Devices: collections of PVs¶
Overview¶
The device
module provides a simple interface to a collection of
PVs. Here an epics device.Device
is an object holding a set of
PVs, all sharing a prefix, but having many attributes. Many PVs will
have names made up of prefix+attribute, with a common prefix for several
related PVs. This almost describes an Epics Record, but as it is concerned
only with PV names, the mapping to an Epics Record is not exact. On the
other hand, the concept of a device is more flexible than a predefined
Epics Record as it can actually hold PVs from several different records.:
motor1 = epics.Device('XXX:motor1.', attrs=('VAL', 'RBV', 'DESC', 'RVAL',
'LVIO', 'HLS', 'LLS'))
motor1.put('VAL', 1)
print 'Motor %s = %f' % ( motor1.get('DESC'), motor1.get('RBV'))
motor1.VAL = 0
print 'Motor %s = %f' % ( motor1.DESC, motor1.RBV )
While useful on its own like this, the real point of a device is as a base class, to be inherited and extended. In fact, there is a more sophisticated Motor device described below at Epics Motor Device
-
class
device.
Device
(prefix=None[, delim=''[, attrs=None]])¶
The attribute PVs are built as needed and held in an internal buffer
self._pvs
. This class is kept intentionally simple so that it may
be subclassed.
To pre-load attribute names on initialization, provide a list or tuple of attributes with the attr option.
Note that prefix is actually optional. When left off, this class can be used as an arbitrary container of PVs, or to turn any subclass into an epics Device.
In general, PV names will be mapped as prefix+delim+attr. See
add_pv()
for details of how to override this.
-
device.
PV
(attr[, connect=True[, **kw]]])¶ returns the PV object for a device attribute. The connect argument and any other keyword arguments are passed to
epics.PV()
.
-
device.
put
(attr, value[, wait=False[, timeout=10.0]])¶ put an attribute value, optionally wait for completion or up to a supplied timeout value
-
device.
get
(attr[, as_string=False])¶ get an attribute value, option as_string returns a string representation
-
device.
add_callback
(attr, callback)¶ add a callback function to an attribute PV, so that the callback function will be run when the at tribute’s value changes
-
device.
add_pv
(pvname[, attr=None[, **kw]])¶ adds an explicitly names
epics.PV()
to the device even though it may violate the normal naming rules (in which attr is mapped to epics.PV(prefix+delim+attr). That is, one can say:import epics m1 = epics.Device('XXX:m1', delim='.') m1.add_pv('XXX:m2.VAL', attr='other') print m1.VAL # print value of XXX:m1.VAL print m1.other # prints value of XXX:m2.VAL
-
device.
save_state
()¶ return a dictionary of all current values – the ‘’current state’’.
-
device.
restore_state
(state)¶ restores a saved state, as saved with
save_state()
-
device.
write_state
(fname[, state=None])¶ write a saved state to a file. If no state is provide, the current state is written.
-
device.
read_state
(fname[, restore=False])¶ reads a state from a file, as written with
write_state()
, and returns it. If ‘’restore’’ isTrue
, the read state will be restored.
-
device.
_pvs
¶ a dictionary of PVs making up the device.
Epics Motor Device¶
The Epics Motor record has over 100 fields associated with it. Of course, it is often preferable to think of 1 Motor with many attributes than 100 or so separate PVs. Many of the fields of the Motor record are interrelated and influence other settings, including limits on the range of motion which need to be respected, and which may send notifications when they are violated. Thus, there is a fair amount of functionality for a Motor. Typically, the user just wants to move the motor by setting its drive position, but a fully enabled Motor should allow the use to change and read many of the Motor parameters.
The Motor
class helps the user create and use Epics motors.
A simple example use would be:
import epics
m1 = epics.Motor('XXX:m1')
print 'Motor: ', m1.DESC , ' Currently at ', m1.RBV
m1.tweak_val = 0.10
m1.move(0.0, dial=True, wait=True)
for i in range(10):
m1.tweak(direction='forward', wait=True)
time.sleep(1.0)
print 'Motor: ', m1.DESC , ' Currently at ', m1.RBV
Which will step the motor through a set of positions. You’ll notice a few features for Motor:
1. Motors can use English-name aliases for attributes for fields of the motor record. Thus ‘VAL’ can be spelled ‘drive’ and ‘DESC’ can be ‘description’. The Table of Motor Attributes give the list of names that can be used.
2. The methods for setting positions can use the User, Dial, or Step coordinate system, and can wait for completion.
The epics.Motor
class¶
-
class
motor.
Motor
(pvname[, timeout=30.])¶ create a Motor object for a named Epics Process Variable.
- Parameters
pvname (string) – prefix name (no ‘.VAL’ needed!) of Epics Process Variable for a Motor
timeout (float) – time (in seconds) to wait before giving up trying to connect.
Once created, a Motor should be ready to use.
>>> from epics import Motor
>>> m = Motor('XX:m1')
>>> print m.drive, m.description, m.slew_speed
1.030 Fine X 5.0
>>> print m.get('device_type', as_string=True)
'asynMotor'
A Motor has very many fields. Only a few of them are created on
initialization – the rest are retrieved as needed. The motor fields can
be retrieved either with an attribute or with the get()
method.
A full list of Motor attributes and their aliases for the motor
record is given in Table of Motor Attributes.
Table of Aliases for attributes for the epics
Motor
class, and the corresponding attribute name of the Motor Record field.
alias |
Motor Record field |
alias |
Motor Record field |
|
---|---|---|---|---|
disabled |
_able.VAL |
moving |
MOVN |
|
acceleration |
ACCL |
resolution |
MRES |
|
back_accel |
BACC |
motor_status |
MSTA |
|
backlash |
BDST |
offset |
OFF |
|
back_speed |
BVEL |
output_mode |
OMSL |
|
card |
CARD |
output |
OUT |
|
dial_high_limit |
DHLM |
prop_gain |
PCOF |
|
direction |
DIR |
precision |
PREC |
|
dial_low_limit |
DLLM |
readback |
RBV |
|
settle_time |
DLY |
retry_max |
RTRY |
|
done_moving |
DMOV |
retry_count |
RCNT |
|
dial_readback |
DRBV |
retry_deadband |
RDBD |
|
description |
DESC |
dial_difference |
RDIF |
|
dial_drive |
DVAL |
raw_encoder_pos |
REP |
|
units |
EGU |
raw_high_limit |
RHLS |
|
encoder_step |
ERES |
raw_low_limit |
RLLS |
|
freeze_offset |
FOFF |
relative_value |
RLV |
|
move_fraction |
FRAC |
raw_motor_pos |
RMP |
|
hi_severity |
HHSV |
raw_readback |
RRBV |
|
hi_alarm |
HIGH |
readback_res |
RRES |
|
hihi_alarm |
HIHI |
raw_drive |
RVAL |
|
high_limit |
HLM |
dial_speed |
RVEL |
|
high_limit_set |
HLS |
s_speed |
S |
|
hw_limit |
HLSV |
s_back_speed |
SBAK |
|
home_forward |
HOMF |
s_base_speed |
SBAS |
|
home_reverse |
HOMR |
s_max_speed |
SMAX |
|
high_op_range |
HOPR |
set |
SET |
|
high_severity |
HSV |
stop_go |
SPMG |
|
integral_gain |
ICOF |
s_revolutions |
SREV |
|
jog_accel |
JAR |
stop |
STOP |
|
jog_forward |
JOGF |
t_direction |
TDIR |
|
jog_reverse |
JOGR |
tweak_forward |
TWF |
|
jog_speed |
JVEL |
tweak_reverse |
TWR |
|
last_dial_val |
LDVL |
tweak_val |
TWV |
|
low_limit |
LLM |
use_encoder |
UEIP |
|
low_limit_set |
LLS |
u_revolutions |
UREV |
|
lo_severity |
LLSV |
use_rdbl |
URIP |
|
lolo_alarm |
LOLO |
drive |
VAL |
|
low_op_range |
LOPR |
base_speed |
VBAS |
|
low_alarm |
LOW |
slew_speed |
VELO |
|
last_rel_val |
LRLV |
version |
VERS |
|
last_dial_drive |
LRVL |
max_speed |
VMAX |
|
last_SPMG |
LSPG |
use_home |
ATHM |
|
low_severity |
LSV |
deriv_gain |
DCOF |
methods for epics.Motor
¶
-
motor.
get
(attr[, as_string=False])¶ sets a field attribute for the motor.
- Parameters
attr (string (from table above)) – attribute name
as_string (
True
/False
) – whether to return string value.
Note that get()
can return the string value, while fetching the
attribute cannot do so:
>>> m = epics.Motor('XXX:m1')
>>> print m.device_type
0
>>> print m.get('device_type', as_string=True)
'asynMotor'
-
motor.
put
(attr, value[, wait=False[, timeout=30]])¶ sets a field attribute for the motor.
- Parameters
attr (string (from table above)) – attribute name
value – value for attribute
wait (
True
/False
) – whether to wait for completion.timeout (float) – time (in seconds) to wait before giving up trying to connect.
-
motor.
check_limits
()¶ checks whether the current motor position is causing a motor limit violation, and raises a MotorLimitException if it is.
returns
None
if there is no limit violation.
-
motor.
within_limits
(value[, limits='user'])¶ checks whether a target value would be a limit violation.
- Parameters
value – target value
limits (string) – one of ‘user’, ‘dial’, or ‘raw’ for which limits to consider
- Return type
True
/False
-
motor.
move
(val=None[, relative=None[, wait=False[, timeout=300.0[, dial=False[, raw=False[, ignore_limits=False[, confirm_move=False]]]]]]])¶ moves motor to specified drive position.
- Parameters
val – value to move to (float) [Must be provided]
relative – move relative to current position (T/F) [F]
wait – whether to wait for move to complete (T/F) [F]
timeout – max time for move to complete (in seconds) [300]
dial – use dial coordinates (T/F) [F]
raw – use raw coordinates (T/F) [F]
ignore_limits – try move without regard to limits (T/F) [F]
confirm_move – try to confirm that move has begun (when wait=False) (T/F) [F]
- Return type
integer
Returns an integer value, according the table below. Note that a return value of 0 with wait=False does not really guarantee a successful move, just that a move request was issued. If you’re interested in checking that a requested move really did start without waiting for the move to complete, you may want to use the confirm_move=True option.
Table of return values from
move()
.
return value
meaning
-13
invalid value (cannot convert to float). Move not attempted.
-12
target value outside soft limits. Move not attempted.
-11
drive PV is not connected: Move not attempted.
-8
move started, but timed-out.
-7
move started, timed-out, but appears done.
-5
move started, unexpected return value from
put()
-4
move-with-wait finished, soft limit violation seen.
-3
move-with-wait finished, hard limit violation seen.
0
move-with-wait finish OK.
0
move-without-wait executed, not confirmed.
1
move-without-wait executed, move confirmed.
3
move-without-wait finished, hard limit violation seen.
4
move-without-wait finished, soft limit violation seen.
-
motor.
tweak
(direction='forward'[, wait=False[, timeout=300.]])¶ move the motor by the current tweak value
- Parameters
direction (string: 'forward' (default) or 'reverse') – direction of motion
wait (
True
/False
) – whether to wait for completiontimeout (float) – max time for move to complete (in seconds) [default=300]
-
motor.
get_position
(readback=False[, dial=False[, raw=False]])¶ Returns the motor position in user, dial or raw coordinates.
- Parameters
readback – whether to return the readback position in the desired coordinate system. The default is to return the drive position of the motor.
dial – whether to return the position in dial coordinates. The default is user coordinates.
raw – whether to return the raw position. The default is user coordinates.
The “raw” and “dial” keywords are mutually exclusive. The “readback” keyword can be used in user, dial or raw coordinates.
-
motor.
set_position
(position[ dial=False[, raw=False]])¶ set (that is, redefine) the current position to supplied value.
- Parameters
position – The new motor position
dial – whether to set in dial coordinates. The default is user coordinates.
raw –
whether to set in raw coordinates. The default is user coordinates.
The ‘raw’ and ‘dial’ keywords are mutually exclusive.
-
motor.
get_pv
(attr)¶ returns the PV for the corresponding attribute.
-
motor.
set_callback
(attr='drive'[, callback=None[, kw=None]])¶ sets a callback on the PV for a particular attribute.
-
motor.
clear_callback
(attr='drive')¶ clears a callback on the PV for a particular attribute.
-
motor.
show_info
()¶ prints out a table of attributes and their current values.
Other Device Examples¶
An epics Device provides a general way to group together a set of PVs. The examples below show how to build on this generality, and may inspire you to build your own device classes.
A basic Device without a prefix¶
Here, we define a very simple device that does not even define a prefix. This is not much more than a collection of PVs. Since there is no prefix given, all PVs in the device must be fully qualified. Note that there is no requirement to share a common prefix in such a collection of PVs:
from epics import Device
dev = Device()
p1 = dev.PV('13IDC:m1.VAL')
p2 = dev.PV('13IDC:m2.VAL')
dev.put('13IDC:m1.VAL', 2.8)
dev.put('13IDC:m2.VAL', 3.0)
print dev.PV('13IDC:m3.DIR').get(as_string=True)
Note that this device cannot use the attributes based on field names.
This may not look very interesting – why not just use a bunch of PVs? If ou consider Device to be a starting point for building more complicated objects by subclassing Device and adding specialized methods, then it can start to get interesting.
Epics ai record as Device¶
For a slightly more useful and typical example, the pyepics distribution includes a Device for an Epics ai (analog input record). The full implementation of this device is:
#!/usr/bin/env python
"""Epics analog input record"""
from .. import Device
class ai(Device):
"Simple analog input device"
attrs = ('VAL', 'EGU', 'HOPR', 'LOPR', 'PREC', 'NAME', 'DESC',
'DTYP', 'INP', 'LINR', 'RVAL', 'ROFF', 'EGUF', 'EGUL',
'AOFF', 'ASLO', 'ESLO', 'EOFF', 'SMOO', 'HIHI', 'LOLO',
'HIGH', 'LOW', 'HHSV', 'LLSV', 'HSV', 'LSV', 'HYST')
def __init__(self, prefix, **kwargs):
if prefix.endswith('.'):
prefix = prefix[:-1]
Device.__init__(self, prefix, delim='.', attrs=self.attrs, **kwargs)
The code simply pre-defines the fields that are the suffixes of an Epics ai
input record, and subclasses Device
with these fields to create the
corresponding PVs. For most record suffixes, these will be available as
attributes of the Device object. For example, the ai
class above can
be used simply and cleanly as:
from epics.devices import ai
This_ai = ai('XXX.PRES')
print 'Value: ', This_ai.VAL
print 'Units: ', This_ai.EGU
Of course, you can also use the get()
, put()
methods above for a
basic Device
:
This_ai.put('DESC', 'My Pump')
Several of the other standard Epics records can easily be exposed as Devices in this way, and the pyepics distribution includes such simple wrappings for the Epics ao, bi, and bo records, as well as several more complex records from synApps.
Epics Scaler Record as Device¶
For a slightly more complicated example: an incomplete, but very useful mapping of the Scaler Record from synApps, including methods for changing modes, and reading and writing data.
#!/usr/bin/env python
"""Epics Scaler"""
from .. import Device, poll
class Scaler(Device):
"""
Simple implementation of SynApps Scaler Record.
"""
attrs = ('CNT', 'CONT', 'TP', 'T', 'VAL')
attr_kws = {'calc_enable': '%s_calcEnable.VAL'}
chan_attrs = ('NM%i', 'S%i')
calc_attrs = {'calc%i': '%s_calc%i.VAL', 'expr%i': '%s_calc%i.CALC'}
_nonpvs = ('_prefix', '_pvs', '_delim', '_nchan', '_chans')
def __init__(self, prefix, nchan=8):
self._nchan = nchan
self._chans = range(1, nchan+1)
attrs = list(self.attrs)
for i in self._chans:
for att in self.chan_attrs:
attrs.append(att % i)
Device.__init__(self, prefix, delim='.', attrs=attrs)
for key, val in self.attr_kws.items():
self.add_pv(val % prefix, attr= key)
for i in self._chans:
for key, val in self.calc_attrs.items():
self.add_pv(val % (prefix, i), attr = key % i)
self._mutable = False
def AutoCountMode(self):
"set to autocount mode"
self.put('CONT', 1)
def OneShotMode(self):
"set to one shot mode"
self.put('CONT', 0)
def CountTime(self, ctime):
"set count time"
self.put('TP', ctime)
def Count(self, ctime=None, wait=False):
"set count, with optional counttime"
if ctime is not None:
self.CountTime(ctime)
self.put('CNT', 1, wait=wait)
poll()
def EnableCalcs(self):
" enable calculations"
self.put('calc_enable', 1)
def setCalc(self, i, calc):
"set the calculation for scaler i"
attr = 'expr%i' % i
self.put(attr, calc)
def getNames(self):
"get all names"
return [self.get('NM%i' % i) for i in self._chans]
def Read(self, use_calc=False):
"read all values"
attr = 'S%i'
if use_calc:
attr = 'calc%i'
return [self.get(attr % i) for i in self._chans]
Note that we can then create a scaler
object from its base PV
prefix, and use methods like Count()
and Read()
without
directly invoking epics calls:
s1 = Scaler('XXX:scaler1')
s1.setCalc(2, '(B-2000*A/10000000.)')
s1.enableCalcs()
s1.OneShotMode()
s1.Count(t=5.0, wait=True)
print 'Names: ', s1.getNames()
print 'Raw values: ', s1.Read(use_calc=False)
print 'Calc values: ', s1.Read(use_calc=True)
Other Devices included in PyEpics¶
Several other Epics Records have been exposed as Devices, and included in PyEpics distribution. These vary some in how complete and feature-rich they are, and are definitely skewed toward data collection at synchrotron beamlines. A table of current Devices are listed in the Table of Included Epics Devices table below. For further details, consult the source code for these modules.
Table of Epics Devices Included in the PyEpics distribution. For those described as “pretty basic”, there are generally only PV suffixes to attributes mapped. Many of the others include one or more methods for specific use of that Device.
module |
class |
description |
---|---|---|
ad_base |
AD_Camera |
areaDetector Camera, pretty basic |
ad_fileplugin |
AD_FilePlugin |
areaDetector File Plugin, many methods |
ad_image |
AD_ImagePlugin |
areaDetector Image, with ArrayData attribute |
ad_overlay |
AD_OverlayPlugin |
areaDetector Overlay, pretty basic |
ad_perkinelmer |
AD_PerkinElmer |
PerkinElmer(xrd1600) detector, several methods |
ai |
ai |
analog input, pretty basic (as above) |
ao |
ao |
analog output, pretty basic |
bi |
bi |
binary input, pretty basic |
bo |
bo |
binary output, pretty basic |
mca |
MCA |
epics DXP record, pretty basic |
mca |
DXP |
epics MCA record, get_rois()/get_calib() |
mca |
MultiXMAP |
Multiple XIA XMaps, several methods |
scaler |
Scaler |
epics Scaler record, many methods |
scan |
Scan |
epics SScan record, some methods |
srs570 |
SRS570 |
SRS570 Amplifier |
struck |
Struck |
SIS Multichannel Scaler, many methods |
transform |
Transform |
epics userTransform record |
xspress3 |
Xspress3 |
Quantum Electronics Xspress3 Multi-MCA |