forked from M-Labs/artiq
Add gateware input event counter
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"""Driver for RTIO-enabled TTL edge counter.
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Like for the TTL input PHYs, sensitivity can be configured over RTIO
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(``gate_rising()``, etc.). In contrast to the former, however, the count is
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accumulated in gateware, and only a single input event is generated at the end
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of each gate period::
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with parallel:
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doppler_cool()
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self.pmt_counter.gate_rising(1 * ms)
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with parallel:
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readout()
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self.pmt_counter.gate_rising(100 * us)
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print("Doppler cooling counts:", self.pmt_counter.fetch_count())
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print("Readout counts:", self.pmt_counter.fetch_count())
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For applications where the timestamps of the individual input events are not
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required, this has two advantages over ``TTLInOut.count()`` beyond raw
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throughput. First, it is easy to count events during multiple separate periods
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without blocking to read back counts in between, as illustrated in the above
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example. Secondly, as each count total only takes up a single input event, it
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is much easier to acquire counts on several channels in parallel without
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risking input FIFO overflows::
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# Using the TTLInOut driver, pmt_1 input events are only processed
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# after pmt_0 is done counting. To avoid RTIOOverflows, a round-robin
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# scheme would have to be implemented manually.
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with parallel:
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self.pmt_0.gate_rising(10 * ms)
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self.pmt_1.gate_rising(10 * ms)
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counts_0 = self.pmt_0.count(now_mu()) # blocks
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counts_1 = self.pmt_1.count(now_mu())
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#
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# Using gateware counters, only a single input event each is
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# generated, greatly reducing the load on the input FIFOs:
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with parallel:
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self.pmt_0_counter.gate_rising(10 * ms)
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self.pmt_1_counter.gate_rising(10 * ms)
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counts_0 = self.pmt_0_counter.fetch_count() # blocks
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counts_1 = self.pmt_1_counter.fetch_count()
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See :mod:`artiq.gateware.rtio.phy.edge_counter` and
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:meth:`artiq.gateware.eem.DIO.add_std` for the gateware components.
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"""
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from artiq.language.core import *
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from artiq.language.types import *
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from artiq.coredevice.rtio import (rtio_output, rtio_input_data,
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rtio_input_timestamped_data)
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from numpy import int32, int64
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CONFIG_COUNT_RISING = 0b0001
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CONFIG_COUNT_FALLING = 0b0010
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CONFIG_SEND_COUNT_EVENT = 0b0100
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CONFIG_RESET_TO_ZERO = 0b1000
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class CounterOverflow(Exception):
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"""Raised when an edge counter value is read which indicates that the
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counter might have overflowed."""
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pass
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class EdgeCounter:
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"""RTIO TTL edge counter driver driver.
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Like for regular TTL inputs, timeline periods where the counter is
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sensitive to a chosen set of input transitions can be specified. Unlike the
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former, however, the specified edges do not create individual input events;
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rather, the total count can be requested as a single input event from the
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core (typically at the end of the gate window).
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:param channel: The RTIO channel of the gateware phy.
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:param gateware_width: The width of the gateware counter register, in
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bits. This is only used for overflow handling; to change the size,
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the gateware needs to be rebuilt.
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"""
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kernel_invariants = {"core", "channel", "counter_max"}
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def __init__(self, dmgr, channel, gateware_width=31, core_device="core"):
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self.core = dmgr.get(core_device)
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self.channel = channel
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self.counter_max = (1 << (gateware_width - 1)) - 1
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@kernel
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def gate_rising(self, duration):
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"""Count rising edges for the given duration and request the total at
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the end.
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The counter is reset at the beginning of the gate period. Use
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:meth:`set_config` directly for more detailed control.
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:param duration: The duration for which the gate is to stay open.
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:return: The timestamp at the end of the gate period, in machine units.
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"""
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return self.gate_rising_mu(self.core.seconds_to_mu(duration))
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@kernel
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def gate_falling(self, duration):
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"""Count falling edges for the given duration and request the total at
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the end.
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The counter is reset at the beginning of the gate period. Use
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:meth:`set_config` directly for more detailed control.
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:param duration: The duration for which the gate is to stay open.
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:return: The timestamp at the end of the gate period, in machine units.
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"""
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return self.gate_falling_mu(self.core.seconds_to_mu(duration))
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@kernel
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def gate_both(self, duration):
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"""Count both rising and falling edges for the given duration, and
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request the total at the end.
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The counter is reset at the beginning of the gate period. Use
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:meth:`set_config` directly for more detailed control.
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:param duration: The duration for which the gate is to stay open.
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:return: The timestamp at the end of the gate period, in machine units.
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"""
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return self.gate_both_mu(self.core.seconds_to_mu(duration))
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@kernel
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def gate_rising_mu(self, duration_mu):
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"""See :meth:`gate_rising`."""
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return self._gate_mu(
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duration_mu, count_rising=True, count_falling=False)
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@kernel
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def gate_falling_mu(self, duration_mu):
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"""See :meth:`gate_falling`."""
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return self._gate_mu(
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duration_mu, count_rising=False, count_falling=True)
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@kernel
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def gate_both_mu(self, duration_mu):
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"""See :meth:`gate_both_mu`."""
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return self._gate_mu(
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duration_mu, count_rising=True, count_falling=True)
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@kernel
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def _gate_mu(self, duration_mu, count_rising, count_falling):
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self.set_config(
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count_rising=count_rising,
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count_falling=count_falling,
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send_count_event=False,
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reset_to_zero=True)
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delay_mu(duration_mu)
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self.set_config(
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count_rising=False,
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count_falling=False,
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send_count_event=True,
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reset_to_zero=False)
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return now_mu()
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@kernel
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def set_config(self, count_rising: TBool, count_falling: TBool,
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send_count_event: TBool, reset_to_zero: TBool):
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"""Emit an RTIO event at the current timeline position to set the
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gateware configuration.
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For most use cases, the `gate_*` wrappers will be more convenient.
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:param count_rising: Whether to count rising signal edges.
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:param count_falling: Whether to count falling signal edges.
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:param send_count_event: If `True`, an input event with the current
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counter value is generated on the next clock cycle (once).
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:param reset_to_zero: If `True`, the counter value is reset to zero on
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the next clock cycle (once).
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"""
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config = int32(0)
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if count_rising:
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config |= CONFIG_COUNT_RISING
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if count_falling:
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config |= CONFIG_COUNT_FALLING
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if send_count_event:
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config |= CONFIG_SEND_COUNT_EVENT
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if reset_to_zero:
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config |= CONFIG_RESET_TO_ZERO
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rtio_output(self.channel << 8, config)
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@kernel
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def fetch_count(self) -> TInt32:
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"""Wait for and return count total from previously requested input
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event.
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It is valid to trigger multiple gate periods without immediately
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reading back the count total; the results will be returned in order on
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subsequent fetch calls.
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This function blocks until a result becomes available.
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"""
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count = rtio_input_data(self.channel)
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if count == self.counter_max:
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raise CounterOverflow(
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"Input edge counter overflow on RTIO channel {0}",
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int64(self.channel))
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return count
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@kernel
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def fetch_timestamped_count(
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self, timeout_mu=int64(-1)) -> TTuple([TInt64, TInt32]):
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"""Wait for and return the timestamp and count total of a previously
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requested input event.
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It is valid to trigger multiple gate periods without immediately
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reading back the count total; the results will be returned in order on
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subsequent fetch calls.
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This function blocks until a result becomes available or the given
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timeout elapses.
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:return: A tuple of timestamp (-1 if timeout elapsed) and counter
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value. (The timestamp is that of the requested input event –
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typically the gate closing time – and not that of any input edges.)
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"""
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timestamp, count = rtio_input_timestamped_data(timeout_mu,
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self.channel)
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if count == self.counter_max:
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raise CounterOverflow(
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"Input edge counter overflow on RTIO channel {0}",
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int64(self.channel))
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return timestamp, count
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@ -38,20 +38,32 @@ class DIO(_EEM):
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for i in range(8)]
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@classmethod
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def add_std(cls, target, eem, ttl03_cls, ttl47_cls, iostandard="LVDS_25"):
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def add_std(cls, target, eem, ttl03_cls, ttl47_cls, iostandard="LVDS_25",
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edge_counter_cls=None):
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cls.add_extension(target, eem, iostandard=iostandard)
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phys = []
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for i in range(4):
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pads = target.platform.request("dio{}".format(eem), i)
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phy = ttl03_cls(pads.p, pads.n)
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phys.append(phy)
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target.submodules += phy
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target.rtio_channels.append(rtio.Channel.from_phy(phy))
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for i in range(4):
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pads = target.platform.request("dio{}".format(eem), 4+i)
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phy = ttl47_cls(pads.p, pads.n)
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phys.append(phy)
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target.submodules += phy
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target.rtio_channels.append(rtio.Channel.from_phy(phy))
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if edge_counter_cls is not None:
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for phy in phys:
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state = getattr(phy, "input_state", None)
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if state is not None:
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counter = edge_counter_cls(state)
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target.submodules += counter
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target.rtio_channels.append(rtio.Channel.from_phy(counter))
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class Urukul(_EEM):
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@staticmethod
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from migen import *
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from artiq.gateware.rtio import rtlink
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class SimpleEdgeCounter(Module):
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"""Counts rising/falling edges of an input signal.
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Control (sensitivity/zeroing) is done via a single RTIO output channel,
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which is is also used to request an input event to be emitted with the
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current counter value.
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:param input_state: The (scalar) input signal to detect edges of. This
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should already be in the rio_phy clock domain.
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:param counter_width: The width of the counter register, in bits. Defaults
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to 31 to match integers being signed in ARTIQ Python.
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"""
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def __init__(self, input_state, counter_width=31):
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assert counter_width >= 2
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# RTIO interface:
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# - output 0: 4 bits, <count_rising><count_falling><send_event><zero_counter>
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# - input 0: 32 bits, accumulated edge count
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self.rtlink = rtlink.Interface(
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rtlink.OInterface(4, enable_replace=False),
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rtlink.IInterface(counter_width))
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# # #
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current_count = Signal(counter_width)
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count_rising = Signal()
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count_falling = Signal()
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send_event_stb = Signal()
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zero_counter_stb = Signal()
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# Read configuration from RTIO output events.
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self.sync.rio += [
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If(self.rtlink.o.stb,
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count_rising.eq(self.rtlink.o.data[0]),
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count_falling.eq(self.rtlink.o.data[1]),
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send_event_stb.eq(self.rtlink.o.data[2]),
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zero_counter_stb.eq(self.rtlink.o.data[3])
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).Else(
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send_event_stb.eq(0),
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zero_counter_stb.eq(0)
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)
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]
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# Generate RTIO input event with current count if requested.
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event_data = Signal.like(current_count)
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self.comb += [
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self.rtlink.i.stb.eq(send_event_stb),
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self.rtlink.i.data.eq(event_data)
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]
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# Keep previous input state for edge detection.
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input_state_d = Signal()
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self.sync.rio_phy += input_state_d.eq(input_state)
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# Count input edges, saturating at the maximum.
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new_count = Signal.like(current_count)
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self.comb += new_count.eq(
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current_count + Mux(current_count == 2**counter_width - 1,
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0,
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(count_rising & (input_state & ~input_state_d)) |
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(count_falling & (~input_state & input_state_d))
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)
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)
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self.sync.rio += [
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event_data.eq(new_count),
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current_count.eq(Mux(zero_counter_stb, 0, new_count))
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]
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if __name__ == '__main__':
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input = Signal(name="input")
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print(fhdl.verilog.convert(SimpleEdgeCounter(input)))
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@ -67,6 +67,10 @@ class InOut(Module):
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override_oe = Signal()
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self.overrides = [override_en, override_o, override_oe]
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#: LSB of the input state (for edge detection; arbitrary choice, support for
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#: short pulses will need a more involved solution).
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self.input_state = Signal()
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# # #
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# Output
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@ -100,6 +104,7 @@ class InOut(Module):
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]
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i = serdes.i[-1]
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self.comb += self.input_state.eq(i)
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i_d = Signal()
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self.sync.rio_phy += [
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i_d.eq(i),
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@ -41,6 +41,9 @@ class Input(Module):
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self.overrides = []
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self.probes = []
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#: Registered copy of the input state, in the rio_phy clock domain.
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self.input_state = Signal()
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# # #
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sensitivity = Signal(2)
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(sensitivity[0] & ( i & ~i_d)) |
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(sensitivity[1] & (~i & i_d))
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),
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self.rtlink.i.data.eq(i)
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self.rtlink.i.data.eq(i),
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self.input_state.eq(i)
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]
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self.probes += [i]
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@ -86,6 +90,9 @@ class InOut(Module):
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self.overrides = [override_en, override_o, override_oe]
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self.probes = []
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# Registered copy of the input state, in the rio_phy clock domain.
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self.input_state = Signal()
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# # #
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ts = TSTriple()
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@ -126,7 +133,8 @@ class InOut(Module):
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(sensitivity[0] & ( i & ~i_d)) |
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(sensitivity[1] & (~i & i_d))
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),
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self.rtlink.i.data.eq(i)
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self.rtlink.i.data.eq(i),
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self.input_state.eq(i)
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]
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self.probes += [i, ts.oe]
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@ -0,0 +1,134 @@
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import unittest
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from migen import *
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from artiq.gateware.rtio.phy.edge_counter import *
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CONFIG_COUNT_RISING = 0b0001
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CONFIG_COUNT_FALLING = 0b0010
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CONFIG_SEND_COUNT_EVENT = 0b0100
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CONFIG_RESET_TO_ZERO = 0b1000
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class TimeoutError(Exception):
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pass
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class Testbench:
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def __init__(self, counter_width=32):
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self.input = Signal()
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self.dut = SimpleEdgeCounter(self.input, counter_width=counter_width)
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self.fragment = self.dut.get_fragment()
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cd = ClockDomain("rio")
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self.fragment.clock_domains.append(cd)
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self.rio_rst = cd.rst
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def write_config(self, config):
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bus = self.dut.rtlink.o
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yield bus.data.eq(config)
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yield bus.stb.eq(1)
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yield
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yield bus.stb.eq(0)
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yield
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def read_event(self, timeout):
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bus = self.dut.rtlink.i
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for _ in range(timeout):
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if (yield bus.stb):
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break
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yield
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else:
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raise TimeoutError
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return (yield bus.data)
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def fetch_count(self, zero=False):
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c = CONFIG_SEND_COUNT_EVENT
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if zero:
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c |= CONFIG_RESET_TO_ZERO
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yield from self.write_config(c)
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return (yield from self.read_event(1))
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def toggle_input(self):
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yield self.input.eq(1)
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yield
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yield self.input.eq(0)
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yield
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def reset_rio(self):
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yield self.rio_rst.eq(1)
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yield
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yield self.rio_rst.eq(0)
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yield
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def run(self, gen):
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run_simulation(self.fragment, gen,
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clocks={n: 5 for n in ["sys", "rio", "rio_phy"]})
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class TestEdgeCounter(unittest.TestCase):
|
||||
def test_init(self):
|
||||
tb = Testbench()
|
||||
|
||||
def gen():
|
||||
# No counts initially...
|
||||
self.assertEqual((yield from tb.fetch_count()), 0)
|
||||
|
||||
# ...nor any sensitivity.
|
||||
yield from tb.toggle_input()
|
||||
self.assertEqual((yield from tb.fetch_count()), 0)
|
||||
|
||||
tb.run(gen())
|
||||
|
||||
def test_sensitivity(self):
|
||||
tb = Testbench()
|
||||
|
||||
def gen(sensitivity_config, expected_rising, expected_falling):
|
||||
yield from tb.write_config(sensitivity_config)
|
||||
yield tb.input.eq(1)
|
||||
yield
|
||||
self.assertEqual((yield from tb.fetch_count(zero=True)),
|
||||
expected_rising)
|
||||
|
||||
yield from tb.write_config(sensitivity_config)
|
||||
yield tb.input.eq(0)
|
||||
yield
|
||||
self.assertEqual((yield from tb.fetch_count()), expected_falling)
|
||||
|
||||
yield
|
||||
with self.assertRaises(TimeoutError):
|
||||
# Make sure there are no more suprious events.
|
||||
yield from tb.read_event(10)
|
||||
|
||||
tb.run(gen(CONFIG_COUNT_RISING, 1, 0))
|
||||
tb.run(gen(CONFIG_COUNT_FALLING, 0, 1))
|
||||
tb.run(gen(CONFIG_COUNT_RISING | CONFIG_COUNT_FALLING, 1, 1))
|
||||
|
||||
def test_reset(self):
|
||||
tb = Testbench()
|
||||
|
||||
def gen():
|
||||
# Generate one count.
|
||||
yield from tb.write_config(CONFIG_COUNT_RISING)
|
||||
yield from tb.toggle_input()
|
||||
self.assertEqual((yield from tb.fetch_count()), 1)
|
||||
|
||||
# Make sure it is gone after an RTIO reset, and the counter isn't
|
||||
# sensitive anymore.
|
||||
yield from tb.write_config(CONFIG_COUNT_RISING)
|
||||
yield from tb.reset_rio()
|
||||
yield from tb.toggle_input()
|
||||
self.assertEqual((yield from tb.fetch_count()), 0)
|
||||
|
||||
tb.run(gen())
|
||||
|
||||
def test_saturation(self):
|
||||
for width in range(3, 5):
|
||||
tb = Testbench(counter_width=width)
|
||||
|
||||
def gen():
|
||||
yield from tb.write_config(CONFIG_COUNT_RISING)
|
||||
for _ in range(2**width + 1):
|
||||
yield from tb.toggle_input()
|
||||
self.assertEqual((yield from tb.fetch_count()), 2**width - 1)
|
||||
|
||||
tb.run(gen())
|
|
@ -0,0 +1,97 @@
|
|||
from artiq.experiment import *
|
||||
from artiq.test.hardware_testbench import ExperimentCase
|
||||
|
||||
|
||||
class EdgeCounterExp(EnvExperiment):
|
||||
def build(self):
|
||||
self.setattr_device("core")
|
||||
self.setattr_device("loop_in_counter")
|
||||
self.setattr_device("loop_out")
|
||||
|
||||
@kernel
|
||||
def count_pulse_edges(self, gate_fn):
|
||||
self.core.break_realtime()
|
||||
with parallel:
|
||||
with sequential:
|
||||
delay(5 * us)
|
||||
self.loop_out.pulse(10 * us)
|
||||
with sequential:
|
||||
gate_fn(10 * us)
|
||||
delay(1 * us)
|
||||
gate_fn(10 * us)
|
||||
return (self.loop_in_counter.fetch_count(),
|
||||
self.loop_in_counter.fetch_count())
|
||||
|
||||
@kernel
|
||||
def timeout_timestamp(self):
|
||||
self.core.break_realtime()
|
||||
timestamp_mu, _ = self.loop_in_counter.fetch_timestamped_count(
|
||||
now_mu())
|
||||
return timestamp_mu
|
||||
|
||||
@kernel
|
||||
def gate_relative_timestamp(self):
|
||||
self.core.break_realtime()
|
||||
gate_end_mu = self.loop_in_counter.gate_rising(1 * us)
|
||||
timestamp_mu, _ = self.loop_in_counter.fetch_timestamped_count()
|
||||
return timestamp_mu - gate_end_mu
|
||||
|
||||
@kernel
|
||||
def many_pulses_split(self, num_pulses):
|
||||
self.core.break_realtime()
|
||||
|
||||
self.loop_in_counter.set_config(
|
||||
count_rising=True,
|
||||
count_falling=True,
|
||||
send_count_event=False,
|
||||
reset_to_zero=True)
|
||||
|
||||
for _ in range(num_pulses):
|
||||
self.loop_out.pulse(5 * us)
|
||||
delay(5 * us)
|
||||
|
||||
self.loop_in_counter.set_config(
|
||||
count_rising=True,
|
||||
count_falling=True,
|
||||
send_count_event=True,
|
||||
reset_to_zero=False)
|
||||
|
||||
for _ in range(num_pulses):
|
||||
self.loop_out.pulse(5 * us)
|
||||
delay(5 * us)
|
||||
|
||||
self.loop_in_counter.set_config(
|
||||
count_rising=False,
|
||||
count_falling=False,
|
||||
send_count_event=True,
|
||||
reset_to_zero=False)
|
||||
|
||||
return (self.loop_in_counter.fetch_count(),
|
||||
self.loop_in_counter.fetch_count())
|
||||
|
||||
|
||||
class EdgeCounterTest(ExperimentCase):
|
||||
def setUp(self):
|
||||
super().setUp()
|
||||
self.exp = self.create(EdgeCounterExp)
|
||||
|
||||
def test_sensitivity(self):
|
||||
c = self.exp.loop_in_counter
|
||||
self.assertEqual(self.exp.count_pulse_edges(c.gate_rising), (1, 0))
|
||||
self.assertEqual(self.exp.count_pulse_edges(c.gate_falling), (0, 1))
|
||||
self.assertEqual(self.exp.count_pulse_edges(c.gate_both), (1, 1))
|
||||
|
||||
def test_timeout_timestamp(self):
|
||||
self.assertEqual(self.exp.timeout_timestamp(), -1)
|
||||
|
||||
def test_gate_timestamp(self):
|
||||
# The input event should be received at some point after it was
|
||||
# requested, with some extra latency as it makes its way through the
|
||||
# DRTIO machinery. (We only impose a somewhat arbitrary upper limit
|
||||
# on the latency here.)
|
||||
delta_mu = self.exp.gate_relative_timestamp()
|
||||
self.assertGreaterEqual(delta_mu, 0)
|
||||
self.assertLess(delta_mu, 100)
|
||||
|
||||
def test_many_pulses_split(self):
|
||||
self.assertEqual(self.exp.many_pulses_split(500), (1000, 2000))
|
|
@ -41,6 +41,12 @@ Digital I/O drivers
|
|||
.. automodule:: artiq.coredevice.ttl
|
||||
:members:
|
||||
|
||||
:mod:`artiq.coredevice.edge_counter` module
|
||||
++++++++++++++++++++++++++++++++++++++++++++
|
||||
|
||||
.. automodule:: artiq.coredevice.edge_counter
|
||||
:members:
|
||||
|
||||
:mod:`artiq.coredevice.shiftreg` module
|
||||
+++++++++++++++++++++++++++++++++++++++
|
||||
|
||||
|
|
Loading…
Reference in New Issue