PV: Epics Process Variables¶
The pv
module provides a higher-level class pv.PV
, which
creates a PV object for an EPICS Process Variable. A PV object has
both methods and attributes for accessing it’s properties.
The PV
class¶
-
class
pv.
PV
(pvname[, callback=None[, form='time'[, verbose=False[, auto_monitor=None[, count=None[, connection_callback=None[, connection_timeout=None[, access_callback=None]]]]]]]])¶ -
create a PV object for a named Epics Process Variable.
- Parameters
pvname – name of Epics Process Variable
callback (callable, tuple, list or None) – user-defined callback function on changes to PV value or state.
form (string, one of ('native','ctrl', or 'time')) – which epics data type to use: the ‘native’, ‘time’, or the ‘ctrl’ (Control) variant.
verbose (
True
/False
) – whether to print out debugging messagesauto_monitor (
None
,True
,False
, or bitmask (see Automatic Monitoring of a PV)) – whether to automatically monitor the PV for changes.count (int) – number of data elements to return by default (see here)
connection_callback (callable or
None
) – user-defined function called on changes to PV connection status.connection_timeout (float or
None
) – time (in seconds) to wait for connection before giving upaccess_callback (callable or
None
) – user-defined function called on changes to PV access rights
Once created, a PV should (barring any network issues) automatically connect and be ready to use.
>>> from epics import PV
>>> p = PV('XX:m1.VAL')
>>> print p.get()
>>> print p.count, p.type
The pvname is required, and is the name of an existing Process Variable.
The callback parameter specifies one or more python methods to be called on changes, as discussed in more detail at User-supplied Callback functions
The connection_callback parameter specifies a python method to be called on changes to the connection status of the PV (that is, when it connects or disconnects). This is discussed in more detail at User-supplied Connection Callback functions
The form parameter specifies which of the three variants ‘native’, ‘ctrl’
(Control) or ‘time’ (the default) to use for the PV. The ‘native’ form
returns just the value, the ‘time’ form includes the timestamp from the
server the PV lives on, as well as status information. The control form
includes several additional fields such as limits to the PV, which can be
useful in some cases. Also note that the additional ‘ctrl’ value fields
(see the Table of Control Attributes) can be
obtained with get_ctrlvars()
even for PVs of ‘native’ or ‘time’ form.
The auto_monitor parameter specifies whether the PV should be automatically monitored. See Automatic Monitoring of a PV for a detailed description of this.
The verbose parameter specifies more verbose output on changes, and is intended for debugging purposes.
The access_callback parameter specifies a python method to be called on changes to the access rights of the PV (read/write access changes). This is discussed in more detail here.
methods¶
A PV has several methods for getting and setting its value and defining callbacks to be executed when the PV changes.
-
pv.
get
([count=None[, as_string=False[, as_numpy=True[, timeout=None[, use_monitor=True[, with_ctrlvars=False]]]]]])¶ get and return the current value of the PV
- Parameters
count (integer or
None
) – maximum number of array elements to returnas_string (
True
/False
) – whether to return the string representation of the value.as_numpy – whether to try to return a numpy array where appropriate.
timeout (float or
None
) – maximum time to wait for data before returningNone
.use_monitor (
True
/False
) – whether to rely on monitor callbacks or explicitly get value now.
see String representation for a PV for details on how the string representation is determined.
With the as_numpy option, an array PV (that is, a PV whose value has more than one element) will be returned as a numpy array, provided the numpy module is available. See Strategies for working with large arrays for a discussion of strategies for how to best deal with very large arrays.
The use_monitor option controls whether the most recent value from the automatic monitoring will be used or whether the value will be explicitly asked for right now. Usually, you can rely on a PVs value being kept up to date, and so the default here is
True
. But, since network traffic is not instantaneous and hard to predict, the value returned with use_monitor=True may be out-of-date.The timeout sets how long (in seconds) to wait for the value to be sent. This only applies with use_monitor=False, or if the PV is not automatically monitored. Otherwise, the most recently received value will be sent immediately.
The with_ctrlvars option requests DBR_CTRL data, including control limits, precision, and so on, in addition to the value normally returned. This metadata will be available by accessing various attributes such as
lower_ctrl_limit
.See Automatic Monitoring of a PV for more on monitoring PVs and The wait and timeout options for get(), ca.get_complete() for more details on what happens when a
pv.get()
times out.
-
pv.
get_with_metadata
([form=None[, count=None[, as_string=False[, as_numpy=True[, timeout=None[, use_monitor=True[, with_ctrlvars=False]]]]]]])¶ Returns a dictionary of the current value and associated metadata
- Parameters
form ({'native', 'time', 'ctrl', None}) – EPICS data type to request: the ‘native’, or the ‘ctrl’ (Control) or ‘time’ variant. Defaults to the PV instance attribute
form
.count (integer or
None
) – maximum number of array elements to returnas_string (
True
/False
) – whether to return the string representation of the value.as_numpy – whether to try to return a numpy array where appropriate.
timeout (float or
None
) – maximum time to wait for data before returningNone
.use_monitor (
True
/False
) – whether to rely on monitor callbacks or explicitly get value now.
See
PV.get
, above, for further notes on each of these parameters.Each request to EPICS can optionally contain additional metadata associated with the value. While
PV.get
updates the PV instance with any metadata,get_with_metadata
will return the requested metadata and value in a dictionary.The exception is when the PV is set to auto-monitor and the use_monitor parameter here is set. This means that both the value and metadata will used the cached values instead of making a new request. Because of this, the metadata and value returned here will be a full dictionary of all known metadata for the PV instance.
-
pv.
put
(value[, wait=False[, timeout=30.0[, use_complete=False[, callback=None[, callback_data=None]]]]])¶ set the PV value, optionally waiting to return until processing has completed, or setting the
put_complete
to indicate complete-ness.- Parameters
value – value to set PV
wait (
True
/False
) – whether to wait for processing to complete (or time-out) before returning.timeout (float) – maximum time to wait for processing to complete before returning anyway.
use_complete (
True
/False
) – whether to use a built-in callback to setput_complete
.callback (
None
or a valid python function) – user-supplied function to run when processing has completed.callback_data – extra data to pass on to a user-supplied callback function.
The wait and callback arguments, as well as the ‘use_complete’ / put_complete
attribute give a few options for knowing that a put()
has
completed. See Put with wait, put callbacks, and put_complete for more details.
-
pv.
get_ctrlvars
()¶ returns a dictionary of the control values for the PV. This dictionary may have many members, depending on the data type of PV. See the Table of Control Attributes for details.
-
pv.
get_timevars
()¶ returns a dictionary of the time values for the PV, which include status, severity, and the timestamp from the CA server.
-
pv.
poll
([evt=1.e-4[, iot=1.0]])¶ poll for changes. This simply calls
epics.ca.poll()
- Parameters
evt (float) – time to pass to
epics.ca.pend_event()
iot (float) – time to pass to
epics.ca.pend_io()
-
pv.
connect
([timeout=None])¶ this explicitly connects a PV, and returns whether or not it has successfully connected. It is probably not that useful, as connection should happen automatically. See
wait_for_connection()
.- Parameters
timeout (float) – maximum connection time, passed to
epics.ca.connect_channel()
- Return type
True
/False
if timeout is
None
, the PVs connection_timeout parameter will be used. If that is alsoNone
,episc.ca.DEFAULT_CONNECTION_TIMEOUT
will be used.
-
pv.
wait_for_connection
([timeout=None])¶ this waits until a PV is connected, or has timed-out waiting for a connection. Returns whether the connection has occurred.
- Parameters
timeout (float) – maximum connection time.
- Return type
True
/False
if timeout is
None
, the PVs connection_timeout parameter will be used. If that is alsoNone
,epics.ca.DEFAULT_CONNECTION_TIMEOUT
will be used.
-
pv.
disconnect
()¶ disconnect a PV, clearing all callbacks.
-
pv.
reconnect
()¶ reconnect (or try to) a disconnected PV.
-
pv.
clear_auto_monitor
()¶ turn off automatic monitoring of a PV. Note that this will suspend all event callbacks on a PV at the CA level by calling
epics.ca.clear_subscription()
, but will not clear the list of PVs callbacks. This means that doingreconnect()
will resume event processing including any callbacks or the PV.
-
pv.
add_callback
(callback=None[, index=None [, with_ctrlvars=True[, **kw]])¶ adds a user-defined callback routine to be run on each change event for this PV. Returns the integer index for the callback.
- Parameters
callback (
None
or callable) – user-supplied function to run when PV changes.index (
None
(integer will be produced) or immutable) – identifying key for this callbackwith_ctrlvars – whether to (try to) make sure that accurate
control values
will be sent to the callback.kw – additional keyword/value arguments to pass to each execution of the callback.
- Return type
integer
Note that multiple callbacks can be defined, each having its own index (a dictionary key, typically an integer). When a PV changes, all the defined callbacks will be executed. They will be called in order (by sorting the keys of the
callbacks
dictionary)See also:
callbacks
attribute, User-supplied Callback functions
-
pv.
remove_callback
(index=None)¶ remove a user-defined callback routine using supplied
- Parameters
index (
None
or integer) – index of user-supplied function, as returned byadd_callback()
, and also to key for this callback in thecallbacks
dictionary.- Return type
integer
If only one callback is defined an index=``None``, this will clear the only defined callback.
See also:
callbacks
attribute, User-supplied Callback functions
-
pv.
clear_callbacks
()¶ remove all user-defined callback routine.
-
pv.
run_callbacks
()¶ execute all user-defined callbacks right now, even if the PV has not changed. Useful for debugging!
See also:
callbacks
attribute, User-supplied Callback functions
-
pv.
run_callback
(index)¶ execute a particular user-defined callback right now, even if the PV has not changed. Useful for debugging!
See also:
callbacks
attribute, User-supplied Callback functions
-
pv.
force_read_access_rights
()¶ force a read of the access rights for a PV. Normally, a PV will have access rights determined automatically and subscribe to changes in access rights. But sometimes (especially 64-bit Windows), the automatically reported values are wrong. This methods will explicitly read the access rights.
attributes¶
A PV object has many attributes, each associated with some property of the
underlying PV: its value, host, count, and so on. For properties
that can change, the PV attribute will hold the latest value for the
corresponding property, Most attributes are read-only, and cannot be
assigned to. The exception to this rule is the value
attribute.
-
pv.
value
¶ The current value of the PV.
Note: The
value
attribute can be assigned to. When read, the latest value will be returned, even if that means aget()
needs to be called.Assigning to
value
is equivalent to setting the value with theput()
method.>>> from epics import PV >>> p1 = PV('xxx.VAL') >>> print p1.value 1.00 >>> p1.value = 2.00
-
pv.
status
¶ The PV status, which will be 0 for a normal, connected PV.
-
pv.
type
¶ string describing data type of PV, such as double, float, enum, string, int, long, char, or one of the ctrl or time variants of these, which will be named ctrl_double, time_enum, and so on. See the Table of DBR Types
-
pv.
ftype
¶ The integer value (from the underlying C library) indicating the PV data type according to Table of DBR Types
-
pv.
host
¶ string of host machine provide this PV.
-
pv.
count
¶ number of data elements in a PV. 1 except for waveform PVs, where it gives the number of elements in the waveform. For recent versions of Epics Base (3.14.11 and later?), this gives the .NORD field, which gives the number of elements last put into the PV and which may be less than the maximum number allowed (see nelm below).
-
pv.
nelm
¶ number of data elements in a PV. 1 except for waveform PVs where it gives the maximum number of elements in the waveform. For recent versions of Epics Base (3.14.11 and later?), this gives the .NELM parameter. See also the count attribute above.
-
pv.
read_access
¶ Boolean (
True
/False
) for whether PV is readable
-
pv.
write_access
¶ Boolean (
True
/False
) for whether PV is writable
-
pv.
access
¶ string describing read/write access. One of ‘read/write’,’read-only’,’write-only’, ‘no access’.
-
pv.
severity
¶ severity value of PV. Usually 0 for PVs that are not in an alarm condition.
-
pv.
timestamp
¶ floating point timestamp (relative to the POSIX time origin, not the EPICS time origin) of the last event seen for this PV. Note that this is will contain the timestamp from the Epics server if the PV object was created with the
form='time'
option. Otherwise, the timestamp will be set to time according to the client, indicating when the data arrive from the server.
-
pv.
posixseconds
¶ Integer number of seconds (relative to the POSIX time origin, not the EPICS time origin) of the last event seen for this PV. This will be set only if the PV object was created with the
form='time'
option, and will reflect the timestamp from the server. Otherwise, this value will be 0 which can be used to signal that the timestamp attribute is from the client.
-
pv.
nanoseconds
¶ Integer number of nanoseconds for the last event seen for this PV. This will be set only if the PV object was created with the
form='time'
option, and will give higher time resolution than the timestamp attribute.
-
pv.
precision
¶ number of decimal places of precision to use for float and double PVs
-
pv.
units
¶ string of engineering units for PV
-
pv.
enum_strs
¶ a list of strings for the enumeration states of this PV (for enum PVs)
-
pv.
info
¶ a string paragraph (ie, including newlines) showing much of the information about the PV.
-
pv.
upper_disp_limit
¶
-
pv.
lower_disp_limit
¶
-
pv.
upper_alarm_limit
¶
-
pv.
lower_alarm_limit
¶
-
pv.
lower_warning_limit
¶
-
pv.
upper_warning_limit
¶
-
pv.
upper_ctrl_limit
¶
-
pv.
lower_ctrl_limit
¶ These are all the various kinds of limits for a PV.
-
pv.
callbacks
¶ a dictionary of currently defined callbacks, to be run on changes to the PV. This dictionary has integer keys (generally in increasing order of when they were defined) which sets which order for executing the callbacks. The values of this dictionary are tuples of (callback, keyword_arguments).
- Note: The
callbacks
attribute can be assigned to or manipulated directly. This is not recommended. Use the methods
add_callback()
,remove_callback()
, andclear_callbacks()
instead of altering this dictionary directly.
- Note: The
-
pv.
connection_callbacks
¶ a simple list of connection callbacks: functions to be run when the connection status of the PV changes. See User-supplied Connection Callback functions for more details.
-
pv.
access_callbacks
¶ an
list
of access callbacks: functions to be run when the access rights of the PV changes. See User-supplied Access Rights Callback functions for more details.
String representation for a PV¶
The string representation for a PV, as returned either with the
as_string argument to epics.ca.get()
or from the char_value
attribute (they are equivalent) needs some further explanation.
The value of the string representation (hereafter, the char_value
),
will depend on the native type and count of a PV.
Table of String Representations
Table of String Representations: How raw data
value
is mapped tochar_value
for different native data types.
data types
count
char_value
string
1
= value
char
1
= value
short
1
= str(value)
long
1
= str(value)
enum
1
= enum_str[value]
double
1
= (“%%.%if” % (precision)) % value
float
1
= (“%%.%if” % (precision)) % value
char
> 1
= long string from bytes in array
all others
> 1
= <array size=*count*, type=*type*>
For double/float values with large exponents, the formatting will be
(“%%.%ig” % (precision)) % value. For character waveforms (char data
with count > 1), the char_value
will be set according to:
>>> firstnull = val.index(0)
>>> if firstnull == -1: firstnull= len(val)
>>> char_value = ''.join([chr(i) for i in val[:firstnull]).rstrip()
Automatic Monitoring of a PV¶
When creating a PV, the auto_monitor parameter specifies whether the PV should be automatically monitored or not. Automatic monitoring means that an internal callback will be registered for changes. Any callbacks defined by the user will be called by this internal callback when changes occur.
For most scalar-value PVs, this automatic monitoring is desirable, as the PV will see all changes (and run callbacks) without any additional interaction from the user. The PV’s value will always be up-to-date and no unnecessary network traffic is needed.
Possible values for auto_monitor
are:
False
For some PVs, especially those that change much more rapidly than you care about or those that contain large arrays as values, auto_monitoring can add network traffic that you don’t need. For these, you may wish to create your PVs with auto_monitor=False. When you do this, you will need to make calls to
get()
to explicitly get the latest value.None
The default value for auto_monitor is
None
, and is set toTrue
if the element count for the PV is smaller thanepics.ca.AUTOMONITOR_MAXLENGTH
(default of 65536). To suppress monitoring of PVs with fewer array values, you will have to explicitly turn auto_monitor toFalse
. For waveform arrays with more elements, automatic monitoring will not be done unless you explicitly set auto_monitor=True, or to an explicit mask. See Strategies for working with large arrays for more details.True
When auto_monitor is set to
True
, the value will be monitored using the default subscription mask set atepics.ca.DEFAULT_SUBSCRIPTION_MASK
.This mask determines which kinds of changes cause the PV to update. By default, the subscription updates when the PV value changes by more than the monitor deadband, or when the PV alarm status changes. This behavior is the same as the default in EPICS’ camonitor tool.
- Mask
It is also possible to request an explicit type of CA subscription by setting auto_monitor to a numeric subscription mask made up of dbr.DBE_ALARM, dbr.DBE_LOG and/or dbr.DBE_VALUE. This mask will be passed directly to
epics.ca.create_subscription()
An example would be:pv1 = PV('AAA', auto_monitor=dbr.DBE_VALUE) pv2 = PV('BBB', auto_monitor=dbr.DBE_VALUE|dbr.DBE_ALARM) pv3 = PV('CCC', auto_monitor=dbr.DBE_VALUE|dbr.DBE_ALARM|dbr.DBE_LOG)
which will generate callbacks for pv1 only when the value of ‘AAA’ changes, while pv2 will receive callbacks if the value or alarm state of ‘BBB’ changes, and pv3 will receive callbacks for all changes to ‘CCC’. Note that these dbr.DBE_**** constants are ORed together as a bitmask.
User-supplied Callback functions¶
This section describes user-defined functions that are called when the
value of a PV changes. These callback functions are useful as they allow
you to be notified of changes without having to continually ask for a PVs
current value. Much of this information is similar to that in
User-supplied Callback functions for the ca
module, though there are some
important enhancements to callbacks on PV objects.
You can define more than one callback function per PV to be run on value
changes. These functions can be specified when creating a PV, with the
callback argument which can take either a single callback function or a
list or tuple of callback functions. After a PV has been created, you can
add callback functions with add_callback()
, remove them with
remove_callback()
, and explicitly run them with run_callback()
.
Each callback has an internal unique index (a small integer number) that
can be used for specifying which one to add, remove, and run.
When defining a callback function to be run on changes to a PV, it is important to know two things:
how your function will be called.
what is permissible to do inside your callback function.
Callback functions will be called with several keyword arguments. You should be prepared to have them passed to your function, and should always include **kw to catch all arguments. Your callback will be sent the following keyword parameters:
pvname: the name of the pv
value: the latest value
char_value: string representation of value
count: the number of data elements
ftype: the numerical CA type indicating the data type
type: the python type for the data
status: the status of the PV (0 for OK)
precision: number of decimal places of precision for floating point values
units: string for PV units
severity: PV severity
timestamp: timestamp from CA server.
read_access: read access (
True
/False
)write_access: write access (
True
/False
)access: string description of read- and write-access
host: host machine and CA port serving PV
enum_strs: the list of enumeration strings
upper_disp_limit: upper display limit
lower_disp_limit: lower display limit
upper_alarm_limit: upper alarm limit
lower_alarm_limit: lower alarm limit
upper_warning_limit: upper warning limit
lower_warning_limit: lower warning limit
upper_ctrl_limit: upper control limit
lower_ctrl_limit: lower control limit
chid: integer channel ID
- cb_info: (index, self) tuple containing callback ID
and the PV object
Some of these may not be directly applicable to all PV data types, and some
values may be None
if the control parameters have not yet been fetched with
get_ctrlvars()
.
It is important to keep in mind that the callback function will be run
inside a CA function, and cannot reliably make any other CA calls. It is
helpful to think “this all happens inside of a pend_event()
call”,
and in an epics thread that may or may not be the main thread of your
program. It is advisable to keep the callback functions short and not
resource-intensive. Consider strategies which use the callback only to
record that a change has occurred and then act on that change later –
perhaps in a separate thread, perhaps after pend_event()
has
completed.
The cb_info parameter supplied to the callback needs special attention,
as it is the only non-Epics information passed. The cb_info parameter
will be a tuple containing (index
, self
) where
index
is the key for the callbacks
dictionary for the PV
and self
is PV object. A principle use of this tuple is to
remove the current callback if an error happens, as for example in GUI
code if the widget that the callback is meant to update disappears.
User-supplied Connection Callback functions¶
A connection callback is a user-defined function that is called when the
connection status of a PV changes – that is, when a PV initially
connects, disconnects or reconnects due to the process serving the PV going
away, or loss of network connection. A connection callback can be
specified when a PV is created, or can be added by appending to the
connection_callbacks
list. If there is more than one connection
callback defined, they will all be run when the connection state changes.
A connection callback should be prepared to receive the following keyword arguments:
pvname: the name of the pv
conn: the connection status
where conn will be either True` or ``False
, specifying whether the PV is
now connected. A simple example is given below.
User-supplied Access Rights Callback functions¶
An access rights callback is a user-defined function that is called when the
access rights - read/write permissions - of a PV undergo changes. The callback
will be invoked upon successful initialization and at all events that change
a PV’s access rights, including disconnection and reconnection events.
An access rights callback can be specified when a PV is created, or can be
added by appending to the access_callbacks
list of the PV object.
If there are multiple access rights callbacks defined for a PV, they will all
be run on access rights events.
Put with wait, put callbacks, and put_complete¶
Some EPICS records take a significant amount of time to fully process, and sometimes you want to wait until the processing completes before going on. There are a few ways to accomplish this. First, one can simply wait until the processing is done:
import epics
p = epics.PV('XXX')
p.put(1.0, wait=True)
print 'Done'
This will hang until the processing of the PV completes (motor moving, etc) before printing ‘Done’. You can also specify a maximum time to wait – a timeout (in seconds):
p.put(1.0, wait=True, timeout=30)
which will wait up to 30 seconds. For the pedantic, this timeout should not be used as an accurate clock – the actual wait time may be slightly longer.
A second method is to use the ‘use_complete’ option and watch for the
put_complete
attribute to become True
after a put()
. This is
somewhat more flexible than using wait=True as above, because you can more
carefully control how often you look for a put()
to complete, and
what to do in the interim. A simple example would be:
p.put(1.0, use_complete=True)
waiting = True
while waiting:
time.sleep(0.001)
waiting = not p.put_complete
An additional advantage of this approach is that you can easily wait for multiple PVs to complete with python’s built-in all function, as with:
pvgroup = (epics.PV('XXX'), epics.PV('YYY'), epics.PV('ZZZ'))
newvals = (1.0, 2.0, 3.0)
for pv, val in zip(pvgroup, newvals):
pv.put(val, use_complete=True)
waiting = True
while waiting:
time.sleep(0.001)
waiting = not all([pv.put_complete for pv in pvgroup])
print 'All puts are done!'
For maximum flexibility, one can all define a put callback, a function to
be run when the put()
has completed. This function requires a
pvname keyword argument, but will receive no others, unless you pass in
data with the callback_data argument (which should be dict-like) to
put()
. A simple example would be:
pv = epics.PV('XXX')
def onPutComplete(pvname=None, **kws):
print 'Put done for %s' % pvname
pv.put(1.0, callback=onPutComplete)
The get_pv()
function and _PVcache_
cache of PVs¶
As mentioned in the previous chapter, a cache of PVs is maintained for each
process using pyepics. When using epics.caget()
, epics.caput()
and so forth, or when creating a PV
directly, the corresponding PV
is kept in a global cache, held in pv._PVcache_
.
The function get_pv()
will retrieve the named PV from this cache, or
create a new PV
if one is not found. In long-running or complex
processes, it is not unusual to access a particular PV many times, perhaps
calling a function that creates a PV but only keeping that PV object for
the life of the function. Using get_pv()
instead of creating a
PV
can improve performance (the PV is already connected) and is
highly recommended.
-
pv.
get_pv
(pvname[, form='time'[, connect=False[, timeout=5[, context=None[, **kws]]]]])¶ retrieves a PV from
_PVcache
or creates and returns a new PV.- Parameters
pvname – name of Epics Process Variable
form (string, one of ('native','ctrl', or 'time')) – which epics data type to use: the ‘native’ , or the ‘ctrl’ (Control) or ‘time’ variant.
connect (
True
/False
) – whether to wait for the PV to connect.timeout (float or
None
) – maximum time to wait (in seconds) for value before returning None.context (integer or
None
(default)) – integer threading context.
Additional keywords are passed directly to
PV
.
Examples¶
Some simple examples using PVs follow.
Basic Use¶
The simplest approach is to simply create a PV and use its value
attribute:
>>> from epics import PV
>>> p1 = PV('xxx.VAL')
>>> print p1.value
1.00
>>> p1.value = 2.00
The print p1.value line automatically fetches the current PV value. The
p1.value = 2.00 line does a put()
to set the value, causing any
necessary processing over the network.
The above example is equivalent to
>>> from epics import PV
>>> p1 = PV('xxx.VAL')
>>> print p1.get()
1.00
>>> p1.put(value = 2.00)
To get a string representation of the value, you can use either
>>> print p1.get(as_string=True)
'1.000'
or, equivalently
>>> print p1.char_value
'1.000'
Requests including Metadata¶
It is also possible to get the metadata associated with a single Channel Access
request using get_with_metadata()
:
>>> from epics import PV
>>> p1 = PV('xxx.VAL', form='time')
>>> print(p1.get())
1.00
>>> p1.get_with_metadata()
{'status': 0,
'severity': 0,
'timestamp': 1543429156.811018,
'posixseconds': 1543429156.0,
'nanoseconds': 811018603,
'value': 1.0}
>>> print(p1.get_with_metadata(form='ctrl'))
{'upper_disp_limit': 100.0,
'lower_disp_limit': -100.0,
'upper_alarm_limit': 0.0,
'upper_warning_limit': 0.0,
'lower_warning_limit': 0.0,
'lower_alarm_limit': 0.0,
'upper_ctrl_limit': 100.0,
'lower_ctrl_limit': -100.0,
'precision': 3,
'units': 'deg',
'status': 0,
'severity': 0,
'value': 1.0}
Example of using info and more properties examples¶
A PV has many attributes. This can be seen from its info paragraph:
>>> import epics
>>> p = epics.PV('13IDA:m3')
>>> print p.info
== 13IDA:m3 (native_double) ==
value = 0.2
char_value = '0.200'
count = 1
type = double
units = mm
precision = 3
host = ioc13ida.cars.aps.anl.gov:5064
access = read/write
status = 0
severity = 0
timestamp = 1274809682.967 (2010-05-25 12:48:02.967364)
upper_ctrl_limit = 5.49393415451
lower_ctrl_limit = -14.5060658455
upper_disp_limit = 5.49393415451
lower_disp_limit = -14.5060658455
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 individual attributes can also be accessed as below. Many of these
(the control attributes, see Table of Control Attributes) will not be filled in until either the info
attribute is accessed or until get_ctrlvars()
is called.
>>> print p.type
double
>>> print p.units, p.precision, p.lower_disp_limit
mm 3 -14.5060658455
Getting a string value¶
It is not uncommon to want a string representation of a PVs value, for
example to show in a display window or to write to some report. For string
PVs and integer PVs, this is a simple task. For floating point values,
there is ambiguity how many significant digits to show. EPICS PVs all have
a precision
field. which sets how many digits after the decimal
place should be described. In addition, for ENUM PVs, it would be
desire able to get at the name of the ENUM state, not just its integer
value.
To get the string representation of a PVs value, use either the
char_value
attribute or the as_string=True argument to get()
Example of put()
¶
To put a new value to a variable, either of these two approaches can be used:
>>> import epics
>>> p = epics.PV('XXX')
>>> p.put(1.0)
Or (equivalently):
>>> import epics
>>> p = epics.PV('XXX')
>>> p.value = 1.0
The value
attribute is the only attribute that can be set.
Example of simple callback¶
It is often useful to get a notification of when a PV changes. In general, it would be inconvenient (and possibly inefficient) to have to continually ask if a PVs value has changed. Instead, it is better to set a callback function: a function to be run when the value has changed.
A simple example of this would be:
import epics
import time
def onChanges(pvname=None, value=None, char_value=None, **kw):
print 'PV Changed! ', pvname, char_value, time.ctime()
mypv = epics.PV(pvname)
mypv.add_callback(onChanges)
print 'Now wait for changes'
t0 = time.time()
while time.time() - t0 < 60.0:
time.sleep(1.e-3)
print 'Done.'
This first defines a callback function called onChanges() and then simply waits for changes to happen. Note that the callback function should take keyword arguments, and generally use **kw to catch all arguments. See User-supplied Callback functions for more details.
Example of connection callback¶
A connection callback:
#
# example of using a connection callback that will be called
# for any change in connection status
import epics
import time
import sys
from pvnames import motor1
write = sys.stdout.write
def onConnectionChange(pvname=None, conn= None, **kws):
write('PV connection status changed: %s %s\n' % (pvname, repr(conn)))
sys.stdout.flush()
def onValueChange(pvname=None, value=None, host=None, **kws):
write('PV value changed: %s (%s) %s\n' % ( pvname, host, repr(value)))
sys.stdout.flush()
mypv = epics.PV(motor1,
connection_callback= onConnectionChange,
callback= onValueChange)
mypv.get()
write('Now waiting, watching values and connection changes:\n')
t0 = time.time()
while time.time()-t0 < 300:
time.sleep(0.01)
Example of an access rights callback¶
Associating an access rights callback with a PV:
import epics
import time
def access_rights_callback(read_access, write_access, pv=None):
print "%s - read=%s, write=%s" % (pv.pvname, read_access, write_access)
# should immediately see the message upon connection
apv = epics.PV('pvname', access_callback=access_rights_callback)
try:
start = time.time()
while (time.time() - start) < 30:
time.sleep(0.25)
except KeyboardInterrupt:
pass