get value now.
The count and as_numpy options apply only to array or waveform data. The default behavior is to return the full data array and convert to a numpy array if available. The count option can be used to explicitly limit the number of array elements returned, and as_numpy can turn on or off conversion to a numpy array.
The timeout argument sets the maximum time to wait for a value to be
fetched over the network. If the timeout is exceeded, caget()
will
return None
. This might imply that the PV is not actually available,
but it might also mean that the data is large or network slow enough that
the data just hasn’t been received yet, but may show up later.
The use_monitor argument sets whether to rely on the monitors from the
underlying PV. The default is True
, so that cached values will be
used. Using False
will make the each caget()
explicitly ask the
value to be sent instead of relying on the automatic monitoring normally
used for persistent PVs. This will make caget()
act more like
command-line tools, and slightly less efficient than creating a PV and
getting values with it. If performance is a concern, using monitors is
recommended. For more details on making caget()
more efficient, see
Automatic Monitoring of a PV and The wait and timeout options for get(), ca.get_complete().
The as_string argument tells the function to return the string representation of the value. The details of the string representation depends on the variable type of the PV. For integer (short or long) and string PVs, the string representation is pretty easy: 0 will become ‘0’, for example. For float and doubles, the internal precision of the PV is used to format the string value. For enum types, the name of the enum state is returned:
>>> from epics import caget, caput, cainfo
>>> print(caget('XXX:m1.VAL')) # A double PV
0.10000000000000001
>>> print(caget('XXX:m1.DESC')) # A string PV
'Motor 1'
>>> print(caget('XXX:m1.FOFF')) # An Enum PV
1
Adding the as_string=True argument always results in string being returned, with the conversion method depending on the data type, for example using the precision field of a double PV to determine how to format the string, or using the names of the enumeration states for an enum PV:
>>> print(caget('XXX:m1.VAL', as_string=True))
'0.10000'
>>> print(caget('XXX:m1.FOFF', as_string=True))
'Frozen'
For integer or double array data from Epics waveform records, the regular value will be a numpy array (or a python list if numpy is not installed). The string representation will be something like ‘<array size=128, type=int>’ depending on the size and type of the waveform. An array of doubles might be:
>>> print(caget('XXX:scan1.P1PA')) # A Double Waveform
array([-0.08 , -0.078 , -0.076 , ...,
1.99599814, 1.99799919, 2. ])
>>> print(caget('XXX:scan1.P1PA', as_string=True))
'<array size=2000, type=time_double>'
As an important special case CHAR waveform records will be turned to Python
strings when as_string is True
. This is useful to work around the
low limit of the maximum length (40 characters!) of EPICS strings which has
inspired the fairly common usage of CHAR waveforms to represent longer
strings:
>>> epics.caget('MyAD:TIFF1:FilePath')
array([ 47, 104, 111, 109, 101, 47, 101, 112, 105, 99, 115, 47, 115,
99, 114, 97, 116, 99, 104, 47, 0], dtype=uint8)
>>> epics.caget('MyAD:TIFF1:FilePath', as_string=True)
'/home/epics/scratch/'
Of course,character waveforms are not always used for long strings, but can also hold byte array data, such as may come from some detectors and devices.
caput()
¶
-
epics.
caput
(pvname, value[, wait=False[, timeout=60]])¶ set the value of the named PV.
- Parameters
pvname – name of Epics Process Variable
value – value to send.
wait (
True
/False
) – whether to wait until the processing has completed.timeout (double) – how long to wait (in seconds) for put to complete before giving up.
- Return type
integer
The optional wait argument tells the function to wait until the
processing completes. This can be useful for PVs which take significant
time to complete, either because it causes a physical device (motor, valve,
etc) to move or because it triggers a complex calculation or data
processing sequence. The timeout argument gives the maximum time to
wait, in seconds. The function will return after this (approximate) time
even if the caput()
has not completed.
This function returns 1 on success. It will return None
if the timeout
has been exceeded.
>>> from epics import caget, caput, cainfo
>>> caput('XXX:m1.VAL',2.30)
1
>>> caput('XXX:m1.VAL',-2.30, wait=True)
... waits a few seconds ...
cainfo()
¶
-
epics.
cainfo
(pvname[, print_out=True])¶ prints (or returns as a string) an informational paragraph about the PV, including Control Settings.
- Parameters
pvname – name of Epics Process Variable
print_out – whether to write results to standard output (otherwise the string is returned).
camonitor()
¶
-
epics.
camonitor
(pvname[, writer=None[, callback=None]])¶ This sets a monitor on the named PV, which will cause something to be done each time the value changes. By default the PV name, time, and value will be printed out (to standard output) when the value changes, but the action that actually happens can be customized.
- Parameters
pvname – name of Epics Process Variable
writer (
None
or a callable function that takes a string argument.) – where to write results to standard output .callback (
None
or callable function) – user-supplied function to receive result
One can specify any function that can take a string as writer, such as
the write()
method of an open file that has been open for writing.
If left as None
, messages of changes will be sent to
sys.stdout.write()
. For more complete control, one can specify a
callback function to be called on each change event. This callback
should take keyword arguments for pvname, value, and char_value. See
User-supplied Callback functions for information on writing callback functions for
camonitor()
.
>>> from epics import camonitor
>>> camonitor('XXX.m1.VAL')
XXX.m1.VAL 2010-08-01 10:34:15.822452 1.3
XXX.m1.VAL 2010-08-01 10:34:16.823233 1.2
XXX.m1.VAL 2010-08-01 10:34:17.823233 1.1
XXX.m1.VAL 2010-08-01 10:34:18.823233 1.0
camonitor_clear()
¶
-
epics.
camonitor_clear
(pvname)¶ clears a monitor set on the named PV by
camonitor()
.- Parameters
pvname – name of Epics Process Variable
This simple example monitors a PV with camonitor()
for while, with
changes being saved to a log file. After a while, the monitor is cleared
and the log file is inspected:
>>> import epics
>>> fh = open('PV1.log','w')
>>> epics.camonitor('XXX:DMM1Ch2_calc.VAL',writer=fh.write)
>>> .... wait for changes ...
>>> epics.camonitor_clear('XXX:DMM1Ch2_calc.VAL')
>>> fh.close()
>>> fh = open('PV1.log','r')
>>> for i in fh.readlines(): print(i[:-1])
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:40.536946 -183.5035
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:41.536757 -183.6716
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:42.535568 -183.5112
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:43.535379 -183.5466
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:44.535191 -183.4890
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:45.535001 -183.5066
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:46.535813 -183.5085
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:47.536623 -183.5223
XXX:DMM1Ch2_calc.VAL 2010-03-24 11:56:48.536434 -183.6832
caget_many()
¶
-
epics.
caget_many
(pvlist[, as_string=False[, count=None[, as_numpy=True[, timeout=None]]]])¶ get a list of PVs as quickly as possible. Returns a list of values for each PV in the list. Unlike
caget()
, this method does not use automatic monitoring (see Automatic Monitoring of a PV).- Parameters
pvlist (
list
ortuple
ofstr
) – A list of process variable names.as_string (
True
/False
) – whether to return string representation of the PV values.count (integer or
None
) – number of elements to return for array data.as_numpy (
True
/False
) – whether to return the Numerical Python representation for array data.timeout (float or
None
) – maximum time to wait (in seconds) for value before returning None.
For detailed information about the arguments, see the documentation for
caget()
. Also see Strategies for connecting to a large number of PVs for more
discussion.
caput_many()
¶
-
epics.
caput_many
(pvlist, values[, wait=False[, connection_timeout=None[, put_timeout=60]]])¶ put values to a list of PVs as quickly as possible. Returns a list of ints for each PV in the list: 1 if the put was successful, -1 if it timed out. Unlike
caput()
, this method does not use automatic monitoring (see Automatic Monitoring of a PV).- Parameters
pvlist (
list
ortuple
ofstr
) – A list of process variable names.values (
list
ortuple
) – values to put to each PV.wait – if
'each'
,caput_many()
will wait for each PV to process before starting the next. If'all'
,caput_many()
will issue puts for all PVs immediately, then wait for all of them to complete. If any other value,caput_many()
will not wait for put processing to complete.connection_timeout (float or
None
) – maximum time to wait (in seconds) for a connection to be established to each PV.put_timeout (float or
None
) – maximum time to wait (in seconds) for processing to complete for each PV (ifwait
is'each'
), or for processing to complete for all PVs (ifwait
is'all'
).
Because connections to channels normally connect very quickly (less than a second), but processing a put may take a significant amount of time (due to a physical device moving, or due to complex calculations or data processing sequences), a separate timeout duration can be specified for connections and processing puts.
Motivation and design concepts¶
There are other Python wrappings for Epics Channel Access, so it it useful to outline the design goals for PyEpics. The motivations for PyEpics3 included:
providing both low-level (C-like) and higher-level access (Python objects) to the EPICS Channel Access protocol.
supporting as many features of Epics 3.14 and greater as possible, including preemptive callbacks and thread support.
easy support and distribution for Windows and Unix-like systems.
support for both Python 2 (now no longer supported) and Python 3.
using Python’s ctypes library.
The idea is to provide both a low-level interface to Epics Channel Access (CA) that closely resembled the C interface to CA, and to build higher level functionality and complex objects on top of that foundation. The Python ctypes library conveniently allows such direct wrapping of a shared libraries, and requires no compiled code for the bridge between Python and the CA library. This makes it very easy to wrap essentially all of CA from Python code, and support multiple platforms. Since ctypes loads a shared object library at runtime, the underlying CA library can be upgraded without having to re-build the Python wrapper. The ctypes interface provides the most reliable thread-safety available, as each call to the underlying C library is automatically made thread-aware without explicit code. Finally, by avoiding the C API altogether, supporting both Python2 and Python3 is greatly simplified.
Status¶
The PyEpics package is actively maintained, but the core library is reasonably stable and ready to use in production code. Features are being added slowly, and testing is integrated into development so that the chance of introducing bugs into existing codes is minimized. The package is targeted and tested to work on all supported versions of Python, currently Python 3.6 and higher.