artiq/artiq/coredevice/ttl.py
2016-03-04 08:37:43 +00:00

294 lines
8.6 KiB
Python

from artiq.language.core import *
from artiq.language.types import *
from artiq.coredevice.rtio import rtio_output, rtio_input_timestamp
class TTLOut:
"""RTIO TTL output driver.
This should be used with output-only channels.
:param channel: channel number
"""
def __init__(self, dmgr, channel):
self.core = dmgr.get("core")
self.channel = channel
# in RTIO cycles
self.o_previous_timestamp = int(0, width=64)
@kernel
def output(self):
pass
@kernel
def set_o(self, o):
rtio_output(now_mu(), self.channel, 0, 1 if o else 0)
self.o_previous_timestamp = now_mu()
@kernel
def sync(self):
"""Busy-wait until all programmed level switches have been
effected."""
while self.core.get_rtio_counter_mu() < self.o_previous_timestamp:
pass
@kernel
def on(self):
"""Sets the output to a logic high state."""
self.set_o(True)
@kernel
def off(self):
"""Set the output to a logic low state."""
self.set_o(False)
@kernel
def pulse_mu(self, duration):
"""Pulse the output high for the specified duration
(in machine units)."""
self.on()
delay_mu(duration)
self.off()
@kernel
def pulse(self, duration):
"""Pulse the output high for the specified duration
(in seconds)."""
self.on()
delay(duration)
self.off()
class TTLInOut:
"""RTIO TTL input/output driver.
In output mode, provides functions to set the logic level on the signal.
In input mode, provides functions to analyze the incoming signal, with
real-time gating to prevent overflows.
RTIO TTLs supports zero-length transition suppression. For example, if
two pulses are emitted back-to-back with no delay between them, they will
be merged into a single pulse with a duration equal to the sum of the
durations of the original pulses.
This should be used with bidirectional channels.
Note that the channel is in input mode by default. If you need to drive a
signal, you must call ``output``. If the channel is in output mode most of
the time in your setup, it is a good idea to call ``output`` in the
startup kernel.
:param channel: channel number
"""
def __init__(self, dmgr, channel):
self.core = dmgr.get("core")
self.channel = channel
# in RTIO cycles
self.o_previous_timestamp = int(0, width=64)
self.i_previous_timestamp = int(0, width=64)
@kernel
def set_oe(self, oe):
rtio_output(now_mu(), self.channel, 1, 1 if oe else 0)
@kernel
def output(self):
"""Set the direction to output.
There must be a delay of at least one RTIO clock cycle before any
other command can be issued."""
self.set_oe(True)
@kernel
def input(self):
"""Set the direction to input.
There must be a delay of at least one RTIO clock cycle before any
other command can be issued."""
self.set_oe(False)
@kernel
def set_o(self, o):
rtio_output(now_mu(), self.channel, 0, 1 if o else 0)
self.o_previous_timestamp = now_mu()
@kernel
def sync(self):
"""Busy-wait until all programmed level switches have been
effected."""
while self.core.get_rtio_counter_mu() < self.o_previous_timestamp:
pass
@kernel
def on(self):
"""Set the output to a logic high state.
The channel must be in output mode."""
self.set_o(True)
@kernel
def off(self):
"""Set the output to a logic low state.
The channel must be in output mode."""
self.set_o(False)
@kernel
def pulse_mu(self, duration):
"""Pulses the output high for the specified duration
(in machine units)."""
self.on()
delay_mu(duration)
self.off()
@kernel
def pulse(self, duration):
"""Pulses the output high for the specified duration
(in seconds)."""
self.on()
delay(duration)
self.off()
@kernel
def _set_sensitivity(self, value):
rtio_output(now_mu(), self.channel, 2, value)
self.i_previous_timestamp = now_mu()
@kernel
def gate_rising_mu(self, duration):
"""Register rising edge events for the specified duration
(in machine units)."""
self._set_sensitivity(1)
delay_mu(duration)
self._set_sensitivity(0)
@kernel
def gate_falling_mu(self, duration):
"""Register falling edge events for the specified duration
(in machine units)."""
self._set_sensitivity(2)
delay_mu(duration)
self._set_sensitivity(0)
@kernel
def gate_both_mu(self, duration):
"""Register both rising and falling edge events for the specified
duration (in machine units)."""
self._set_sensitivity(3)
delay_mu(duration)
self._set_sensitivity(0)
@kernel
def gate_rising(self, duration):
"""Register rising edge events for the specified duration
(in seconds)."""
self._set_sensitivity(1)
delay(duration)
self._set_sensitivity(0)
@kernel
def gate_falling(self, duration):
"""Register falling edge events for the specified duration
(in seconds)."""
self._set_sensitivity(2)
delay(duration)
self._set_sensitivity(0)
@kernel
def gate_both(self, duration):
"""Register both rising and falling edge events for the specified
duration (in seconds)."""
self._set_sensitivity(3)
delay(duration)
self._set_sensitivity(0)
@kernel
def count(self):
"""Poll the RTIO input during all the previously programmed gate
openings, and returns the number of registered events."""
count = 0
while rtio_input_timestamp(self.i_previous_timestamp, self.channel) >= 0:
count += 1
return count
@kernel
def timestamp_mu(self):
"""Poll the RTIO input and returns an event timestamp (in machine
units), according to the gating.
If the gate is permanently closed, returns a negative value.
"""
return rtio_input_timestamp(self.i_previous_timestamp, self.channel)
class TTLClockGen:
"""RTIO TTL clock generator driver.
This should be used with TTL channels that have a clock generator
built into the gateware (not compatible with regular TTL channels).
:param channel: channel number
"""
def __init__(self, dmgr, channel):
self.core = dmgr.get("core")
self.channel = channel
# in RTIO cycles
self.previous_timestamp = int(0, width=64)
self.acc_width = int(24, width=64)
@portable
def frequency_to_ftw(self, frequency):
"""Returns the frequency tuning word corresponding to the given
frequency.
"""
return round(2**self.acc_width*frequency*self.core.ref_period)
@portable
def ftw_to_frequency(self, ftw):
"""Returns the frequency corresponding to the given frequency tuning
word.
"""
return ftw/self.core.ref_period/2**self.acc_width
@kernel
def set_mu(self, frequency):
"""Set the frequency of the clock, in machine units.
This also sets the phase, as the time of the first generated rising
edge corresponds to the time of the call.
The clock generator contains a 24-bit phase accumulator operating on
the RTIO clock. At each RTIO clock tick, the frequency tuning word is
added to the phase accumulator. The most significant bit of the phase
accumulator is connected to the TTL line. Setting the frequency tuning
word has the additional effect of setting the phase accumulator to
0x800000.
Due to the way the clock generator operates, frequency tuning words
that are not powers of two cause jitter of one RTIO clock cycle at the
output.
"""
rtio_output(now_mu(), self.channel, 0, frequency)
self.previous_timestamp = now_mu()
@kernel
def set(self, frequency):
"""Like ``set_mu``, but using Hz."""
self.set_mu(self.frequency_to_ftw(frequency))
@kernel
def stop(self):
"""Stop the toggling of the clock and set the output level to 0."""
self.set_mu(0)
@kernel
def sync(self):
"""Busy-wait until all programmed frequency switches and stops have
been effected."""
while self.core.get_rtio_counter_mu() < self.o_previous_timestamp:
pass