artiq_ddb_template: fixed missing separator

master: implement devarg_override
dashboard,client: add device argument overrides to expid
2023-12-18 13:23:39 +08:00 · 2023-12-18 12:11:40 +08:00 · 2023-12-17 19:43:41 +08:00 · 2023-12-17 19:42:56 +08:00 · 2023-12-17 16:37:02 +08:00 · 2023-12-17 13:41:49 +08:00
426 changed files with 28242 additions and 20528 deletions
--- a/.gitignore
+++ b/.gitignore
@ -29,6 +29,7 @@ __pycache__/
 /repository/
 /results
 /last_rid.pyon
-/dataset_db.pyon
+/dataset_db.mdb
 /dataset_db.mdb-lock
 /device_db*.py
 /test*
--- a/0
+++ b/0
--- a/CONTRIBUTING.rst
+++ b/CONTRIBUTING.rst
@ -7,8 +7,7 @@ Reporting Issues/Bugs
 Thanks for `reporting issues to ARTIQ
 <https://github.com/m-labs/artiq/issues/new>`_! You can also discuss issues and
-ask questions on IRC (the `#m-labs channel on freenode
+ask questions on IRC (the #m-labs channel on OFTC), the `Mattermost chat
 <https://webchat.freenode.net/?channels=m-labs>`_), the `Mattermost chat
 <https://chat.m-labs.hk>`_, or on the `forum <https://forum.m-labs.hk>`_.
 The best bug reports are those which contain sufficient information. With
@ -27,7 +26,6 @@ report if possible:
  * Operating System
  * ARTIQ version (with recent versions of ARTIQ, run ``artiq_client --version``)
  * Version of the gateware and runtime loaded in the core device (in the output of ``artiq_coremgmt -D .... log``)
  * If using Conda, output of `conda list`
  * Hardware involved
--- a/1
+++ b/1
@ -1 +0,0 @@
 6
--- a/MANIFEST.in
+++ b/MANIFEST.in
@ -4,3 +4,5 @@ include artiq/gui/logo*.svg
 include versioneer.py
 include artiq/_version.py
 include artiq/coredevice/coredevice_generic.schema.json
 include artiq/compiler/kernel.ld
 include artiq/afws.pem
--- a/README.rst
+++ b/README.rst
@ -13,14 +13,14 @@ ARTIQ uses FPGA hardware to perform its time-critical tasks. The `Sinara hardwar
 ARTIQ is designed to be portable to hardware platforms from different vendors and FPGA manufacturers.
 Several different configurations of a `FPGA evaluation kit <https://www.xilinx.com/products/boards-and-kits/ek-k7-kc705-g.html>`_ and of a `Zynq evaluation kit <https://www.xilinx.com/products/boards-and-kits/ek-z7-zc706-g.html>`_ are also used and supported. FPGA platforms can be combined with any number of additional peripherals, either already accessible from ARTIQ or made accessible with little effort.
-ARTIQ and its dependencies are available in the form of Nix packages (for Linux) and Conda packages (for Windows and Linux). See `the manual <https://m-labs.hk/experiment-control/resources/>`_ for installation instructions.
+ARTIQ and its dependencies are available in the form of Nix packages (for Linux) and MSYS2 packages (for Windows). See `the manual <https://m-labs.hk/experiment-control/resources/>`_ for installation instructions.
 Packages containing pre-compiled binary images to be loaded onto the hardware platforms are supplied for each configuration.
 Like any open source software ARTIQ can equally be built and installed directly from `source <https://github.com/m-labs/artiq>`_.
 ARTIQ is supported by M-Labs and developed openly.
 Components, features, fixes, improvements, and extensions are often `funded <https://m-labs.hk/experiment-control/funding/>`_ by and developed for the partnering research groups.
-Core technologies employed include `Python <https://www.python.org/>`_, `Migen <https://github.com/m-labs/migen>`_, `Migen-AXI <https://github.com/peteut/migen-axi>`_, `Rust <https://www.rust-lang.org/>`_, `MiSoC <https://github.com/m-labs/misoc>`_/`mor1kx <https://github.com/openrisc/mor1kx>`_, `LLVM <https://llvm.org/>`_/`llvmlite <https://github.com/numba/llvmlite>`_, and `Qt5 <https://www.qt.io/>`_.
+Core technologies employed include `Python <https://www.python.org/>`_, `Migen <https://github.com/m-labs/migen>`_, `Migen-AXI <https://github.com/peteut/migen-axi>`_, `Rust <https://www.rust-lang.org/>`_, `MiSoC <https://github.com/m-labs/misoc>`_/`VexRiscv <https://github.com/SpinalHDL/VexRiscv>`_, `LLVM <https://llvm.org/>`_/`llvmlite <https://github.com/numba/llvmlite>`_, and `Qt5 <https://www.qt.io/>`_.
 Website: https://m-labs.hk/artiq
@ -29,7 +29,7 @@ Website: https://m-labs.hk/artiq
 License
 =======
-Copyright (C) 2014-2021 M-Labs Limited.
+Copyright (C) 2014-2023 M-Labs Limited.
 ARTIQ is free software: you can redistribute it and/or modify
 it under the terms of the GNU Lesser General Public License as published by
--- a/RELEASE_NOTES.rst
+++ b/RELEASE_NOTES.rst
@ -3,6 +3,170 @@
 Release notes
 =============
 ARTIQ-8 (Unreleased)
 --------------------
 Highlights:
 * New hardware support:
   - Support for Shuttler, a 16-channel 125MSPS DAC card intended for ion transport.
     Waveform generator and user API are similar to the NIST PDQ.
   - Implemented Phaser-servo. This requires recent gateware on Phaser.
   - Almazny v1.2 with finer RF switch control.
   - Metlino and Sayma support has been dropped due to complications with synchronous RTIO clocking.
   - More user LEDs are exposed to RTIO on Kasli.
   - Implemented Phaser-MIQRO support. This requires the proprietary Phaser MIQRO gateware
     variant from QUARTIQ.
   - Sampler: fixed ADC MU to Volt conversion factor for Sampler v2.2+.
     For earlier hardware versions, specify the hardware version in the device
     database file (e.g. ``"hw_rev": "v2.1"``) to use the correct conversion factor.
 * Support for distributed DMA, where DMA is run directly on satellites for corresponding
  RTIO events, increasing bandwidth in scenarios with heavy satellite usage.
 * Support for subkernels, where kernels are run on satellite device CPUs to offload some
  of the processing and RTIO operations.
 * CPU (on softcore platforms) and AXI bus (on Zynq) are now clocked synchronously with the RTIO
  clock, to facilitate implementation of local processing on DRTIO satellites, and to slightly
  reduce RTIO latency.
 * Support for DRTIO-over-EEM, used with Shuttler.
 * Added channel names to RTIO error messages.
 * GUI:
   - Implemented Applet Request Interfaces which allow applets to modify datasets and set the
     current values of widgets in the dashboard's experiment windows.
   - Implemented a new EntryArea widget which allows argument entry widgets to be used in applets.
   - The "Close all applets" command (shortcut: Ctrl-Alt-W) now ignores docked applets,
     making it a convenient way to clean up after exploratory work without destroying a
     carefully arranged default workspace.
   - Hotkeys now organize experiment windows in the order they were last interacted with:
      + CTRL+SHIFT+T tiles experiment windows
      + CTRL+SHIFT+C cascades experiment windows
 * Persistent datasets are now stored in a LMDB database for improved performance.
 * Python's built-in types (such as ``float``, or ``List[...]``) can now be used in type annotations on
  kernel functions.
 * Full Python 3.10 support.
 * MSYS2 packaging for Windows, which replaces Conda. Conda packages are still available to
  support legacy installations, but may be removed in a future release.
 Breaking changes:
 * ``SimpleApplet`` now calls widget constructors with an additional ``ctl`` parameter for control
  operations, which includes dataset operations. It can be ignored if not needed. For an example usage,
  refer to the ``big_number.py`` applet.
 * ``SimpleApplet`` and ``TitleApplet`` now call ``data_changed`` with additional parameters. Derived applets
  should change the function signature as below:
 ::
  # SimpleApplet
  def data_changed(self, value, metadata, persist, mods)
  # SimpleApplet (old version)
  def data_changed(self, data, mods)
  # TitleApplet
  def data_changed(self, value, metadata, persist, mods, title)
  # TitleApplet (old version)
  def data_changed(self, data, mods, title)
 Accesses to the data argument should be replaced as below:
 ::
  data[key][0] ==> persist[key]
  data[key][1] ==> value[key]
 * The ``ndecimals`` parameter in ``NumberValue`` and ``Scannable`` has been renamed to ``precision``. 
  Parameters after and including ``scale`` in both constructors are now keyword-only.
  Refer to the updated ``no_hardware/arguments_demo.py`` example for current usage.
 * Almazny v1.2 is incompatible with the legacy versions and is the default.
  To use legacy versions, specify ``almazny_hw_rev`` in the JSON description.
 * kasli_generic.py has been merged into kasli.py, and the demonstration designs without JSON descriptions
  have been removed. The base classes remain present in kasli.py to support third-party flows without
  JSON descriptions.
 * Legacy PYON databases should be converted to LMDB with the script below:
 ::
  from sipyco import pyon
  import lmdb
  old = pyon.load_file("dataset_db.pyon")
  new = lmdb.open("dataset_db.mdb", subdir=False, map_size=2**30)
  with new.begin(write=True) as txn:
    for key, value in old.items():
      txn.put(key.encode(), pyon.encode((value, {})).encode())
  new.close()
 * ``artiq.wavesynth`` has been removed.
 ARTIQ-7
 -------
 Highlights:
 * New hardware support:
   - Kasli-SoC, a new EEM carrier based on a Zynq SoC, enabling much faster kernel execution
     (see: https://arxiv.org/abs/2111.15290).
   - DRTIO support on Zynq-based devices (Kasli-SoC and ZC706).
   - DRTIO support on KC705.
   - HVAMP_8CH 8 channel HV amplifier for Fastino / Zotinos
   - Almazny mezzanine board for Mirny
   - Phaser: improved documentation, exposed the DAC coarse mixer and ``sif_sync``, exposed upconverter calibration
     and enabling/disabling of upconverter LO & RF outputs, added helpers to align Phaser updates to the
     RTIO timeline (``get_next_frame_mu()``).
   - Urukul: ``get()``, ``get_mu()``, ``get_att()``, and ``get_att_mu()`` functions added for AD9910 and AD9912.
 * Softcore targets now use the RISC-V architecture (VexRiscv) instead of OR1K (mor1kx).
 * Gateware FPU is supported on KC705 and Kasli 2.0.
 * Faster compilation for large arrays/lists.
 * Faster exception handling.
 * Several exception handling bugs fixed.
 * Support for a simpler shared library system with faster calls into the runtime. This is only used by the NAC3
  compiler (nac3ld) and improves RTIO output performance (test_pulse_rate) by 9-10%.
 * Moninj improvements:
  - Urukul monitoring and frequency setting (through dashboard) is now supported.
  - Core device moninj is now proxied via the ``aqctl_moninj_proxy`` controller.
 * The configuration entry ``rtio_clock`` supports multiple clocking settings, deprecating the usage
  of compile-time options.
 * Added support for 100MHz RTIO clock in DRTIO.
 * Previously detected RTIO async errors are reported to the host after each kernel terminates and a
  warning is logged. The warning is additional to the one already printed in the core device log
  immediately upon detection of the error.
 * Extended Kasli gateware JSON description with configuration for SPI over DIO.
 * TTL outputs can be now configured to work as a clock generator from the JSON.
 * On Kasli, the number of FIFO lanes in the scalable events dispatcher (SED) can now be configured in
  the JSON.
 * ``artiq_ddb_template`` generates edge-counter keys that start with the key of the corresponding
  TTL device (e.g. ``ttl_0_counter`` for the edge counter on TTL device ``ttl_0``).
 * ``artiq_master`` now has an ``--experiment-subdir`` option to scan only a subdirectory of the
  repository when building the list of experiments.
 * Experiments can now be submitted by-content.
 * The master can now optionally log all experiments submitted into a CSV file.
 * Removed worker DB warning for writing a dataset that is also in the archive.
 * Experiments can now call ``scheduler.check_termination()`` to test if the user
  has requested graceful termination.
 * ARTIQ command-line programs and controllers now exit cleanly on Ctrl-C.
 * ``artiq_coremgmt reboot`` now reloads gateware as well, providing a more thorough and reliable
  device reset (7-series FPGAs only).
 * Firmware and gateware can now be built on-demand on the M-Labs server using ``afws_client``
  (subscribers only). Self-compilation remains possible.
 * Easier-to-use packaging via Nix Flakes.
 * Python 3.10 support (experimental).
 Breaking changes:
 * Due to the new RISC-V CPU, the device database entry for the core device needs to be updated.
  The ``target`` parameter needs to be set to ``rv32ima`` for Kasli 1.x and to ``rv32g`` for all
  other boards. Freshly generated device database templates already contain this update.
 * Updated Phaser-Upconverter default frequency 2.875 GHz. The new default uses the target PFD
  frequency of the hardware design.
 * ``Phaser.init()`` now disables all Kasli-oscillators. This avoids full power RF output being
  generated for some configurations.
 * Phaser: fixed coarse mixer frequency configuration
 * Mirny: Added extra delays in ``ADF5356.sync()``. This avoids the need of an extra delay before
  calling ``ADF5356.init()``.
 * The deprecated ``set_dataset(..., save=...)`` is no longer supported.
 * The ``PCA9548`` I2C switch class was renamed to ``I2CSwitch``, to accommodate support for PCA9547,
  and possibly other switches in future. Readback has been removed, and now only one channel per
  switch is supported.
 ARTIQ-6
 -------
@ -11,7 +175,7 @@ Highlights:
 * New hardware support:
   - Phaser, a quad channel 1GS/s RF generator card with dual IQ upconverter and dual 5MS/s
     ADC and FPGA.
-   - Zynq SoC core devices, enabling kernels to run on 1 GHz CPU core with a floating-point
+   - Zynq SoC core device (ZC706), enabling kernels to run on 1 GHz CPU core with a floating-point
     unit for faster computations. This currently requires an external
     repository (https://git.m-labs.hk/m-labs/artiq-zynq).
   - Mirny 4-channel wide-band PLL/VCO-based microwave frequency synthesiser
@ -33,8 +197,11 @@ Highlights:
   - Improved performance for kernel RPC involving list and array.
 * Coredevice SI to mu conversions now always return valid codes, or raise a ``ValueError``.
 * Zotino now exposes  ``voltage_to_mu()``
-* ``ad9910``: The maximum amplitude scale factor is now ``0x3fff`` (was ``0x3ffe``
+* ``ad9910``: 
-  before).
+   - The maximum amplitude scale factor is now ``0x3fff`` (was ``0x3ffe`` before).
   - The default single-tone profile is now 7 (was 0).
   - Added option to ``set_mu()`` that affects the ASF, FTW and POW registers
     instead of the single-tone profile register.
 * Mirny now supports HW revision independent, human readable ``clk_sel`` parameters:
  "XO", "SMA", and "MMCX". Passing an integer is backwards compatible.
 * Dashboard:
@ -67,6 +234,9 @@ Breaking changes:
 * ``quamash`` has been replaced with ``qasync``.
 * Protocols are updated to use device endian.
 * Analyzer dump format includes a byte for device endianness.
 * To support variable numbers of Urukul cards in the future, the
  ``artiq.coredevice.suservo.SUServo`` constructor now accepts two device name lists,
  ``cpld_devices`` and ``dds_devices``, rather than four individual arguments.
 * Experiment classes with underscore-prefixed names are now ignored when ``artiq_client``
  determines which experiment to submit (consistent with ``artiq_run``).
--- a/artiq/_version.py
+++ b/artiq/_version.py
@ -1,13 +1,7 @@
 import os
 def get_rev():
    return os.getenv("VERSIONEER_REV", default="unknown")
 def get_version():
-    override = os.getenv("VERSIONEER_OVERRIDE")
+    return os.getenv("VERSIONEER_OVERRIDE", default="8.0+unknown.beta")
    if override:
      return override
    srcroot = os.path.join(os.path.dirname(os.path.abspath(__file__)), os.pardir)
    with open(os.path.join(srcroot, "MAJOR_VERSION"), "r") as f:
        version = f.read().strip()
    version += ".unknown"
    if os.path.exists(os.path.join(srcroot, "BETA")):
        version += ".beta"
    return version
--- a/artiq/applets/big_number.py
+++ b/artiq/applets/big_number.py
@ -1,22 +1,96 @@
 #!/usr/bin/env python3
-from PyQt5 import QtWidgets
+from PyQt5 import QtWidgets, QtCore, QtGui
 from artiq.applets.simple import SimpleApplet
 from artiq.tools import scale_from_metadata
 from artiq.gui.tools import LayoutWidget
-class NumberWidget(QtWidgets.QLCDNumber):
+class QResponsiveLCDNumber(QtWidgets.QLCDNumber):
-    def __init__(self, args):
+    doubleClicked = QtCore.pyqtSignal()
-        QtWidgets.QLCDNumber.__init__(self)
+
-        self.setDigitCount(args.digit_count)
+    def mouseDoubleClickEvent(self, event):
        self.doubleClicked.emit()
 class QCancellableLineEdit(QtWidgets.QLineEdit):
    editCancelled = QtCore.pyqtSignal()
    def keyPressEvent(self, event):
        if event.key() == QtCore.Qt.Key_Escape:
            self.editCancelled.emit()
        else:
            super().keyPressEvent(event)
 class NumberWidget(LayoutWidget):
    def __init__(self, args, req):
        LayoutWidget.__init__(self)
        self.dataset_name = args.dataset
        self.req = req
        self.metadata = dict()
-    def data_changed(self, data, mods):
+        self.number_area = QtWidgets.QStackedWidget()
        self.addWidget(self.number_area, 0, 0)
        self.unit_area = QtWidgets.QLabel()
        self.unit_area.setAlignment(QtCore.Qt.AlignRight | QtCore.Qt.AlignTop)
        self.addWidget(self.unit_area, 0, 1)
        self.lcd_widget = QResponsiveLCDNumber()
        self.lcd_widget.setDigitCount(args.digit_count)
        self.lcd_widget.doubleClicked.connect(self.start_edit)
        self.number_area.addWidget(self.lcd_widget)
        self.edit_widget = QCancellableLineEdit()
        self.edit_widget.setValidator(QtGui.QDoubleValidator())
        self.edit_widget.setAlignment(QtCore.Qt.AlignRight | QtCore.Qt.AlignVCenter)
        self.edit_widget.editCancelled.connect(self.cancel_edit)
        self.edit_widget.returnPressed.connect(self.confirm_edit)
        self.number_area.addWidget(self.edit_widget)
        font = QtGui.QFont()
        font.setPointSize(60)
        self.edit_widget.setFont(font)
        unit_font = QtGui.QFont()
        unit_font.setPointSize(20)
        self.unit_area.setFont(unit_font)
        self.number_area.setCurrentWidget(self.lcd_widget)
    def start_edit(self):
        # QLCDNumber value property contains the value of zero
        # if the displayed value is not a number.
        self.edit_widget.setText(str(self.lcd_widget.value()))
        self.edit_widget.selectAll()
        self.edit_widget.setFocus()
        self.number_area.setCurrentWidget(self.edit_widget)
    def confirm_edit(self):
        scale = scale_from_metadata(self.metadata)
        val = float(self.edit_widget.text())
        val *= scale
        self.req.set_dataset(self.dataset_name, val, **self.metadata)
        self.number_area.setCurrentWidget(self.lcd_widget)
    def cancel_edit(self):
        self.number_area.setCurrentWidget(self.lcd_widget)
    def data_changed(self, value, metadata, persist, mods):
        try:
-            n = float(data[self.dataset_name][1])
+            self.metadata = metadata[self.dataset_name]
            # This applet will degenerate other scalar types to native float on edit
            # Use the dashboard ChangeEditDialog for consistent type casting 
            val = float(value[self.dataset_name])
            scale = scale_from_metadata(self.metadata)
            val /= scale
        except (KeyError, ValueError, TypeError):
-            n = "---"
+            val = "---"
-        self.display(n)
+        
        unit = self.metadata.get("unit", "")
        self.unit_area.setText(unit)
        self.lcd_widget.display(val)
 def main():
--- a/artiq/applets/image.py
+++ b/artiq/applets/image.py
@ -7,13 +7,13 @@ from artiq.applets.simple import SimpleApplet
 class Image(pyqtgraph.ImageView):
-    def __init__(self, args):
+    def __init__(self, args, req):
        pyqtgraph.ImageView.__init__(self)
        self.args = args
-    def data_changed(self, data, mods):
+    def data_changed(self, value, metadata, persist, mods):
        try:
-            img = data[self.args.img][1]
+            img = value[self.args.img]
        except KeyError:
            return
        self.setImage(img)
--- a/artiq/applets/plot_hist.py
+++ b/artiq/applets/plot_hist.py
@ -1,33 +1,47 @@
 #!/usr/bin/env python3
 import PyQt5    # make sure pyqtgraph imports Qt5
 from PyQt5.QtCore import QTimer
 import pyqtgraph
 from artiq.applets.simple import TitleApplet
 class HistogramPlot(pyqtgraph.PlotWidget):
-    def __init__(self, args):
+    def __init__(self, args, req):
        pyqtgraph.PlotWidget.__init__(self)
        self.args = args
        self.timer = QTimer()
        self.timer.setSingleShot(True)
        self.timer.timeout.connect(self.length_warning)
-    def data_changed(self, data, mods, title):
+    def data_changed(self, value, metadata, persist, mods, title):
        try:
-            y = data[self.args.y][1]
+            y = value[self.args.y]
            if self.args.x is None:
                x = None
            else:
-                x = data[self.args.x][1]
+                x = value[self.args.x]
        except KeyError:
            return
        if x is None:
            x = list(range(len(y)+1))
        if len(y) and len(x) == len(y) + 1:
            self.timer.stop()
            self.clear()
            self.plot(x, y, stepMode=True, fillLevel=0,
                      brush=(0, 0, 255, 150))
            self.setTitle(title)
        else:
            if not self.timer.isActive():
                self.timer.start(1000)
    def length_warning(self):
        self.clear()
        text = "⚠️ dataset lengths mismatch:\n"\
            "There should be one more bin boundaries than there are Y values"
        self.addItem(pyqtgraph.TextItem(text))
 def main():
--- a/artiq/applets/plot_xy.py
+++ b/artiq/applets/plot_xy.py
@ -2,38 +2,57 @@
 import numpy as np
 import PyQt5  # make sure pyqtgraph imports Qt5
 from PyQt5.QtCore import QTimer
 import pyqtgraph
 from artiq.applets.simple import TitleApplet
 class XYPlot(pyqtgraph.PlotWidget):
-    def __init__(self, args):
+    def __init__(self, args, req):
        pyqtgraph.PlotWidget.__init__(self)
        self.args = args
        self.timer = QTimer()
        self.timer.setSingleShot(True)
        self.timer.timeout.connect(self.length_warning)
        self.mismatch = {'X values': False,
                         'Error bars': False,
                         'Fit values': False}
-    def data_changed(self, data, mods, title):
+    def data_changed(self, value, metadata, persist, mods, title):
        try:
-            y = data[self.args.y][1]
+            y = value[self.args.y]
        except KeyError:
            return
-        x = data.get(self.args.x, (False, None))[1]
+        x = value.get(self.args.x, (False, None))
        if x is None:
            x = np.arange(len(y))
-        error = data.get(self.args.error, (False, None))[1]
+        error = value.get(self.args.error, (False, None))
-        fit = data.get(self.args.fit, (False, None))[1]
+        fit = value.get(self.args.fit, (False, None))
        if not len(y) or len(y) != len(x):
-            return
+            self.mismatch['X values'] = True
        else:
            self.mismatch['X values'] = False
        if error is not None and hasattr(error, "__len__"):
            if not len(error):
                error = None
            elif len(error) != len(y):
-                return
+                self.mismatch['Error bars'] = True
            else:
                self.mismatch['Error bars'] = False
        if fit is not None:
            if not len(fit):
                fit = None
            elif len(fit) != len(y):
                self.mismatch['Fit values'] = True
            else:
                self.mismatch['Fit values'] = False
        if not any(self.mismatch.values()):
            self.timer.stop()
        else:
            if not self.timer.isActive():
                self.timer.start(1000)
            return
        self.clear()
@ -50,6 +69,13 @@ class XYPlot(pyqtgraph.PlotWidget):
            xi = np.argsort(x)
            self.plot(x[xi], fit[xi])
    def length_warning(self):
        self.clear()
        text = "⚠️ dataset lengths mismatch:\n"
        errors = ', '.join([k for k, v in self.mismatch.items() if v])
        text = ' '.join([errors, "should have the same length as Y values"])
        self.addItem(pyqtgraph.TextItem(text))
 def main():
    applet = TitleApplet(XYPlot)
--- a/artiq/applets/plot_xy_hist.py
+++ b/artiq/applets/plot_xy_hist.py
@ -2,6 +2,7 @@
 import numpy as np
 from PyQt5 import QtWidgets
 from PyQt5.QtCore import QTimer
 import pyqtgraph
 from artiq.applets.simple import SimpleApplet
@ -21,7 +22,7 @@ def _compute_ys(histogram_bins, histograms_counts):
 # pyqtgraph.GraphicsWindow fails to behave like a regular Qt widget
 # and breaks embedding. Do not use as top widget.
 class XYHistPlot(QtWidgets.QSplitter):
-    def __init__(self, args):
+    def __init__(self, args, req):
        QtWidgets.QSplitter.__init__(self)
        self.resize(1000, 600)
        self.setWindowTitle("XY/Histogram")
@ -37,6 +38,10 @@ class XYHistPlot(QtWidgets.QSplitter):
        self.hist_plot_data = None
        self.args = args
        self.timer = QTimer()
        self.timer.setSingleShot(True)
        self.timer.timeout.connect(self.length_warning)
        self.mismatch = {'bins': False, 'xs': False}
    def _set_full_data(self, xs, histogram_bins, histograms_counts):
        self.xy_plot.clear()
@ -59,9 +64,9 @@ class XYHistPlot(QtWidgets.QSplitter):
            point.histogram_index = index
            point.histogram_counts = counts
-        self.hist_plot_data = self.hist_plot.plot(
+        text = "click on a data point at the left\n"\
-            stepMode=True, fillLevel=0,
+               "to see the corresponding histogram"
-            brush=(0, 0, 255, 150))
+        self.hist_plot.addItem(pyqtgraph.TextItem(text))
    def _set_partial_data(self, xs, histograms_counts):
        ys = _compute_ys(self.histogram_bins, histograms_counts)
@ -87,6 +92,15 @@ class XYHistPlot(QtWidgets.QSplitter):
        else:
            self.arrow.setPos(position)
        self.selected_index = spot_item.histogram_index
        if self.hist_plot_data is None:
            self.hist_plot.clear()
            self.hist_plot_data = self.hist_plot.plot(
                x=self.histogram_bins,
                y=spot_item.histogram_counts,
                stepMode=True, fillLevel=0,
                brush=(0, 0, 255, 150))
        else:
            self.hist_plot_data.setData(x=self.histogram_bins,
                                        y=spot_item.histogram_counts)
@ -110,18 +124,48 @@ class XYHistPlot(QtWidgets.QSplitter):
                return False
        return True
-    def data_changed(self, data, mods):
+    def data_changed(self, value, metadata, persist, mods):
        try:
-            xs = data[self.args.xs][1]
+            xs = value[self.args.xs]
-            histogram_bins = data[self.args.histogram_bins][1]
+            histogram_bins = value[self.args.histogram_bins]
-            histograms_counts = data[self.args.histograms_counts][1]
+            histograms_counts = value[self.args.histograms_counts]
        except KeyError:
            return
        if len(xs) != histograms_counts.shape[0]:
            self.mismatch['xs'] = True
        else:
            self.mismatch['xs'] = False
        if histograms_counts.shape[1] != len(histogram_bins) - 1:
            self.mismatch['bins'] = True
        else:
            self.mismatch['bins'] = False
        if any(self.mismatch.values()):
            if not self.timer.isActive():
                self.timer.start(1000)
            return
        else:
            self.timer.stop()
        if self._can_use_partial(mods):
            self._set_partial_data(xs, histograms_counts)
        else:
            self._set_full_data(xs, histogram_bins, histograms_counts)
    def length_warning(self):
        self.xy_plot.clear()
        self.hist_plot.clear()
        text = "⚠️ dataset lengths mismatch:\n\n"
        if self.mismatch['bins']:
            text = ''.join([text,
                            "bin boundaries should have the same length\n"
                            "as the first dimension of histogram counts."])
        if self.mismatch['bins'] and self.mismatch['xs']:
            text = ''.join([text, '\n\n'])
        if self.mismatch['xs']:
            text = ''.join([text,
                            "point abscissas should have the same length\n"
                            "as the second dimension of histogram counts."])
        self.xy_plot.addItem(pyqtgraph.TextItem(text))
 def main():
    applet = SimpleApplet(XYHistPlot)
--- a/artiq/applets/progress_bar.py
+++ b/artiq/applets/progress_bar.py
@ -0,0 +1,34 @@
 #!/usr/bin/env python3
 from PyQt5 import QtWidgets
 from artiq.applets.simple import SimpleApplet
 class ProgressWidget(QtWidgets.QProgressBar):
    def __init__(self, args, req):
        QtWidgets.QProgressBar.__init__(self)
        self.setMinimum(args.min)
        self.setMaximum(args.max)
        self.dataset_value = args.value
    def data_changed(self, value, metadata, persist, mods):
        try:
            val = round(value[self.dataset_value])
        except (KeyError, ValueError, TypeError):
            val = 0
        self.setValue(val)
 def main():
    applet = SimpleApplet(ProgressWidget)
    applet.add_dataset("value", "counter")
    applet.argparser.add_argument("--min", type=int, default=0,
                                  help="minimum (left) value of the bar")
    applet.argparser.add_argument("--max", type=int, default=100,
                                  help="maximum (right) value of the bar")
    applet.run()
 if __name__ == "__main__":
    main()
--- a/artiq/applets/simple.py
+++ b/artiq/applets/simple.py
@ -7,13 +7,112 @@ import string
 from qasync import QEventLoop, QtWidgets, QtCore
 from sipyco.sync_struct import Subscriber, process_mod
 from sipyco.pc_rpc import AsyncioClient as RPCClient
 from sipyco import pyon
 from sipyco.pipe_ipc import AsyncioChildComm
 from artiq.language.scan import ScanObject
 logger = logging.getLogger(__name__)
 class _AppletRequestInterface:
    def __init__(self):
        raise NotImplementedError
    def set_dataset(self, key, value, unit=None, scale=None, precision=None, persist=None):
        """
        Set a dataset.
        See documentation of ``artiq.language.environment.set_dataset``.
        """
        raise NotImplementedError
    def mutate_dataset(self, key, index, value):
        """
        Mutate a dataset.
        See documentation of ``artiq.language.environment.mutate_dataset``.
        """
        raise NotImplementedError
    def append_to_dataset(self, key, value):
        """
        Append to a dataset.
        See documentation of ``artiq.language.environment.append_to_dataset``.
        """
        raise NotImplementedError
    def set_argument_value(self, expurl, name, value):
        """
        Temporarily set the value of an argument in a experiment in the dashboard.
        The value resets to default value when recomputing the argument.
        :param expurl: Experiment URL identifying the experiment in the dashboard. Example: 'repo:ArgumentsDemo'.
        :param name: Name of the argument in the experiment.
        :param value: Object representing the new temporary value of the argument. For ``Scannable`` arguments, this parameter
            should be a ``ScanObject``. The type of the ``ScanObject`` will be set as the selected type when this function is called. 
        """
        raise NotImplementedError
 class AppletRequestIPC(_AppletRequestInterface):
    def __init__(self, ipc):
        self.ipc = ipc
    def set_dataset(self, key, value, unit=None, scale=None, precision=None, persist=None):
        metadata = {}
        if unit is not None:
            metadata["unit"] = unit
        if scale is not None:
            metadata["scale"] = scale
        if precision is not None:
            metadata["precision"] = precision
        self.ipc.set_dataset(key, value, metadata, persist)
    def mutate_dataset(self, key, index, value):
        mod = {"action": "setitem", "path": [key, 1], "key": index, "value": value}
        self.ipc.update_dataset(mod)
    def append_to_dataset(self, key, value):
        mod = {"action": "append", "path": [key, 1], "x": value}
        self.ipc.update_dataset(mod)
    def set_argument_value(self, expurl, name, value):
        if isinstance(value, ScanObject):
            value = value.describe()
        self.ipc.set_argument_value(expurl, name, value)
 class AppletRequestRPC(_AppletRequestInterface):
    def __init__(self, loop, dataset_ctl):
        self.loop = loop
        self.dataset_ctl = dataset_ctl
        self.background_tasks = set()
    def _background(self, coro, *args, **kwargs):
        task = self.loop.create_task(coro(*args, **kwargs))
        self.background_tasks.add(task)
        task.add_done_callback(self.background_tasks.discard)
    def set_dataset(self, key, value, unit=None, scale=None, precision=None, persist=None):
        metadata = {}
        if unit is not None:
            metadata["unit"] = unit
        if scale is not None:
            metadata["scale"] = scale
        if precision is not None:
            metadata["precision"] = precision
        self._background(self.dataset_ctl.set, key, value, metadata=metadata, persist=persist)
    def mutate_dataset(self, key, index, value):
        mod = {"action": "setitem", "path": [key, 1], "key": index, "value": value}
        self._background(self.dataset_ctl.update, mod)
    def append_to_dataset(self, key, value):
        mod = {"action": "append", "path": [key, 1], "x": value}
        self._background(self.dataset_ctl.update, mod)
 class AppletIPCClient(AsyncioChildComm):
    def set_close_cb(self, close_cb):
        self.close_cb = close_cb
@ -64,12 +163,30 @@ class AppletIPCClient(AsyncioChildComm):
                             exc_info=True)
                self.close_cb()
-    def subscribe(self, datasets, init_cb, mod_cb):
+    def subscribe(self, datasets, init_cb, mod_cb, dataset_prefixes=[], *, loop):
        self.write_pyon({"action": "subscribe",
-                         "datasets": datasets})
+                         "datasets": datasets,
                         "dataset_prefixes": dataset_prefixes})
        self.init_cb = init_cb
        self.mod_cb = mod_cb
-        asyncio.ensure_future(self.listen())
+        self.listen_task = loop.create_task(self.listen())
    def set_dataset(self, key, value, metadata, persist=None):
        self.write_pyon({"action": "set_dataset",
                         "key": key,
                         "value": value,
                         "metadata": metadata,
                         "persist": persist})
    def update_dataset(self, mod):
        self.write_pyon({"action": "update_dataset",
                         "mod": mod})
    def set_argument_value(self, expurl, name, value):
        self.write_pyon({"action": "set_argument_value",
                         "expurl": expurl,
                         "name": name,
                         "value": value})
 class SimpleApplet:
@ -91,8 +208,11 @@ class SimpleApplet:
                 "for dataset notifications "
                 "(ignored in embedded mode)")
        group.add_argument(
-            "--port", default=3250, type=int,
+            "--port-notify", default=3250, type=int,
-            help="TCP port to connect to")
+            help="TCP port to connect to for notifications (ignored in embedded mode)")
        group.add_argument(
            "--port-control", default=3251, type=int,
            help="TCP port to connect to for control (ignored in embedded mode)")
        self._arggroup_datasets = self.argparser.add_argument_group("datasets")
@ -113,6 +233,9 @@ class SimpleApplet:
        self.embed = os.getenv("ARTIQ_APPLET_EMBED")
        self.datasets = {getattr(self.args, arg.replace("-", "_"))
                         for arg in self.dataset_args}
        # Optional prefixes (dataset sub-trees) to match subscriptions against;
        # currently only used by out-of-tree subclasses (ndscan).
        self.dataset_prefixes = []
    def qasync_init(self):
        app = QtWidgets.QApplication([])
@ -128,8 +251,21 @@ class SimpleApplet:
        if self.embed is not None:
            self.ipc.close()
    def req_init(self):
        if self.embed is None:
            dataset_ctl = RPCClient()
            self.loop.run_until_complete(dataset_ctl.connect_rpc(
                self.args.server, self.args.port_control, "master_dataset_db"))
            self.req = AppletRequestRPC(self.loop, dataset_ctl)
        else:
            self.req = AppletRequestIPC(self.ipc)
    def req_close(self):
        if self.embed is None:
            self.req.dataset_ctl.close_rpc()
    def create_main_widget(self):
-        self.main_widget = self.main_widget_class(self.args)
+        self.main_widget = self.main_widget_class(self.args, self.req)
        if self.embed is not None:
            self.ipc.set_close_cb(self.main_widget.close)
            if os.name == "nt":
@ -162,6 +298,14 @@ class SimpleApplet:
        self.data = data
        return data
    def is_dataset_subscribed(self, key):
        if key in self.datasets:
            return True
        for prefix in self.dataset_prefixes:
            if key.startswith(prefix):
                return True
        return False
    def filter_mod(self, mod):
        if self.embed is not None:
            # the parent already filters for us
@ -170,14 +314,19 @@ class SimpleApplet:
        if mod["action"] == "init":
            return True
        if mod["path"]:
-            return mod["path"][0] in self.datasets
+            return self.is_dataset_subscribed(mod["path"][0])
        elif mod["action"] in {"setitem", "delitem"}:
-            return mod["key"] in self.datasets
+            return self.is_dataset_subscribed(mod["key"])
        else:
            return False
    def emit_data_changed(self, data, mod_buffer):
-        self.main_widget.data_changed(data, mod_buffer)
+        persist = dict()
        value = dict()
        metadata = dict()
        for k, d in data.items():
            persist[k], value[k], metadata[k] = d
        self.main_widget.data_changed(value, metadata, persist, mod_buffer)
    def flush_mod_buffer(self):
        self.emit_data_changed(self.data, self.mod_buffer)
@ -192,7 +341,7 @@ class SimpleApplet:
                self.mod_buffer.append(mod)
            else:
                self.mod_buffer = [mod]
-                asyncio.get_event_loop().call_later(self.args.update_delay,
+                self.loop.call_later(self.args.update_delay,
                                     self.flush_mod_buffer)
        else:
            self.emit_data_changed(self.data, [mod])
@ -202,9 +351,11 @@ class SimpleApplet:
            self.subscriber = Subscriber("datasets",
                                         self.sub_init, self.sub_mod)
            self.loop.run_until_complete(self.subscriber.connect(
-                self.args.server, self.args.port))
+                self.args.server, self.args.port_notify))
        else:
-            self.ipc.subscribe(self.datasets, self.sub_init, self.sub_mod)
+            self.ipc.subscribe(self.datasets, self.sub_init, self.sub_mod,
                               dataset_prefixes=self.dataset_prefixes,
                               loop=self.loop)
    def unsubscribe(self):
        if self.embed is None:
@ -215,6 +366,8 @@ class SimpleApplet:
        self.qasync_init()
        try:
            self.ipc_init()
            try:
                self.req_init()
                try:
                    self.create_main_widget()
                    self.subscribe()
@ -222,6 +375,8 @@ class SimpleApplet:
                        self.loop.run_forever()
                    finally:
                        self.unsubscribe()
                finally:
                    self.req_close()
            finally:
                self.ipc_close()
        finally:
@ -260,4 +415,9 @@ class TitleApplet(SimpleApplet):
                title = self.args.title
        else:
            title = None
-        self.main_widget.data_changed(data, mod_buffer, title)
+        persist = dict()
        value = dict()
        metadata = dict()
        for k, d in data.items():
            persist[k], value[k], metadata[k] = d
        self.main_widget.data_changed(value, metadata, persist, mod_buffer, title)
--- a/artiq/browser/datasets.py
+++ b/artiq/browser/datasets.py
@ -20,11 +20,46 @@ class Model(DictSyncTreeSepModel):
        DictSyncTreeSepModel.__init__(self, ".", ["Dataset", "Value"], init)
    def convert(self, k, v, column):
-        return short_format(v[1])
+        return short_format(v[1], v[2])
 class DatasetCtl:
    def __init__(self, master_host, master_port):
        self.master_host = master_host
        self.master_port = master_port
    async def _execute_rpc(self, op_name, key_or_mod, value=None, persist=None, metadata=None):
        logger.info("Starting %s operation on %s", op_name, key_or_mod)
        try:
            remote = RPCClient()
            await remote.connect_rpc(self.master_host, self.master_port,
                                     "master_dataset_db")
            try:
                if op_name == "set":
                    await remote.set(key_or_mod, value, persist, metadata)
                elif op_name == "update":
                    await remote.update(key_or_mod)
                else:
                    logger.error("Invalid operation: %s", op_name)
                    return
            finally:
                remote.close_rpc()
        except:
            logger.error("Failed %s operation on %s", op_name,
                        key_or_mod, exc_info=True)
        else:
            logger.info("Finished %s operation on %s", op_name,
                     key_or_mod)
    async def set(self, key, value, persist=None, metadata=None):
        await self._execute_rpc("set", key, value, persist, metadata)
    async def update(self, mod):
        await self._execute_rpc("update", mod)
 class DatasetsDock(QtWidgets.QDockWidget):
-    def __init__(self, datasets_sub, master_host, master_port):
+    def __init__(self, dataset_sub, dataset_ctl):
        QtWidgets.QDockWidget.__init__(self, "Datasets")
        self.setObjectName("Datasets")
        self.setFeatures(QtWidgets.QDockWidget.DockWidgetMovable |
@ -62,10 +97,9 @@ class DatasetsDock(QtWidgets.QDockWidget):
        self.table.addAction(upload_action)
        self.set_model(Model(dict()))
-        datasets_sub.add_setmodel_callback(self.set_model)
+        dataset_sub.add_setmodel_callback(self.set_model)
-        self.master_host = master_host
+        self.dataset_ctl = dataset_ctl
        self.master_port = master_port
    def _search_datasets(self):
        if hasattr(self, "table_model_filter"):
@ -82,30 +116,14 @@ class DatasetsDock(QtWidgets.QDockWidget):
        self.table_model_filter.setSourceModel(self.table_model)
        self.table.setModel(self.table_model_filter)
    async def _upload_dataset(self, name, value,):
        logger.info("Uploading dataset '%s' to master...", name)
        try:
            remote = RPCClient()
            await remote.connect_rpc(self.master_host, self.master_port,
                                     "master_dataset_db")
            try:
                await remote.set(name, value)
            finally:
                remote.close_rpc()
        except:
            logger.error("Failed uploading dataset '%s'",
                         name, exc_info=True)
        else:
            logger.info("Finished uploading dataset '%s'", name)
    def upload_clicked(self):
        idx = self.table.selectedIndexes()
        if idx:
            idx = self.table_model_filter.mapToSource(idx[0])
            key = self.table_model.index_to_key(idx)
            if key is not None:
-                persist, value = self.table_model.backing_store[key]
+                persist, value, metadata = self.table_model.backing_store[key]
-                asyncio.ensure_future(self._upload_dataset(key, value))
+                asyncio.ensure_future(self.dataset_ctl.set(key, value, metadata=metadata))
    def save_state(self):
        return bytes(self.table.header().saveState())
--- a/artiq/browser/experiments.py
+++ b/artiq/browser/experiments.py
@ -10,22 +10,14 @@ import h5py
 from sipyco import pyon
 from artiq import __artiq_dir__ as artiq_dir
-from artiq.gui.tools import LayoutWidget, log_level_to_name, get_open_file_name
+from artiq.gui.tools import (LayoutWidget, WheelFilter, 
                             log_level_to_name, get_open_file_name)
 from artiq.gui.entries import procdesc_to_entry
 from artiq.master.worker import Worker, log_worker_exception
 logger = logging.getLogger(__name__)
 class _WheelFilter(QtCore.QObject):
    def eventFilter(self, obj, event):
        if (event.type() == QtCore.QEvent.Wheel and
                event.modifiers() != QtCore.Qt.NoModifier):
            event.ignore()
            return True
        return False
 class _ArgumentEditor(QtWidgets.QTreeWidget):
    def __init__(self, dock):
        QtWidgets.QTreeWidget.__init__(self)
@ -46,7 +38,7 @@ class _ArgumentEditor(QtWidgets.QTreeWidget):
        self.setStyleSheet("QTreeWidget {background: " +
                           self.palette().midlight().color().name() + " ;}")
-        self.viewport().installEventFilter(_WheelFilter(self.viewport()))
+        self.viewport().installEventFilter(WheelFilter(self.viewport(), True))
        self._groups = dict()
        self._arg_to_widgets = dict()
@ -378,9 +370,9 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
 class LocalDatasetDB:
-    def __init__(self, datasets_sub):
+    def __init__(self, dataset_sub):
-        self.datasets_sub = datasets_sub
+        self.dataset_sub = dataset_sub
-        datasets_sub.add_setmodel_callback(self.init)
+        dataset_sub.add_setmodel_callback(self.init)
    def init(self, data):
        self._data = data
@ -389,11 +381,11 @@ class LocalDatasetDB:
        return self._data.backing_store[key][1]
    def update(self, mod):
-        self.datasets_sub.update(mod)
+        self.dataset_sub.update(mod)
 class ExperimentsArea(QtWidgets.QMdiArea):
-    def __init__(self, root, datasets_sub):
+    def __init__(self, root, dataset_sub):
        QtWidgets.QMdiArea.__init__(self)
        self.pixmap = QtGui.QPixmap(os.path.join(
            artiq_dir, "gui", "logo_ver.svg"))
@ -402,11 +394,11 @@ class ExperimentsArea(QtWidgets.QMdiArea):
        self.open_experiments = []
-        self._ddb = LocalDatasetDB(datasets_sub)
+        self._ddb = LocalDatasetDB(dataset_sub)
        self.worker_handlers = {
            "get_device_db": lambda: {},
-            "get_device": lambda k: {"type": "dummy"},
+            "get_device": lambda key, resolve_alias=False: {"type": "dummy"},
            "get_dataset": self._ddb.get,
            "update_dataset": self._ddb.update,
        }
@ -516,5 +508,9 @@ class ExperimentsArea(QtWidgets.QMdiArea):
        self.open_experiments.append(dock)
        return dock
    def set_argument_value(self, expurl, name, value):
        logger.warning("Unable to set argument '%s', dropping change. "
                       "'set_argument_value' not supported in browser.", name)
    def on_dock_closed(self, dock):
        self.open_experiments.remove(dock)
--- a/artiq/browser/files.py
+++ b/artiq/browser/files.py
@ -71,7 +71,7 @@ class ZoomIconView(QtWidgets.QListView):
        self._char_width = QtGui.QFontMetrics(self.font()).averageCharWidth()
        self.setViewMode(self.IconMode)
        w = self._char_width*self.default_size
-        self.setIconSize(QtCore.QSize(w, w*self.aspect))
+        self.setIconSize(QtCore.QSize(w, int(w*self.aspect)))
        self.setFlow(self.LeftToRight)
        self.setResizeMode(self.Adjust)
        self.setWrapping(True)
@ -102,13 +102,14 @@ class Hdf5FileSystemModel(QtWidgets.QFileSystemModel):
            h5 = open_h5(info)
            if h5 is not None:
                try:
-                    expid = pyon.decode(h5["expid"][()])
+                    expid = pyon.decode(h5["expid"][()]) if "expid" in h5 else dict()
-                    start_time = datetime.fromtimestamp(h5["start_time"][()])
+                    start_time = datetime.fromtimestamp(h5["start_time"][()]) if "start_time" in h5 else "<none>"
                    v = ("artiq_version: {}\nrepo_rev: {}\nfile: {}\n"
                         "class_name: {}\nrid: {}\nstart_time: {}").format(
-                             h5["artiq_version"][()], expid["repo_rev"],
+                             h5["artiq_version"].asstr()[()] if "artiq_version" in h5 else "<none>",
-                             expid["file"], expid["class_name"],
+                             expid.get("repo_rev", "<none>"),
-                             h5["rid"][()], start_time)
+                             expid.get("file", "<none>"), expid.get("class_name", "<none>"),
                             h5["rid"][()] if "rid" in h5 else "<none>", start_time)
                    return v
                except:
                    logger.warning("unable to read metadata from %s",
@ -174,31 +175,45 @@ class FilesDock(QtWidgets.QDockWidget):
        logger.debug("loading datasets from %s", info.filePath())
        with f:
            try:
-                expid = pyon.decode(f["expid"][()])
+                expid = pyon.decode(f["expid"][()]) if "expid" in f else dict()
-                start_time = datetime.fromtimestamp(f["start_time"][()])
+                start_time = datetime.fromtimestamp(f["start_time"][()]) if "start_time" in f else "<none>"
                v = {
-                    "artiq_version": f["artiq_version"][()],
+                    "artiq_version": f["artiq_version"].asstr()[()] if "artiq_version" in f else "<none>",
-                    "repo_rev": expid["repo_rev"],
+                    "repo_rev": expid.get("repo_rev", "<none>"),
-                    "file": expid["file"],
+                    "file": expid.get("file", "<none>"),
-                    "class_name": expid["class_name"],
+                    "class_name": expid.get("class_name", "<none>"),
-                    "rid": f["rid"][()],
+                    "rid": f["rid"][()] if "rid" in f else "<none>",
                    "start_time": start_time,
                }
                self.metadata_changed.emit(v)
            except:
                logger.warning("unable to read metadata from %s",
                               info.filePath(), exc_info=True)
-            rd = dict()
+
            rd = {}
            if "archive" in f:
-                rd = {k: (True, v[()]) for k, v in f["archive"].items()}
+                def visitor(k, v):
                    if isinstance(v, h5py.Dataset):
                        # v.attrs is a non-serializable h5py.AttributeManager, need to convert to dict
                        # See https://docs.h5py.org/en/stable/high/attr.html#h5py.AttributeManager
                        rd[k] = (True, v[()], dict(v.attrs))
                f["archive"].visititems(visitor)
            if "datasets" in f:
-                for k, v in f["datasets"].items():
+                def visitor(k, v):
                    if isinstance(v, h5py.Dataset):
                        if k in rd:
-                        logger.warning("dataset '%s' is both in archive and "
+                            logger.warning("dataset '%s' is both in archive "
-                                       "outputs", k)
+                                           "and outputs", k)
-                    rd[k] = (True, v[()])
+                        # v.attrs is a non-serializable h5py.AttributeManager, need to convert to dict
-            if rd:
+                        # See https://docs.h5py.org/en/stable/high/attr.html#h5py.AttributeManager
                        rd[k] = (True, v[()], dict(v.attrs))
                f["datasets"].visititems(visitor)
            self.datasets.init(rd)
        self.dataset_changed.emit(info.filePath())
    def list_activated(self, idx):
--- a/artiq/build_soc.py
+++ b/artiq/build_soc.py
@ -2,6 +2,7 @@ import os
 import subprocess
 from migen import *
 from migen.build.platforms.sinara import kasli
 from misoc.interconnect.csr import *
 from misoc.integration.builder import *
@ -57,14 +58,19 @@ def build_artiq_soc(soc, argdict):
    builder = Builder(soc, **argdict)
    builder.software_packages = []
    builder.add_software_package("bootloader", os.path.join(firmware_dir, "bootloader"))
-    if isinstance(soc, AMPSoC):
+    is_kasli_v1 = isinstance(soc.platform, kasli.Platform) and soc.platform.hw_rev in ("v1.0", "v1.1")
-        builder.add_software_package("libm")
+    kernel_cpu_type = "vexriscv" if is_kasli_v1 else "vexriscv-g"
-        builder.add_software_package("libprintf")
+    builder.add_software_package("libm", cpu_type=kernel_cpu_type)
    builder.add_software_package("libprintf", cpu_type=kernel_cpu_type)
    builder.add_software_package("libunwind", cpu_type=kernel_cpu_type)
    builder.add_software_package("ksupport", os.path.join(firmware_dir, "ksupport"), cpu_type=kernel_cpu_type)
    # Generate unwinder for soft float target (ARTIQ runtime)
    # If the kernel lacks FPU, then the runtime unwinder is already generated
    if not is_kasli_v1:
        builder.add_software_package("libunwind")
-        builder.add_software_package("ksupport", os.path.join(firmware_dir, "ksupport"))
+    if not soc.config["DRTIO_ROLE"] == "satellite":
        builder.add_software_package("runtime", os.path.join(firmware_dir, "runtime"))
    else:
        # Assume DRTIO satellite.
        builder.add_software_package("satman", os.path.join(firmware_dir, "satman"))
    try:
        builder.build()
--- a/artiq/compiler/asttyped.py
+++ b/artiq/compiler/asttyped.py
@ -21,13 +21,19 @@ class scoped(object):
        set of variables resolved as globals
    """
 class remote(object):
    """
    :ivar remote_fn: (bool) whether function is ran on a remote device,
        meaning arguments are received remotely and return is sent remotely
    """
 # Typed versions of untyped nodes
 class argT(ast.arg, commontyped):
    pass
 class ClassDefT(ast.ClassDef):
    _types = ("constructor_type",)
-class FunctionDefT(ast.FunctionDef, scoped):
+class FunctionDefT(ast.FunctionDef, scoped, remote):
    _types = ("signature_type",)
 class QuotedFunctionDefT(FunctionDefT):
    """
@ -58,7 +64,7 @@ class BinOpT(ast.BinOp, commontyped):
    pass
 class BoolOpT(ast.BoolOp, commontyped):
    pass
-class CallT(ast.Call, commontyped):
+class CallT(ast.Call, commontyped, remote):
    """
    :ivar iodelay: (:class:`iodelay.Expr`)
    :ivar arg_exprs: (dict of str to :class:`iodelay.Expr`)
--- a/artiq/compiler/builtins.py
+++ b/artiq/compiler/builtins.py
@ -38,6 +38,9 @@ class TInt(types.TMono):
    def one():
        return 1
 def TInt8():
    return TInt(types.TValue(8))
 def TInt32():
    return TInt(types.TValue(32))
@ -123,18 +126,23 @@ class TException(types.TMono):
    #  * File, line and column where it was raised (str, int, int).
    #  * Message, which can contain substitutions {0}, {1} and {2} (str).
    #  * Three 64-bit integers, parameterizing the message (numpy.int64).
    # These attributes are prefixed with `#` so that users cannot access them,
    # and we don't have to do string allocation in the runtime.
    # #__name__ is now a string key in the host. TStr may not be an actual
    # CSlice in the runtime, they might be a CSlice with length = i32::MAX and
    # ptr = string key in the host.
    # Keep this in sync with the function ARTIQIRGenerator.alloc_exn.
    attributes = OrderedDict([
-        ("__name__",    TStr()),
+        ("#__name__",    TInt32()),
-        ("__file__",    TStr()),
+        ("#__file__",    TStr()),
-        ("__line__",    TInt32()),
+        ("#__line__",    TInt32()),
-        ("__col__",     TInt32()),
+        ("#__col__",     TInt32()),
-        ("__func__",    TStr()),
+        ("#__func__",    TStr()),
-        ("__message__", TStr()),
+        ("#__message__", TStr()),
-        ("__param0__",  TInt64()),
+        ("#__param0__",  TInt64()),
-        ("__param1__",  TInt64()),
+        ("#__param1__",  TInt64()),
-        ("__param2__",  TInt64()),
+        ("#__param2__",  TInt64()),
    ])
    def __init__(self, name="Exception", id=0):
@ -169,7 +177,9 @@ def fn_list():
    return types.TConstructor(TList())
 def fn_array():
-    return types.TConstructor(TArray())
+    # numpy.array() is actually a "magic" macro that is expanded in-place, but
    # just as for builtin functions, we do not want to quote it, etc.
    return types.TBuiltinFunction("array")
 def fn_Exception():
    return types.TExceptionConstructor(TException("Exception"))
@ -237,6 +247,12 @@ def fn_at_mu():
 def fn_rtio_log():
    return types.TBuiltinFunction("rtio_log")
 def fn_subkernel_await():
    return types.TBuiltinFunction("subkernel_await")
 def fn_subkernel_preload():
    return types.TBuiltinFunction("subkernel_preload")
 # Accessors
 def is_none(typ):
@ -315,8 +331,11 @@ def is_iterable(typ):
    return is_listish(typ) or is_range(typ)
 def get_iterable_elt(typ):
    # TODO: Arrays count as listish, but this returns the innermost element type for
    # n-dimensional arrays, rather than the n-1 dimensional result of iterating over
    # the first axis, which makes the name a bit misleading.
    if is_str(typ) or is_bytes(typ) or is_bytearray(typ):
-        return TInt(types.TValue(8))
+        return TInt8()
    elif types._is_pointer(typ) or is_iterable(typ):
        return typ.find()["elt"].find()
    else:
@ -332,5 +351,5 @@ def is_allocated(typ):
                  is_float(typ) or is_range(typ) or
                  types._is_pointer(typ) or types.is_function(typ) or
                  types.is_external_function(typ) or types.is_rpc(typ) or
-                  types.is_method(typ) or types.is_tuple(typ) or
+                  types.is_subkernel(typ) or types.is_method(typ) or
-                  types.is_value(typ))
+                  types.is_tuple(typ) or types.is_value(typ))
--- a/artiq/compiler/embedding.py
+++ b/artiq/compiler/embedding.py
@ -5,7 +5,8 @@ the references to the host objects and translates the functions
 annotated as ``@kernel`` when they are referenced.
 """
-import sys, os, re, linecache, inspect, textwrap, types as pytypes, numpy
+import typing
 import os, re, linecache, inspect, textwrap, types as pytypes, numpy
 from collections import OrderedDict, defaultdict
 from pythonparser import ast, algorithm, source, diagnostic, parse_buffer
@ -18,6 +19,13 @@ from . import types, builtins, asttyped, math_fns, prelude
 from .transforms import ASTTypedRewriter, Inferencer, IntMonomorphizer, TypedtreePrinter
 from .transforms.asttyped_rewriter import LocalExtractor
 try:
    # From numpy=1.25.0 dispatching for `__array_function__` is done via
    # a C wrapper: https://github.com/numpy/numpy/pull/23020
    from numpy.core._multiarray_umath import _ArrayFunctionDispatcher
 except ImportError:
    _ArrayFunctionDispatcher = None    
 class SpecializedFunction:
    def __init__(self, instance_type, host_function):
@ -45,8 +53,48 @@ class EmbeddingMap:
        self.object_forward_map = {}
        self.object_reverse_map = {}
        self.module_map = {}
        # type_map connects the host Python `type` to the pair of associated
        # `(TInstance, TConstructor)`s. The `used_…_names` sets cache the
        # respective `.name`s for O(1) collision avoidance.
        self.type_map = {}
        self.used_instance_type_names = set()
        self.used_constructor_type_names = set()
        self.function_map = {}
        self.str_forward_map = {}
        self.str_reverse_map = {}
        self.preallocate_runtime_exception_names(["RuntimeError",
                                                  "RTIOUnderflow",
                                                  "RTIOOverflow",
                                                  "RTIODestinationUnreachable",
                                                  "DMAError",
                                                  "I2CError",
                                                  "CacheError",
                                                  "SPIError",
                                                  "0:ZeroDivisionError",
                                                  "0:IndexError",
                                                  "UnwrapNoneError",
                                                  "SubkernelError"])
    def preallocate_runtime_exception_names(self, names):
        for i, name in enumerate(names):
            if ":" not in name:
                name = "0:artiq.coredevice.exceptions." + name
            exn_id = self.store_str(name)
            assert exn_id == i
    def store_str(self, s):
        if s in self.str_forward_map:
            return self.str_forward_map[s]
        str_id = len(self.str_forward_map)
        self.str_forward_map[s] = str_id
        self.str_reverse_map[str_id] = s
        return str_id
    def retrieve_str(self, str_id):
        return self.str_reverse_map[str_id]
    # Modules
    def store_module(self, module, module_type):
@ -60,16 +108,6 @@ class EmbeddingMap:
    # Types
    def store_type(self, host_type, instance_type, constructor_type):
        self._rename_type(instance_type)
        self.type_map[host_type] = (instance_type, constructor_type)
    def retrieve_type(self, host_type):
        return self.type_map[host_type]
    def has_type(self, host_type):
        return host_type in self.type_map
    def _rename_type(self, new_instance_type):
        # Generally, user-defined types that have exact same name (which is to say, classes
        # defined inside functions) do not pose a problem to the compiler. The two places which
        # cannot handle this are:
@ -78,12 +116,29 @@ class EmbeddingMap:
        # Since handling #2 requires renaming on ARTIQ side anyway, it's more straightforward
        # to do it once when embedding (since non-embedded code cannot define classes in
        # functions). Also, easier to debug.
-        n = 0
+        suffix = 0
-        for host_type in self.type_map:
+        new_instance_name = instance_type.name
-            instance_type, constructor_type = self.type_map[host_type]
+        new_constructor_name = constructor_type.name
-            if instance_type.name == new_instance_type.name:
+        while True:
-                n += 1
+            if (new_instance_name not in self.used_instance_type_names
-                new_instance_type.name = "{}.{}".format(new_instance_type.name, n)
+                    and new_constructor_name not in self.used_constructor_type_names):
                break
            suffix += 1
            new_instance_name = f"{instance_type.name}.{suffix}"
            new_constructor_name = f"{constructor_type.name}.{suffix}"
        self.used_instance_type_names.add(new_instance_name)
        instance_type.name = new_instance_name
        self.used_constructor_type_names.add(new_constructor_name)
        constructor_type.name = new_constructor_name
        self.type_map[host_type] = (instance_type, constructor_type)
    def retrieve_type(self, host_type):
        return self.type_map[host_type]
    def has_type(self, host_type):
        return host_type in self.type_map
    def attribute_count(self):
        count = 0
@ -130,7 +185,22 @@ class EmbeddingMap:
                obj_typ, _ = self.type_map[type(obj_ref)]
            yield obj_id, obj_ref, obj_typ
    def subkernels(self):
        subkernels = {}
        for k, v in self.object_forward_map.items():
            if hasattr(v, "artiq_embedded"):
                if v.artiq_embedded.destination is not None:
                    subkernels[k] = v
        return subkernels
    def has_rpc(self):
        return any(filter(
                lambda x: (inspect.isfunction(x) or inspect.ismethod(x)) and \
                    (not hasattr(x, "artiq_embedded") or x.artiq_embedded.destination is None),
                self.object_forward_map.values()
            ))
    def has_rpc_or_subkernel(self):
        return any(filter(lambda x: inspect.isfunction(x) or inspect.ismethod(x),
                          self.object_forward_map.values()))
@ -138,6 +208,7 @@ class EmbeddingMap:
 class ASTSynthesizer:
    def __init__(self, embedding_map, value_map, quote_function=None, expanded_from=None):
        self.source = ""
        self.source_last_new_line = 0
        self.source_buffer = source.Buffer(self.source, "<synthesized>")
        self.embedding_map = embedding_map
        self.value_map = value_map
@ -156,20 +227,90 @@ class ASTSynthesizer:
        return source.Range(self.source_buffer, range_from, range_to,
                            expanded_from=self.expanded_from)
    def _add_iterable(self, fragment):
        # Since DILocation points on the beginning of the piece of source
        # we don't care if the fragment's end will overflow LLVM's limit.
        if len(self.source) - self.source_last_new_line >= 2**16:
            fragment = "\\\n" + fragment
            self.source_last_new_line = len(self.source) + 2
        return self._add(fragment)
    def fast_quote_list(self, value):
        elts = [None] * len(value)
        is_T = False
        if len(value) > 0:
            v = value[0]
            is_T = True
            if isinstance(v, int):
                T = int
            elif isinstance(v, float):
                T = float
            elif isinstance(v, numpy.int32):
                T = numpy.int32
            elif isinstance(v, numpy.int64):
                T = numpy.int64
            else:
                is_T = False
            if is_T:
                for v in value:
                    if not isinstance(v, T):
                        is_T = False
                        break
        if is_T:
            is_int = T != float
            if T == int:
                typ = builtins.TInt()
            elif T == float:
                typ = builtins.TFloat()
            elif T == numpy.int32:
                typ = builtins.TInt32()
            elif T == numpy.int64:
                typ = builtins.TInt64()
            else:
                assert False
            text = [repr(elt) for elt in value]
            start = len(self.source)
            self.source += ", ".join(text)
            if is_int:
                for i, (v, t) in enumerate(zip(value, text)):
                    l = len(t)
                    elts[i] = asttyped.NumT(
                        n=int(v), ctx=None, type=typ,
                        loc=source.Range(
                            self.source_buffer, start, start + l,
                            expanded_from=self.expanded_from))
                    start += l + 2
            else:
                for i, (v, t) in enumerate(zip(value, text)):
                    l = len(t)
                    elts[i] = asttyped.NumT(
                        n=v, ctx=None, type=typ,
                        loc=source.Range(
                            self.source_buffer, start, start + l,
                            expanded_from=self.expanded_from))
                    start += l + 2
        else:
            for index, elt in enumerate(value):
                elts[index] = self.quote(elt)
                if index < len(value) - 1:
                    self._add_iterable(", ")
        return elts
    def quote(self, value):
        """Construct an AST fragment equal to `value`."""
        if value is None:
            typ = builtins.TNone()
            return asttyped.NameConstantT(value=value, type=typ,
                                          loc=self._add(repr(value)))
-        elif value is True or value is False:
+        elif isinstance(value, (bool, numpy.bool_)):
            typ = builtins.TBool()
-            return asttyped.NameConstantT(value=value, type=typ,
+            coerced = bool(value)
-                                          loc=self._add(repr(value)))
+            return asttyped.NameConstantT(value=coerced, type=typ,
-        elif value is numpy.float:
+                                          loc=self._add(repr(coerced)))
        elif value is float:
            typ = builtins.fn_float()
            return asttyped.NameConstantT(value=None, type=typ,
-                                          loc=self._add("numpy.float"))
+                                          loc=self._add("float"))
        elif value is numpy.int32:
            typ = builtins.fn_int32()
            return asttyped.NameConstantT(value=None, type=typ,
@ -203,35 +344,28 @@ class ASTSynthesizer:
                                 loc=self._add(repr(value)))
        elif isinstance(value, str):
            return asttyped.StrT(s=value, ctx=None, type=builtins.TStr(),
-                                 loc=self._add(repr(value)))
+                                 loc=self._add_iterable(repr(value)))
        elif isinstance(value, bytes):
            return asttyped.StrT(s=value, ctx=None, type=builtins.TBytes(),
-                                 loc=self._add(repr(value)))
+                                 loc=self._add_iterable(repr(value)))
        elif isinstance(value, bytearray):
-            quote_loc   = self._add('`')
+            quote_loc   = self._add_iterable('`')
-            repr_loc    = self._add(repr(value))
+            repr_loc    = self._add_iterable(repr(value))
-            unquote_loc = self._add('`')
+            unquote_loc = self._add_iterable('`')
            loc         = quote_loc.join(unquote_loc)
            return asttyped.QuoteT(value=value, type=builtins.TByteArray(), loc=loc)
        elif isinstance(value, list):
-            begin_loc = self._add("[")
+            begin_loc = self._add_iterable("[")
-            elts = []
+            elts = self.fast_quote_list(value)
-            for index, elt in enumerate(value):
+            end_loc   = self._add_iterable("]")
                elts.append(self.quote(elt))
                if index < len(value) - 1:
                    self._add(", ")
            end_loc   = self._add("]")
            return asttyped.ListT(elts=elts, ctx=None, type=builtins.TList(),
                                  begin_loc=begin_loc, end_loc=end_loc,
                                  loc=begin_loc.join(end_loc))
        elif isinstance(value, tuple):
-            begin_loc = self._add("(")
+            begin_loc = self._add_iterable("(")
-            elts = []
+            elts = self.fast_quote_list(value)
-            for index, elt in enumerate(value):
+            end_loc   = self._add_iterable(")")
                elts.append(self.quote(elt))
                self._add(", ")
            end_loc   = self._add(")")
            return asttyped.TupleT(elts=elts, ctx=None,
                                   type=types.TTuple([e.type for e in elts]),
                                   begin_loc=begin_loc, end_loc=end_loc,
@ -241,7 +375,9 @@ class ASTSynthesizer:
        elif inspect.isfunction(value) or inspect.ismethod(value) or \
                isinstance(value, pytypes.BuiltinFunctionType) or \
                isinstance(value, SpecializedFunction) or \
-                isinstance(value, numpy.ufunc):
+                isinstance(value, numpy.ufunc) or \
                (isinstance(value, _ArrayFunctionDispatcher) if 
                            _ArrayFunctionDispatcher is not None else False):
            if inspect.ismethod(value):
                quoted_self   = self.quote(value.__self__)
                function_type = self.quote_function(value.__func__, self.expanded_from)
@ -350,7 +486,7 @@ class ASTSynthesizer:
                return asttyped.QuoteT(value=value, type=instance_type,
                                       loc=loc)
-    def call(self, callee, args, kwargs, callback=None):
+    def call(self, callee, args, kwargs, callback=None, remote_fn=False):
        """
        Construct an AST fragment calling a function specified by
        an AST node `function_node`, with given arguments.
@ -394,7 +530,7 @@ class ASTSynthesizer:
            starargs=None, kwargs=None,
            type=types.TVar(), iodelay=None, arg_exprs={},
            begin_loc=begin_loc, end_loc=end_loc, star_loc=None, dstar_loc=None,
-            loc=callee_node.loc.join(end_loc))
+            loc=callee_node.loc.join(end_loc), remote_fn=remote_fn)
        if callback is not None:
            node = asttyped.CallT(
@ -429,7 +565,7 @@ class StitchingASTTypedRewriter(ASTTypedRewriter):
                             arg=node.arg, annotation=None,
                             arg_loc=node.arg_loc, colon_loc=node.colon_loc, loc=node.loc)
-    def visit_quoted_function(self, node, function):
+    def visit_quoted_function(self, node, function, remote_fn):
        extractor = LocalExtractor(env_stack=self.env_stack, engine=self.engine)
        extractor.visit(node)
@ -446,11 +582,11 @@ class StitchingASTTypedRewriter(ASTTypedRewriter):
        node = asttyped.QuotedFunctionDefT(
            typing_env=extractor.typing_env, globals_in_scope=extractor.global_,
            signature_type=types.TVar(), return_type=types.TVar(),
-            name=node.name, args=node.args, returns=node.returns,
+            name=node.name, args=node.args, returns=None,
            body=node.body, decorator_list=node.decorator_list,
            keyword_loc=node.keyword_loc, name_loc=node.name_loc,
            arrow_loc=node.arrow_loc, colon_loc=node.colon_loc, at_locs=node.at_locs,
-            loc=node.loc)
+            loc=node.loc, remote_fn=remote_fn)
        try:
            self.env_stack.append(node.typing_env)
@ -522,7 +658,7 @@ class StitchingInferencer(Inferencer):
            self.engine.process(diag)
            return
-        # Figure out what ARTIQ type does the value of the attribute have.
+        # Figure out the ARTIQ type of the value of the attribute.
        # We do this by quoting it, as if to serialize. This has some
        # overhead (i.e. synthesizing a source buffer), but has the advantage
        # of having the host-to-ARTIQ mapping code in only one place and
@ -658,7 +794,7 @@ class TypedtreeHasher(algorithm.Visitor):
        return hash(tuple(freeze(getattr(node, field_name)) for field_name in fields))
 class Stitcher:
-    def __init__(self, core, dmgr, engine=None, print_as_rpc=True):
+    def __init__(self, core, dmgr, engine=None, print_as_rpc=True, destination=0, subkernel_arg_types=[]):
        self.core = core
        self.dmgr = dmgr
        if engine is None:
@ -682,12 +818,21 @@ class Stitcher:
        self.embedding_map = EmbeddingMap()
        self.value_map = defaultdict(lambda: [])
        self.definitely_changed = False
        self.destination = destination
        self.first_call = True
        # for non-annotated subkernels: 
        # main kernel inferencer output with types of arguments
        self.subkernel_arg_types = subkernel_arg_types
    def stitch_call(self, function, args, kwargs, callback=None):
        # We synthesize source code for the initial call so that
        # diagnostics would have something meaningful to display to the user.
        synthesizer = self._synthesizer(self._function_loc(function.artiq_embedded.function))
-        call_node = synthesizer.call(function, args, kwargs, callback)
+        # first call of a subkernel will get its arguments from remote (DRTIO)
        remote_fn = self.destination != 0
        call_node = synthesizer.call(function, args, kwargs, callback, remote_fn=remote_fn)
        synthesizer.finalize()
        self.typedtree.append(call_node)
@ -702,14 +847,20 @@ class Stitcher:
        old_attr_count = None
        while True:
            inferencer.visit(self.typedtree)
            if self.definitely_changed:
                changed = True
                self.definitely_changed = False
            else:
                typedtree_hash = typedtree_hasher.visit(self.typedtree)
                attr_count = self.embedding_map.attribute_count()
-
+                changed = old_attr_count != attr_count or \
-            if old_typedtree_hash == typedtree_hash and old_attr_count == attr_count:
+                          old_typedtree_hash != typedtree_hash
                break
                old_typedtree_hash = typedtree_hash
                old_attr_count = attr_count
            if not changed:
                break
        # After we've discovered every referenced attribute, check if any kernel_invariant
        # specifications refers to ones we didn't encounter.
        for host_type in self.embedding_map.type_map:
@ -793,6 +944,10 @@ class Stitcher:
                return [diagnostic.Diagnostic("note",
                    "in kernel function here", {},
                    call_loc)]
            elif fn_kind == 'subkernel':
                return [diagnostic.Diagnostic("note",
                    "in subkernel call here", {},
                    call_loc)]
            else:
                assert False
        else:
@ -812,7 +967,7 @@ class Stitcher:
                self._function_loc(function),
                notes=self._call_site_note(loc, fn_kind))
            self.engine.process(diag)
-        elif fn_kind == 'rpc' and param.default is not inspect.Parameter.empty:
+        elif fn_kind == 'rpc' or fn_kind == 'subkernel' and param.default is not inspect.Parameter.empty:
            notes = []
            notes.append(diagnostic.Diagnostic("note",
                "expanded from here while trying to infer a type for an"
@ -831,11 +986,21 @@ class Stitcher:
                Inferencer(engine=self.engine).visit(ast)
                IntMonomorphizer(engine=self.engine).visit(ast)
                return ast.type
-        else:
+        elif fn_kind == 'kernel' and self.first_call and self.destination != 0:
            # subkernels do not have access to the main kernel code to infer
            # arg types - so these are cached and passed onto subkernel
            # compilation, to avoid having to annotate them fully
            for name, typ in self.subkernel_arg_types:
                if param.name == name:
                    return typ
        # Let the rest of the program decide.
        return types.TVar()
-    def _quote_embedded_function(self, function, flags):
+    def _quote_embedded_function(self, function, flags, remote_fn=False):
        # we are now parsing new functions... definitely changed the type
        self.definitely_changed = True
        if isinstance(function, SpecializedFunction):
            host_function = function.host_function
        else:
@ -902,13 +1067,11 @@ class Stitcher:
        # Parse.
        source_buffer = source.Buffer(source_code, filename, first_line)
-        lexer = source_lexer.Lexer(source_buffer, version=sys.version_info[0:2],
+        lexer = source_lexer.Lexer(source_buffer, version=(3, 6), diagnostic_engine=self.engine)
                                   diagnostic_engine=self.engine)
        lexer.indent = [(initial_indent,
                         source.Range(source_buffer, 0, len(initial_whitespace)),
                         initial_whitespace)]
-        parser = source_parser.Parser(lexer, version=sys.version_info[0:2],
+        parser = source_parser.Parser(lexer, version=(3, 6), diagnostic_engine=self.engine)
                                      diagnostic_engine=self.engine)
        function_node = parser.file_input().body[0]
        # Mangle the name, since we put everything into a single module.
@ -933,7 +1096,7 @@ class Stitcher:
            engine=self.engine, prelude=self.prelude,
            globals=self.globals, host_environment=host_environment,
            quote=self._quote)
-        function_node = asttyped_rewriter.visit_quoted_function(function_node, embedded_function)
+        function_node = asttyped_rewriter.visit_quoted_function(function_node, embedded_function, remote_fn)
        function_node.flags = flags
        # Add it into our typedtree so that it gets inferenced and codegen'd.
@ -945,26 +1108,108 @@ class Stitcher:
        return function_node
    def _extract_annot(self, function, annot, kind, call_loc, fn_kind):
-        if annot is None:
+        if isinstance(function, SpecializedFunction):
-            annot = builtins.TNone()
+            host_function = function.host_function
        else:
            host_function = function
-        if not isinstance(annot, types.Type):
+        if hasattr(host_function, 'artiq_embedded'):
-            diag = diagnostic.Diagnostic("error",
+            embedded_function = host_function.artiq_embedded.function
-                "type annotation for {kind}, '{annot}', is not an ARTIQ type",
+        else:
            embedded_function = host_function
        if isinstance(embedded_function, str):
            embedded_function = host_function
        return self._to_artiq_type(
            annot,
            function=function,
            kind=kind,
            eval_in_scope=lambda x: eval(x, embedded_function.__globals__),
            call_loc=call_loc,
            fn_kind=fn_kind)
    def _to_artiq_type(
        self, annot, *, function, kind: str, eval_in_scope, call_loc: str, fn_kind: str
    ) -> types.Type:
        if isinstance(annot, str):
            try:
                annot = eval_in_scope(annot)
            except Exception:
                diag = diagnostic.Diagnostic(
                    "error",
                    "type annotation for {kind}, {annot}, cannot be evaluated",
                    {"kind": kind, "annot": repr(annot)},
                    self._function_loc(function),
                    notes=self._call_site_note(call_loc, fn_kind))
                self.engine.process(diag)
-            return types.TVar()
+        if isinstance(annot, types.Type):
        else:
            return annot
        # Convert built-in Python types to ARTIQ ones.
        if annot is None:
            return builtins.TNone()
        elif annot is numpy.int64:
            return builtins.TInt64()
        elif annot is numpy.int32:
            return builtins.TInt32()
        elif annot is float:
            return builtins.TFloat()
        elif annot is bool:
            return builtins.TBool()
        elif annot is str:
            return builtins.TStr()
        elif annot is bytes:
            return builtins.TBytes()
        elif annot is bytearray:
            return builtins.TByteArray()
        # Convert generic Python types to ARTIQ ones.
        generic_ty = typing.get_origin(annot)
        if generic_ty is not None:
            type_args = typing.get_args(annot)
            artiq_args = [
                self._to_artiq_type(
                    x,
                    function=function,
                    kind=kind,
                    eval_in_scope=eval_in_scope,
                    call_loc=call_loc,
                    fn_kind=fn_kind)
                for x in type_args
            ]
            if generic_ty is list and len(artiq_args) == 1:
                return builtins.TList(artiq_args[0])
            elif generic_ty is tuple:
                return types.TTuple(artiq_args)
        # Otherwise report an unknown type and just use a fresh tyvar.
        if annot is int:
            message = (
                "type annotation for {kind}, 'int' cannot be used as an ARTIQ type. "
                "Use numpy's int32 or int64 instead."
            )
            ty = builtins.TInt()
        else:
            message = "type annotation for {kind}, '{annot}', is not an ARTIQ type"
            ty = types.TVar()
        diag = diagnostic.Diagnostic("error",
            message,
            {"kind": kind, "annot": repr(annot)},
            self._function_loc(function),
            notes=self._call_site_note(call_loc, fn_kind))
        self.engine.process(diag)
        return ty
    def _quote_syscall(self, function, loc):
        signature = inspect.signature(function)
        arg_types = OrderedDict()
        optarg_types = OrderedDict()
        for param in signature.parameters.values():
            if param.kind != inspect.Parameter.POSITIONAL_OR_KEYWORD:
                diag = diagnostic.Diagnostic("error",
@ -1002,6 +1247,40 @@ class Stitcher:
        self.functions[function] = function_type
        return function_type
    def _quote_subkernel(self, function, loc):
        if isinstance(function, SpecializedFunction):
            host_function = function.host_function
        else:
            host_function = function
        ret_type = builtins.TNone()
        signature = inspect.signature(host_function)
        if signature.return_annotation is not inspect.Signature.empty:
            ret_type = self._extract_annot(host_function, signature.return_annotation,
                                            "return type", loc, fn_kind='subkernel')
        arg_types = OrderedDict()
        optarg_types = OrderedDict()
        for param in signature.parameters.values():
            if param.kind != inspect.Parameter.POSITIONAL_OR_KEYWORD:
                diag = diagnostic.Diagnostic("error",
                    "subkernels must only use positional arguments; '{argument}' isn't",
                    {"argument": param.name},
                    self._function_loc(function),
                    notes=self._call_site_note(loc, fn_kind='subkernel'))
                self.engine.process(diag)
            arg_type = self._type_of_param(function, loc, param, fn_kind='subkernel')
            if param.default is inspect.Parameter.empty:
                arg_types[param.name] = arg_type
            else:
                optarg_types[param.name] = arg_type
        function_type = types.TSubkernel(arg_types, optarg_types, ret_type,
                                   sid=self.embedding_map.store_object(host_function),
                                   destination=host_function.artiq_embedded.destination)
        self.functions[function] = function_type
        return function_type
    def _quote_rpc(self, function, loc):
        if isinstance(function, SpecializedFunction):
            host_function = function.host_function
@ -1061,8 +1340,18 @@ class Stitcher:
                (host_function.artiq_embedded.core_name is None and
                 host_function.artiq_embedded.portable is False and
                 host_function.artiq_embedded.syscall is None and
                 host_function.artiq_embedded.destination is None and
                 host_function.artiq_embedded.forbidden is False):
            self._quote_rpc(function, loc)
        elif host_function.artiq_embedded.destination is not None and \
            host_function.artiq_embedded.destination != self.destination:
            # treat subkernels as kernels if running on the same device
            if not 0 < host_function.artiq_embedded.destination <= 255:
                diag = diagnostic.Diagnostic("error",
                    "subkernel destination must be between 1 and 255 (inclusive)", {},
                    self._function_loc(host_function))
                self.engine.process(diag)
            self._quote_subkernel(function, loc)
        elif host_function.artiq_embedded.function is not None:
            if host_function.__name__ == "<lambda>":
                note = diagnostic.Diagnostic("note",
@ -1086,8 +1375,13 @@ class Stitcher:
                    notes=[note])
                self.engine.process(diag)
            destination = host_function.artiq_embedded.destination
            # remote_fn only for first call in subkernels
            remote_fn = destination is not None and self.first_call
            self._quote_embedded_function(function,
-                                          flags=host_function.artiq_embedded.flags)
+                                          flags=host_function.artiq_embedded.flags,
                                          remote_fn=remote_fn)
            self.first_call = False
        elif host_function.artiq_embedded.syscall is not None:
            # Insert a storage-less global whose type instructs the compiler
            # to perform a system call instead of a regular call.
--- a/artiq/compiler/ir.py
+++ b/artiq/compiler/ir.py
@ -135,6 +135,7 @@ class NamedValue(Value):
    def __init__(self, typ, name):
        super().__init__(typ)
        self.name, self.function = name, None
        self.is_removed = False
    def set_name(self, new_name):
        if self.function is not None:
@ -235,7 +236,7 @@ class Instruction(User):
        self.drop_references()
        # Check this after drop_references in case this
        # is a self-referencing phi.
-        assert not any(self.uses)
+        assert all(use.is_removed for use in self.uses)
    def replace_with(self, value):
        self.replace_all_uses_with(value)
@ -370,7 +371,7 @@ class BasicBlock(NamedValue):
        self.remove_from_parent()
        # Check this after erasing instructions in case the block
        # loops into itself.
-        assert not any(self.uses)
+        assert all(use.is_removed for use in self.uses)
    def prepend(self, insn):
        assert isinstance(insn, Instruction)
@ -705,6 +706,81 @@ class SetLocal(Instruction):
    def value(self):
        return self.operands[1]
 class GetArgFromRemote(Instruction):
    """
    An instruction that receives function arguments from remote 
    (ie. subkernel in DRTIO context)
    :ivar arg_name: (string) argument name
    :ivar arg_type: argument type
    """
    """
    :param arg_name: (string) argument name
    :param arg_type: argument type
    """
    def __init__(self, arg_name, arg_type, name=""):
        assert isinstance(arg_name, str)
        super().__init__([], arg_type, name)
        self.arg_name = arg_name
        self.arg_type = arg_type
    def copy(self, mapper):
        self_copy = super().copy(mapper)
        self_copy.arg_name = self.arg_name
        self_copy.arg_type = self.arg_type
        return self_copy
    def opcode(self):
        return "getargfromremote({})".format(repr(self.arg_name))
 class GetOptArgFromRemote(GetArgFromRemote):
    """
    An instruction that may or may not retrieve an optional function argument
    from remote, depending on number of values received by firmware.
    :ivar rcv_count: number of received values,
                     determined by firmware
    :ivar index: (integer) index of the current argument, 
                 in reference to remote arguments
    """
    """
    :param rcv_count: number of received valuese
    :param index: (integer) index of the current argument, 
                  in reference to remote arguments
    """
    def __init__(self, arg_name, arg_type, rcv_count, index, name=""):
        super().__init__(arg_name, arg_type, name)
        self.rcv_count = rcv_count
        self.index = index
    def copy(self, mapper):
        self_copy = super().copy(mapper)
        self_copy.rcv_count = self.rcv_count
        self_copy.index = self.index
        return self_copy
    def opcode(self):
        return "getoptargfromremote({})".format(repr(self.arg_name))
 class SubkernelAwaitArgs(Instruction):
    """
    A builtin instruction that takes min and max received messages as operands,
    and a list of received types.
    :ivar arg_types: (list of types) types of passed arguments (including optional)
    """
    """
    :param arg_types: (list of types) types of passed arguments (including optional)
    """
    def __init__(self, operands, arg_types, name=None):
        assert isinstance(arg_types, list)
        self.arg_types = arg_types
        super().__init__(operands, builtins.TNone(), name)
 class GetAttr(Instruction):
    """
    An intruction that loads an attribute from an object,
@ -727,7 +803,7 @@ class GetAttr(Instruction):
            typ = obj.type.attributes[attr]
        else:
            typ = obj.type.constructor.attributes[attr]
-            if types.is_function(typ) or types.is_rpc(typ):
+            if types.is_function(typ) or types.is_rpc(typ) or types.is_subkernel(typ):
                typ = types.TMethod(obj.type, typ)
        super().__init__([obj], typ, name)
        self.attr = attr
@ -1189,14 +1265,18 @@ class IndirectBranch(Terminator):
 class Return(Terminator):
    """
    A return instruction.
    :param remote_return: (bool) 
        marks a return in subkernel context,
        where the return value is sent back through DRTIO
    """
    """
    :param value: (:class:`Value`) return value
    """
-    def __init__(self, value, name=""):
+    def __init__(self, value, remote_return=False, name=""):
        assert isinstance(value, Value)
        super().__init__([value], builtins.TNone(), name)
        self.remote_return = remote_return
    def opcode(self):
        return "return"
@ -1245,9 +1325,9 @@ class Raise(Terminator):
        if len(self.operands) > 1:
            return self.operands[1]
-class Reraise(Terminator):
+class Resume(Terminator):
    """
-    A reraise instruction.
+    A resume instruction.
    """
    """
@ -1261,7 +1341,7 @@ class Reraise(Terminator):
        super().__init__(operands, builtins.TNone(), name)
    def opcode(self):
-        return "reraise"
+        return "resume"
    def exception_target(self):
        if len(self.operands) > 0:
@ -1347,6 +1427,7 @@ class LandingPad(Terminator):
    def __init__(self, cleanup, name=""):
        super().__init__([cleanup], builtins.TException(), name)
        self.types = []
        self.has_cleanup = True
    def copy(self, mapper):
        self_copy = super().copy(mapper)
--- a/artiq/compiler/kernel.ld
+++ b/artiq/compiler/kernel.ld
@ -0,0 +1,70 @@
 /* Force ld to make the ELF header as loadable. */
 PHDRS
 {
    headers     PT_LOAD FILEHDR PHDRS ;
    text        PT_LOAD ;
    data        PT_LOAD ;
    dynamic     PT_DYNAMIC ;
    eh_frame    PT_GNU_EH_FRAME ;
 }
 SECTIONS
 {
    /* Push back .text section enough so that ld.lld not complain */
    . = SIZEOF_HEADERS;
    .text :
    {
        *(.text .text.*)
    } : text
    .rodata :
    {
        *(.rodata .rodata.*)
    }
    .eh_frame :
    {
        KEEP(*(.eh_frame))
    } : text
    .eh_frame_hdr :
    {
        KEEP(*(.eh_frame_hdr))
    } : text : eh_frame
    .got :
    {
        *(.got)
    } : text
    .got.plt :
    {
        *(.got.plt)
    } : text
    .data :
    {
        *(.data .data.*)
    } : data
    .dynamic :
    {
        *(.dynamic)
    } : data : dynamic
    .bss (NOLOAD) : ALIGN(4)
    {
        __bss_start = .;
        *(.sbss .sbss.* .bss .bss.*);
        . = ALIGN(4);
        _end = .;
    }
    /* Kernel stack grows downward from end of memory, so put guard page after
     * all the program contents. Note: This requires all loaded sections (at
     * least those accessed) to be explicitly listed in the above!
     */
    . = ALIGN(0x1000);
    _sstack_guard = .;
 }
--- a/artiq/compiler/module.py
+++ b/artiq/compiler/module.py
@ -10,7 +10,7 @@ string and infers types for it using a trivial :module:`prelude`.
 import os
 from pythonparser import source, diagnostic, parse_buffer
-from . import prelude, types, transforms, analyses, validators
+from . import prelude, types, transforms, analyses, validators, embedding
 class Source:
    def __init__(self, source_buffer, engine=None):
@ -18,7 +18,7 @@ class Source:
            self.engine = diagnostic.Engine(all_errors_are_fatal=True)
        else:
            self.engine = engine
-        self.embedding_map = None
+        self.embedding_map = embedding.EmbeddingMap()
        self.name, _ = os.path.splitext(os.path.basename(source_buffer.name))
        asttyped_rewriter = transforms.ASTTypedRewriter(engine=engine,
@ -57,7 +57,8 @@ class Module:
        constness_validator = validators.ConstnessValidator(engine=self.engine)
        artiq_ir_generator = transforms.ARTIQIRGenerator(engine=self.engine,
                                                         module_name=src.name,
-                                                         ref_period=ref_period)
+                                                         ref_period=ref_period,
                                                         embedding_map=self.embedding_map)
        dead_code_eliminator = transforms.DeadCodeEliminator(engine=self.engine)
        local_access_validator = validators.LocalAccessValidator(engine=self.engine)
        local_demoter = transforms.LocalDemoter()
@ -83,6 +84,8 @@ class Module:
        constant_hoister.process(self.artiq_ir)
        if remarks:
            invariant_detection.process(self.artiq_ir)
        # for subkernels: main kernel inferencer output, to be passed to further compilations
        self.subkernel_arg_types = inferencer.subkernel_arg_types
    def build_llvm_ir(self, target):
        """Compile the module to LLVM IR for the specified target."""
--- a/artiq/compiler/prelude.py
+++ b/artiq/compiler/prelude.py
@ -37,6 +37,7 @@ def globals():
        # ARTIQ decorators
        "kernel":               builtins.fn_kernel(),
        "subkernel":            builtins.fn_kernel(),
        "portable":             builtins.fn_kernel(),
        "rpc":                  builtins.fn_kernel(),
@ -54,4 +55,8 @@ def globals():
        # ARTIQ utility functions
        "rtio_log":             builtins.fn_rtio_log(),
        "core_log":             builtins.fn_print(),
        # ARTIQ subkernel utility functions
        "subkernel_await":     builtins.fn_subkernel_await(),
        "subkernel_preload":   builtins.fn_subkernel_preload(),
    }
--- a/artiq/compiler/targets.py
+++ b/artiq/compiler/targets.py
@ -1,6 +1,6 @@
 import os, sys, tempfile, subprocess, io
 from artiq.compiler import types, ir
-from llvmlite_artiq import ir as ll, binding as llvm
+from llvmlite import ir as ll, binding as llvm
 llvm.initialize()
 llvm.initialize_all_targets()
@ -28,8 +28,10 @@ class RunTool:
        for argument in self._pattern:
            cmdline.append(argument.format(**self._tempnames))
        # https://bugs.python.org/issue17023
        windows = os.name == "nt"
        process = subprocess.Popen(cmdline, stdout=subprocess.PIPE, stderr=subprocess.PIPE,
-                                   universal_newlines=True)
+                                   universal_newlines=True, shell=windows)
        stdout, stderr = process.communicate()
        if process.returncode != 0:
            raise Exception("{} invocation failed: {}".
@ -67,40 +69,41 @@ class Target:
    generated by the ARTIQ compiler will be deployed.
    :var triple: (string)
-        LLVM target triple, e.g. ``"or1k"``
+        LLVM target triple, e.g. ``"riscv32"``
    :var data_layout: (string)
        LLVM target data layout, e.g. ``"E-m:e-p:32:32-i64:32-f64:32-v64:32-v128:32-a:0:32-n32"``
    :var features: (list of string)
        LLVM target CPU features, e.g. ``["mul", "div", "ffl1"]``
    :var additional_linker_options: (list of string)
        Linker options for the target in addition to the target-independent ones, e.g. ``["--target2=rel"]``
    :var print_function: (string)
        Name of a formatted print functions (with the signature of ``printf``)
        provided by the target, e.g. ``"printf"``.
    :var little_endian: (boolean)
        Whether the code will be executed on a little-endian machine. This cannot be always
        determined from data_layout due to JIT.
    :var now_pinning: (boolean)
        Whether the target implements the now-pinning RTIO optimization.
    """
    triple = "unknown"
    data_layout = ""
    features = []
    additional_linker_options = []
    print_function = "printf"
    little_endian = False
    now_pinning = True
    tool_ld = "ld.lld"
    tool_strip = "llvm-strip"
-    tool_addr2line = "llvm-addr2line"
+    tool_symbolizer = "llvm-symbolizer"
    tool_cxxfilt = "llvm-cxxfilt"
-    def __init__(self):
+    def __init__(self, subkernel_id=None):
        self.llcontext = ll.Context()
        self.subkernel_id = subkernel_id
    def target_machine(self):
        lltarget = llvm.Target.from_triple(self.triple)
        llmachine = lltarget.create_target_machine(
                        features=",".join(["+{}".format(f) for f in self.features]),
-                        reloc="pic", codemodel="default")
+                        reloc="pic", codemodel="default",
                        abiname="ilp32d" if isinstance(self, RV32GTarget) else "")
        llmachine.set_asm_verbosity(True)
        return llmachine
@ -146,7 +149,8 @@ class Target:
            ir.BasicBlock._dump_loc = False
        type_printer = types.TypePrinter()
-        _dump(os.getenv("ARTIQ_DUMP_IR"), "ARTIQ IR", ".txt",
+        suffix = "_subkernel_{}".format(self.subkernel_id) if self.subkernel_id is not None else ""
        _dump(os.getenv("ARTIQ_DUMP_IR"), "ARTIQ IR", suffix + ".txt",
              lambda: "\n".join(fn.as_entity(type_printer) for fn in module.artiq_ir))
        llmod = module.build_llvm_ir(self)
@ -158,12 +162,12 @@ class Target:
            _dump("", "LLVM IR (broken)", ".ll", lambda: str(llmod))
            raise
-        _dump(os.getenv("ARTIQ_DUMP_UNOPT_LLVM"), "LLVM IR (generated)", "_unopt.ll",
+        _dump(os.getenv("ARTIQ_DUMP_UNOPT_LLVM"), "LLVM IR (generated)", suffix + "_unopt.ll",
              lambda: str(llparsedmod))
        self.optimize(llparsedmod)
-        _dump(os.getenv("ARTIQ_DUMP_LLVM"), "LLVM IR (optimized)", ".ll",
+        _dump(os.getenv("ARTIQ_DUMP_LLVM"), "LLVM IR (optimized)", suffix + ".ll",
              lambda: str(llparsedmod))
        return llparsedmod
@ -182,6 +186,8 @@ class Target:
    def link(self, objects):
        """Link the relocatable objects into a shared library for this target."""
        with RunTool([self.tool_ld, "-shared", "--eh-frame-hdr"] +
                     self.additional_linker_options +
                     ["-T" + os.path.join(os.path.dirname(__file__), "kernel.ld")] +
                     ["{{obj{}}}".format(index) for index in range(len(objects))] +
                     ["-x"] +
                     ["-o", "{output}"],
@ -212,9 +218,10 @@ class Target:
        # just after the call. Offset them back to get an address somewhere
        # inside the call instruction (or its delay slot), since that's what
        # the backtrace entry should point at.
        last_inlined = None
        offset_addresses = [hex(addr - 1) for addr in addresses]
-        with RunTool([self.tool_addr2line, "--addresses",  "--functions", "--inlines",
+        with RunTool([self.tool_symbolizer, "--addresses",  "--functions", "--inlines",
-                      "--demangle", "--exe={library}"] + offset_addresses,
+                      "--demangle", "--output-style=GNU", "--exe={library}"] + offset_addresses,
                     library=library) \
                as results:
            lines = iter(results["__stdout__"].read().rstrip().split("\n"))
@ -227,9 +234,11 @@ class Target:
                if address_or_function[:2] == "0x":
                    address  = int(address_or_function[2:], 16) + 1 # remove offset
                    function = next(lines)
                    inlined = False
                else:
                    address  = backtrace[-1][4] # inlined
                    function = address_or_function
                    inlined = True
                location = next(lines)
                filename, line = location.rsplit(":", 1)
@ -240,10 +249,17 @@ class Target:
                else:
                    line = int(line)
                # can't get column out of addr2line D:
-                backtrace.append((filename, line, -1, function, address))
+                if inlined:
                    last_inlined.append((filename, line, -1, function, address))
                else:
                    last_inlined = []
                    backtrace.append((filename, line, -1, function, address,
                                      last_inlined))
            return backtrace
    def demangle(self, names):
        if not any(names):
            return names
        with RunTool([self.tool_cxxfilt] + names) as results:
            return results["__stdout__"].read().rstrip().split("\n")
@ -251,33 +267,43 @@ class NativeTarget(Target):
    def __init__(self):
        super().__init__()
        self.triple = llvm.get_default_triple()
-        host_data_layout = str(llvm.targets.Target.from_default_triple().create_target_machine().target_data)
+        self.data_layout = str(llvm.targets.Target.from_default_triple().create_target_machine().target_data)
        assert host_data_layout[0] in "eE"
        self.little_endian = host_data_layout[0] == "e"
-class OR1KTarget(Target):
+class RV32IMATarget(Target):
-    triple = "or1k-linux"
+    triple = "riscv32-unknown-linux"
-    data_layout = "E-m:e-p:32:32-i8:8:8-i16:16:16-i64:32:32-" \
+    data_layout = "e-m:e-p:32:32-i64:64-n32-S128"
-                  "f64:32:32-v64:32:32-v128:32:32-a0:0:32-n32"
+    features = ["m", "a"]
-    features = ["mul", "div", "ffl1", "cmov", "addc"]
+    additional_linker_options = ["-m", "elf32lriscv"]
    print_function = "core_log"
    little_endian = False
    now_pinning = True
-    tool_ld = "or1k-linux-ld"
+    tool_ld = "ld.lld"
-    tool_strip = "or1k-linux-strip"
+    tool_strip = "llvm-strip"
-    tool_addr2line = "or1k-linux-addr2line"
+    tool_symbolizer = "llvm-symbolizer"
-    tool_cxxfilt = "or1k-linux-c++filt"
+    tool_cxxfilt = "llvm-cxxfilt"
 class RV32GTarget(Target):
    triple = "riscv32-unknown-linux"
    data_layout = "e-m:e-p:32:32-i64:64-n32-S128"
    features = ["m", "a", "f", "d"]
    additional_linker_options = ["-m", "elf32lriscv"]
    print_function = "core_log"
    now_pinning = True
    tool_ld = "ld.lld"
    tool_strip = "llvm-strip"
    tool_symbolizer = "llvm-symbolizer"
    tool_cxxfilt = "llvm-cxxfilt"
 class CortexA9Target(Target):
    triple = "armv7-unknown-linux-gnueabihf"
    data_layout = "e-m:e-p:32:32-i64:64-v128:64:128-a:0:32-n32-S64"
    features = ["dsp", "fp16", "neon", "vfp3"]
    additional_linker_options = ["-m", "armelf_linux_eabi", "--target2=rel"]
    print_function = "core_log"
    little_endian = True
    now_pinning = False
-    tool_ld = "armv7-unknown-linux-gnueabihf-ld"
+    tool_ld = "ld.lld"
-    tool_strip = "armv7-unknown-linux-gnueabihf-strip"
+    tool_strip = "llvm-strip"
-    tool_addr2line = "armv7-unknown-linux-gnueabihf-addr2line"
+    tool_symbolizer = "llvm-symbolizer"
-    tool_cxxfilt = "armv7-unknown-linux-gnueabihf-c++filt"
+    tool_cxxfilt = "llvm-cxxfilt"
--- a/artiq/compiler/testbench/jit.py
+++ b/artiq/compiler/testbench/jit.py
@ -1,6 +1,6 @@
 import os, sys, fileinput, ctypes
 from pythonparser import diagnostic
-from llvmlite_artiq import binding as llvm
+from llvmlite import binding as llvm
 from ..module import Module, Source
 from ..targets import NativeTarget
--- a/artiq/compiler/testbench/llvmgen.py
+++ b/artiq/compiler/testbench/llvmgen.py
@ -1,6 +1,6 @@
 import sys, fileinput
 from pythonparser import diagnostic
-from llvmlite_artiq import ir as ll
+from llvmlite import ir as ll
 from ..module import Module, Source
 from ..targets import NativeTarget
--- a/artiq/compiler/testbench/perf.py
+++ b/artiq/compiler/testbench/perf.py
@ -1,7 +1,7 @@
 import sys, os
 from pythonparser import diagnostic
 from ..module import Module, Source
-from ..targets import OR1KTarget
+from ..targets import RV32GTarget
 from . import benchmark
 def main():
@ -30,7 +30,7 @@ def main():
    benchmark(lambda: Module(source),
              "ARTIQ transforms and validators")
-    benchmark(lambda: OR1KTarget().compile_and_link([module]),
+    benchmark(lambda: RV32GTarget().compile_and_link([module]),
              "LLVM optimization and linking")
 if __name__ == "__main__":
--- a/artiq/compiler/testbench/perf_embedding.py
+++ b/artiq/compiler/testbench/perf_embedding.py
@ -5,7 +5,7 @@ from ...master.databases import DeviceDB, DatasetDB
 from ...master.worker_db import DeviceManager, DatasetManager
 from ..module import Module
 from ..embedding import Stitcher
-from ..targets import OR1KTarget
+from ..targets import RV32GTarget
 from . import benchmark
@ -30,8 +30,9 @@ def main():
    device_db_path = os.path.join(os.path.dirname(sys.argv[1]), "device_db.py")
    device_mgr = DeviceManager(DeviceDB(device_db_path))
-    dataset_db_path = os.path.join(os.path.dirname(sys.argv[1]), "dataset_db.pyon")
+    dataset_db_path = os.path.join(os.path.dirname(sys.argv[1]), "dataset_db.mdb")
-    dataset_mgr = DatasetManager(DatasetDB(dataset_db_path))
+    dataset_db = DatasetDB(dataset_db_path)
    dataset_mgr = DatasetManager()
    argument_mgr = ProcessArgumentManager({})
@ -45,7 +46,7 @@ def main():
    stitcher = embed()
    module = Module(stitcher)
-    target = OR1KTarget()
+    target = RV32GTarget()
    llvm_ir = target.compile(module)
    elf_obj = target.assemble(llvm_ir)
    elf_shlib = target.link([elf_obj])
@ -68,5 +69,7 @@ def main():
    benchmark(lambda: target.strip(elf_shlib),
              "Stripping debug information")
    dataset_db.close_db()
 if __name__ == "__main__":
    main()
--- a/artiq/compiler/testbench/shlib.py
+++ b/artiq/compiler/testbench/shlib.py
@ -1,7 +1,7 @@
 import sys, os
 from pythonparser import diagnostic
 from ..module import Module, Source
-from ..targets import OR1KTarget
+from ..targets import RV32GTarget
 def main():
    if not len(sys.argv) > 1:
@ -20,7 +20,7 @@ def main():
    for filename in sys.argv[1:]:
        modules.append(Module(Source.from_filename(filename, engine=engine)))
-    llobj = OR1KTarget().compile_and_link(modules)
+    llobj = RV32GTarget().compile_and_link(modules)
    basename, ext = os.path.splitext(sys.argv[-1])
    with open(basename + ".so", "wb") as f:
--- a/artiq/compiler/transforms/artiq_ir_generator.py
+++ b/artiq/compiler/transforms/artiq_ir_generator.py
@ -8,6 +8,7 @@ semantics explicitly.
 from collections import OrderedDict, defaultdict
 from functools import reduce
 from itertools import chain
 from pythonparser import algorithm, diagnostic, ast
 from .. import types, builtins, asttyped, ir, iodelay
@ -61,6 +62,9 @@ class ARTIQIRGenerator(algorithm.Visitor):
        the basic block to which ``return`` will transfer control
    :ivar unwind_target: (:class:`ir.BasicBlock` or None)
        the basic block to which unwinding will transfer control
    :ivar catch_clauses: (list of (:class:`ir.BasicBlock`, :class:`types.Type` or None))
        a list of catch clauses that should be appended to inner try block
        landingpad
    :ivar final_branch: (function (target: :class:`ir.BasicBlock`, block: :class:`ir.BasicBlock)
                         or None)
        the function that appends to ``block`` a jump through the ``finally`` statement
@ -88,8 +92,9 @@ class ARTIQIRGenerator(algorithm.Visitor):
    _size_type = builtins.TInt32()
-    def __init__(self, module_name, engine, ref_period):
+    def __init__(self, module_name, engine, ref_period, embedding_map):
        self.engine = engine
        self.embedding_map = embedding_map
        self.functions = []
        self.name = [module_name] if module_name != "" else []
        self.ref_period = ir.Constant(ref_period, builtins.TFloat())
@ -102,10 +107,13 @@ class ARTIQIRGenerator(algorithm.Visitor):
        self.current_private_env = None
        self.current_args = None
        self.current_assign = None
        self.current_exception = None
        self.current_remote_fn = False
        self.break_target = None
        self.continue_target = None
        self.return_target = None
        self.unwind_target = None
        self.catch_clauses = []
        self.final_branch = None
        self.function_map = dict()
        self.variable_map = dict()
@ -204,7 +212,8 @@ class ARTIQIRGenerator(algorithm.Visitor):
            old_priv_env, self.current_private_env = self.current_private_env, priv_env
            self.generic_visit(node)
-            self.terminate(ir.Return(ir.Constant(None, builtins.TNone())))
+            self.terminate(ir.Return(ir.Constant(None, builtins.TNone()),
                           remote_return=self.current_remote_fn))
            return self.functions
        finally:
@ -287,6 +296,8 @@ class ARTIQIRGenerator(algorithm.Visitor):
            old_block, self.current_block = self.current_block, entry
            old_globals, self.current_globals = self.current_globals, node.globals_in_scope
            old_remote_fn = self.current_remote_fn
            self.current_remote_fn = getattr(node, "remote_fn", False)
            env_without_globals = \
                {var: node.typing_env[var]
@ -319,7 +330,8 @@ class ARTIQIRGenerator(algorithm.Visitor):
                self.terminate(ir.Return(result))
            elif builtins.is_none(typ.ret):
                if not self.current_block.is_terminated():
-                    self.current_block.append(ir.Return(ir.Constant(None, builtins.TNone())))
+                    self.current_block.append(ir.Return(ir.Constant(None, builtins.TNone()), 
                                                        remote_return=self.current_remote_fn))
            else:
                if not self.current_block.is_terminated():
                    if len(self.current_block.predecessors()) != 0:
@ -338,6 +350,7 @@ class ARTIQIRGenerator(algorithm.Visitor):
            self.current_block = old_block
            self.current_globals = old_globals
            self.current_env = old_env
            self.current_remote_fn = old_remote_fn
            if not is_lambda:
                self.current_private_env = old_priv_env
@ -360,7 +373,8 @@ class ARTIQIRGenerator(algorithm.Visitor):
            return_value = self.visit(node.value)
        if self.return_target is None:
-            self.append(ir.Return(return_value))
+            self.append(ir.Return(return_value, 
                                  remote_return=self.current_remote_fn))
        else:
            self.append(ir.SetLocal(self.current_private_env, "$return", return_value))
            self.append(ir.Branch(self.return_target))
@ -626,6 +640,11 @@ class ARTIQIRGenerator(algorithm.Visitor):
            self.final_branch(raise_proxy, self.current_block)
            self.current_block = raise_proxy
        if exn is not None:
            # if we need to raise the exception in a final body, we have to
            # lazy-evaluate the exception object to make sure that we generate
            # it in the raise_proxy block
            exn = exn()
        if exn is not None:
            assert loc is not None
            loc_file = ir.Constant(loc.source_buffer.name, builtins.TStr())
@ -633,10 +652,10 @@ class ARTIQIRGenerator(algorithm.Visitor):
            loc_column = ir.Constant(loc.column(), builtins.TInt32())
            loc_function = ir.Constant(".".join(self.name), builtins.TStr())
-            self.append(ir.SetAttr(exn, "__file__", loc_file))
+            self.append(ir.SetAttr(exn, "#__file__", loc_file))
-            self.append(ir.SetAttr(exn, "__line__", loc_line))
+            self.append(ir.SetAttr(exn, "#__line__", loc_line))
-            self.append(ir.SetAttr(exn, "__col__", loc_column))
+            self.append(ir.SetAttr(exn, "#__col__", loc_column))
-            self.append(ir.SetAttr(exn, "__func__", loc_function))
+            self.append(ir.SetAttr(exn, "#__func__", loc_function))
            if self.unwind_target is not None:
                self.append(ir.Raise(exn, self.unwind_target))
@ -644,18 +663,21 @@ class ARTIQIRGenerator(algorithm.Visitor):
                self.append(ir.Raise(exn))
        else:
            if self.unwind_target is not None:
-                self.append(ir.Reraise(self.unwind_target))
+                self.append(ir.Resume(self.unwind_target))
            else:
-                self.append(ir.Reraise())
+                self.append(ir.Resume())
    def visit_Raise(self, node):
        if node.exc is not None and types.is_exn_constructor(node.exc.type):
-            self.raise_exn(self.alloc_exn(node.exc.type.instance), loc=self.current_loc)
+            self.raise_exn(lambda: self.alloc_exn(node.exc.type.instance), loc=self.current_loc)
        else:
-            self.raise_exn(self.visit(node.exc), loc=self.current_loc)
+            self.raise_exn(lambda: self.visit(node.exc), loc=self.current_loc)
    def visit_Try(self, node):
        dispatcher = self.add_block("try.dispatch")
        cleanup = self.add_block('handler.cleanup')
        landingpad = ir.LandingPad(cleanup)
        dispatcher.append(landingpad)
        if any(node.finalbody):
            # k for continuation
@ -690,16 +712,51 @@ class ARTIQIRGenerator(algorithm.Visitor):
                value = return_action.append(ir.GetLocal(self.current_private_env, "$return"))
                return_action.append(ir.Return(value))
                final_branch(return_action, return_proxy)
        else:
            landingpad.has_cleanup = False
        # we should propagate the clauses to nested try catch blocks
        # so nested try catch will jump to our clause if the inner one does not
        # match
        # note that the phi instruction here requires some hack, see
        # llvm_ir_generator process_function for details
        clauses = []
        found_catch_all = False
        for handler_node in node.handlers:
            if found_catch_all:
                self.warn_unreachable(handler_node)
                continue
            exn_type = handler_node.name_type.find()
            if handler_node.filter is not None and \
                    not builtins.is_exception(exn_type, 'Exception'):
                handler = self.add_block("handler." + exn_type.name)
                phi = ir.Phi(builtins.TException(), 'exn')
                handler.append(phi)
                clauses.append((handler, exn_type, phi))
            else:
                handler = self.add_block("handler.catchall")
                phi = ir.Phi(builtins.TException(), 'exn')
                handler.append(phi)
                clauses.append((handler, None, phi))
                found_catch_all = True
        all_clauses = clauses[:]
        for clause in self.catch_clauses:
            # if the last clause is accept all, do not add further clauses
            if len(all_clauses) == 0 or all_clauses[-1][1] is not None:
                all_clauses.append(clause)
        body = self.add_block("try.body")
        self.append(ir.Branch(body))
        self.current_block = body
        try:
        old_unwind, self.unwind_target = self.unwind_target, dispatcher
        old_clauses, self.catch_clauses = self.catch_clauses, all_clauses
        try:
            self.visit(node.body)
        finally:
            self.unwind_target = old_unwind
            self.catch_clauses = old_clauses
        if not self.current_block.is_terminated():
            self.visit(node.orelse)
@ -708,85 +765,149 @@ class ARTIQIRGenerator(algorithm.Visitor):
        body = self.current_block
        if any(node.finalbody):
            # if we have a final block, we should not append clauses to our
            # landingpad or we will skip the finally block.
            # when the finally block calls resume, it will unwind to the outer
            # try catch block automatically
            all_clauses = clauses
            # reset targets
            if self.break_target:
                self.break_target = old_break
            if self.continue_target:
                self.continue_target = old_continue
            self.return_target = old_return
-            old_final_branch, self.final_branch = self.final_branch, final_branch
+        if any(node.finalbody):
            # create new unwind target for cleanup
            final_dispatcher = self.add_block("try.final.dispatch")
            final_landingpad = ir.LandingPad(cleanup)
            final_dispatcher.append(final_landingpad)
-        cleanup = self.add_block('handler.cleanup')
+            # make sure that exception clauses are unwinded to the finally block
-        landingpad = dispatcher.append(ir.LandingPad(cleanup))
+            old_unwind, self.unwind_target = self.unwind_target, final_dispatcher
        if any(node.finalbody):
            # if we have a while:try/finally continue must execute finally
            # before continuing the while
            redirect = final_branch
        else:
            redirect = lambda dest, proxy: proxy.append(ir.Branch(dest))
        # we need to set break/continue/return to execute end_catch
        if self.break_target is not None:
            break_proxy = self.add_block("try.break")
            break_proxy.append(ir.Builtin("end_catch", [], builtins.TNone()))
            old_break, self.break_target = self.break_target, break_proxy
            redirect(old_break, break_proxy)
        if self.continue_target is not None:
            continue_proxy = self.add_block("try.continue")
            continue_proxy.append(ir.Builtin("end_catch", [],
                                             builtins.TNone()))
            old_continue, self.continue_target = self.continue_target, continue_proxy
            redirect(old_continue, continue_proxy)
        return_proxy = self.add_block("try.return")
        return_proxy.append(ir.Builtin("end_catch", [], builtins.TNone()))
        old_return, self.return_target = self.return_target, return_proxy
        old_return_target = old_return
        if old_return_target is None:
            old_return_target = self.add_block("try.doreturn")
            value = old_return_target.append(ir.GetLocal(self.current_private_env, "$return"))
            old_return_target.append(ir.Return(value))
        redirect(old_return_target, return_proxy)
        handlers = []
        for handler_node in node.handlers:
            exn_type = handler_node.name_type.find()
            if handler_node.filter is not None and \
                    not builtins.is_exception(exn_type, 'Exception'):
                handler = self.add_block("handler." + exn_type.name)
                landingpad.add_clause(handler, exn_type)
            else:
                handler = self.add_block("handler.catchall")
                landingpad.add_clause(handler, None)
        for (handler_node, (handler, exn_type, phi)) in zip(node.handlers, clauses):
            self.current_block = handler
            if handler_node.name is not None:
-                exn = self.append(ir.Builtin("exncast", [landingpad], handler_node.name_type))
+                exn = self.append(ir.Builtin("exncast", [phi], handler_node.name_type))
                self._set_local(handler_node.name, exn)
            self.visit(handler_node.body)
            # only need to call end_catch if the current block is not terminated
            # other possible paths: break/continue/return/raise
            # we will call end_catch in the first 3 cases, and we should not
            # end_catch in the last case for nested exception
            if not self.current_block.is_terminated():
                self.append(ir.Builtin("end_catch", [], builtins.TNone()))
            post_handler = self.current_block
            handlers.append(post_handler)
-            handlers.append((handler, post_handler))
+        # branch to all possible clauses, including those from outer try catch
        # block
        # if we have a finally block, all_clauses will not include those from
        # the outer block
        for (handler, clause, phi) in all_clauses:
            phi.add_incoming(landingpad, dispatcher)
            landingpad.add_clause(handler, clause)
        if self.break_target:
            self.break_target = old_break
        if self.continue_target:
            self.continue_target = old_continue
        self.return_target = old_return
        if any(node.finalbody):
            # Finalize and continue after try statement.
-            self.final_branch = old_final_branch
+            self.unwind_target = old_unwind
-
+            # Exception path
-            finalizer = self.add_block("finally")
+            finalizer_reraise = self.add_block("finally.resume")
            self.current_block = finalizer
            self.visit(node.finalbody)
            post_finalizer = self.current_block
            # Finalize and reraise. Separate from previous case to expose flow
            # to LocalAccessValidator.
            finalizer_reraise = self.add_block("finally.reraise")
            self.current_block = finalizer_reraise
            self.visit(node.finalbody)
-            self.terminate(ir.Reraise(self.unwind_target))
+            self.terminate(ir.Resume(self.unwind_target))
        self.current_block = tail = self.add_block("try.tail")
        if any(node.finalbody):
            final_targets.append(tail)
            for block in final_paths:
                block.append(ir.Branch(finalizer))
            if not body.is_terminated():
                body.append(ir.SetLocal(final_state, "$cont", tail))
                body.append(ir.Branch(finalizer))
            cleanup.append(ir.Branch(finalizer_reraise))
-            for handler, post_handler in handlers:
+            # Normal path
-                if not post_handler.is_terminated():
+            finalizer = self.add_block("finally")
-                    post_handler.append(ir.SetLocal(final_state, "$cont", tail))
+            self.current_block = finalizer
-                    post_handler.append(ir.Branch(finalizer))
+            self.visit(node.finalbody)
            post_finalizer = self.current_block
            self.current_block = tail = self.add_block("try.tail")
            final_targets.append(tail)
            # if final block is not terminated, branch to tail
            if not post_finalizer.is_terminated():
                dest = post_finalizer.append(ir.GetLocal(final_state, "$cont"))
                post_finalizer.append(ir.IndirectBranch(dest, final_targets))
            # make sure proxies will branch to finalizer
            for block in final_paths:
                if finalizer in block.predecessors():
                    # avoid producing irreducible graphs
                    # generate a new finalizer
                    self.current_block = tmp_finalizer = self.add_block("finally.tmp")
                    self.visit(node.finalbody)
                    if not self.current_block.is_terminated():
                        assert isinstance(block.instructions[-1], ir.SetLocal)
                        self.current_block.append(ir.Branch(block.instructions[-1].operands[-1]))
                        block.instructions[-1].erase()
                    block.append(ir.Branch(tmp_finalizer))
                    self.current_block = tail
                else:
                    block.append(ir.Branch(finalizer))
            # if no raise in body/handlers, branch to finalizer
            for block in chain([body], handlers):
                if not block.is_terminated():
                    if finalizer in block.predecessors():
                        # similar to the above case
                        self.current_block = tmp_finalizer = self.add_block("finally.tmp")
                        self.visit(node.finalbody)
                        self.terminate(ir.Branch(tail))
                        block.append(ir.Branch(tmp_finalizer))
                        self.current_block = tail
                    else:
                        block.append(ir.SetLocal(final_state, "$cont", tail))
                        block.append(ir.Branch(finalizer))
        else:
            self.current_block = tail = self.add_block("try.tail")
            if not body.is_terminated():
                body.append(ir.Branch(tail))
-            cleanup.append(ir.Reraise(self.unwind_target))
+            cleanup.append(ir.Resume(self.unwind_target))
-            for handler, post_handler in handlers:
+            for handler in handlers:
-                if not post_handler.is_terminated():
+                if not handler.is_terminated():
-                    post_handler.append(ir.Branch(tail))
+                    handler.append(ir.Branch(tail))
    def _try_finally(self, body_gen, finally_gen, name):
        dispatcher = self.add_block("{}.dispatch".format(name))
@ -805,7 +926,7 @@ class ARTIQIRGenerator(algorithm.Visitor):
        self.current_block = self.add_block("{}.cleanup".format(name))
        dispatcher.append(ir.LandingPad(self.current_block))
        finally_gen()
-        self.raise_exn()
+        self.terminate(ir.Resume(self.unwind_target))
        self.current_block = self.post_body
@ -995,7 +1116,7 @@ class ARTIQIRGenerator(algorithm.Visitor):
            old_final_branch, self.final_branch = self.final_branch, None
            old_unwind, self.unwind_target = self.unwind_target, None
-            self.raise_exn(exn_gen(*args[1:]), loc=loc)
+            self.raise_exn(lambda: exn_gen(*args[1:]), loc=loc)
        finally:
            self.current_function = old_func
            self.current_block = old_block
@ -1084,7 +1205,27 @@ class ARTIQIRGenerator(algorithm.Visitor):
        finally:
            self.current_assign = old_assign
-        if isinstance(node.slice, ast.Index):
+        if types.is_tuple(node.value.type):
            assert isinstance(node.slice, ast.Index), \
                "Internal compiler error: tuple index should be an Index"
            assert isinstance(node.slice.value, ast.Num), \
                "Internal compiler error: tuple index should be a constant"
            if self.current_assign is not None:
                diag = diagnostic.Diagnostic("error",
                    "cannot assign to a tuple element",
                    {}, node.loc)
                self.engine.process(diag)
            index = node.slice.value.n
            indexed = self.append(
                ir.GetAttr(value, index, name="{}.e{}".format(value.name, index)),
                loc=node.loc
            )
            return indexed
        elif isinstance(node.slice, ast.Index):
            try:
                old_assign, self.current_assign = self.current_assign, None
                index = self.visit(node.slice.value)
@ -1116,7 +1257,11 @@ class ARTIQIRGenerator(algorithm.Visitor):
                                                                  _readable_name(index))))
            if self.current_assign is None:
                return indexed
-        else: # Slice
+        else:
            # This is a slice. The endpoint checking logic is the same for both lists
            # and NumPy arrays, but the actual implementations differ – while slices of
            # built-in lists are always copies in Python, they are views sharing the
            # same backing storage in NumPy.
            length = self.iterable_len(value, node.slice.type)
            if node.slice.lower is not None:
@ -1141,6 +1286,42 @@ class ARTIQIRGenerator(algorithm.Visitor):
            mapped_stop_index = self._map_index(length, stop_index, one_past_the_end=True,
                                                loc=node.begin_loc)
            if builtins.is_array(node.type):
                # To implement strided slicing with the proper NumPy reference
                # semantics, the pointer/length array representation will need to be
                # extended by another field to hold a variable stride.
                assert node.slice.step is None, (
                    "array slices with non-trivial step "
                    "should have been disallowed during type inference")
                # One-dimensionally slicing an array only affects the outermost
                # dimension.
                shape = self.append(ir.GetAttr(value, "shape"))
                lengths = [
                    self.append(ir.GetAttr(shape, i))
                    for i in range(len(shape.type.elts))
                ]
                # Compute outermost length – zero for "backwards" indices.
                raw_len = self.append(
                    ir.Arith(ast.Sub(loc=None), mapped_stop_index, mapped_start_index))
                is_neg_len = self.append(
                    ir.Compare(ast.Lt(loc=None), raw_len, ir.Constant(0, raw_len.type)))
                outer_len = self.append(
                    ir.Select(is_neg_len, ir.Constant(0, raw_len.type), raw_len))
                new_shape = self._make_array_shape([outer_len] + lengths[1:])
                # Offset buffer pointer by start index (times stride for inner dims).
                stride = reduce(
                    lambda l, r: self.append(ir.Arith(ast.Mult(loc=None), l, r)),
                    lengths[1:], ir.Constant(1, lengths[0].type))
                offset = self.append(
                    ir.Arith(ast.Mult(loc=None), stride, mapped_start_index))
                buffer = self.append(ir.GetAttr(value, "buffer"))
                new_buffer = self.append(ir.Offset(buffer, offset))
                return self.append(ir.Alloc([new_buffer, new_shape], node.type))
            else:
                if node.slice.step is not None:
                    try:
                        old_assign, self.current_assign = self.current_assign, None
@ -2038,11 +2219,13 @@ class ARTIQIRGenerator(algorithm.Visitor):
        return phi
    # Keep this function with builtins.TException.attributes.
-    def alloc_exn(self, typ, message=None, param0=None, param1=None, param2=None):
+    def alloc_exn(self, typ, message=None, param0=None, param1=None,
                  param2=None, nomsgcheck=False):
        typ = typ.find()
        name = "{}:{}".format(typ.id, typ.name)
        name_id = self.embedding_map.store_str(name)
        attributes = [
-            ir.Constant(name,           builtins.TStr()),   # typeinfo
+            ir.Constant(name_id,        builtins.TInt32()),   # typeinfo
            ir.Constant("<not thrown>", builtins.TStr()),   # file
            ir.Constant(0,              builtins.TInt32()), # line
            ir.Constant(0,              builtins.TInt32()), # column
@ -2051,8 +2234,16 @@ class ARTIQIRGenerator(algorithm.Visitor):
        if message is None:
            attributes.append(ir.Constant(typ.name, builtins.TStr()))
-        else:
+        elif isinstance(message, ir.Constant) or nomsgcheck:
            attributes.append(message)                  # message
        else:
            diag = diagnostic.Diagnostic(
                "error",
                "only constant exception messages are supported",
                {},
                self.current_loc if message.loc is None else message.loc
            )
            self.engine.process(diag)
        param_type = builtins.TInt64()
        for param in [param0, param1, param2]:
@ -2340,6 +2531,33 @@ class ARTIQIRGenerator(algorithm.Visitor):
                or types.is_builtin(typ, "at_mu"):
            return self.append(ir.Builtin(typ.name,
                                          [self.visit(arg) for arg in node.args], node.type))
        elif types.is_builtin(typ, "subkernel_await"):
            if len(node.args) == 2 and len(node.keywords) == 0:
                fn = node.args[0].type
                timeout = self.visit(node.args[1])
            elif len(node.args) == 1 and len(node.keywords) == 0:
                fn = node.args[0].type
                timeout = ir.Constant(10_000, builtins.TInt64())
            else:
                assert False
            if types.is_method(fn):
                fn = types.get_method_function(fn)
            sid = ir.Constant(fn.sid, builtins.TInt32())
            if not builtins.is_none(fn.ret):
                ret = self.append(ir.Builtin("subkernel_retrieve_return", [sid, timeout], fn.ret))
            else:
                ret = ir.Constant(None, builtins.TNone())
            self.append(ir.Builtin("subkernel_await_finish", [sid, timeout], builtins.TNone()))
            return ret
        elif types.is_builtin(typ, "subkernel_preload"):
            if len(node.args) == 1 and len(node.keywords) == 0:
                fn = node.args[0].type
            else:
                assert False
            if types.is_method(fn):
                fn = types.get_method_function(fn)
            sid = ir.Constant(fn.sid, builtins.TInt32())
            return self.append(ir.Builtin("subkernel_preload", [sid], builtins.TNone()))
        elif types.is_exn_constructor(typ):
            return self.alloc_exn(node.type, *[self.visit(arg_node) for arg_node in node.args])
        elif types.is_constructor(typ):
@ -2351,8 +2569,8 @@ class ARTIQIRGenerator(algorithm.Visitor):
                node.loc)
            self.engine.process(diag)
-    def _user_call(self, callee, positional, keywords, arg_exprs={}):
+    def _user_call(self, callee, positional, keywords, arg_exprs={}, remote_fn=False):
-        if types.is_function(callee.type) or types.is_rpc(callee.type):
+        if types.is_function(callee.type) or types.is_rpc(callee.type) or types.is_subkernel(callee.type):
            func     = callee
            self_arg = None
            fn_typ   = callee.type
@ -2367,16 +2585,51 @@ class ARTIQIRGenerator(algorithm.Visitor):
        else:
            assert False
-        if types.is_rpc(fn_typ):
+        if types.is_rpc(fn_typ) or types.is_subkernel(fn_typ):
-            if self_arg is None:
+            if self_arg is None or types.is_subkernel(fn_typ):
                # self is not passed to subkernels by remote
                args = positional
-            else:
+            elif self_arg is not None:
                args = [self_arg] + positional
            for keyword in keywords:
                arg = keywords[keyword]
                args.append(self.append(ir.Alloc([ir.Constant(keyword, builtins.TStr()), arg],
                                                 ir.TKeyword(arg.type))))
        elif remote_fn:
            assert self_arg is None
            assert len(fn_typ.args) >= len(positional)
            assert len(keywords) == 0  # no keyword support
            args = [None] * fn_typ.arity()
            index = 0
            # fill in first available args
            for arg in positional:
                args[index] = arg
                index += 1
            # remaining args are received through DRTIO
            if index < len(args):
                # min/max args received remotely (minus already filled)
                offset = index
                min_args = ir.Constant(len(fn_typ.args)-offset, builtins.TInt8())
                max_args = ir.Constant(fn_typ.arity()-offset, builtins.TInt8())
                arg_types = list(fn_typ.args.items())[offset:] 
                arg_type_list = [a[1] for a in arg_types] + [a[1] for a in fn_typ.optargs.items()]
                rcvd_count = self.append(ir.SubkernelAwaitArgs([min_args, max_args], arg_type_list))
                # obligatory arguments
                for arg_name, arg_type in arg_types:
                    args[index] = self.append(ir.GetArgFromRemote(arg_name, arg_type,
                                            name="ARG.{}".format(arg_name)))
                    index += 1
                # optional arguments
                for optarg_name, optarg_type in fn_typ.optargs.items():
                    idx = ir.Constant(index-offset, builtins.TInt8())
                    args[index] = \
                        self.append(ir.GetOptArgFromRemote(optarg_name, optarg_type, rcvd_count, idx))
                    index += 1
        else:
            args = [None] * (len(fn_typ.args) + len(fn_typ.optargs))
@ -2462,7 +2715,8 @@ class ARTIQIRGenerator(algorithm.Visitor):
            else:
                assert False, "Broadcasting for {} arguments not implemented".format(len)
        else:
-            insn = self._user_call(callee, args, keywords, node.arg_exprs)
+            remote_fn = getattr(node, "remote_fn", False)
            insn = self._user_call(callee, args, keywords, node.arg_exprs, remote_fn)
            if isinstance(node.func, asttyped.AttributeT):
                attr_node = node.func
                self.method_map[(attr_node.value.type.find(),
@ -2513,11 +2767,12 @@ class ARTIQIRGenerator(algorithm.Visitor):
            old_final_branch, self.final_branch = self.final_branch, None
            old_unwind, self.unwind_target = self.unwind_target, None
-            exn = self.alloc_exn(builtins.TException("AssertionError"), message=msg)
+            exn = self.alloc_exn(builtins.TException("AssertionError"),
-            self.append(ir.SetAttr(exn, "__file__", file))
+                                 message=msg, nomsgcheck=True)
-            self.append(ir.SetAttr(exn, "__line__", line))
+            self.append(ir.SetAttr(exn, "#__file__", file))
-            self.append(ir.SetAttr(exn, "__col__", col))
+            self.append(ir.SetAttr(exn, "#__line__", line))
-            self.append(ir.SetAttr(exn, "__func__", function))
+            self.append(ir.SetAttr(exn, "#__col__", col))
            self.append(ir.SetAttr(exn, "#__func__", function))
            self.append(ir.Raise(exn))
        finally:
            self.current_function = old_func
@ -2653,14 +2908,15 @@ class ARTIQIRGenerator(algorithm.Visitor):
                format_string += ")"
            elif builtins.is_exception(value.type):
-                name    = self.append(ir.GetAttr(value, "__name__"))
+                # message may not be an actual string...
-                message = self.append(ir.GetAttr(value, "__message__"))
+                # so we cannot really print it
-                param1  = self.append(ir.GetAttr(value, "__param0__"))
+                name    = self.append(ir.GetAttr(value, "#__name__"))
-                param2  = self.append(ir.GetAttr(value, "__param1__"))
+                param1  = self.append(ir.GetAttr(value, "#__param0__"))
-                param3  = self.append(ir.GetAttr(value, "__param2__"))
+                param2  = self.append(ir.GetAttr(value, "#__param1__"))
                param3  = self.append(ir.GetAttr(value, "#__param2__"))
-                format_string += "%.*s(%.*s, %lld, %lld, %lld)"
+                format_string += "%ld(%lld, %lld, %lld)"
-                args += [name, message, param1, param2, param3]
+                args += [name, param1, param2, param3]
            else:
                assert False
--- a/artiq/compiler/transforms/asttyped_rewriter.py
+++ b/artiq/compiler/transforms/asttyped_rewriter.py
@ -238,7 +238,7 @@ class ASTTypedRewriter(algorithm.Transformer):
            body=node.body, decorator_list=node.decorator_list,
            keyword_loc=node.keyword_loc, name_loc=node.name_loc,
            arrow_loc=node.arrow_loc, colon_loc=node.colon_loc, at_locs=node.at_locs,
-            loc=node.loc)
+            loc=node.loc, remote_fn=False)
        try:
            self.env_stack.append(node.typing_env)
@ -440,7 +440,8 @@ class ASTTypedRewriter(algorithm.Transformer):
    def visit_Call(self, node):
        node = self.generic_visit(node)
        node = asttyped.CallT(type=types.TVar(), iodelay=None, arg_exprs={}, 
-                              func=node.func, args=node.args, keywords=node.keywords,
+                              remote_fn=False, func=node.func, 
                              args=node.args, keywords=node.keywords, 
                              starargs=node.starargs, kwargs=node.kwargs,
                              star_loc=node.star_loc, dstar_loc=node.dstar_loc,
                              begin_loc=node.begin_loc, end_loc=node.end_loc, loc=node.loc)
--- a/artiq/compiler/transforms/dead_code_eliminator.py
+++ b/artiq/compiler/transforms/dead_code_eliminator.py
@ -15,13 +15,26 @@ class DeadCodeEliminator:
            self.process_function(func)
    def process_function(self, func):
-        modified = True
+        # defer removing those blocks, so our use checks will ignore deleted blocks
-        while modified:
+        preserve = [func.entry()]
-            modified = False
+        work_list = [func.entry()]
-            for block in list(func.basic_blocks):
+        while any(work_list):
-                if not any(block.predecessors()) and block != func.entry():
+            block = work_list.pop()
            for succ in block.successors():
                if succ not in preserve:
                    preserve.append(succ)
                    work_list.append(succ)
        to_be_removed = []
        for block in func.basic_blocks:
            if block not in preserve:
                block.is_removed = True
                to_be_removed.append(block)
                for insn in block.instructions:
                    insn.is_removed = True
        for block in to_be_removed:
            self.remove_block(block)
                    modified = True
        modified = True
        while modified:
@ -42,6 +55,8 @@ class DeadCodeEliminator:
    def remove_block(self, block):
        # block.uses are updated while iterating
        for use in set(block.uses):
            if use.is_removed:
                continue
            if isinstance(use, ir.Phi):
                use.remove_incoming_block(block)
                if not any(use.operands):
@ -56,6 +71,8 @@ class DeadCodeEliminator:
    def remove_instruction(self, insn):
        for use in set(insn.uses):
            if use.is_removed:
                continue
            if isinstance(use, ir.Phi):
                use.remove_incoming_value(insn)
                if not any(use.operands):
--- a/artiq/compiler/transforms/inferencer.py
+++ b/artiq/compiler/transforms/inferencer.py
@ -6,6 +6,29 @@ from collections import OrderedDict
 from pythonparser import algorithm, diagnostic, ast
 from .. import asttyped, types, builtins
 from .typedtree_printer import TypedtreePrinter
 from artiq.experiment import kernel
 def is_nested_empty_list(node):
    """If the passed AST node is an empty list, or a regularly nested list thereof,
    returns the number of nesting layers, or ``None`` otherwise.
    For instance, ``is_nested_empty_list([]) == 1`` and
    ``is_nested_empty_list([[], []]) == 2``, but
    ``is_nested_empty_list([[[]], []]) == None`` as the number of nesting layers doesn't
    match.
    """
    if not isinstance(node, ast.List):
        return None
    if not node.elts:
        return 1
    result = is_nested_empty_list(node.elts[0])
    if result is None:
        return None
    for elt in node.elts[:1]:
        if result != is_nested_empty_list(elt):
            return None
    return result + 1
 class Inferencer(algorithm.Visitor):
@ -23,6 +46,7 @@ class Inferencer(algorithm.Visitor):
        self.function = None # currently visited function, for Return inference
        self.in_loop = False
        self.has_return = False
        self.subkernel_arg_types = dict()
    def _unify(self, typea, typeb, loca, locb, makenotes=None, when=""):
        try:
@ -155,7 +179,7 @@ class Inferencer(algorithm.Visitor):
                    # Convert to a method.
                    attr_type = types.TMethod(object_type, attr_type)
                    self._unify_method_self(attr_type, attr_name, attr_loc, loc, value_node.loc)
-                elif types.is_rpc(attr_type):
+                elif types.is_rpc(attr_type) or types.is_subkernel(attr_type):
                    # Convert to a method. We don't have to bother typechecking
                    # the self argument, since for RPCs anything goes.
                    attr_type = types.TMethod(object_type, attr_type)
@ -216,6 +240,7 @@ class Inferencer(algorithm.Visitor):
                        value.loc, None)
    def visit_SliceT(self, node):
        self.generic_visit(node)
        if (node.lower, node.upper, node.step) == (None, None, None):
            self._unify(node.type, builtins.TInt32(),
                        node.loc, None)
@ -235,7 +260,31 @@ class Inferencer(algorithm.Visitor):
    def visit_SubscriptT(self, node):
        self.generic_visit(node)
-        if isinstance(node.slice, ast.Index):
+
        if types.is_tuple(node.value.type):
            if (not isinstance(node.slice, ast.Index) or
                not isinstance(node.slice.value, ast.Num)):
                diag = diagnostic.Diagnostic(
                    "error", "tuples can only be indexed by a constant", {},
                    node.slice.loc, []
                )
                self.engine.process(diag)
                return
            tuple_type = node.value.type.find()
            index = node.slice.value.n
            if index < 0 or index >= len(tuple_type.elts):
                diag = diagnostic.Diagnostic(
                    "error",
                    "index {index} is out of range for tuple of size {size}",
                    {"index": index, "size": len(tuple_type.elts)},
                    node.slice.loc, []
                )
                self.engine.process(diag)
                return
            self._unify(node.type, tuple_type.elts[index], node.loc, node.value.loc)
        elif isinstance(node.slice, ast.Index):
            if types.is_tuple(node.slice.value.type):
                if types.is_var(node.value.type):
                    return
@ -268,12 +317,21 @@ class Inferencer(algorithm.Visitor):
            else:
                self._unify_iterable(element=node, collection=node.value)
        elif isinstance(node.slice, ast.Slice):
            if builtins.is_array(node.value.type):
                if node.slice.step is not None:
                    diag = diagnostic.Diagnostic(
                        "error",
                        "strided slicing not yet supported for NumPy arrays", {},
                        node.slice.step.loc, [])
                    self.engine.process(diag)
                    return
            self._unify(node.type, node.value.type, node.loc, node.value.loc)
        else:  # ExtSlice
            pass  # error emitted above
    def visit_IfExpT(self, node):
        self.generic_visit(node)
        self._unify(node.test.type, builtins.TBool(), node.test.loc, None)
        self._unify(node.body.type, node.orelse.type,
                    node.body.loc, node.orelse.loc)
        self._unify(node.type, node.body.type,
@ -882,21 +940,38 @@ class Inferencer(algorithm.Visitor):
            if len(node.args) == 1 and keywords_acceptable:
                arg, = node.args
                num_empty_dims = is_nested_empty_list(arg)
                if num_empty_dims is not None:
                    # As a special case, following the behaviour of numpy.array (and
                    # repr() on ndarrays), consider empty lists to be exactly of the
                    # number of dimensions given, instead of potentially containing an
                    # unknown number of extra dimensions.
                    num_dims = num_empty_dims
                    # The ultimate element type will be TVar initially, but we might be
                    # able to resolve it from context.
                    elt = arg.type
                    for _ in range(num_dims):
                        assert builtins.is_list(elt)
                        elt = elt.find()["elt"]
                else:
                    # In the absence of any other information (there currently isn't a way
                    # to specify any), assume that all iterables are expandable into a
                    # (runtime-checked) rectangular array of the innermost element type.
                    elt = arg.type
                    num_dims = 0
-                result_dims = (node.type.find()["num_dims"].value
+                    expected_dims = (node.type.find()["num_dims"].value
                                    if builtins.is_array(node.type) else -1)
                    while True:
-                    if num_dims == result_dims:
+                        if num_dims == expected_dims:
                            # If we already know the number of dimensions of the result,
                            # stop so we can disambiguate the (innermost) element type of
-                        # the argument if it is still unknown (e.g. empty array).
+                            # the argument if it is still unknown.
                            break
                        if types.is_var(elt):
-                        return  # undetermined yet
+                            # Can't make progress here because we don't know how many more
                            # dimensions might be "hidden" inside.
                            return
                        if not builtins.is_iterable(elt) or builtins.is_str(elt):
                            break
                        if builtins.is_array(elt):
@ -1219,6 +1294,55 @@ class Inferencer(algorithm.Visitor):
            # Ignored.
            self._unify(node.type, builtins.TNone(),
                        node.loc, None)
        elif types.is_builtin(typ, "subkernel_await"):
            valid_forms = lambda: [
                valid_form("subkernel_await(f: subkernel) -> f return type"),
                valid_form("subkernel_await(f: subkernel, timeout: numpy.int64) -> f return type")
            ]
            if 1 <= len(node.args) <= 2:
                arg0 = node.args[0].type
                if types.is_var(arg0):
                    pass  # undetermined yet
                else:
                    if types.is_method(arg0):
                        fn = types.get_method_function(arg0)
                    elif types.is_function(arg0) or types.is_subkernel(arg0):
                        fn = arg0
                    else:
                        diagnose(valid_forms())
                    self._unify(node.type, fn.ret,
                                node.loc, None)
                if len(node.args) == 2:
                    arg1 = node.args[1]
                    if types.is_var(arg1.type):
                        pass
                    elif builtins.is_int(arg1.type):
                        # promote to TInt64
                        self._unify(arg1.type, builtins.TInt64(),
                                    arg1.loc, None)
                    else:
                        diagnose(valid_forms())
            else:
                diagnose(valid_forms())
        elif types.is_builtin(typ, "subkernel_preload"):
            valid_forms = lambda: [
                valid_form("subkernel_preload(f: subkernel) -> None")
            ]
            if len(node.args) == 1:
                arg0 = node.args[0].type
                if types.is_var(arg0):
                    pass  # undetermined yet
                else:
                    if types.is_method(arg0):
                        fn = types.get_method_function(arg0)
                    elif types.is_function(arg0) or types.is_subkernel(arg0):
                        fn = arg0
                    else:
                        diagnose(valid_forms())
                    self._unify(node.type, fn.ret,
                                node.loc, None)
            else:
                diagnose(valid_forms())
        else:
            assert False
@ -1257,6 +1381,7 @@ class Inferencer(algorithm.Visitor):
            typ_args    = typ.args
            typ_optargs = typ.optargs
            typ_ret     = typ.ret
            typ_func    = typ
        else:
            typ_self    = types.get_method_self(typ)
            typ_func    = types.get_method_function(typ)
@ -1314,12 +1439,23 @@ class Inferencer(algorithm.Visitor):
                                                    other_node=node.args[0])
                    self._unify(node.type, ret, node.loc, None)
                    return
        if types.is_subkernel(typ_func) and typ_func.sid not in self.subkernel_arg_types:
            self.subkernel_arg_types[typ_func.sid] = []
        for actualarg, (formalname, formaltyp) in \
                zip(node.args, list(typ_args.items()) + list(typ_optargs.items())):
            self._unify(actualarg.type, formaltyp,
                        actualarg.loc, None)
            passed_args[formalname] = actualarg.loc
            if types.is_subkernel(typ_func):
                if types.is_instance(actualarg.type):
                    # objects cannot be passed to subkernels, as rpc code doesn't support them
                    diag = diagnostic.Diagnostic("error",
                        "argument '{name}' of type: {typ} is not supported in subkernels",
                        {"name": formalname, "typ": actualarg.type},
                        actualarg.loc, [])
                    self.engine.process(diag)
                self.subkernel_arg_types[typ_func.sid].append((formalname, formaltyp))
        for keyword in node.keywords:
            if keyword.arg in passed_args:
@ -1350,7 +1486,7 @@ class Inferencer(algorithm.Visitor):
            passed_args[keyword.arg] = keyword.arg_loc
        for formalname in typ_args:
-            if formalname not in passed_args:
+            if formalname not in passed_args and not node.remote_fn:
                note = diagnostic.Diagnostic("note",
                    "the called function is of type {type}",
                    {"type": types.TypePrinter().name(node.func.type)},
@ -1613,7 +1749,14 @@ class Inferencer(algorithm.Visitor):
    def visit_FunctionDefT(self, node):
        for index, decorator in enumerate(node.decorator_list):
-            if types.is_builtin(decorator.type, "kernel") or \
+            def eval_attr(attr):
                if isinstance(attr.value, asttyped.QuoteT):
                    return getattr(attr.value.value, attr.attr)
                return getattr(eval_attr(attr.value), attr.attr)
            if isinstance(decorator, asttyped.AttributeT):
                decorator = eval_attr(decorator)
            if id(decorator) == id(kernel) or \
                    types.is_builtin(decorator.type, "kernel") or \
                    isinstance(decorator, asttyped.CallT) and \
                    types.is_builtin(decorator.func.type, "kernel"):
                continue
--- a/artiq/compiler/transforms/iodelay_estimator.py
+++ b/artiq/compiler/transforms/iodelay_estimator.py
@ -280,7 +280,7 @@ class IODelayEstimator(algorithm.Visitor):
                                  context="as an argument for delay_mu()")
            call_delay = value
        elif not types.is_builtin(typ):
-            if types.is_function(typ) or types.is_rpc(typ):
+            if types.is_function(typ) or types.is_rpc(typ) or types.is_subkernel(typ):
                offset = 0
            elif types.is_method(typ):
                offset = 1
@ -288,7 +288,7 @@ class IODelayEstimator(algorithm.Visitor):
            else:
                assert False
-            if types.is_rpc(typ):
+            if types.is_rpc(typ) or types.is_subkernel(typ):
                call_delay = iodelay.Const(0)
            else:
                delay = typ.find().delay.find()
@ -311,6 +311,7 @@ class IODelayEstimator(algorithm.Visitor):
                        args[arg_name] = arg_node
                    free_vars = delay.duration.free_vars()
                    try:
                        node.arg_exprs = {
                            arg: self.evaluate(args[arg], abort=abort,
                                            context="in the expression for argument '{}' "
@ -318,6 +319,12 @@ class IODelayEstimator(algorithm.Visitor):
                            for arg in free_vars
                        }
                        call_delay = delay.duration.fold(node.arg_exprs)
                    except KeyError as e:
                        if getattr(node, "remote_fn", False):
                            note = diagnostic.Diagnostic("note",
                                "function called here", {},
                                node.loc)
                            self.abort("due to arguments passed remotely", node.loc, note)
                else:
                    assert False
        else:
--- a/artiq/compiler/transforms/llvm_ir_generator.py
+++ b/artiq/compiler/transforms/llvm_ir_generator.py
--- a/artiq/compiler/types.py
+++ b/artiq/compiler/types.py
@ -3,6 +3,7 @@ The :mod:`types` module contains the classes describing the types
 in :mod:`asttyped`.
 """
 import builtins
 import string
 from collections import OrderedDict
 from . import iodelay
@ -55,40 +56,39 @@ class TVar(Type):
    def __init__(self):
        self.parent = self
        self.rank = 0
    def find(self):
-        if self.parent is self:
+        parent = self.parent
        if parent is self:
            return self
        else:
            # The recursive find() invocation is turned into a loop
            # because paths resulting from unification of large arrays
            # can easily cause a stack overflow.
            root = self
-            while root.__class__ == TVar:
+            while parent.__class__ == TVar and root is not parent:
-                if root is root.parent:
+                _, parent = root, root.parent = parent, parent.parent
-                    break
+            return root.parent
                else:
                    root = root.parent
            # path compression
            iter = self
            while iter.__class__ == TVar:
                if iter is root:
                    break
                else:
                    iter, iter.parent = iter.parent, root
            return root
    def unify(self, other):
        if other is self:
            return
-        other = other.find()
+        x = other.find()
-
+        y = self.find()
-        if self.parent is self:
+        if x is y:
-            self.parent = other
+            return
        if y.__class__ == TVar:
            if x.__class__ == TVar:
                if x.rank < y.rank:
                    x, y = y, x
                y.parent = x
                if x.rank == y.rank:
                    x.rank += 1
            else:
-            self.find().unify(other)
+                y.parent = x
        else:
            y.unify(x)
    def fold(self, accum, fn):
        if self.parent is self:
@ -97,6 +97,8 @@ class TVar(Type):
            return self.find().fold(accum, fn)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        if self.parent is self:
            return "<artiq.compiler.types.TVar %d>" % id(self)
        else:
@ -143,6 +145,8 @@ class TMono(Type):
        return fn(accum, self)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
                return str(self)
        return "artiq.compiler.types.TMono(%s, %s)" % (repr(self.name), repr(self.params))
    def __getitem__(self, param):
@ -191,6 +195,8 @@ class TTuple(Type):
        return fn(accum, self)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        return "artiq.compiler.types.TTuple(%s)" % repr(self.elts)
    def __eq__(self, other):
@ -269,6 +275,8 @@ class TFunction(Type):
        return fn(accum, self)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        return "artiq.compiler.types.TFunction({}, {}, {})".format(
            repr(self.args), repr(self.optargs), repr(self.ret))
@ -296,7 +304,7 @@ class TExternalFunction(TFunction):
        mangling rules).
    :ivar flags: (set of str) function flags.
        Flag ``nounwind`` means the function never raises an exception.
-        Flag ``nowrite`` means the function never writes any memory
+        Flag ``nowrite`` means the function never accesses any memory
        that the ARTIQ Python code can observe.
    :ivar broadcast_across_arrays: (bool)
        If True, the function is transparently applied element-wise when called
@ -362,6 +370,8 @@ class TRPC(Type):
        return fn(accum, self)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        return "artiq.compiler.types.TRPC({})".format(repr(self.ret))
    def __eq__(self, other):
@ -375,6 +385,50 @@ class TRPC(Type):
    def __hash__(self):
        return hash(self.service)
 class TSubkernel(TFunction):
    """
    A kernel to be run on a satellite.
    :ivar args: (:class:`collections.OrderedDict` of string to :class:`Type`)
        function arguments
    :ivar ret: (:class:`Type`)
        return type
    :ivar sid: (int) subkernel ID number
    :ivar destination: (int) satellite destination number
    """
    attributes = OrderedDict()
    def __init__(self, args, optargs, ret, sid, destination):
        assert isinstance(ret, Type)
        super().__init__(args, optargs, ret)
        self.sid, self.destination = sid, destination
        self.delay = TFixedDelay(iodelay.Const(0))
    def unify(self, other):
        if other is self:
            return
        if isinstance(other, TSubkernel) and \
                self.sid == other.sid and \
                self.destination == other.destination:
            self.ret.unify(other.ret)
        elif isinstance(other, TVar):
            other.unify(self)
        else:
            raise UnificationError(self, other)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        return "artiq.compiler.types.TSubkernel({})".format(repr(self.ret))
    def __eq__(self, other):
        return isinstance(other, TSubkernel) and \
                self.sid == other.sid
    def __hash__(self):
        return hash(self.sid)
 class TBuiltin(Type):
    """
    An instance of builtin type. Every instance of a builtin
@ -399,6 +453,8 @@ class TBuiltin(Type):
        return fn(accum, self)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        return "artiq.compiler.types.{}({})".format(type(self).__name__, repr(self.name))
    def __eq__(self, other):
@ -459,6 +515,8 @@ class TInstance(TMono):
        self.constant_attributes = set()
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        return "artiq.compiler.types.TInstance({}, {})".format(
                    repr(self.name), repr(self.attributes))
@ -474,6 +532,8 @@ class TModule(TMono):
        self.constant_attributes = set()
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        return "artiq.compiler.types.TModule({}, {})".format(
                    repr(self.name), repr(self.attributes))
@ -513,6 +573,8 @@ class TValue(Type):
        return fn(accum, self)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        return "artiq.compiler.types.TValue(%s)" % repr(self.value)
    def __eq__(self, other):
@ -571,6 +633,8 @@ class TDelay(Type):
        return not (self == other)
    def __repr__(self):
        if getattr(builtins, "__in_sphinx__", False):
            return str(self)
        if self.duration is None:
            return "<{}.TIndeterminateDelay>".format(__name__)
        elif self.cause is None:
@ -624,6 +688,9 @@ def is_function(typ):
 def is_rpc(typ):
    return isinstance(typ.find(), TRPC)
 def is_subkernel(typ):
    return isinstance(typ.find(), TSubkernel)
 def is_external_function(typ, name=None):
    typ = typ.find()
    if name is None:
@ -790,6 +857,10 @@ class TypePrinter(object):
            return "[rpc{} #{}](...)->{}".format(typ.service,
                                                 " async" if typ.is_async else "",
                                                 self.name(typ.ret, depth + 1))
        elif isinstance(typ, TSubkernel):
            return "<subkernel{} dest#{}>->{}".format(typ.sid,
                                                      typ.destination,
                                                      self.name(typ.ret, depth + 1))
        elif isinstance(typ, TBuiltinFunction):
            return "<function {}>".format(typ.name)
        elif isinstance(typ, (TConstructor, TExceptionConstructor)):
--- a/artiq/compiler/validators/escape.py
+++ b/artiq/compiler/validators/escape.py
@ -102,7 +102,19 @@ class RegionOf(algorithm.Visitor):
        if types.is_external_function(node.func.type, "cache_get"):
            # The cache is borrow checked dynamically
            return Global()
-        else:
+
        if (types.is_builtin_function(node.func.type, "array")
              or types.is_builtin_function(node.func.type, "make_array")
              or types.is_builtin_function(node.func.type, "numpy.transpose")):
            # While lifetime tracking across function calls in general is currently
            # broken (see below), these special builtins that allocate an array on
            # the stack of the caller _always_ allocate regardless of the parameters,
            # and we can thus handle them without running into the precision issue
            # mentioned in commit ae999db.
            return self.visit_allocating(node)
        # FIXME: Return statement missing here, but see m-labs/artiq#1497 and
        # commit ae999db.
        self.visit_sometimes_allocating(node)
    # Value lives as long as the object/container, if it's mutable,
--- a/artiq/coredevice/ad53xx.py
+++ b/artiq/coredevice/ad53xx.py
@ -127,9 +127,9 @@ class AD53xx:
      transactions (default: 1)
    :param div_write: SPI clock divider for write operations (default: 4,
      50MHz max SPI clock with {t_high, t_low} >=8ns)
-    :param div_read: SPI clock divider for read operations (default: 8, not
+    :param div_read: SPI clock divider for read operations (default: 16, not
-      optimized for speed, but cf data sheet t22: 25ns min SCLK edge to SDO
+      optimized for speed; datasheet says t22: 25ns min SCLK edge to SDO
-      valid)
+      valid, and suggests the SPI speed for reads should be <=20 MHz)
    :param vref: DAC reference voltage (default: 5.)
    :param offset_dacs: Initial register value for the two offset DACs, device
      dependent and must be set correctly for correct voltage to mu
@ -233,7 +233,7 @@ class AD53xx:
    def write_gain_mu(self, channel, gain=0xffff):
        """Program the gain register for a DAC channel.
-        The DAC output is not updated until LDAC is pulsed (see :meth load:).
+        The DAC output is not updated until LDAC is pulsed (see :meth:`load`).
        This method advances the timeline by the duration of one SPI transfer.
        :param gain: 16-bit gain register value (default: 0xffff)
@ -245,7 +245,7 @@ class AD53xx:
    def write_offset_mu(self, channel, offset=0x8000):
        """Program the offset register for a DAC channel.
-        The DAC output is not updated until LDAC is pulsed (see :meth load:).
+        The DAC output is not updated until LDAC is pulsed (see :meth:`load`).
        This method advances the timeline by the duration of one SPI transfer.
        :param offset: 16-bit offset register value (default: 0x8000)
@ -258,7 +258,7 @@ class AD53xx:
        """Program the DAC offset voltage for a channel.
        An offset of +V can be used to trim out a DAC offset error of -V.
-        The DAC output is not updated until LDAC is pulsed (see :meth load:).
+        The DAC output is not updated until LDAC is pulsed (see :meth:`load`).
        This method advances the timeline by the duration of one SPI transfer.
        :param voltage: the offset voltage
@ -270,7 +270,7 @@ class AD53xx:
    def write_dac_mu(self, channel, value):
        """Program the DAC input register for a channel.
-        The DAC output is not updated until LDAC is pulsed (see :meth load:).
+        The DAC output is not updated until LDAC is pulsed (see :meth:`load`).
        This method advances the timeline by the duration of one SPI transfer.
        """
        self.bus.write(
@ -280,7 +280,7 @@ class AD53xx:
    def write_dac(self, channel, voltage):
        """Program the DAC output voltage for a channel.
-        The DAC output is not updated until LDAC is pulsed (see :meth load:).
+        The DAC output is not updated until LDAC is pulsed (see :meth:`load`).
        This method advances the timeline by the duration of one SPI transfer.
        """
        self.write_dac_mu(channel, voltage_to_mu(voltage, self.offset_dacs,
@ -313,7 +313,7 @@ class AD53xx:
        If no LDAC device was defined, the LDAC pulse is skipped.
-        See :meth load:.
+        See :meth:`load`.
        :param values: list of DAC values to program
        :param channels: list of DAC channels to program. If not specified,
@ -355,7 +355,7 @@ class AD53xx:
        """ Two-point calibration of a DAC channel.
        Programs the offset and gain register to trim out DAC errors. Does not
-        take effect until LDAC is pulsed (see :meth load:).
+        take effect until LDAC is pulsed (see :meth:`load`).
        Calibration consists of measuring the DAC output voltage for a channel
        with the DAC set to zero-scale (0x0000) and full-scale (0xffff).
--- a/artiq/coredevice/ad9154_reg.py
+++ b/artiq/coredevice/ad9154_reg.py
--- a/artiq/coredevice/ad9154_spi.py
+++ b/artiq/coredevice/ad9154_spi.py
@ -1,23 +0,0 @@
 from artiq.language.core import kernel
 class AD9154:
    """Kernel interface to AD9154 registers, using non-realtime SPI."""
    def __init__(self, dmgr, spi_device, chip_select):
        self.core = dmgr.get("core")
        self.bus = dmgr.get(spi_device)
        self.chip_select = chip_select
    @kernel
    def setup_bus(self, div=16):
        self.bus.set_config_mu(0, 24, div, self.chip_select)
    @kernel
    def write(self, addr, data):
        self.bus.write((addr << 16) | (data<< 8))
    @kernel
    def read(self, addr):
        self.write((1 << 15) | addr, 0)
        return self.bus.read()
--- a/artiq/coredevice/ad9910.py
+++ b/artiq/coredevice/ad9910.py
@ -3,15 +3,16 @@ from numpy import int32, int64
 from artiq.language.core import (
    kernel, delay, portable, delay_mu, now_mu, at_mu)
 from artiq.language.units import us, ms
-from artiq.language.types import *
+from artiq.language.types import TBool, TInt32, TInt64, TFloat, TList, TTuple
 from artiq.coredevice import spi2 as spi
 from artiq.coredevice import urukul
 from artiq.coredevice.urukul import DEFAULT_PROFILE
 # Work around ARTIQ-Python import machinery
 urukul_sta_pll_lock = urukul.urukul_sta_pll_lock
 urukul_sta_smp_err = urukul.urukul_sta_smp_err
 __all__ = [
    "AD9910",
    "PHASE_MODE_CONTINUOUS", "PHASE_MODE_ABSOLUTE", "PHASE_MODE_TRACKING",
@ -20,7 +21,6 @@ __all__ = [
    "RAM_MODE_CONT_BIDIR_RAMP", "RAM_MODE_CONT_RAMPUP",
 ]
 _PHASE_MODE_DEFAULT = -1
 PHASE_MODE_CONTINUOUS = 0
 PHASE_MODE_ABSOLUTE = 1
@ -61,6 +61,9 @@ RAM_MODE_BIDIR_RAMP = 2
 RAM_MODE_CONT_BIDIR_RAMP = 3
 RAM_MODE_CONT_RAMPUP = 4
 # Default profile for RAM mode
 _DEFAULT_PROFILE_RAM = 0
 class SyncDataUser:
    def __init__(self, core, sync_delay_seed, io_update_delay):
@ -124,22 +127,24 @@ class AD9910:
        To stabilize the SYNC_IN delay tuning, run :meth:`tune_sync_delay` once
        and set this to the delay tap number returned (default: -1 to signal no
        synchronization and no tuning during :meth:`init`).
-        Can be a string of the form "eeprom_device:byte_offset" to read the value
+        Can be a string of the form "eeprom_device:byte_offset" to read the
-        from a I2C EEPROM; in which case, `io_update_delay` must be set to the
+        value from a I2C EEPROM; in which case, `io_update_delay` must be set
-        same string value.
+        to the same string value.
    :param io_update_delay: IO_UPDATE pulse alignment delay.
        To align IO_UPDATE to SYNC_CLK, run :meth:`tune_io_update_delay` and
        set this to the delay tap number returned.
-        Can be a string of the form "eeprom_device:byte_offset" to read the value
+        Can be a string of the form "eeprom_device:byte_offset" to read the
-        from a I2C EEPROM; in which case, `sync_delay_seed` must be set to the
+        value from a I2C EEPROM; in which case, `sync_delay_seed` must be set
-        same string value.
+        to the same string value.
    """
    kernel_invariants = {"chip_select", "cpld", "core", "bus",
                         "ftw_per_hz", "sysclk_per_mu"}
    def __init__(self, dmgr, chip_select, cpld_device, sw_device=None,
                 pll_n=40, pll_cp=7, pll_vco=5, sync_delay_seed=-1,
                 io_update_delay=0, pll_en=1):
        self.kernel_invariants = {"cpld", "core", "bus", "chip_select",
                                  "pll_en", "pll_n", "pll_vco", "pll_cp",
                                  "ftw_per_hz", "sysclk_per_mu", "sysclk",
                                  "sync_data"}
        self.cpld = dmgr.get(cpld_device)
        self.core = self.cpld.core
        self.bus = self.cpld.bus
@ -169,17 +174,20 @@ class AD9910:
        self.sysclk_per_mu = int(round(sysclk * self.core.ref_period))
        self.sysclk = sysclk
-        if isinstance(sync_delay_seed, str) or isinstance(io_update_delay, str):
+        if isinstance(sync_delay_seed, str) or isinstance(io_update_delay,
                                                          str):
            if sync_delay_seed != io_update_delay:
-                raise ValueError("When using EEPROM, sync_delay_seed must be equal to io_update_delay")
+                raise ValueError("When using EEPROM, sync_delay_seed must be "
                                 "equal to io_update_delay")
            self.sync_data = SyncDataEeprom(dmgr, self.core, sync_delay_seed)
        else:
-            self.sync_data = SyncDataUser(self.core, sync_delay_seed, io_update_delay)
+            self.sync_data = SyncDataUser(self.core, sync_delay_seed,
                                          io_update_delay)
        self.phase_mode = PHASE_MODE_CONTINUOUS
    @kernel
-    def set_phase_mode(self, phase_mode):
+    def set_phase_mode(self, phase_mode: TInt32):
        r"""Set the default phase mode.
        for future calls to :meth:`set` and
@ -224,7 +232,7 @@ class AD9910:
        self.phase_mode = phase_mode
    @kernel
-    def write16(self, addr, data):
+    def write16(self, addr: TInt32, data: TInt32):
        """Write to 16 bit register.
        :param addr: Register address
@ -232,10 +240,10 @@ class AD9910:
        """
        self.bus.set_config_mu(urukul.SPI_CONFIG | spi.SPI_END, 24,
                               urukul.SPIT_DDS_WR, self.chip_select)
-        self.bus.write((addr << 24) | (data << 8))
+        self.bus.write((addr << 24) | ((data & 0xffff) << 8))
    @kernel
-    def write32(self, addr, data):
+    def write32(self, addr: TInt32, data: TInt32):
        """Write to 32 bit register.
        :param addr: Register address
@ -249,7 +257,7 @@ class AD9910:
        self.bus.write(data)
    @kernel
-    def read16(self, addr):
+    def read16(self, addr: TInt32) -> TInt32:
        """Read from 16 bit register.
        :param addr: Register address
@ -264,7 +272,7 @@ class AD9910:
        return self.bus.read()
    @kernel
-    def read32(self, addr):
+    def read32(self, addr: TInt32) -> TInt32:
        """Read from 32 bit register.
        :param addr: Register address
@ -279,7 +287,7 @@ class AD9910:
        return self.bus.read()
    @kernel
-    def read64(self, addr):
+    def read64(self, addr: TInt32) -> TInt64:
        """Read from 64 bit register.
        :param addr: Register address
@ -302,7 +310,7 @@ class AD9910:
        return (int64(hi) << 32) | lo
    @kernel
-    def write64(self, addr, data_high, data_low):
+    def write64(self, addr: TInt32, data_high: TInt32, data_low: TInt32):
        """Write to 64 bit register.
        :param addr: Register address
@ -320,14 +328,14 @@ class AD9910:
        self.bus.write(data_low)
    @kernel
-    def write_ram(self, data):
+    def write_ram(self, data: TList(TInt32)):
        """Write data to RAM.
        The profile to write to and the step, start, and end address
        need to be configured before and separately using
        :meth:`set_profile_ram` and the parent CPLD `set_profile`.
-        :param data List(int32): Data to be written to RAM.
+        :param data: Data to be written to RAM.
        """
        self.bus.set_config_mu(urukul.SPI_CONFIG, 8, urukul.SPIT_DDS_WR,
                               self.chip_select)
@ -341,14 +349,14 @@ class AD9910:
        self.bus.write(data[len(data) - 1])
    @kernel
-    def read_ram(self, data):
+    def read_ram(self, data: TList(TInt32)):
        """Read data from RAM.
        The profile to read from and the step, start, and end address
        need to be configured before and separately using
        :meth:`set_profile_ram` and the parent CPLD `set_profile`.
-        :param data List(int32): List to be filled with data read from RAM.
+        :param data: List to be filled with data read from RAM.
        """
        self.bus.set_config_mu(urukul.SPI_CONFIG, 8, urukul.SPIT_DDS_WR,
                               self.chip_select)
@ -370,16 +378,25 @@ class AD9910:
            data[(n - preload) + i] = self.bus.read()
    @kernel
-    def set_cfr1(self, power_down=0b0000, phase_autoclear=0,
+    def set_cfr1(self,
-                 drg_load_lrr=0, drg_autoclear=0,
+                 power_down: TInt32 = 0b0000,
-                 internal_profile=0, ram_destination=0, ram_enable=0,
+                 phase_autoclear: TInt32 = 0,
-                 manual_osk_external=0, osk_enable=0, select_auto_osk=0):
+                 drg_load_lrr: TInt32 = 0,
                 drg_autoclear: TInt32 = 0,
                 phase_clear: TInt32 = 0,
                 internal_profile: TInt32 = 0,
                 ram_destination: TInt32 = 0,
                 ram_enable: TInt32 = 0,
                 manual_osk_external: TInt32 = 0,
                 osk_enable: TInt32 = 0,
                 select_auto_osk: TInt32 = 0):
        """Set CFR1. See the AD9910 datasheet for parameter meanings.
        This method does not pulse IO_UPDATE.
        :param power_down: Power down bits.
        :param phase_autoclear: Autoclear phase accumulator.
        :param phase_clear: Asynchronous, static reset of the phase accumulator.
        :param drg_load_lrr: Load digital ramp generator LRR.
        :param drg_autoclear: Autoclear digital ramp generator.
        :param internal_profile: Internal profile control.
@ -399,13 +416,43 @@ class AD9910:
                     (drg_load_lrr << 15) |
                     (drg_autoclear << 14) |
                     (phase_autoclear << 13) |
                     (phase_clear << 11) |
                     (osk_enable << 9) |
                     (select_auto_osk << 8) |
                     (power_down << 4) |
                     2)  # SDIO input only, MSB first
    @kernel
-    def init(self, blind=False):
+    def set_cfr2(self, 
                 asf_profile_enable: TInt32 = 1, 
                 drg_enable: TInt32 = 0, 
                 effective_ftw: TInt32 = 1,
                 sync_validation_disable: TInt32 = 0, 
                 matched_latency_enable: TInt32 = 0):
        """Set CFR2. See the AD9910 datasheet for parameter meanings.
        This method does not pulse IO_UPDATE.
        :param asf_profile_enable: Enable amplitude scale from single tone profiles.
        :param drg_enable: Digital ramp enable.
        :param effective_ftw: Read effective FTW.
        :param sync_validation_disable: Disable the SYNC_SMP_ERR pin indicating
            (active high) detection of a synchronization pulse sampling error.
        :param matched_latency_enable: Simultaneous application of amplitude,
            phase, and frequency changes to the DDS arrive at the output
            * matched_latency_enable = 0: in the order listed
            * matched_latency_enable = 1: simultaneously.
        """
        self.write32(_AD9910_REG_CFR2,
                     (asf_profile_enable << 24) |
                     (drg_enable << 19) |
                     (effective_ftw << 16) |
                     (matched_latency_enable << 7) |
                     (sync_validation_disable << 5))
    @kernel
    def init(self, blind: TBool = False):
        """Initialize and configure the DDS.
        Sets up SPI mode, confirms chip presence, powers down unused blocks,
@ -436,7 +483,7 @@ class AD9910:
        # enable amplitude scale from profiles
        # read effective FTW
        # sync timing validation disable (enabled later)
-        self.write32(_AD9910_REG_CFR2, 0x01010020)
+        self.set_cfr2(sync_validation_disable=1)
        self.cpld.io_update.pulse(1 * us)
        cfr3 = (0x0807c000 | (self.pll_vco << 24) |
                (self.pll_cp << 19) | (self.pll_en << 8) |
@ -459,12 +506,12 @@ class AD9910:
                    if i >= 100 - 1:
                        raise ValueError("PLL lock timeout")
        delay(10 * us)  # slack
-        if self.sync_data.sync_delay_seed >= 0:
+        if self.sync_data.sync_delay_seed >= 0 and not blind:
            self.tune_sync_delay(self.sync_data.sync_delay_seed)
        delay(1 * ms)
    @kernel
-    def power_down(self, bits=0b1111):
+    def power_down(self, bits: TInt32 = 0b1111):
        """Power down DDS.
        :param bits: Power down bits, see datasheet
@ -472,16 +519,17 @@ class AD9910:
        self.set_cfr1(power_down=bits)
        self.cpld.io_update.pulse(1 * us)
    # KLUDGE: ref_time_mu default argument is explicitly marked int64() to
    # avoid silent truncation of explicitly passed timestamps. (Compiler bug?)
    @kernel
-    def set_mu(self, ftw, pow_=0, asf=0x3fff, phase_mode=_PHASE_MODE_DEFAULT,
+    def set_mu(self, ftw: TInt32 = 0, pow_: TInt32 = 0, asf: TInt32 = 0x3fff,
-               ref_time_mu=int64(-1), profile=0):
+               phase_mode: TInt32 = _PHASE_MODE_DEFAULT,
-        """Set profile 0 data in machine units.
+               ref_time_mu: TInt64 = int64(-1),
               profile: TInt32 = DEFAULT_PROFILE,
               ram_destination: TInt32 = -1) -> TInt32:
        """Set DDS data in machine units.
        This uses machine units (FTW, POW, ASF). The frequency tuning word
        width is 32, the phase offset word width is 16, and the amplitude
-        scale factor width is 12.
+        scale factor width is 14.
        After the SPI transfer, the shared IO update pin is pulsed to
        activate the data.
@ -496,7 +544,13 @@ class AD9910:
            by :meth:`set_phase_mode` for this call.
        :param ref_time_mu: Fiducial time used to compute absolute or tracking
            phase updates. In machine units as obtained by `now_mu()`.
-        :param profile: Profile number to set (0-7, default: 0).
+        :param profile: Single tone profile number to set (0-7, default: 7).
            Ineffective if `ram_destination` is specified.
        :param ram_destination: RAM destination (:const:`RAM_DEST_FTW`,
            :const:`RAM_DEST_POW`, :const:`RAM_DEST_ASF`,
            :const:`RAM_DEST_POWASF`). If specified, write free DDS parameters
            to the ASF/FTW/POW registers instead of to the single tone profile
            register (default behaviour, see `profile`).
        :return: Resulting phase offset word after application of phase
            tracking offset. When using :const:`PHASE_MODE_CONTINUOUS` in
            subsequent calls, use this value as the "current" phase.
@ -519,8 +573,17 @@ class AD9910:
                # is equivalent to an output pipeline latency.
                dt = int32(now_mu()) - int32(ref_time_mu)
                pow_ += dt * ftw * self.sysclk_per_mu >> 16
        if ram_destination == -1:
            self.write64(_AD9910_REG_PROFILE0 + profile,
                         (asf << 16) | (pow_ & 0xffff), ftw)
        else:
            if not ram_destination == RAM_DEST_FTW:
                self.set_ftw(ftw)
            if not ram_destination == RAM_DEST_POWASF:
                if not ram_destination == RAM_DEST_ASF:
                    self.set_asf(asf)
                if not ram_destination == RAM_DEST_POW:
                    self.set_pow(pow_)
        delay_mu(int64(self.sync_data.io_update_delay))
        self.cpld.io_update.pulse_mu(8)  # assumes 8 mu > t_SYN_CCLK
        at_mu(now_mu() & ~7)  # clear fine TSC again
@ -530,8 +593,30 @@ class AD9910:
        return pow_
    @kernel
-    def set_profile_ram(self, start, end, step=1, profile=0, nodwell_high=0,
+    def get_mu(self, profile: TInt32 = DEFAULT_PROFILE
-                        zero_crossing=0, mode=1):
+               ) -> TTuple([TInt32, TInt32, TInt32]):
        """Get the frequency tuning word, phase offset word,
        and amplitude scale factor.
        .. seealso:: :meth:`get`
        :param profile: Profile number to get (0-7, default: 7)
        :return: A tuple ``(ftw, pow, asf)``
        """
        # Read data
        data = int64(self.read64(_AD9910_REG_PROFILE0 + profile))
        # Extract and return fields
        ftw = int32(data)
        pow_ = int32((data >> 32) & 0xffff)
        asf = int32((data >> 48) & 0x3fff)
        return ftw, pow_, asf
    @kernel
    def set_profile_ram(self, start: TInt32, end: TInt32, step: TInt32 = 1,
                        profile: TInt32 = _DEFAULT_PROFILE_RAM,
                        nodwell_high: TInt32 = 0, zero_crossing: TInt32 = 0,
                        mode: TInt32 = 1):
        """Set the RAM profile settings.
        :param start: Profile start address in RAM.
@ -555,57 +640,87 @@ class AD9910:
        self.write64(_AD9910_REG_PROFILE0 + profile, hi, lo)
    @kernel
-    def set_ftw(self, ftw):
+    def set_ftw(self, ftw: TInt32):
-        """Set the value stored to the AD9910's frequency tuning word (FTW) register.
+        """Set the value stored to the AD9910's frequency tuning word (FTW)
        register.
        :param ftw: Frequency tuning word to be stored, range: 0 to 0xffffffff.
        """
        self.write32(_AD9910_REG_FTW, ftw)
    @kernel
-    def set_asf(self, asf):
+    def set_asf(self, asf: TInt32):
-        """Set the value stored to the AD9910's amplitude scale factor (ASF) register.
+        """Set the value stored to the AD9910's amplitude scale factor (ASF)
        register.
        :param asf: Amplitude scale factor to be stored, range: 0 to 0x3fff.
        """
        self.write32(_AD9910_REG_ASF, asf << 2)
    @kernel
-    def set_pow(self, pow_):
+    def set_pow(self, pow_: TInt32):
-        """Set the value stored to the AD9910's phase offset word (POW) register.
+        """Set the value stored to the AD9910's phase offset word (POW)
        register.
        :param pow_: Phase offset word to be stored, range: 0 to 0xffff.
        """
        self.write16(_AD9910_REG_POW, pow_)
    @kernel
    def get_ftw(self) -> TInt32:
        """Get the value stored to the AD9910's frequency tuning word (FTW)
        register.
        :return: Frequency tuning word
        """
        return self.read32(_AD9910_REG_FTW)
    @kernel
    def get_asf(self) -> TInt32:
        """Get the value stored to the AD9910's amplitude scale factor (ASF)
        register.
        :return: Amplitude scale factor
        """
        return self.read32(_AD9910_REG_ASF) >> 2
    @kernel
    def get_pow(self) -> TInt32:
        """Get the value stored to the AD9910's phase offset word (POW)
        register.
        :return: Phase offset word
        """
        return self.read16(_AD9910_REG_POW)
    @portable(flags={"fast-math"})
-    def frequency_to_ftw(self, frequency) -> TInt32:
+    def frequency_to_ftw(self, frequency: TFloat) -> TInt32:
        """Return the 32-bit frequency tuning word corresponding to the given
        frequency.
        """
        return int32(round(self.ftw_per_hz * frequency))
    @portable(flags={"fast-math"})
-    def ftw_to_frequency(self, ftw):
+    def ftw_to_frequency(self, ftw: TInt32) -> TFloat:
        """Return the frequency corresponding to the given frequency tuning
        word.
        """
        return ftw / self.ftw_per_hz
    @portable(flags={"fast-math"})
-    def turns_to_pow(self, turns) -> TInt32:
+    def turns_to_pow(self, turns: TFloat) -> TInt32:
        """Return the 16-bit phase offset word corresponding to the given phase
        in turns."""
        return int32(round(turns * 0x10000)) & int32(0xffff)
    @portable(flags={"fast-math"})
-    def pow_to_turns(self, pow_):
+    def pow_to_turns(self, pow_: TInt32) -> TFloat:
        """Return the phase in turns corresponding to a given phase offset
        word."""
        return pow_ / 0x10000
    @portable(flags={"fast-math"})
-    def amplitude_to_asf(self, amplitude) -> TInt32:
+    def amplitude_to_asf(self, amplitude: TFloat) -> TInt32:
        """Return 14-bit amplitude scale factor corresponding to given
        fractional amplitude."""
        code = int32(round(amplitude * 0x3fff))
@ -614,13 +729,13 @@ class AD9910:
        return code
    @portable(flags={"fast-math"})
-    def asf_to_amplitude(self, asf):
+    def asf_to_amplitude(self, asf: TInt32) -> TFloat:
        """Return amplitude as a fraction of full scale corresponding to given
        amplitude scale factor."""
        return asf / float(0x3fff)
    @portable(flags={"fast-math"})
-    def frequency_to_ram(self, frequency, ram):
+    def frequency_to_ram(self, frequency: TList(TFloat), ram: TList(TInt32)):
        """Convert frequency values to RAM profile data.
        To be used with :const:`RAM_DEST_FTW`.
@ -633,7 +748,7 @@ class AD9910:
            ram[i] = self.frequency_to_ftw(frequency[i])
    @portable(flags={"fast-math"})
-    def turns_to_ram(self, turns, ram):
+    def turns_to_ram(self, turns: TList(TFloat), ram: TList(TInt32)):
        """Convert phase values to RAM profile data.
        To be used with :const:`RAM_DEST_POW`.
@ -646,7 +761,7 @@ class AD9910:
            ram[i] = self.turns_to_pow(turns[i]) << 16
    @portable(flags={"fast-math"})
-    def amplitude_to_ram(self, amplitude, ram):
+    def amplitude_to_ram(self, amplitude: TList(TFloat), ram: TList(TInt32)):
        """Convert amplitude values to RAM profile data.
        To be used with :const:`RAM_DEST_ASF`.
@ -659,7 +774,8 @@ class AD9910:
            ram[i] = self.amplitude_to_asf(amplitude[i]) << 18
    @portable(flags={"fast-math"})
-    def turns_amplitude_to_ram(self, turns, amplitude, ram):
+    def turns_amplitude_to_ram(self, turns: TList(TFloat),
                               amplitude: TList(TFloat), ram: TList(TInt32)):
        """Convert phase and amplitude values to RAM profile data.
        To be used with :const:`RAM_DEST_POWASF`.
@ -674,33 +790,65 @@ class AD9910:
                      self.amplitude_to_asf(amplitude[i]) << 2)
    @kernel
-    def set_frequency(self, frequency):
+    def set_frequency(self, frequency: TFloat):
-        """Set the value stored to the AD9910's frequency tuning word (FTW) register.
+        """Set the value stored to the AD9910's frequency tuning word (FTW)
        register.
        :param frequency: frequency to be stored, in Hz.
        """
-        return self.set_ftw(self.frequency_to_ftw(frequency))
+        self.set_ftw(self.frequency_to_ftw(frequency))
    @kernel
-    def set_amplitude(self, amplitude):
+    def set_amplitude(self, amplitude: TFloat):
-        """Set the value stored to the AD9910's amplitude scale factor (ASF) register.
+        """Set the value stored to the AD9910's amplitude scale factor (ASF)
        register.
        :param amplitude: amplitude to be stored, in units of full scale.
        """
-        return self.set_asf(self.amplitude_to_asf(amplitude))
+        self.set_asf(self.amplitude_to_asf(amplitude))
    @kernel
-    def set_phase(self, turns):
+    def set_phase(self, turns: TFloat):
-        """Set the value stored to the AD9910's phase offset word (POW) register.
+        """Set the value stored to the AD9910's phase offset word (POW)
        register.
        :param turns: phase offset to be stored, in turns.
        """
-        return self.set_pow(self.turns_to_pow(turns))
+        self.set_pow(self.turns_to_pow(turns))
    @kernel
-    def set(self, frequency, phase=0.0, amplitude=1.0,
+    def get_frequency(self) -> TFloat:
-            phase_mode=_PHASE_MODE_DEFAULT, ref_time_mu=int64(-1), profile=0):
+        """Get the value stored to the AD9910's frequency tuning word (FTW)
-        """Set profile 0 data in SI units.
+        register.
        :return: frequency in Hz.
        """
        return self.ftw_to_frequency(self.get_ftw())
    @kernel
    def get_amplitude(self) -> TFloat:
        """Get the value stored to the AD9910's amplitude scale factor (ASF)
        register.
        :return: amplitude in units of full scale.
        """
        return self.asf_to_amplitude(self.get_asf())
    @kernel
    def get_phase(self) -> TFloat:
        """Get the value stored to the AD9910's phase offset word (POW)
        register.
        :return: phase offset in turns.
        """
        return self.pow_to_turns(self.get_pow())
    @kernel
    def set(self, frequency: TFloat = 0.0, phase: TFloat = 0.0,
            amplitude: TFloat = 1.0, phase_mode: TInt32 = _PHASE_MODE_DEFAULT,
            ref_time_mu: TInt64 = int64(-1), profile: TInt32 = DEFAULT_PROFILE,
            ram_destination: TInt32 = -1) -> TFloat:
        """Set DDS data in SI units.
        .. seealso:: :meth:`set_mu`
@ -709,16 +857,34 @@ class AD9910:
        :param amplitude: Amplitude in units of full scale
        :param phase_mode: Phase mode constant
        :param ref_time_mu: Fiducial time stamp in machine units
-        :param profile: Profile to affect
+        :param profile: Single tone profile to affect.
        :param ram_destination: RAM destination.
        :return: Resulting phase offset in turns
        """
        return self.pow_to_turns(self.set_mu(
            self.frequency_to_ftw(frequency), self.turns_to_pow(phase),
            self.amplitude_to_asf(amplitude), phase_mode, ref_time_mu,
-            profile))
+            profile, ram_destination))
    @kernel
-    def set_att_mu(self, att):
+    def get(self, profile: TInt32 = DEFAULT_PROFILE
            ) -> TTuple([TFloat, TFloat, TFloat]):
        """Get the frequency, phase, and amplitude.
        .. seealso:: :meth:`get_mu`
        :param profile: Profile number to get (0-7, default: 7)
        :return: A tuple ``(frequency, phase, amplitude)``
        """
        # Get values
        ftw, pow_, asf = self.get_mu(profile)
        # Convert and return
        return (self.ftw_to_frequency(ftw), self.pow_to_turns(pow_),
                self.asf_to_amplitude(asf))
    @kernel
    def set_att_mu(self, att: TInt32):
        """Set digital step attenuator in machine units.
        This method will write the attenuator settings of all four channels.
@ -730,7 +896,7 @@ class AD9910:
        self.cpld.set_att_mu(self.chip_select - 4, att)
    @kernel
-    def set_att(self, att):
+    def set_att(self, att: TFloat):
        """Set digital step attenuator in SI units.
        This method will write the attenuator settings of all four channels.
@ -742,7 +908,27 @@ class AD9910:
        self.cpld.set_att(self.chip_select - 4, att)
    @kernel
-    def cfg_sw(self, state):
+    def get_att_mu(self) -> TInt32:
        """Get digital step attenuator value in machine units.
        .. seealso:: :meth:`artiq.coredevice.urukul.CPLD.get_channel_att_mu`
        :return: Attenuation setting, 8 bit digital.
        """
        return self.cpld.get_channel_att_mu(self.chip_select - 4)
    @kernel
    def get_att(self) -> TFloat:
        """Get digital step attenuator value in SI units.
        .. seealso:: :meth:`artiq.coredevice.urukul.CPLD.get_channel_att`
        :return: Attenuation in dB.
        """
        return self.cpld.get_channel_att(self.chip_select - 4)
    @kernel
    def cfg_sw(self, state: TBool):
        """Set CPLD CFG RF switch state. The RF switch is controlled by the
        logical or of the CPLD configuration shift register
        RF switch bit and the SW TTL line (if used).
@ -752,20 +938,26 @@ class AD9910:
        self.cpld.cfg_sw(self.chip_select - 4, state)
    @kernel
-    def set_sync(self, in_delay, window):
+    def set_sync(self, 
                 in_delay: TInt32, 
                 window: TInt32, 
                 en_sync_gen: TInt32 = 0):
        """Set the relevant parameters in the multi device synchronization
        register. See the AD9910 datasheet for details. The SYNC clock
        generator preset value is set to zero, and the SYNC_OUT generator is
-        disabled.
+        disabled by default.
        :param in_delay: SYNC_IN delay tap (0-31) in steps of ~75ps
        :param window: Symmetric SYNC_IN validation window (0-15) in
            steps of ~75ps for both hold and setup margin.
        :param en_sync_gen: Whether to enable the DDS-internal sync generator
            (SYNC_OUT, cf. sync_sel == 1). Should be left off for the normal
            use case, where the SYNC clock is supplied by the core device.
        """
        self.write32(_AD9910_REG_SYNC,
                     (window << 28) |  # SYNC S/H validation delay
                     (1 << 27) |  # SYNC receiver enable
-                     (0 << 26) |  # SYNC generator disable
+                     (en_sync_gen << 26) |  # SYNC generator enable
                     (0 << 25) |  # SYNC generator SYS rising edge
                     (0 << 18) |  # SYNC preset
                     (0 << 11) |  # SYNC output delay
@ -781,13 +973,15 @@ class AD9910:
        Also modifies CFR2.
        """
-        self.write32(_AD9910_REG_CFR2, 0x01010020)  # clear SMP_ERR
+        self.set_cfr2(sync_validation_disable=1)  # clear SMP_ERR
        self.cpld.io_update.pulse(1 * us)
-        self.write32(_AD9910_REG_CFR2, 0x01010000)  # enable SMP_ERR
+        delay(10 * us)  # slack
        self.set_cfr2(sync_validation_disable=0)  # enable SMP_ERR
        self.cpld.io_update.pulse(1 * us)
    @kernel
-    def tune_sync_delay(self, search_seed=15):
+    def tune_sync_delay(self,
                        search_seed: TInt32 = 15) -> TTuple([TInt32, TInt32]):
        """Find a stable SYNC_IN delay.
        This method first locates a valid SYNC_IN delay at zero validation
@ -843,7 +1037,8 @@ class AD9910:
        raise ValueError("no valid window/delay")
    @kernel
-    def measure_io_update_alignment(self, delay_start, delay_stop):
+    def measure_io_update_alignment(self, delay_start: TInt64,
                                    delay_stop: TInt64) -> TInt32:
        """Use the digital ramp generator to locate the alignment between
        IO_UPDATE and SYNC_CLK.
@ -859,7 +1054,7 @@ class AD9910:
        # set up DRG
        self.set_cfr1(drg_load_lrr=1, drg_autoclear=1)
        # DRG -> FTW, DRG enable
-        self.write32(_AD9910_REG_CFR2, 0x01090000)
+        self.set_cfr2(drg_enable=1)
        # no limits
        self.write64(_AD9910_REG_RAMP_LIMIT, -1, 0)
        # DRCTL=0, dt=1 t_SYNC_CLK
@ -880,12 +1075,12 @@ class AD9910:
        ftw = self.read32(_AD9910_REG_FTW)  # read out effective FTW
        delay(100 * us)  # slack
        # disable DRG
-        self.write32(_AD9910_REG_CFR2, 0x01010000)
+        self.set_cfr2(drg_enable=0)
        self.cpld.io_update.pulse_mu(8)
        return ftw & 1
    @kernel
-    def tune_io_update_delay(self):
+    def tune_io_update_delay(self) -> TInt32:
        """Find a stable IO_UPDATE delay alignment.
        Scan through increasing IO_UPDATE delays until a delay is found that
--- a/artiq/coredevice/ad9912.py
+++ b/artiq/coredevice/ad9912.py
@ -1,6 +1,6 @@
 from numpy import int32, int64
-from artiq.language.types import TInt32, TInt64
+from artiq.language.types import TInt32, TInt64, TFloat, TTuple, TBool
 from artiq.language.core import kernel, delay, portable
 from artiq.language.units import ms, us, ns
 from artiq.coredevice.ad9912_reg import *
@ -25,11 +25,14 @@ class AD9912:
        f_ref/clk_div*pll_n where f_ref is the reference frequency and clk_div
        is the reference clock divider (both set in the parent Urukul CPLD
        instance).
    :param pll_en: PLL enable bit, set to 0 to bypass PLL (default: 1).
        Note that when bypassing the PLL the red front panel LED may remain on.
    """
    kernel_invariants = {"chip_select", "cpld", "core", "bus", "ftw_per_hz"}
    def __init__(self, dmgr, chip_select, cpld_device, sw_device=None,
-                 pll_n=10):
+                 pll_n=10, pll_en=1):
        self.kernel_invariants = {"cpld", "core", "bus", "chip_select",
                                  "pll_n", "pll_en", "ftw_per_hz"}
        self.cpld = dmgr.get(cpld_device)
        self.core = self.cpld.core
        self.bus = self.cpld.bus
@ -38,13 +41,17 @@ class AD9912:
        if sw_device:
            self.sw = dmgr.get(sw_device)
            self.kernel_invariants.add("sw")
        self.pll_en = pll_en
        self.pll_n = pll_n
        if pll_en:
            sysclk = self.cpld.refclk / [1, 1, 2, 4][self.cpld.clk_div] * pll_n
        else:
            sysclk = self.cpld.refclk
        assert sysclk <= 1e9
        self.ftw_per_hz = 1 / sysclk * (int64(1) << 48)
    @kernel
-    def write(self, addr, data, length):
+    def write(self, addr: TInt32, data: TInt32, length: TInt32):
        """Variable length write to a register.
        Up to 4 bytes.
@ -62,7 +69,7 @@ class AD9912:
        self.bus.write(data << (32 - length * 8))
    @kernel
-    def read(self, addr, length):
+    def read(self, addr: TInt32, length: TInt32) -> TInt32:
        """Variable length read from a register.
        Up to 4 bytes.
@ -101,8 +108,10 @@ class AD9912:
            raise ValueError("Urukul AD9912 product id mismatch")
        delay(50 * us)
        # HSTL power down, CMOS power down
-        self.write(AD9912_PWRCNTRL1, 0x80, length=1)
+        pwrcntrl1 = 0x80 | ((~self.pll_en & 1) << 4)
        self.write(AD9912_PWRCNTRL1, pwrcntrl1, length=1)
        self.cpld.io_update.pulse(2 * us)
        if self.pll_en:
            self.write(AD9912_N_DIV, self.pll_n // 2 - 2, length=1)
            self.cpld.io_update.pulse(2 * us)
            # I_cp = 375 µA, VCO high range
@ -111,7 +120,7 @@ class AD9912:
        delay(1 * ms)
    @kernel
-    def set_att_mu(self, att):
+    def set_att_mu(self, att: TInt32):
        """Set digital step attenuator in machine units.
        This method will write the attenuator settings of all four channels.
@ -123,7 +132,7 @@ class AD9912:
        self.cpld.set_att_mu(self.chip_select - 4, att)
    @kernel
-    def set_att(self, att):
+    def set_att(self, att: TFloat):
        """Set digital step attenuator in SI units.
        This method will write the attenuator settings of all four channels.
@ -135,14 +144,34 @@ class AD9912:
        self.cpld.set_att(self.chip_select - 4, att)
    @kernel
-    def set_mu(self, ftw, pow):
+    def get_att_mu(self) -> TInt32:
        """Get digital step attenuator value in machine units.
        .. seealso:: :meth:`artiq.coredevice.urukul.CPLD.get_channel_att_mu`
        :return: Attenuation setting, 8 bit digital.
        """
        return self.cpld.get_channel_att_mu(self.chip_select - 4)
    @kernel
    def get_att(self) -> TFloat:
        """Get digital step attenuator value in SI units.
        .. seealso:: :meth:`artiq.coredevice.urukul.CPLD.get_channel_att`
        :return: Attenuation in dB.
        """
        return self.cpld.get_channel_att(self.chip_select - 4)
    @kernel
    def set_mu(self, ftw: TInt64, pow_: TInt32 = 0):
        """Set profile 0 data in machine units.
        After the SPI transfer, the shared IO update pin is pulsed to
        activate the data.
        :param ftw: Frequency tuning word: 48 bit unsigned.
-        :param pow: Phase tuning word: 16 bit unsigned.
+        :param pow_: Phase tuning word: 16 bit unsigned.
        """
        # streaming transfer of FTW and POW
        self.bus.set_config_mu(urukul.SPI_CONFIG, 16,
@ -150,47 +179,90 @@ class AD9912:
        self.bus.write((AD9912_POW1 << 16) | (3 << 29))
        self.bus.set_config_mu(urukul.SPI_CONFIG, 32,
                               urukul.SPIT_DDS_WR, self.chip_select)
-        self.bus.write((pow << 16) | (int32(ftw >> 32) & 0xffff))
+        self.bus.write((pow_ << 16) | (int32(ftw >> 32) & 0xffff))
        self.bus.set_config_mu(urukul.SPI_CONFIG | spi.SPI_END, 32,
                               urukul.SPIT_DDS_WR, self.chip_select)
        self.bus.write(int32(ftw))
        self.cpld.io_update.pulse(10 * ns)
    @kernel
    def get_mu(self) -> TTuple([TInt64, TInt32]):
        """Get the frequency tuning word and phase offset word.
        .. seealso:: :meth:`get`
        :return: A tuple ``(ftw, pow)``.
        """
        # Read data
        high = self.read(AD9912_POW1, 4)
        self.core.break_realtime()  # Regain slack to perform second read
        low = self.read(AD9912_FTW3, 4)
        # Extract and return fields
        ftw = (int64(high & 0xffff) << 32) | (int64(low) & int64(0xffffffff))
        pow_ = (high >> 16) & 0x3fff
        return ftw, pow_
    @portable(flags={"fast-math"})
-    def frequency_to_ftw(self, frequency) -> TInt64:
+    def frequency_to_ftw(self, frequency: TFloat) -> TInt64:
        """Returns the 48-bit frequency tuning word corresponding to the given
        frequency.
        """
-        return int64(round(self.ftw_per_hz*frequency)) & ((int64(1) << 48) - 1)
+        return int64(round(self.ftw_per_hz * frequency)) & (
                (int64(1) << 48) - 1)
    @portable(flags={"fast-math"})
-    def ftw_to_frequency(self, ftw):
+    def ftw_to_frequency(self, ftw: TInt64) -> TFloat:
        """Returns the frequency corresponding to the given
        frequency tuning word.
        """
        return ftw / self.ftw_per_hz
    @portable(flags={"fast-math"})
-    def turns_to_pow(self, phase) -> TInt32:
+    def turns_to_pow(self, phase: TFloat) -> TInt32:
        """Returns the 16-bit phase offset word corresponding to the given
        phase.
        """
        return int32(round((1 << 14) * phase)) & 0xffff
    @portable(flags={"fast-math"})
    def pow_to_turns(self, pow_: TInt32) -> TFloat:
        """Return the phase in turns corresponding to a given phase offset
        word.
        :param pow_: Phase offset word.
        :return: Phase in turns.
        """
        return pow_ / (1 << 14)
    @kernel
-    def set(self, frequency, phase=0.0):
+    def set(self, frequency: TFloat, phase: TFloat = 0.0):
        """Set profile 0 data in SI units.
        .. seealso:: :meth:`set_mu`
-        :param ftw: Frequency in Hz
+        :param frequency: Frequency in Hz
-        :param pow: Phase tuning word in turns
+        :param phase: Phase tuning word in turns
        """
        self.set_mu(self.frequency_to_ftw(frequency),
                    self.turns_to_pow(phase))
    @kernel
-    def cfg_sw(self, state):
+    def get(self) -> TTuple([TFloat, TFloat]):
        """Get the frequency and phase.
        .. seealso:: :meth:`get_mu`
        :return: A tuple ``(frequency, phase)``.
        """
        # Get values
        ftw, pow_ = self.get_mu()
        # Convert and return
        return self.ftw_to_frequency(ftw), self.pow_to_turns(pow_)
    @kernel
    def cfg_sw(self, state: TBool):
        """Set CPLD CFG RF switch state. The RF switch is controlled by the
        logical or of the CPLD configuration shift register
        RF switch bit and the SW TTL line (if used).
--- a/artiq/coredevice/ad9914.py
+++ b/artiq/coredevice/ad9914.py
@ -80,6 +80,13 @@ class AD9914:
        self.set_x_duration_mu     = 7 * self.write_duration_mu
        self.exit_x_duration_mu    = 3 * self.write_duration_mu
    @staticmethod
    def get_rtio_channels(bus_channel, channel, **kwargs):
        # return only first entry, as there are several devices with the same RTIO channel
        if channel == 0:
            return [(bus_channel, None)]
        return []
    @kernel
    def write(self, addr, data):
        rtio_output((self.bus_channel << 8) | addr, data)
--- a/artiq/coredevice/adf5356.py
+++ b/artiq/coredevice/adf5356.py
@ -73,6 +73,10 @@ class ADF5356:
        self._init_registers()
    @staticmethod
    def get_rtio_channels(**kwargs):
        return []
    @kernel
    def init(self, blind=False):
        """
@ -102,6 +106,18 @@ class ADF5356:
        else:
            self.sync()
    @kernel
    def set_att(self, att):
        """Set digital step attenuator in SI units.
        This method will write the attenuator settings of the channel.
        .. seealso:: :meth:`artiq.coredevice.mirny.Mirny.set_att`
        :param att: Attenuation in dB.
        """
        self.cpld.set_att(self.channel, att)
    @kernel
    def set_att_mu(self, att):
        """Set digital step attenuator in machine units.
@ -236,6 +252,7 @@ class ADF5356:
        Write all registers to the device. Attempts to lock the PLL.
        """
        f_pfd = self.f_pfd()
        delay(200 * us)         # Slack
        if f_pfd <= 75.0 * MHz:
            for i in range(13, 0, -1):
@ -249,6 +266,7 @@ class ADF5356:
            n, frac1, (frac2_msb, frac2_lsb), (mod2_msb, mod2_lsb) = calculate_pll(
                self.f_vco(), f_pfd >> 1
            )
            delay(200 * us)     # Slack
            self.write(
                13
--- a/artiq/coredevice/almazny.py
+++ b/artiq/coredevice/almazny.py
@ -0,0 +1,185 @@
 from artiq.language.core import kernel, portable
 from numpy import int32
 # almazny-specific data
 ALMAZNY_LEGACY_REG_BASE = 0x0C
 ALMAZNY_LEGACY_OE_SHIFT = 12
 # higher SPI write divider to match almazny shift register timing 
 # min SER time before SRCLK rise = 125ns
 # -> div=32 gives 125ns for data before clock rise
 # works at faster dividers too but could be less reliable
 ALMAZNY_LEGACY_SPIT_WR = 32
 class AlmaznyLegacy:
    """
    Almazny (High frequency mezzanine board for Mirny)
    This applies to Almazny hardware v1.1 and earlier.
    Use :class:`artiq.coredevice.almazny.AlmaznyChannel` for Almazny v1.2 and later.
    :param host_mirny: Mirny device Almazny is connected to
    """
    def __init__(self, dmgr, host_mirny):
        self.mirny_cpld = dmgr.get(host_mirny)
        self.att_mu = [0x3f] * 4
        self.channel_sw = [0] * 4
        self.output_enable = False
    @kernel
    def init(self):
        self.output_toggle(self.output_enable)
    @kernel
    def att_to_mu(self, att):
        """
        Convert an attenuator setting in dB to machine units.
        :param att: attenuator setting in dB [0-31.5]
        :return: attenuator setting in machine units
        """
        mu = round(att * 2.0)
        if mu > 63 or mu < 0:
            raise ValueError("Invalid Almazny attenuator settings!")
        return mu
    @kernel
    def mu_to_att(self, att_mu):
        """
        Convert a digital attenuator setting to dB.
        :param att_mu: attenuator setting in machine units
        :return: attenuator setting in dB
        """
        return att_mu / 2
    @kernel
    def set_att(self, channel, att, rf_switch=True):
        """
        Sets attenuators on chosen shift register (channel).
        :param channel: index of the register [0-3]
        :param att: attenuation setting in dBm [0-31.5]
        :param rf_switch: rf switch (bool)
        """
        self.set_att_mu(channel, self.att_to_mu(att), rf_switch)
    @kernel
    def set_att_mu(self, channel, att_mu, rf_switch=True):
        """
        Sets attenuators on chosen shift register (channel).
        :param channel: index of the register [0-3]
        :param att_mu: attenuation setting in machine units [0-63]
        :param rf_switch: rf switch (bool)
        """
        self.channel_sw[channel] = 1 if rf_switch else 0
        self.att_mu[channel] = att_mu
        self._update_register(channel)
    @kernel
    def output_toggle(self, oe):
        """
        Toggles output on all shift registers on or off.
        :param oe: toggle output enable (bool)
        """
        self.output_enable = oe
        cfg_reg = self.mirny_cpld.read_reg(1)
        en = 1 if self.output_enable else 0
        delay(100 * us)
        new_reg = (en << ALMAZNY_LEGACY_OE_SHIFT) | (cfg_reg & 0x3FF)
        self.mirny_cpld.write_reg(1, new_reg)
        delay(100 * us)
    @kernel
    def _flip_mu_bits(self, mu):
        # in this form MSB is actually 0.5dB attenuator
        # unnatural for users, so we flip the six bits
        return (((mu & 0x01) << 5)
                | ((mu & 0x02) << 3) 
                | ((mu & 0x04) << 1) 
                | ((mu & 0x08) >> 1) 
                | ((mu & 0x10) >> 3) 
                | ((mu & 0x20) >> 5))
    @kernel
    def _update_register(self, ch):
        self.mirny_cpld.write_ext(
            ALMAZNY_LEGACY_REG_BASE + ch, 
            8, 
            self._flip_mu_bits(self.att_mu[ch]) | (self.channel_sw[ch] << 6), 
            ALMAZNY_LEGACY_SPIT_WR
        )
        delay(100 * us)
    @kernel
    def _update_all_registers(self):
        for i in range(4):
            self._update_register(i)
 class AlmaznyChannel:
    """
    One Almazny channel
    Almazny is a mezzanine for the Quad PLL RF source Mirny that exposes and
    controls the frequency-doubled outputs.
    This driver requires Almazny hardware revision v1.2 or later
    and Mirny CPLD gateware v0.3 or later.
    Use :class:`artiq.coredevice.almazny.AlmaznyLegacy` for Almazny hardware v1.1 and earlier.
    :param host_mirny: Mirny CPLD device name
    :param channel: channel index (0-3)
    """
    def __init__(self, dmgr, host_mirny, channel):
        self.channel = channel
        self.mirny_cpld = dmgr.get(host_mirny)
    @portable
    def to_mu(self, att, enable, led):
        """
        Convert an attenuation in dB, RF switch state and LED state to machine
        units.
        :param att: attenuator setting in dB (0-31.5)
        :param enable: RF switch state (bool)
        :param led: LED state (bool)
        :return: channel setting in machine units
        """
        mu = int32(round(att * 2.))
        if mu >= 64 or mu < 0:
            raise ValueError("Attenuation out of range")
        # unfortunate hardware design: bit reverse
        mu = ((mu & 0x15) << 1) | ((mu >> 1) & 0x15)
        mu = ((mu & 0x03) << 4) | (mu & 0x0c) | ((mu >> 4) & 0x03)
        if enable:
          mu |= 1 << 6
        if led:
          mu |= 1 << 7
        return mu
    @kernel
    def set_mu(self, mu):
        """
        Set channel state (machine units).
        :param mu: channel state in machine units.
        """
        self.mirny_cpld.write_ext(
            addr=0xc + self.channel, length=8, data=mu, ext_div=32)
    @kernel
    def set(self, att, enable, led=False):
        """
        Set attenuation, RF switch, and LED state (SI units).
        :param att: attenuator setting in dB (0-31.5)
        :param enable: RF switch state (bool)
        :param led: LED state (bool)
        """
        self.set_mu(self.to_mu(att, enable, led))
--- a/artiq/coredevice/basemod_att.py
+++ b/artiq/coredevice/basemod_att.py
@ -1,79 +0,0 @@
 from artiq.language.core import kernel, portable, delay
 from artiq.language.units import us, ms
 from artiq.coredevice.shiftreg import ShiftReg
@portable
 def to_mu(att):
    return round(att*2.0) ^ 0x3f
@portable
 def from_mu(att_mu):
    return 0.5*(att_mu ^ 0x3f)
 class BaseModAtt:
    def __init__(self, dmgr, rst_n, clk, le, mosi, miso):
        self.rst_n = dmgr.get(rst_n)
        self.shift_reg = ShiftReg(dmgr,
            clk=clk, ser=mosi, latch=le, ser_in=miso, n=8*4)
    @kernel
    def reset(self):
        # HMC's incompetence in digital design and interfaces means that
        # the HMC542 needs a level low on RST_N and then a rising edge
        # on Latch Enable. Their "latch" isn't a latch but a DFF.
        # Of course, it also powers up with a random attenuation, and
        # that cannot be fixed with simple pull-ups/pull-downs.
        self.rst_n.off()
        self.shift_reg.latch.off()
        delay(1*us)
        self.shift_reg.latch.on()
        delay(1*us)
        self.shift_reg.latch.off()
        self.rst_n.on()
        delay(1*us)
    @kernel
    def set_mu(self, att0, att1, att2, att3):
        """
        Sets the four attenuators on BaseMod.
        The values are in half decibels, between 0 (no attenuation)
        and 63 (31.5dB attenuation).
        """
        word = (
            (att0 <<  2) |
            (att1 << 10) | 
            (att2 << 18) | 
            (att3 << 26)
        )
        self.shift_reg.set(word)
    @kernel
    def get_mu(self):
        """
        Retrieves the current settings of the four attenuators on BaseMod.
        """
        word = self.shift_reg.get()
        att0 = (word >>  2) & 0x3f
        att1 = (word >> 10) & 0x3f
        att2 = (word >> 18) & 0x3f
        att3 = (word >> 26) & 0x3f
        return att0, att1, att2, att3
    @kernel
    def set(self, att0, att1, att2, att3):
        """
        Sets the four attenuators on BaseMod.
        The values are in decibels.
        """
        self.set_mu(to_mu(att0), to_mu(att1), to_mu(att2), to_mu(att3))
    @kernel
    def get(self):
        """
        Retrieves the current settings of the four attenuators on BaseMod.
        The values are in decibels.
        """
        att0, att1, att2, att3 = self.get_mu()
        return from_mu(att0), from_mu(att1), from_mu(att2), from_mu(att3)
--- a/artiq/coredevice/cache.py
+++ b/artiq/coredevice/cache.py
@ -2,11 +2,11 @@ from artiq.language.core import *
 from artiq.language.types import *
-@syscall(flags={"nounwind", "nowrite"})
+@syscall(flags={"nounwind"})
 def cache_get(key: TStr) -> TList(TInt32):
    raise NotImplementedError("syscall not simulated")
-@syscall(flags={"nowrite"})
+@syscall
 def cache_put(key: TStr, value: TList(TInt32)) -> TNone:
    raise NotImplementedError("syscall not simulated")
--- a/artiq/coredevice/comm.py
+++ b/artiq/coredevice/comm.py
@ -1,28 +0,0 @@
 import sys
 import socket
 import logging
 logger = logging.getLogger(__name__)
 def set_keepalive(sock, after_idle, interval, max_fails):
    if sys.platform.startswith("linux"):
        sock.setsockopt(socket.SOL_SOCKET, socket.SO_KEEPALIVE, 1)
        sock.setsockopt(socket.IPPROTO_TCP, socket.TCP_KEEPIDLE, after_idle)
        sock.setsockopt(socket.IPPROTO_TCP, socket.TCP_KEEPINTVL, interval)
        sock.setsockopt(socket.IPPROTO_TCP, socket.TCP_KEEPCNT, max_fails)
    elif sys.platform.startswith("win") or sys.platform.startswith("cygwin"):
        # setting max_fails is not supported, typically ends up being 5 or 10
        # depending on Windows version
        sock.ioctl(socket.SIO_KEEPALIVE_VALS,
                   (1, after_idle * 1000, interval * 1000))
    else:
        logger.warning("TCP keepalive not supported on platform '%s', ignored",
                       sys.platform)
 def initialize_connection(host, port):
    sock = socket.create_connection((host, port))
    set_keepalive(sock, 10, 10, 3)
    logger.debug("connected to %s:%d", host, port)
    return sock
--- a/artiq/coredevice/comm_analyzer.py
+++ b/artiq/coredevice/comm_analyzer.py
@ -102,15 +102,15 @@ def decode_dump(data):
    # messages are big endian
    parts = struct.unpack(endian + "IQbbb", data[:15])
    (sent_bytes, total_byte_count,
-     error_occured, log_channel, dds_onehot_sel) = parts
+     error_occurred, log_channel, dds_onehot_sel) = parts
    expected_len = sent_bytes + 15
    if expected_len != len(data):
        raise ValueError("analyzer dump has incorrect length "
                         "(got {}, expected {})".format(
                            len(data), expected_len))
-    if error_occured:
+    if error_occurred:
-        logger.warning("error occured within the analyzer, "
+        logger.warning("error occurred within the analyzer, "
                       "data may be corrupted")
    if total_byte_count > sent_bytes:
        logger.info("analyzer ring buffer has wrapped %d times",
--- a/artiq/coredevice/comm_kernel.py
+++ b/artiq/coredevice/comm_kernel.py
@ -8,9 +8,8 @@ from fractions import Fraction
 from collections import namedtuple
 from artiq.coredevice import exceptions
 from artiq.coredevice.comm import initialize_connection
 from artiq import __version__ as software_version
-
+from sipyco.keepalive import create_connection
 logger = logging.getLogger(__name__)
@ -24,6 +23,8 @@ class Request(Enum):
    RPCReply = 7
    RPCException = 8
    SubkernelUpload = 9
 class Reply(Enum):
    SystemInfo = 2
@ -66,13 +67,13 @@ def _receive_list(kernel, embedding_map):
    tag = chr(kernel._read_int8())
    if tag == "b":
        buffer = kernel._read(length)
-        return list(buffer)
+        return list(struct.unpack(kernel.endian + "%s?" % length, buffer))
    elif tag == "i":
        buffer = kernel._read(4 * length)
        return list(struct.unpack(kernel.endian + "%sl" % length, buffer))
    elif tag == "I":
        buffer = kernel._read(8 * length)
-        return list(struct.unpack(kernel.endian + "%sq" % length, buffer))
+        return list(numpy.ndarray((length, ), kernel.endian + 'i8', buffer))
    elif tag == "f":
        buffer = kernel._read(8 * length)
        return list(struct.unpack(kernel.endian + "%sd" % length, buffer))
@ -96,7 +97,7 @@ def _receive_array(kernel, embedding_map):
    length = numpy.prod(shape)
    if tag == "b":
        buffer = kernel._read(length)
-        elems = numpy.ndarray((length, ), 'B', buffer)
+        elems = numpy.ndarray((length, ), '?', buffer)
    elif tag == "i":
        buffer = kernel._read(4 * length)
        elems = numpy.ndarray((length, ), kernel.endian + 'i4', buffer)
@ -171,6 +172,16 @@ class CommKernelDummy:
        pass
 def incompatible_versions(v1, v2):
    if v1.endswith(".beta") or v2.endswith(".beta"):
        # Beta branches may introduce breaking changes. Check version strictly.
        return v1 != v2
    else:
        # On stable branches, runtime/software protocol backward compatibility is kept.
        # Runtime and software with the same major version number are compatible.
        return v1.split(".", maxsplit=1)[0] != v2.split(".", maxsplit=1)[0]
 class CommKernel:
    warned_of_mismatch = False
@ -185,7 +196,7 @@ class CommKernel:
    def open(self):
        if hasattr(self, "socket"):
            return
-        self.socket = initialize_connection(self.host, self.port)
+        self.socket = create_connection(self.host, self.port)
        self.socket.sendall(b"ARTIQ coredev\n")
        endian = self._read(1)
        if endian == b"e":
@ -199,6 +210,7 @@ class CommKernel:
        self.unpack_float64 = struct.Struct(self.endian + "d").unpack
        self.pack_header = struct.Struct(self.endian + "lB").pack
        self.pack_int8 = struct.Struct(self.endian + "B").pack
        self.pack_int32 = struct.Struct(self.endian + "l").pack
        self.pack_int64 = struct.Struct(self.endian + "q").pack
        self.pack_float64 = struct.Struct(self.endian + "d").pack
@ -313,7 +325,7 @@ class CommKernel:
        self._write(chunk)
    def _write_int8(self, value):
-        self._write(value)
+        self._write(self.pack_int8(value))
    def _write_int32(self, value):
        self._write(self.pack_int32(value))
@ -347,7 +359,7 @@ class CommKernel:
        runtime_id = self._read(4)
        if runtime_id == b"AROR":
            gateware_version = self._read_string().split(";")[0]
-            if gateware_version != software_version and not self.warned_of_mismatch:
+            if not self.warned_of_mismatch and incompatible_versions(gateware_version, software_version):
                logger.warning("Mismatch between gateware (%s) "
                               "and software (%s) versions",
                               gateware_version, software_version)
@ -373,6 +385,19 @@ class CommKernel:
        else:
            self._read_expect(Reply.LoadCompleted)
    def upload_subkernel(self, kernel_library, id, destination):
        self._write_header(Request.SubkernelUpload)
        self._write_int32(id)
        self._write_int8(destination)
        self._write_bytes(kernel_library)
        self._flush()
        self._read_header()
        if self._read_type == Reply.LoadFailed:
            raise LoadError(self._read_string())
        else:
            self._read_expect(Reply.LoadCompleted)
    def run(self):
        self._write_empty(Request.RunKernel)
        self._flush()
@ -409,6 +434,9 @@ class CommKernel:
            self._skip_rpc_value(tags)
        elif tag == "r":
            self._skip_rpc_value(tags)
        elif tag == "a":
            _ndims = tags.pop(0)
            self._skip_rpc_value(tags)
        else:
            pass
@ -437,12 +465,12 @@ class CommKernel:
            self._write_bool(value)
        elif tag == "i":
            check(isinstance(value, (int, numpy.int32)) and
-                  (-2**31 < value < 2**31-1),
+                  (-2**31 <= value < 2**31),
                  lambda: "32-bit int")
            self._write_int32(value)
        elif tag == "I":
            check(isinstance(value, (int, numpy.int32, numpy.int64)) and
-                  (-2**63 < value < 2**63-1),
+                  (-2**63 <= value < 2**63),
                  lambda: "64-bit int")
            self._write_int64(value)
        elif tag == "f":
@ -451,8 +479,8 @@ class CommKernel:
            self._write_float64(value)
        elif tag == "F":
            check(isinstance(value, Fraction) and
-                  (-2**63 < value.numerator < 2**63-1) and
+                  (-2**63 <= value.numerator < 2**63) and
-                  (-2**63 < value.denominator < 2**63-1),
+                  (-2**63 <= value.denominator < 2**63),
                  lambda: "64-bit Fraction")
            self._write_int64(value.numerator)
            self._write_int64(value.denominator)
@ -476,11 +504,19 @@ class CommKernel:
            if tag_element == "b":
                self._write(bytes(value))
            elif tag_element == "i":
-                self._write(struct.pack(self.endian + "%sl" %
+                try:
-                                        len(value), *value))
+                    self._write(struct.pack(self.endian + "%sl" % len(value), *value))
                except struct.error:
                    raise RPCReturnValueError(
                        "type mismatch: cannot serialize {value} as {type}".format(
                            value=repr(value), type="32-bit integer list"))
            elif tag_element == "I":
-                self._write(struct.pack(self.endian + "%sq" %
+                try:
-                                        len(value), *value))
+                    self._write(struct.pack(self.endian + "%sq" % len(value), *value))
                except struct.error:
                    raise RPCReturnValueError(
                        "type mismatch: cannot serialize {value} as {type}".format(
                            value=repr(value), type="64-bit integer list"))
            elif tag_element == "f":
                self._write(struct.pack(self.endian + "%sd" %
                                        len(value), *value))
@ -555,14 +591,6 @@ class CommKernel:
        try:
            result = service(*args, **kwargs)
            logger.debug("rpc service: %d %r %r = %r",
                         service_id, args, kwargs, result)
            self._write_header(Request.RPCReply)
            self._write_bytes(return_tags)
            self._send_rpc_value(bytearray(return_tags),
                                 result, result, service)
            self._flush()
        except RPCReturnValueError as exn:
            raise
        except Exception as exn:
@ -571,29 +599,33 @@ class CommKernel:
            self._write_header(Request.RPCException)
            # Note: instead of sending strings, we send object ID
            # This is to avoid the need of allocatio on the device side
            # This is a special case: this only applies to exceptions
            if hasattr(exn, "artiq_core_exception"):
                exn = exn.artiq_core_exception
-                self._write_string(exn.name)
+                self._write_int32(embedding_map.store_str(exn.name))
-                self._write_string(self._truncate_message(exn.message))
+                self._write_int32(embedding_map.store_str(self._truncate_message(exn.message)))
                for index in range(3):
                    self._write_int64(exn.param[index])
                filename, line, column, function = exn.traceback[-1]
-                self._write_string(filename)
+                self._write_int32(embedding_map.store_str(filename))
                self._write_int32(line)
                self._write_int32(column)
-                self._write_string(function)
+                self._write_int32(embedding_map.store_str(function))
            else:
                exn_type = type(exn)
                if exn_type in (ZeroDivisionError, ValueError, IndexError, RuntimeError) or \
                        hasattr(exn, "artiq_builtin"):
-                    self._write_string("0:{}".format(exn_type.__name__))
+                    name = "0:{}".format(exn_type.__name__)
                else:
                    exn_id = embedding_map.store_object(exn_type)
-                    self._write_string("{}:{}.{}".format(exn_id,
+                    name = "{}:{}.{}".format(exn_id,
                                             exn_type.__module__,
-                                                         exn_type.__qualname__))
+                                             exn_type.__qualname__)
-                self._write_string(self._truncate_message(str(exn)))
+                self._write_int32(embedding_map.store_str(name))
                self._write_int32(embedding_map.store_str(self._truncate_message(str(exn))))
                for index in range(3):
                    self._write_int64(0)
@ -604,37 +636,93 @@ class CommKernel:
                    ((filename, line, function, _), ) = tb
                else:
                    assert False
-                self._write_string(filename)
+                self._write_int32(embedding_map.store_str(filename))
                self._write_int32(line)
                self._write_int32(-1)  # column not known
-                self._write_string(function)
+                self._write_int32(embedding_map.store_str(function))
            self._flush()
        else:
            logger.debug("rpc service: %d %r %r = %r",
                         service_id, args, kwargs, result)
            self._write_header(Request.RPCReply)
            self._write_bytes(return_tags)
            self._send_rpc_value(bytearray(return_tags),
                                 result, result, service)
            self._flush()
    def _serve_exception(self, embedding_map, symbolizer, demangler):
-        name = self._read_string()
+        exception_count = self._read_int32()
-        message = self._read_string()
+        nested_exceptions = []
        def read_exception_string():
            # note: if length == -1, the following int32 is the object key
            length = self._read_int32()
            if length == -1:
                return embedding_map.retrieve_str(self._read_int32())
            else:
                return self._read(length).decode("utf-8")
        for _ in range(exception_count):
            name = embedding_map.retrieve_str(self._read_int32())
            message = read_exception_string()
            params = [self._read_int64() for _ in range(3)]
-        filename = self._read_string()
+            filename = read_exception_string()
            line = self._read_int32()
            column = self._read_int32()
-        function = self._read_string()
+            function = read_exception_string()
            nested_exceptions.append([name, message, params,
                                      filename, line, column, function])
-        backtrace = [self._read_int32() for _ in range(self._read_int32())]
+        demangled_names = demangler([ex[6] for ex in nested_exceptions])
        for i in range(exception_count):
            nested_exceptions[i][6] = demangled_names[i]
-        traceback = list(reversed(symbolizer(backtrace))) + \
+        exception_info = []
-            [(filename, line, column, *demangler([function]), None)]
+        for _ in range(exception_count):
-        core_exn = exceptions.CoreException(name, message, params, traceback)
+            sp = self._read_int32()
            initial_backtrace = self._read_int32()
            current_backtrace = self._read_int32()
            exception_info.append((sp, initial_backtrace, current_backtrace))
        backtrace = []
        stack_pointers = []
        for _ in range(self._read_int32()):
            backtrace.append(self._read_int32())
            stack_pointers.append(self._read_int32())
        self._process_async_error()
        traceback = list(symbolizer(backtrace))
        core_exn = exceptions.CoreException(nested_exceptions, exception_info,
                                            traceback, stack_pointers)
        if core_exn.id == 0:
            python_exn_type = getattr(exceptions, core_exn.name.split('.')[-1])
        else:
            python_exn_type = embedding_map.retrieve_object(core_exn.id)
-        python_exn = python_exn_type(message.format(*params))
+        try:
            python_exn = python_exn_type(
                nested_exceptions[-1][1].format(*nested_exceptions[0][2]))
        except Exception as ex:
            python_exn = RuntimeError(
                f"Exception type={python_exn_type}, which couldn't be "
                f"reconstructed ({ex})"
            )
        python_exn.artiq_core_exception = core_exn
        raise python_exn
    def _process_async_error(self):
        errors = self._read_int8()
        if errors > 0:
            map_name = lambda y, z: [f"{y}(s)"] if z else []
            errors = map_name("collision",      errors & 2 ** 0) + \
                     map_name("busy error",     errors & 2 ** 1) + \
                     map_name("sequence error", errors & 2 ** 2)
            logger.warning(f"{(', '.join(errors[:-1]) + ' and ') if len(errors) > 1 else ''}{errors[-1]} "
                           f"reported during kernel execution")
    def serve(self, embedding_map, symbolizer, demangler):
        while True:
            self._read_header()
@ -646,4 +734,5 @@ class CommKernel:
                raise exceptions.ClockFailure
            else:
                self._read_expect(Reply.KernelFinished)
                self._process_async_error()
                return
--- a/artiq/coredevice/comm_mgmt.py
+++ b/artiq/coredevice/comm_mgmt.py
@ -2,8 +2,7 @@ from enum import Enum
 import logging
 import struct
-from artiq.coredevice.comm import initialize_connection
+from sipyco.keepalive import create_connection
 logger = logging.getLogger(__name__)
@ -20,11 +19,6 @@ class Request(Enum):
    ConfigRemove = 14
    ConfigErase = 15
    StartProfiler = 9
    StopProfiler = 10
    GetProfile = 11
    Hotswap = 4
    Reboot = 5
    DebugAllocator = 8
@ -39,8 +33,6 @@ class Reply(Enum):
    ConfigData = 7
    Profile = 5
    RebootImminent = 3
@ -61,7 +53,7 @@ class CommMgmt:
    def open(self):
        if hasattr(self, "socket"):
            return
-        self.socket = initialize_connection(self.host, self.port)
+        self.socket = create_connection(self.host, self.port)
        self.socket.sendall(b"ARTIQ management\n")
        endian = self._read(1)
        if endian == b"e":
@ -118,9 +110,10 @@ class CommMgmt:
        return ty
    def _read_expect(self, ty):
-        if self._read_header() != ty:
+        header = self._read_header()
        if header != ty:
            raise IOError("Incorrect reply from device: {} (expected {})".
-                          format(self._read_type, ty))
+                          format(header, ty))
    def _read_int32(self):
        (value, ) = struct.unpack(self.endian + "l", self._read(4))
@ -167,7 +160,12 @@ class CommMgmt:
    def config_read(self, key):
        self._write_header(Request.ConfigRead)
        self._write_string(key)
-        self._read_expect(Reply.ConfigData)
+        ty = self._read_header()
        if ty == Reply.Error:
            raise IOError("Device failed to read config. The key may not exist.")
        elif ty != Reply.ConfigData:
            raise IOError("Incorrect reply from device: {} (expected {})".
                          format(ty, Reply.ConfigData))
        return self._read_string()
    def config_write(self, key, value):
@ -176,7 +174,7 @@ class CommMgmt:
        self._write_bytes(value)
        ty = self._read_header()
        if ty == Reply.Error:
-            raise IOError("Flash storage is full")
+            raise IOError("Device failed to write config. More information may be available in the log.")
        elif ty != Reply.Success:
            raise IOError("Incorrect reply from device: {} (expected {})".
                          format(ty, Reply.Success))
@ -190,45 +188,6 @@ class CommMgmt:
        self._write_header(Request.ConfigErase)
        self._read_expect(Reply.Success)
    def start_profiler(self, interval, edges_size, hits_size):
        self._write_header(Request.StartProfiler)
        self._write_int32(interval)
        self._write_int32(edges_size)
        self._write_int32(hits_size)
        self._read_expect(Reply.Success)
    def stop_profiler(self):
        self._write_header(Request.StopProfiler)
        self._read_expect(Reply.Success)
    def stop_profiler(self):
        self._write_header(Request.StopProfiler)
        self._read_expect(Reply.Success)
    def get_profile(self):
        self._write_header(Request.GetProfile)
        self._read_expect(Reply.Profile)
        hits = {}
        for _ in range(self._read_int32()):
            addr = self._read_int32()
            count = self._read_int32()
            hits[addr] = count
        edges = {}
        for _ in range(self._read_int32()):
            caller = self._read_int32()
            callee = self._read_int32()
            count = self._read_int32()
            edges[(caller, callee)] = count
        return hits, edges
    def hotswap(self, firmware):
        self._write_header(Request.Hotswap)
        self._write_bytes(firmware)
        self._read_expect(Reply.RebootImminent)
    def reboot(self):
        self._write_header(Request.Reboot)
        self._read_expect(Reply.RebootImminent)
--- a/artiq/coredevice/comm_moninj.py
+++ b/artiq/coredevice/comm_moninj.py
@ -3,6 +3,7 @@ import logging
 import struct
 from enum import Enum
 from sipyco.keepalive import async_open_connection
 __all__ = ["TTLProbe", "TTLOverride", "CommMonInj"]
@ -28,17 +29,16 @@ class CommMonInj:
        self.disconnect_cb = disconnect_cb
    async def connect(self, host, port=1383):
-        self._reader, self._writer = await asyncio.open_connection(host, port)
+        self._reader, self._writer = await async_open_connection(
            host,
            port,
            after_idle=1,
            interval=1,
            max_fails=3,
        )
        try:
            self._writer.write(b"ARTIQ moninj\n")
            # get device endian
            endian = await self._reader.read(1)
            if endian == b"e":
                self.endian = "<"
            elif endian == b"E":
                self.endian = ">"
            else:
                raise IOError("Incorrect reply from device: expected e/E.")
            self._receive_task = asyncio.ensure_future(self._receive_cr())
        except:
            self._writer.close()
@ -46,6 +46,9 @@ class CommMonInj:
            del self._writer
            raise
    def wait_terminate(self):
        return self._receive_task
    async def close(self):
        self.disconnect_cb = None
        try:
@ -60,19 +63,19 @@ class CommMonInj:
            del self._writer
    def monitor_probe(self, enable, channel, probe):
-        packet = struct.pack(self.endian + "bblb", 0, enable, channel, probe)
+        packet = struct.pack("<bblb", 0, enable, channel, probe)
        self._writer.write(packet)
    def monitor_injection(self, enable, channel, overrd):
-        packet = struct.pack(self.endian + "bblb", 3, enable, channel, overrd)
+        packet = struct.pack("<bblb", 3, enable, channel, overrd)
        self._writer.write(packet)
    def inject(self, channel, override, value):
-        packet = struct.pack(self.endian + "blbb", 1, channel, override, value)
+        packet = struct.pack("<blbb", 1, channel, override, value)
        self._writer.write(packet)
    def get_injection_status(self, channel, override):
-        packet = struct.pack(self.endian + "blb", 2, channel, override)
+        packet = struct.pack("<blb", 2, channel, override)
        self._writer.write(packet)
    async def _receive_cr(self):
@ -82,17 +85,19 @@ class CommMonInj:
                if not ty:
                    return
                if ty == b"\x00":
-                    payload = await self._reader.read(9)
+                    payload = await self._reader.readexactly(13)
-                    channel, probe, value = struct.unpack(
+                    channel, probe, value = struct.unpack("<lbq", payload)
                        self.endian + "lbl", payload)
                    self.monitor_cb(channel, probe, value)
                elif ty == b"\x01":
-                    payload = await self._reader.read(6)
+                    payload = await self._reader.readexactly(6)
-                    channel, override, value = struct.unpack(
+                    channel, override, value = struct.unpack("<lbb", payload)
                        self.endian + "lbb", payload)
                    self.injection_status_cb(channel, override, value)
                else:
                    raise ValueError("Unknown packet type", ty)
        except asyncio.CancelledError:
            raise
        except:
            logger.error("Moninj connection terminating with exception", exc_info=True)
        finally:
            if self.disconnect_cb is not None:
                self.disconnect_cb()
--- a/artiq/coredevice/core.py
+++ b/artiq/coredevice/core.py
@ -1,5 +1,7 @@
 import os, sys
 import numpy
 from inspect import getfullargspec
 from functools import wraps
 from pythonparser import diagnostic
@ -11,7 +13,7 @@ from artiq.language.units import *
 from artiq.compiler.module import Module
 from artiq.compiler.embedding import Stitcher
-from artiq.compiler.targets import OR1KTarget, CortexA9Target
+from artiq.compiler.targets import RV32IMATarget, RV32GTarget, CortexA9Target
 from artiq.coredevice.comm_kernel import CommKernel, CommKernelDummy
 # Import for side effects (creating the exception classes).
@ -52,6 +54,17 @@ def rtio_get_counter() -> TInt64:
    raise NotImplementedError("syscall not simulated")
 def get_target_cls(target):
    if target == "rv32g":
        return RV32GTarget
    elif target == "rv32ima":
        return RV32IMATarget
    elif target == "cortexa9":
        return CortexA9Target
    else:
        raise ValueError("Unsupported target")
 class Core:
    """Core device driver.
@ -65,79 +78,164 @@ class Core:
    :param ref_multiplier: ratio between the RTIO fine timestamp frequency
        and the RTIO coarse timestamp frequency (e.g. SERDES multiplication
        factor).
    :param analyzer_proxy: name of the core device analyzer proxy to trigger
        (optional).
    :param analyze_at_run_end: automatically trigger the core device analyzer
        proxy after the Experiment's run stage finishes.
    """
    kernel_invariants = {
        "core", "ref_period", "coarse_ref_period", "ref_multiplier",
    }
-    def __init__(self, dmgr, host, ref_period, ref_multiplier=8, target="or1k"):
+    def __init__(self, dmgr,
                 host, ref_period,
                 analyzer_proxy=None, analyze_at_run_end=False,
                 ref_multiplier=8,
                 target="rv32g", satellite_cpu_targets={}):
        self.ref_period = ref_period
        self.ref_multiplier = ref_multiplier
-        if target == "or1k":
+        self.satellite_cpu_targets = satellite_cpu_targets
-            self.target_cls = OR1KTarget
+        self.target_cls = get_target_cls(target)
        elif target == "cortexa9":
            self.target_cls = CortexA9Target
        else:
            raise ValueError("Unsupported target")
        self.coarse_ref_period = ref_period*ref_multiplier
        if host is None:
            self.comm = CommKernelDummy()
        else:
            self.comm = CommKernel(host)
        self.analyzer_proxy_name = analyzer_proxy
        self.analyze_at_run_end = analyze_at_run_end
        self.first_run = True
        self.dmgr = dmgr
        self.core = self
        self.comm.core = self
        self.analyzer_proxy = None
    def notify_run_end(self):
        if self.analyze_at_run_end:
            self.trigger_analyzer_proxy()
    def close(self):
        self.comm.close()
    def compile(self, function, args, kwargs, set_result=None,
-                attribute_writeback=True, print_as_rpc=True):
+                attribute_writeback=True, print_as_rpc=True,
                target=None, destination=0, subkernel_arg_types=[]):
        try:
            engine = _DiagnosticEngine(all_errors_are_fatal=True)
            stitcher = Stitcher(engine=engine, core=self, dmgr=self.dmgr,
-                                print_as_rpc=print_as_rpc)
+                                print_as_rpc=print_as_rpc,
                                destination=destination, subkernel_arg_types=subkernel_arg_types)
            stitcher.stitch_call(function, args, kwargs, set_result)
            stitcher.finalize()
            module = Module(stitcher,
                ref_period=self.ref_period,
                attribute_writeback=attribute_writeback)
-            target = self.target_cls()
+            target = target if target is not None else self.target_cls()
            library = target.compile_and_link([module])
            stripped_library = target.strip(library)
            return stitcher.embedding_map, stripped_library, \
                   lambda addresses: target.symbolize(library, addresses), \
-                   lambda symbols: target.demangle(symbols)
+                   lambda symbols: target.demangle(symbols), \
                   module.subkernel_arg_types
        except diagnostic.Error as error:
            raise CompileError(error.diagnostic) from error
    def _run_compiled(self, kernel_library, embedding_map, symbolizer, demangler):
        if self.first_run:
            self.comm.check_system_info()
            self.first_run = False
        self.comm.load(kernel_library)
        self.comm.run()
        self.comm.serve(embedding_map, symbolizer, demangler)
    def run(self, function, args, kwargs):
        result = None
        @rpc(flags={"async"})
        def set_result(new_result):
            nonlocal result
            result = new_result
-
+        embedding_map, kernel_library, symbolizer, demangler, subkernel_arg_types = \
        embedding_map, kernel_library, symbolizer, demangler = \
            self.compile(function, args, kwargs, set_result)
-
+        self.compile_and_upload_subkernels(embedding_map, args, subkernel_arg_types)
-        if self.first_run:
+        self._run_compiled(kernel_library, embedding_map, symbolizer, demangler)
            self.comm.check_system_info()
            self.first_run = False
        self.comm.load(kernel_library)
        self.comm.run()
        self.comm.serve(embedding_map, symbolizer, demangler)
        return result
    def compile_subkernel(self, sid, subkernel_fn, embedding_map, args, subkernel_arg_types):
        # pass self to subkernels (if applicable)
        # assuming the first argument is self
        subkernel_args = getfullargspec(subkernel_fn.artiq_embedded.function)
        self_arg = []
        if len(subkernel_args[0]) > 0:
            if subkernel_args[0][0] == 'self':
                self_arg = args[:1]
        destination = subkernel_fn.artiq_embedded.destination
        destination_tgt = self.satellite_cpu_targets[destination]
        target = get_target_cls(destination_tgt)(subkernel_id=sid)
        object_map, kernel_library, _, _, _ = \
            self.compile(subkernel_fn, self_arg, {}, attribute_writeback=False,
                        print_as_rpc=False, target=target, destination=destination, 
                        subkernel_arg_types=subkernel_arg_types.get(sid, []))
        if object_map.has_rpc_or_subkernel():
            raise ValueError("Subkernel must not use RPC or subkernels in other destinations")
        return destination, kernel_library
    def compile_and_upload_subkernels(self, embedding_map, args, subkernel_arg_types):
        for sid, subkernel_fn in embedding_map.subkernels().items():
            destination, kernel_library = \
                self.compile_subkernel(sid, subkernel_fn, embedding_map,
                                       args, subkernel_arg_types)
            self.comm.upload_subkernel(kernel_library, sid, destination)
    def precompile(self, function, *args, **kwargs):
        """Precompile a kernel and return a callable that executes it on the core device
        at a later time.
        Arguments to the kernel are set at compilation time and passed to this function,
        as additional positional and keyword arguments.
        The returned callable accepts no arguments.
        Precompiled kernels may use RPCs and subkernels.
        Object attributes at the beginning of a precompiled kernel execution have the
        values they had at precompilation time. If up-to-date values are required,
        use RPC to read them.
        Similarly, modified values are not written back, and explicit RPC should be used
        to modify host objects.
        Carefully review the source code of drivers calls used in precompiled kernels, as
        they may rely on host object attributes being transfered between kernel calls.
        Examples include code used to control DDS phase, and Urukul RF switch control
        via the CPLD register.
        The return value of the callable is the return value of the kernel, if any.
        The callable may be called several times.
        """
        if not hasattr(function, "artiq_embedded"):
            raise ValueError("Argument is not a kernel")
        result = None
        @rpc(flags={"async"})
        def set_result(new_result):
            nonlocal result
            result = new_result
        embedding_map, kernel_library, symbolizer, demangler, subkernel_arg_types = \
            self.compile(function, args, kwargs, set_result, attribute_writeback=False)
        self.compile_and_upload_subkernels(embedding_map, args, subkernel_arg_types)
        @wraps(function)
        def run_precompiled():
            nonlocal result
            self._run_compiled(kernel_library, embedding_map, symbolizer, demangler)
            return result
        return run_precompiled
    @portable
    def seconds_to_mu(self, seconds):
        """Convert seconds to the corresponding number of machine units
@ -204,3 +302,23 @@ class Core:
        min_now = rtio_get_counter() + 125000
        if now_mu() < min_now:
            at_mu(min_now)
    def trigger_analyzer_proxy(self):
        """Causes the core analyzer proxy to retrieve a dump from the device,
        and distribute it to all connected clients (typically dashboards).
        Returns only after the dump has been retrieved from the device.
        Raises IOError if no analyzer proxy has been configured, or if the
        analyzer proxy fails. In the latter case, more details would be
        available in the proxy log.
        """
        if self.analyzer_proxy is None:
            if self.analyzer_proxy_name is not None:
                self.analyzer_proxy = self.dmgr.get(self.analyzer_proxy_name)
        if self.analyzer_proxy is None:
            raise IOError("No analyzer proxy configured")
        else:
            success = self.analyzer_proxy.trigger()
            if not success:
                raise IOError("Analyzer proxy reported failure")
--- a/artiq/coredevice/coredevice_generic.schema.json
+++ b/artiq/coredevice/coredevice_generic.schema.json
@ -19,16 +19,24 @@
        },
        "min_artiq_version": {
            "type": "string",
-            "description": "Minimum required ARTIQ version"
+            "description": "Minimum required ARTIQ version",
            "default": "0"
        },
        "hw_rev": {
            "type": "string",
            "description": "Hardware revision"
        },
        "base": {
            "type": "string",
            "enum": ["use_drtio_role", "standalone", "master", "satellite"],
            "description": "Deprecated, use drtio_role instead",
            "default": "use_drtio_role"
        },
        "drtio_role": {
            "type": "string",
            "enum": ["standalone", "master", "satellite"],
-            "description": "SoC base; value depends on intended system topology"
+            "description": "Role that this device takes in a DRTIO network; 'standalone' means no DRTIO",
            "default": "standalone"
        },
        "ext_ref_frequency": {
            "type": "number",
@ -64,6 +72,13 @@
            "type": "boolean",
            "default": false
        },
        "sed_lanes": {
            "type": "number",
            "minimum": 1,
            "maximum": 32,
            "default": 8,
            "description": "Number of FIFOs in the SED, must be a power of 2"
        },
        "peripherals": {
            "type": "array",
            "items": {
@ -71,6 +86,26 @@
            }
        }
    },
    "if": {
        "properties": {
            "target": { "const": "kasli" },
            "hw_rev": {
                "not": {
                    "oneOf": [
                        { "const": "v1.0" },
                        { "const": "v1.1" }
                    ]
                }
            }
        }
    },
    "then": {
        "properties": {
            "enable_sata_drtio": {
                "const": false
            }
        }
    },
    "required": ["target", "variant", "hw_rev", "base", "peripherals"],
    "additionalProperties": false,
@ -95,7 +130,7 @@
                },
                "hw_rev": {
                    "type": "string",
-                    "enum": ["v1.0"]
+                    "enum": ["v1.0", "v1.1"]
                }
            }
        }
@ -107,7 +142,7 @@
            "properties": {
                "type": {
                    "type": "string",
-                    "enum": ["dio", "urukul", "novogorny", "sampler", "suservo", "zotino", "grabber", "mirny", "fastino", "phaser"]
+                    "enum": ["dio", "dio_spi", "urukul", "novogorny", "sampler", "suservo", "zotino", "grabber", "mirny", "fastino", "phaser", "hvamp", "shuttler"]
                },
                "board": {
                    "type": "string"
@ -143,15 +178,101 @@
                        },
                        "bank_direction_low": {
                            "type": "string",
-                            "enum": ["input", "output"]
+                            "enum": ["input", "output", "clkgen"]
                        },
                        "bank_direction_high": {
                            "type": "string",
-                            "enum": ["input", "output"]
+                            "enum": ["input", "output", "clkgen"]
                        }
                    },
                    "required": ["ports", "bank_direction_low", "bank_direction_high"]
                }
            }, {
                "title": "DIO_SPI",
                "if": {
                    "properties": {
                        "type": {
                            "const": "dio_spi"
                        }
                    }
                },
                "then": {
                    "properties": {
                        "ports": {
                            "type": "array",
                            "items": {
                                "type": "integer"
                            },
                            "minItems": 1,
                            "maxItems": 1
                        },
                        "spi": {
                            "type": "array",
                            "items": {
                                "type": "object",
                                "properties": {
                                    "name": {
                                        "type": "string",
                                        "default": "dio_spi"
                                    },
                                    "clk": {
                                        "type": "integer",
                                        "minimum": 0,
                                        "maximum": 7
                                    },
                                    "mosi": {
                                        "type": "integer",
                                        "minimum": 0,
                                        "maximum": 7
                                    },
                                    "miso": {
                                        "type": "integer",
                                        "minimum": 0,
                                        "maximum": 7
                                    },
                                    "cs": {
                                        "type": "array",
                                        "items": {
                                            "type": "integer",
                                            "minimum": 0,
                                            "maximum": 7
                                        }
                                    }
                                },
                                "required": ["clk"]
                            },
                            "minItems": 1
                        },
                        "ttl": {
                            "type": "array",
                            "items": {
                                "type": "object",
                                "properties": {
                                    "name": {
                                        "type": "string",
                                        "default": "ttl"
                                    },
                                    "pin": {
                                        "type": "integer",
                                        "minimum": 0,
                                        "maximum": 7
                                    },
                                    "direction": {
                                        "type": "string",
                                        "enum": ["input", "output"]
                                    },
                                    "edge_counter": {
                                        "type": "boolean",
                                        "default": false
                                    }
                                },
                                "required": ["pin", "direction"]
                            },
                            "default": []
                        }
                    },
                    "required": ["ports", "spi"]
                }
            }, {
                "title": "Urukul",
                "if": {
@ -187,11 +308,18 @@
                        "clk_div": {
                            "type": "integer",
                            "minimum": 0,
-		            "maximum": 3
+                            "maximum": 3,
                            "default": 0
                        },
                        "pll_n": {
                            "type": "integer"
                        },
                        "pll_en": {
                            "type": "integer",
                            "minimum": 0,
                            "maximum": 1,
                            "default": 1
                        },
                        "pll_vco": {
                            "type": "integer"
                        },
@ -266,6 +394,11 @@
                            "minItems": 2,
                            "maxItems": 2
                        },
                        "sampler_hw_rev": {
                            "type": "string",
                            "pattern": "^v[0-9]+\\.[0-9]+",
                            "default": "v2.2"
                        },
                        "urukul0_ports": {
                            "type": "array",
                            "items": {
@ -295,6 +428,12 @@
                            "type": "integer",
                            "default": 32
                        },
                        "pll_en": {
                            "type": "integer",
                            "minimum": 0,
                            "maximum": 1,
                            "default": 1
                        },
                        "pll_vco": {
                            "type": "integer"
                        }
@ -370,10 +509,27 @@
                            "default": 100e6
                        },
                        "clk_sel": {
                            "oneOf": [
                                {
                                    "type": "integer",
                                    "minimum": 0,
-		            "maximum": 3,
+                                    "maximum": 3
                                },
                                {
                                    "type": "string",
                                    "enum": ["xo", "mmcx", "sma"]
                                }
                            ],
                            "default": 0
                        },
                        "almazny": {
                            "type": "boolean",
                            "default": false
                        },
                        "almazny_hw_rev": {
                            "type": "string",
                            "pattern": "^v[0-9]+\\.[0-9]+",
                            "default": "v1.2"
                        }
                    },
                    "required": ["ports"]
@ -423,6 +579,58 @@
                            },
                            "minItems": 1,
                            "maxItems": 1
                        },
                        "mode": {
                            "type": "string",
                            "enum": ["base", "miqro"],
                            "default": "base"
                        }
                    },
                    "required": ["ports"]
                }
            }, {
                "title": "HVAmp",
                "if": {
                    "properties": {
                        "type": {
                            "const": "hvamp"
                        }
                    }
                },
                "then": {
                    "properties": {
                        "ports": {
                            "type": "array",
                            "items": {
                                "type": "integer"
                            },
                            "minItems": 1,
                            "maxItems": 1
                        }
                    },
                    "required": ["ports"]
                }
            },{
                "title": "Shuttler",
                "if": {
                    "properties": {
                        "type": {
                            "const": "shuttler"
                        }
                    }
                },
                "then": {
                    "properties": {
                        "ports": {
                            "type": "array",
                            "items": {
                                "type": "integer"
                            },
                            "minItems": 1,
                            "maxItems": 2
                        },
                        "drtio_destination": {
                            "type": "integer"
                        }
                    },
                    "required": ["ports"]
--- a/artiq/coredevice/dac34h84.py
+++ b/artiq/coredevice/dac34h84.py
@ -110,7 +110,7 @@ class DAC34H84:
    syncsel_mixercd = 0b1001  # sif_sync and register write
    syncsel_nco = 0b1000  # sif_sync
    syncsel_fifo_input = 0b10  # external lvds istr
-    sif_sync = 1
+    sif_sync = 0
    syncsel_fifoin = 0b0010  # istr
    syncsel_fifoout = 0b0100  # ostr
@ -178,7 +178,8 @@ class DAC34H84:
            (self.collisiongone_ena << 12) | (self.sif4_ena << 7) |
            (self.mixer_ena << 6) | (self.mixer_gain << 5) |
            (self.nco_ena << 4) | (self.revbus << 3) | (self.twos << 1))
-        mmap.append((0x03 << 16) | (self.coarse_dac << 12) | (self.sif_txenable << 0))
+        mmap.append((0x03 << 16) | (self.coarse_dac << 12) |
                    (self.sif_txenable << 0))
        mmap.append(
            (0x07 << 16) |
            (self.mask_alarm_from_zerochk << 15) | (1 << 14) |
@ -200,7 +201,7 @@ class DAC34H84:
        mmap.append(
            (0x0d << 16) |
            (self.cmix_fs8 << 15) | (self.cmix_fs4 << 14) |
-            (self.cmix_fs2 << 12) | (self.cmix_nfs4 << 11) |
+            (self.cmix_fs2 << 13) | (self.cmix_nfs4 << 12) |
            (self.qmc_gainb << 0))
        mmap.append((0x0e << 16) | (self.qmc_gainc << 0))
        mmap.append(
--- a/artiq/coredevice/dma.py
+++ b/artiq/coredevice/dma.py
@ -6,7 +6,7 @@ alone could achieve.
 """
 from artiq.language.core import syscall, kernel
-from artiq.language.types import TInt32, TInt64, TStr, TNone, TTuple
+from artiq.language.types import TInt32, TInt64, TStr, TNone, TTuple, TBool
 from artiq.coredevice.exceptions import DMAError
 from numpy import int64
@ -17,7 +17,7 @@ def dma_record_start(name: TStr) -> TNone:
    raise NotImplementedError("syscall not simulated")
@syscall
-def dma_record_stop(duration: TInt64) -> TNone:
+def dma_record_stop(duration: TInt64, enable_ddma: TBool) -> TNone:
    raise NotImplementedError("syscall not simulated")
@syscall
@ -25,11 +25,11 @@ def dma_erase(name: TStr) -> TNone:
    raise NotImplementedError("syscall not simulated")
@syscall
-def dma_retrieve(name: TStr) -> TTuple([TInt64, TInt32]):
+def dma_retrieve(name: TStr) -> TTuple([TInt64, TInt32, TBool]):
    raise NotImplementedError("syscall not simulated")
@syscall
-def dma_playback(timestamp: TInt64, ptr: TInt32) -> TNone:
+def dma_playback(timestamp: TInt64, ptr: TInt32, enable_ddma: TBool) -> TNone:
    raise NotImplementedError("syscall not simulated")
@ -47,6 +47,7 @@ class DMARecordContextManager:
    def __init__(self):
        self.name = ""
        self.saved_now_mu = int64(0)
        self.enable_ddma = False
    @kernel
    def __enter__(self):
@ -56,7 +57,7 @@ class DMARecordContextManager:
    @kernel
    def __exit__(self, type, value, traceback):
-        dma_record_stop(now_mu()) # see above
+        dma_record_stop(now_mu(), self.enable_ddma) # see above
        at_mu(self.saved_now_mu)
@ -74,12 +75,20 @@ class CoreDMA:
        self.epoch    = 0
    @kernel
-    def record(self, name):
+    def record(self, name, enable_ddma=False):
        """Returns a context manager that will record a DMA trace called ``name``.
        Any previously recorded trace with the same name is overwritten.
-        The trace will persist across kernel switches."""
+        The trace will persist across kernel switches.
        In DRTIO context, distributed DMA can be toggled with ``enable_ddma``.
        Enabling it allows running DMA on satellites, rather than sending all
        events from the master.
        Keeping it disabled it may improve performance in some scenarios, 
        e.g. when there are many small satellite buffers."""
        self.epoch += 1
        self.recorder.name = name
        self.recorder.enable_ddma = enable_ddma
        return self.recorder
    @kernel
@ -92,24 +101,24 @@ class CoreDMA:
    def playback(self, name):
        """Replays a previously recorded DMA trace. This function blocks until
        the entire trace is submitted to the RTIO FIFOs."""
-        (advance_mu, ptr) = dma_retrieve(name)
+        (advance_mu, ptr, uses_ddma) = dma_retrieve(name)
-        dma_playback(now_mu(), ptr)
+        dma_playback(now_mu(), ptr, uses_ddma)
        delay_mu(advance_mu)
    @kernel
    def get_handle(self, name):
        """Returns a handle to a previously recorded DMA trace. The returned handle
        is only valid until the next call to :meth:`record` or :meth:`erase`."""
-        (advance_mu, ptr) = dma_retrieve(name)
+        (advance_mu, ptr, uses_ddma) = dma_retrieve(name)
-        return (self.epoch, advance_mu, ptr)
+        return (self.epoch, advance_mu, ptr, uses_ddma)
    @kernel
    def playback_handle(self, handle):
        """Replays a handle obtained with :meth:`get_handle`. Using this function
        is much faster than :meth:`playback` for replaying a set of traces repeatedly,
        but incurs the overhead of managing the handles onto the programmer."""
-        (epoch, advance_mu, ptr) = handle
+        (epoch, advance_mu, ptr, uses_ddma) = handle
        if self.epoch != epoch:
            raise DMAError("Invalid handle")
-        dma_playback(now_mu(), ptr)
+        dma_playback(now_mu(), ptr, uses_ddma)
        delay_mu(advance_mu)
--- a/artiq/coredevice/edge_counter.py
+++ b/artiq/coredevice/edge_counter.py
@ -91,6 +91,10 @@ class EdgeCounter:
        self.channel = channel
        self.counter_max = (1 << (gateware_width - 1)) - 1
    @staticmethod
    def get_rtio_channels(channel, **kwargs):
        return [(channel, None)]
    @kernel
    def gate_rising(self, duration):
        """Count rising edges for the given duration and request the total at
--- a/artiq/coredevice/exceptions.py
+++ b/artiq/coredevice/exceptions.py
@ -16,50 +16,94 @@ AssertionError = builtins.AssertionError
 class CoreException:
    """Information about an exception raised or passed through the core device."""
    def __init__(self, exceptions, exception_info, traceback, stack_pointers):
        self.exceptions = exceptions
        self.exception_info = exception_info
        self.traceback = list(traceback)
        self.stack_pointers = stack_pointers
-    def __init__(self, name, message, params, traceback):
+        first_exception = exceptions[0]
        name = first_exception[0]
        if ':' in name:
            exn_id, self.name = name.split(':', 2)
            self.id = int(exn_id)
        else:
            self.id, self.name = 0, name
-        self.message, self.params = message, params
+        self.message = first_exception[1]
-        self.traceback = list(traceback)
+        self.params = first_exception[2]
-    def __str__(self):
+    def append_backtrace(self, record, inlined=False):
-        lines = []
+        filename, line, column, function, address = record
        lines.append("Core Device Traceback (most recent call last):")
        last_address = 0
        for (filename, line, column, function, address) in self.traceback:
        stub_globals = {"__name__": filename, "__loader__": source_loader}
        source_line = linecache.getline(filename, line, stub_globals)
        indentation = re.search(r"^\s*", source_line).end()
        if address is None:
            formatted_address = ""
-            elif address == last_address:
+        elif inlined:
            formatted_address = " (inlined)"
        else:
            formatted_address = " (RA=+0x{:x})".format(address)
            last_address = address
        filename = filename.replace(artiq_dir, "<artiq>")
        lines = []
        if column == -1:
            lines.append("    {}".format(source_line.strip() if source_line else "<unknown>"))
            lines.append("  File \"{file}\", line {line}, in {function}{address}".
                         format(file=filename, line=line, function=function,
                                address=formatted_address))
                lines.append("    {}".format(source_line.strip() if source_line else "<unknown>"))
        else:
            lines.append("    {}^".format(" " * (column - indentation)))
            lines.append("    {}".format(source_line.strip() if source_line else "<unknown>"))
            lines.append("  File \"{file}\", line {line}, column {column},"
                         " in {function}{address}".
                         format(file=filename, line=line, column=column + 1,
                                function=function, address=formatted_address))
-                lines.append("    {}".format(source_line.strip() if source_line else "<unknown>"))
+        return lines
                lines.append("    {}^".format(" " * (column - indentation)))
-        lines.append("{}({}): {}".format(self.name, self.id,
+    def single_traceback(self, exception_index):
-                                         self.message.format(*self.params)))
+        # note that we insert in reversed order
-        return "\n".join(lines)
+        lines = []
        last_sp = 0
        start_backtrace_index = self.exception_info[exception_index][1]
        zipped = list(zip(self.traceback[start_backtrace_index:],
                          self.stack_pointers[start_backtrace_index:]))
        exception = self.exceptions[exception_index]
        name = exception[0]
        message = exception[1]
        params = exception[2]
        if ':' in name:
            exn_id, name = name.split(':', 2)
            exn_id = int(exn_id)
        else:
            exn_id = 0
        lines.append("{}({}): {}".format(name, exn_id, message.format(*params)))
        zipped.append(((exception[3], exception[4], exception[5], exception[6],
                       None, []), None))
        for ((filename, line, column, function, address, inlined), sp) in zipped:
            # backtrace of nested exceptions may be discontinuous
            # but the stack pointer must increase monotonically
            if sp is not None and sp <= last_sp:
                continue
            last_sp = sp
            for record in reversed(inlined):
                lines += self.append_backtrace(record, True)
            lines += self.append_backtrace((filename, line, column, function,
                                            address))
        lines.append("Traceback (most recent call first):")
        return "\n".join(reversed(lines))
    def __str__(self):
        tracebacks = [self.single_traceback(i) for i in range(len(self.exceptions))]
        traceback_str = ('\n\nDuring handling of the above exception, ' +
                        'another exception occurred:\n\n').join(tracebacks)
        return 'Core Device Traceback:\n' +\
                traceback_str +\
                '\n\nEnd of Core Device Traceback\n'
 class InternalError(Exception):
@ -104,6 +148,13 @@ class DMAError(Exception):
    artiq_builtin = True
 class SubkernelError(Exception):
    """Raised when an operation regarding a subkernel is invalid 
    or cannot be completed.
    """
    artiq_builtin = True
 class ClockFailure(Exception):
    """Raised when RTIO PLL has lost lock."""
--- a/artiq/coredevice/fastino.py
+++ b/artiq/coredevice/fastino.py
@ -1,11 +1,12 @@
 """RTIO driver for the Fastino 32channel, 16 bit, 2.5 MS/s per channel,
 streaming DAC.
 """
 from numpy import int32, int64
-from artiq.language.core import kernel, portable, delay
+from artiq.language.core import kernel, portable, delay, delay_mu
 from artiq.coredevice.rtio import (rtio_output, rtio_output_wide,
                                   rtio_input_data)
-from artiq.language.units import us
+from artiq.language.units import ns
 from artiq.language.types import TInt32, TList
@ -20,7 +21,7 @@ class Fastino:
    DAC updates synchronized to a frame edge.
    The `log2_width=0` RTIO layout uses one DAC channel per RTIO address and a
-    dense RTIO address space. The RTIO words are narrow. (32 bit) and
+    dense RTIO address space. The RTIO words are narrow (32 bit) and
    few-channel updates are efficient. There is the least amount of DAC state
    tracking in kernels, at the cost of more DMA and RTIO data.
    The setting here and in the RTIO PHY (gateware) must match.
@ -40,24 +41,52 @@ class Fastino:
    :param log2_width: Width of DAC channel group (logarithm base 2).
        Value must match the corresponding value in the RTIO PHY (gateware).
    """
-    kernel_invariants = {"core", "channel", "width"}
+    kernel_invariants = {"core", "channel", "width", "t_frame"}
    def __init__(self, dmgr, channel, core_device="core", log2_width=0):
        self.channel = channel << 8
        self.core = dmgr.get(core_device)
        self.width = 1 << log2_width
        # frame duration in mu (14 words each 7 clock cycles each 4 ns)
        # self.core.seconds_to_mu(14*7*4*ns)  # unfortunately this may round wrong
        assert self.core.ref_period == 1*ns
        self.t_frame = int64(14*7*4)
    @staticmethod
    def get_rtio_channels(channel, **kwargs):
        return [(channel, None)]
    @kernel
    def init(self):
        """Initialize the device.
-        This clears reset, unsets DAC_CLR, enables AFE_PWR,
+            * disables RESET, DAC_CLR, enables AFE_PWR
-        clears error counters, then enables error counting
+            * clears error counters, enables error counting
            * turns LEDs off
            * clears `hold` and `continuous` on all channels
            * clear and resets interpolators to unit rate change on all
              channels
        It does not change set channel voltages and does not reset the PLLs or clock
        domains.
        Note: On Fastino gateware before v0.2 this may lead to 0 voltage being emitted
        transiently.
        """
        self.set_cfg(reset=0, afe_power_down=0, dac_clr=0, clr_err=1)
-        delay(1*us)
+        delay_mu(self.t_frame)
        self.set_cfg(reset=0, afe_power_down=0, dac_clr=0, clr_err=0)
-        delay(1*us)
+        delay_mu(self.t_frame)
        self.set_continuous(0)
        delay_mu(self.t_frame)
        self.stage_cic(1)
        delay_mu(self.t_frame)
        self.apply_cic(0xffffffff)
        delay_mu(self.t_frame)
        self.set_leds(0)
        delay_mu(self.t_frame)
        self.set_hold(0)
        delay_mu(self.t_frame)
    @kernel
    def write(self, addr, data):
@ -77,8 +106,9 @@ class Fastino:
        :param addr: Address to read from.
        :return: The data read.
        """
-        rtio_output(self.channel | addr | 0x80)
+        raise NotImplementedError
-        return rtio_input_data(self.channel >> 8)
+        # rtio_output(self.channel | addr | 0x80)
        # return rtio_input_data(self.channel >> 8)
    @kernel
    def set_dac_mu(self, dac, data):
@ -112,7 +142,7 @@ class Fastino:
        :param voltage: Voltage in SI Volts.
        :return: DAC data word in machine units, 16 bit integer.
        """
-        data = int(round((0x8000/10.)*voltage)) + 0x8000
+        data = int32(round((0x8000/10.)*voltage)) + int32(0x8000)
        if data < 0 or data > 0xffff:
            raise ValueError("DAC voltage out of bounds")
        return data
@ -129,7 +159,7 @@ class Fastino:
            v = self.voltage_to_mu(voltage[i])
            if i & 1:
                v = data[i // 2] | (v << 16)
-            data[i // 2] = v
+            data[i // 2] = int32(v)
    @kernel
    def set_dac(self, dac, voltage):
@ -190,3 +220,85 @@ class Fastino:
            green LED.
        """
        self.write(0x23, leds)
    @kernel
    def set_continuous(self, channel_mask):
        """Enable continuous DAC updates on channels regardless of new data
        being submitted.
        """
        self.write(0x25, channel_mask)
    @kernel
    def stage_cic_mu(self, rate_mantissa, rate_exponent, gain_exponent):
        """Stage machine unit CIC interpolator configuration.
        """
        if rate_mantissa < 0 or rate_mantissa >= 1 << 6:
            raise ValueError("rate_mantissa out of bounds")
        if rate_exponent < 0 or rate_exponent >= 1 << 4:
            raise ValueError("rate_exponent out of bounds")
        if gain_exponent < 0 or gain_exponent >= 1 << 6:
            raise ValueError("gain_exponent out of bounds")
        config = rate_mantissa | (rate_exponent << 6) | (gain_exponent << 10)
        self.write(0x26, config)
    @kernel
    def stage_cic(self, rate) -> TInt32:
        """Compute and stage interpolator configuration.
        This method approximates the desired interpolation rate using a 10 bit
        floating point representation (6 bit mantissa, 4 bit exponent) and
        then determines an optimal interpolation gain compensation exponent
        to avoid clipping. Gains for rates that are powers of two are accurately
        compensated. Other rates lead to overall less than unity gain (but more
        than 0.5 gain).
        The overall gain including gain compensation is
        `actual_rate**order/2**ceil(log2(actual_rate**order))`
        where `order = 3`.
        Returns the actual interpolation rate.
        """
        if rate <= 0 or rate > 1 << 16:
            raise ValueError("rate out of bounds")
        rate_mantissa = rate
        rate_exponent = 0
        while rate_mantissa > 1 << 6:
            rate_exponent += 1
            rate_mantissa >>= 1
        order = 3
        gain = 1
        for i in range(order):
            gain *= rate_mantissa
        gain_exponent = 0
        while gain > 1 << gain_exponent:
            gain_exponent += 1
        gain_exponent += order*rate_exponent
        assert gain_exponent <= order*16
        self.stage_cic_mu(rate_mantissa - 1, rate_exponent, gain_exponent)
        return rate_mantissa << rate_exponent
    @kernel
    def apply_cic(self, channel_mask):
        """Apply the staged interpolator configuration on the specified channels.
        Each Fastino channel starting with gateware v0.2 includes a fourth order
        (cubic) CIC interpolator with variable rate change and variable output
        gain compensation (see :meth:`stage_cic`).
        Fastino gateware before v0.2 does not include the interpolators and the
        methods affecting the CICs should not be used.
        Channels using non-unity interpolation rate should have
        continous DAC updates enabled (see :meth:`set_continuous`) unless
        their output is supposed to be constant.
        This method resets and settles the affected interpolators. There will be
        no output updates for the next `order = 3` input samples.
        Affected channels will only accept one input sample per input sample
        period. This method synchronizes the input sample period to the current
        frame on the affected channels.
        If application of new interpolator settings results in a change of the
        overall gain, there will be a corresponding output step.
        """
        self.write(0x27, channel_mask)
--- a/artiq/coredevice/grabber.py
+++ b/artiq/coredevice/grabber.py
@ -25,6 +25,10 @@ class Grabber:
        # ROI engine outputs for one video frame.
        self.sentinel = int32(int64(2**count_width))
    @staticmethod
    def get_rtio_channels(channel_base, **kwargs):
        return [(channel_base, "ROI coordinates"), (channel_base + 1, "ROI mask")]
    @kernel
    def setup_roi(self, n, x0, y0, x1, y1):
        """
--- a/artiq/coredevice/i2c.py
+++ b/artiq/coredevice/i2c.py
@ -33,6 +33,11 @@ def i2c_read(busno: TInt32, ack: TBool) -> TInt32:
    raise NotImplementedError("syscall not simulated")
@syscall(flags={"nounwind", "nowrite"})
 def i2c_switch_select(busno: TInt32, address: TInt32, mask: TInt32) -> TNone:
    raise NotImplementedError("syscall not simulated")
@kernel
 def i2c_poll(busno, busaddr):
    """Poll I2C device at address.
@ -137,8 +142,10 @@ def i2c_read_many(busno, busaddr, addr, data):
        i2c_stop(busno)
-class PCA9548:
+class I2CSwitch:
-    """Driver for the PCA9548 I2C bus switch.
+    """Driver for the I2C bus switch.
    PCA954X (or other) type detection is done by the CPU during I2C init.
    I2C transactions not real-time, and are performed by the CPU without
    involving RTIO.
@ -151,25 +158,19 @@ class PCA9548:
        self.busno = busno
        self.address = address
    @kernel
    def select(self, mask):
        """Enable/disable channels.
        :param mask: Bit mask of enabled channels
        """
        i2c_write_byte(self.busno, self.address, mask)
    @kernel
    def set(self, channel):
        """Enable one channel.
        :param channel: channel number (0-7)
        """
-        self.select(1 << channel)
+        i2c_switch_select(self.busno, self.address >> 1, 1 << channel)
    @kernel
-    def readback(self):
+    def unset(self):
-        return i2c_read_byte(self.busno, self.address)
+        """Disable output of the I2C switch.
        """
        i2c_switch_select(self.busno, self.address >> 1, 0)
 class TCA6424A:
@ -207,3 +208,46 @@ class TCA6424A:
        self._write24(0x8c, 0)  # set all directions to output
        self._write24(0x84, outputs_le)  # set levels
 class PCF8574A:
    """Driver for the PCF8574 I2C remote 8-bit I/O expander.
    I2C transactions not real-time, and are performed by the CPU without
    involving RTIO.
    """
    def __init__(self, dmgr, busno=0, address=0x7c, core_device="core"):
        self.core = dmgr.get(core_device)
        self.busno = busno
        self.address = address
    @kernel
    def set(self, data):
        """Drive data on the quasi-bidirectional pins.
        :param data: Pin data. High bits are weakly driven high
            (and thus inputs), low bits are strongly driven low.
        """
        i2c_start(self.busno)
        try:
            if not i2c_write(self.busno, self.address):
                raise I2CError("PCF8574A failed to ack address")
            if not i2c_write(self.busno, data):
                raise I2CError("PCF8574A failed to ack data")
        finally:
            i2c_stop(self.busno)
    @kernel
    def get(self):
        """Retrieve quasi-bidirectional pin input data.
        :return: Pin data
        """
        i2c_start(self.busno)
        ret = 0
        try:
            if not i2c_write(self.busno, self.address | 1):
                raise I2CError("PCF8574A failed to ack address")
            ret = i2c_read(self.busno, False)
        finally:
            i2c_stop(self.busno)
        return ret
--- a/artiq/coredevice/jsondesc.py
+++ b/artiq/coredevice/jsondesc.py
@ -32,4 +32,7 @@ def load(description_path):
    global validator
    validator.validate(result)
    if result["base"] != "use_drtio_role":
        result["drtio_role"] = result["base"]
    return result
--- a/artiq/coredevice/kasli_i2c.py
+++ b/artiq/coredevice/kasli_i2c.py
@ -37,13 +37,17 @@ class KasliEEPROM:
    @kernel
    def select(self):
        mask = 1 << self.port
-        self.sw0.select(mask)
+        if self.port < 8:
-        self.sw1.select(mask >> 8)
+            self.sw0.set(self.port)
            self.sw1.unset()
        else:
            self.sw0.unset()
            self.sw1.set(self.port - 8)
    @kernel
    def deselect(self):
-        self.sw0.select(0)
+        self.sw0.unset()
-        self.sw1.select(0)
+        self.sw1.unset()
    @kernel
    def write_i32(self, addr, value):
--- a/artiq/coredevice/mirny.py
+++ b/artiq/coredevice/mirny.py
@ -1,7 +1,7 @@
 """RTIO driver for Mirny (4 channel GHz PLLs)
 """
-from artiq.language.core import kernel, delay
+from artiq.language.core import kernel, delay, portable
 from artiq.language.units import us
 from numpy import int32
@ -40,9 +40,8 @@ class Mirny:
    :param refclk: Reference clock (SMA, MMCX or on-board 100 MHz oscillator)
        frequency in Hz
    :param clk_sel: Reference clock selection.
-        valid options are: "XO" - onboard crystal oscillator
+        Valid options are: "XO" - onboard crystal oscillator;
-                           "SMA" - front-panel SMA connector
+        "SMA" - front-panel SMA connector; "MMCX" - internal MMCX connector.
                           "MMCX" - internal MMCX connector
        Passing an integer writes it as ``clk_sel`` in the CPLD's register 1.
        The effect depends on the hardware revision.
    :param core_device: Core device name (default: "core")
@ -123,6 +122,18 @@ class Mirny:
        self.write_reg(1, (self.clk_sel << 4))
        delay(1000 * us)
    @portable(flags={"fast-math"})
    def att_to_mu(self, att):
        """Convert an attenuation setting in dB to machine units.
        :param att: Attenuation setting in dB.
        :return: Digital attenuation setting.
        """
        code = int32(255) - int32(round(att * 8))
        if code < 0 or code > 255:
            raise ValueError("Invalid Mirny attenuation!")
        return code
    @kernel
    def set_att_mu(self, channel, att):
        """Set digital step attenuator in machine units.
@ -133,11 +144,26 @@ class Mirny:
        self.bus.write(((channel | 8) << 25) | (att << 16))
    @kernel
-    def write_ext(self, addr, length, data):
+    def set_att(self, channel, att):
        """Set digital step attenuator in SI units.
        This method will write the attenuator settings of the selected channel.
        .. seealso:: :meth:`set_att_mu`
        :param channel: Attenuator channel (0-3).
        :param att: Attenuation setting in dB. Higher value is more
            attenuation. Minimum attenuation is 0*dB, maximum attenuation is
            31.5*dB.
        """
        self.set_att_mu(channel, self.att_to_mu(att))
    @kernel
    def write_ext(self, addr, length, data, ext_div=SPIT_WR):
        """Perform SPI write to a prefixed address"""
        self.bus.set_config_mu(SPI_CONFIG, 8, SPIT_WR, SPI_CS)
        self.bus.write(addr << 25)
-        self.bus.set_config_mu(SPI_CONFIG | spi.SPI_END, length, SPIT_WR, SPI_CS)
+        self.bus.set_config_mu(SPI_CONFIG | spi.SPI_END, length, ext_div, SPI_CS)
        if length < 32:
            data <<= 32 - length
        self.bus.write(data)
--- a/artiq/coredevice/pcf8574a.py
+++ b/artiq/coredevice/pcf8574a.py
@ -1,47 +0,0 @@
 from artiq.experiment import kernel
 from artiq.coredevice.i2c import (
    i2c_start, i2c_write, i2c_read, i2c_stop, I2CError)
 class PCF8574A:
    """Driver for the PCF8574 I2C remote 8-bit I/O expander.
    I2C transactions not real-time, and are performed by the CPU without
    involving RTIO.
    """
    def __init__(self, dmgr, busno=0, address=0x7c, core_device="core"):
        self.core = dmgr.get(core_device)
        self.busno = busno
        self.address = address
    @kernel
    def set(self, data):
        """Drive data on the quasi-bidirectional pins.
        :param data: Pin data. High bits are weakly driven high
            (and thus inputs), low bits are strongly driven low.
        """
        i2c_start(self.busno)
        try:
            if not i2c_write(self.busno, self.address):
                raise I2CError("PCF8574A failed to ack address")
            if not i2c_write(self.busno, data):
                raise I2CError("PCF8574A failed to ack data")
        finally:
            i2c_stop(self.busno)
    @kernel
    def get(self):
        """Retrieve quasi-bidirectional pin input data.
        :return: Pin data
        """
        i2c_start(self.busno)
        ret = 0
        try:
            if not i2c_write(self.busno, self.address | 1):
                raise I2CError("PCF8574A failed to ack address")
            ret = i2c_read(self.busno, False)
        finally:
            i2c_stop(self.busno)
        return ret
--- a/artiq/coredevice/pcu.py
+++ b/artiq/coredevice/pcu.py
@ -1,77 +0,0 @@
 from .spr import mtspr, mfspr
 from artiq.language.core import kernel
 _MAX_SPRS_PER_GRP_BITS = 11
 _SPRGROUP_PC = 7 << _MAX_SPRS_PER_GRP_BITS
 _SPR_PCMR_CP    = 0x00000001  # Counter present
 _SPR_PCMR_CISM  = 0x00000004  # Count in supervisor mode
 _SPR_PCMR_CIUM  = 0x00000008  # Count in user mode
 _SPR_PCMR_LA    = 0x00000010  # Load access event
 _SPR_PCMR_SA    = 0x00000020  # Store access event
 _SPR_PCMR_IF    = 0x00000040  # Instruction fetch event
 _SPR_PCMR_DCM   = 0x00000080  # Data cache miss event
 _SPR_PCMR_ICM   = 0x00000100  # Insn cache miss event
 _SPR_PCMR_IFS   = 0x00000200  # Insn fetch stall event
 _SPR_PCMR_LSUS  = 0x00000400  # LSU stall event
 _SPR_PCMR_BS    = 0x00000800  # Branch stall event
 _SPR_PCMR_DTLBM = 0x00001000  # DTLB miss event
 _SPR_PCMR_ITLBM = 0x00002000  # ITLB miss event
 _SPR_PCMR_DDS   = 0x00004000  # Data dependency stall event
 _SPR_PCMR_WPE   = 0x03ff8000  # Watchpoint events
@kernel(flags={"nowrite", "nounwind"})
 def _PCCR(n):
    return _SPRGROUP_PC + n
@kernel(flags={"nowrite", "nounwind"})
 def _PCMR(n):
    return _SPRGROUP_PC + 8 + n
 class CorePCU:
    """Core device performance counter unit (PCU) access"""
    def __init__(self, dmgr, core_device="core"):
        self.core = dmgr.get(core_device)
    @kernel
    def start(self):
        """
        Configure and clear the kernel CPU performance counters.
        The eight counters are configured to count the following events:
            * Load or store
            * Instruction fetch
            * Data cache miss
            * Instruction cache miss
            * Instruction fetch stall
            * Load-store-unit stall
            * Branch stall
            * Data dependency stall
        """
        for i in range(8):
            if not mfspr(_PCMR(i)) & _SPR_PCMR_CP:
                raise ValueError("counter not present")
            mtspr(_PCMR(i), 0)
            mtspr(_PCCR(i), 0)
        mtspr(_PCMR(0), _SPR_PCMR_CISM | _SPR_PCMR_LA | _SPR_PCMR_SA)
        mtspr(_PCMR(1), _SPR_PCMR_CISM | _SPR_PCMR_IF)
        mtspr(_PCMR(2), _SPR_PCMR_CISM | _SPR_PCMR_DCM)
        mtspr(_PCMR(3), _SPR_PCMR_CISM | _SPR_PCMR_ICM)
        mtspr(_PCMR(4), _SPR_PCMR_CISM | _SPR_PCMR_IFS)
        mtspr(_PCMR(5), _SPR_PCMR_CISM | _SPR_PCMR_LSUS)
        mtspr(_PCMR(6), _SPR_PCMR_CISM | _SPR_PCMR_BS)
        mtspr(_PCMR(7), _SPR_PCMR_CISM | _SPR_PCMR_DDS)
    @kernel
    def get(self, r):
        """
        Read the performance counters and store the counts in the
        array provided.
        :param list[int] r: array to store the counter values
        """
        for i in range(8):
            r[i] = mfspr(_PCCR(i))
--- a/artiq/coredevice/phaser.py
+++ b/artiq/coredevice/phaser.py
@ -1,12 +1,18 @@
 from numpy import int32, int64
 from artiq.language.core import kernel, delay_mu, delay
-from artiq.coredevice.rtio import rtio_output, rtio_input_data
+from artiq.coredevice.rtio import rtio_output, rtio_input_data, rtio_input_timestamp
-from artiq.language.units import us, ns, ms, MHz, dB
+from artiq.language.units import us, ns, ms, MHz
 from artiq.language.types import TInt32
 from artiq.coredevice.dac34h84 import DAC34H84
 from artiq.coredevice.trf372017 import TRF372017
 PHASER_BOARD_ID = 19
 PHASER_GW_BASE = 1
 PHASER_GW_MIQRO = 2
 PHASER_ADDR_BOARD_ID = 0x00
 PHASER_ADDR_HW_REV = 0x01
 PHASER_ADDR_GW_REV = 0x02
@ -38,6 +44,20 @@ PHASER_ADDR_DUC1_P = 0x26
 PHASER_ADDR_DAC1_DATA = 0x28
 PHASER_ADDR_DAC1_TEST = 0x2c
 # servo registers
 PHASER_ADDR_SERVO_CFG0 = 0x30
 PHASER_ADDR_SERVO_CFG1 = 0x31
 # 0x32 - 0x71 servo coefficients + offset data
 PHASER_ADDR_SERVO_DATA_BASE = 0x32
 # 0x72 - 0x78 Miqro channel profile/window memories
 PHASER_ADDR_MIQRO_MEM_ADDR = 0x72
 PHASER_ADDR_MIQRO_MEM_DATA = 0x74
 # Miqro profile memory select
 PHASER_MIQRO_SEL_PROFILE = 1 << 14
 PHASER_SEL_DAC = 1 << 0
 PHASER_SEL_TRF0 = 1 << 1
 PHASER_SEL_TRF1 = 1 << 2
@ -56,6 +76,11 @@ PHASER_DAC_SEL_TEST = 1
 PHASER_HW_REV_VARIANT = 1 << 4
 SERVO_COEFF_WIDTH = 16
 SERVO_DATA_WIDTH = 16
 SERVO_COEFF_SHIFT = 14
 SERVO_T_CYCLE = (32+12+192+24+4)*ns  # Must match gateware ADC parameters
 class Phaser:
    """Phaser 4-channel, 16-bit, 1 GS/s DAC coredevice driver.
@ -63,6 +88,26 @@ class Phaser:
    Phaser contains a 4 channel, 1 GS/s DAC chip with integrated upconversion,
    quadrature modulation compensation and interpolation features.
    The coredevice RTIO PHY and the Phaser gateware come in different modes
    that have different features. Phaser mode and coredevice PHY mode are both
    selected at their respective gateware compile-time and need to match.
    ===============  ==============  ===================================
    Phaser gateware  Coredevice PHY  Features per :class:`PhaserChannel`
    ===============  ==============  ===================================
    Base <= v0.5     Base            Base (5 :class:`PhaserOscillator`)
    Base >= v0.6     Base            Base + Servo
    Miqro >= v0.6    Miqro           :class:`Miqro`
    ===============  ==============  ===================================
    The coredevice driver (this class and :class:`PhaserChannel`) exposes
    the superset of all functionality regardless of the Coredevice RTIO PHY
    or Phaser gateware modes. This is to evade type unification limitations.
    Features absent in Coredevice PHY/Phaser gateware will not work and
    should not be accessed.
    **Base mode**
    The coredevice produces 2 IQ (in-phase and quadrature) data streams with 25
    MS/s and 14 bit per quadrature. Each data stream supports 5 independent
    numerically controlled IQ oscillators (NCOs, DDSs with 32 bit frequency, 16
@ -84,12 +129,22 @@ class Phaser:
    LVDS bus operating at 1 Gb/s per pin pair and processed in the DAC (Texas
    Instruments DAC34H84). On the DAC 2x interpolation, sinx/x compensation,
    quadrature modulator compensation, fine and coarse mixing as well as group
-    delay capabilities are available.
+    delay capabilities are available. If desired, these features my be
    configured via the `dac` dictionary.
    The latency/group delay from the RTIO events setting
    :class:`PhaserOscillator` or :class:`PhaserChannel` DUC parameters all the
    way to the DAC outputs is deterministic. This enables deterministic
-    absolute phase with respect to other RTIO input and output events.
+    absolute phase with respect to other RTIO input and output events
    (see `get_next_frame_mu()`).
    **Miqro mode**
    See :class:`Miqro`
    Here the DAC operates in 4x interpolation.
    **Analog flow**
    The four analog DAC outputs are passed through anti-aliasing filters.
@ -108,6 +163,33 @@ class Phaser:
    configured through a shared SPI bus that is accessed and controlled via
    FPGA registers.
    **Servo**
    Each phaser output channel features a servo to control the RF output amplitude
    using feedback from an ADC. The servo consists of a first order IIR (infinite
    impulse response) filter fed by the ADC and a multiplier that scales the I
    and Q datastreams from the DUC by the IIR output. The IIR state is updated at
    the 3.788 MHz ADC sampling rate.
    Each channel IIR features 4 profiles, each consisting of the [b0, b1, a1] filter
    coefficients as well as an output offset. The coefficients and offset can be
    set for each profile individually and the profiles each have their own ``y0``,
    ``y1`` output registers (the ``x0``, ``x1`` inputs are shared). To avoid
    transient effects, care should be taken to not update the coefficents in the
    currently selected profile.
    The servo can be en- or disabled for each channel. When disabled, the servo
    output multiplier is simply bypassed and the datastream reaches the DAC unscaled.
    The IIR output can be put on hold for each channel. In hold mode, the filter
    still ingests samples and updates its input ``x0`` and ``x1`` registers, but
    does not update the ``y0``, ``y1`` output registers.
    After power-up the servo is disabled, in profile 0, with coefficients [0, 0, 0]
    and hold is enabled. If older gateware without ther servo is loaded onto the
    Phaser FPGA, the device simply behaves as if the servo is disabled and none of
    the servo functions have any effect.
    .. note:: Various register settings of the DAC and the quadrature
        upconverters are available to be modified through the `dac`, `trf0`,
        `trf1` dictionaries. These can be set through the device database
@ -147,7 +229,7 @@ class Phaser:
                         "dac_mmap"}
    def __init__(self, dmgr, channel_base, miso_delay=1, tune_fifo_offset=True,
-                 clk_sel=0, sync_dly=0, dac=None, trf0=None, trf1=None,
+                 clk_sel=0, sync_dly=0, dac=None, trf0=None, trf1=None, gw_rev=PHASER_GW_BASE,
                 core_device="core"):
        self.channel_base = channel_base
        self.core = dmgr.get(core_device)
@ -157,15 +239,29 @@ class Phaser:
        # self.core.seconds_to_mu(10*8*4*ns)  # unfortunately this returns 319
        assert self.core.ref_period == 1*ns
        self.t_frame = 10*8*4
        self.frame_tstamp = int64(0)
        self.clk_sel = clk_sel
        self.tune_fifo_offset = tune_fifo_offset
        self.sync_dly = sync_dly
        self.gw_rev = gw_rev  # verified in init()
        self.dac_mmap = DAC34H84(dac).get_mmap()
        self.channel = [PhaserChannel(self, ch, trf)
                        for ch, trf in enumerate([trf0, trf1])]
    @staticmethod
    def get_rtio_channels(channel_base, gw_rev=PHASER_GW_BASE, **kwargs):
        if gw_rev == PHASER_GW_MIQRO:
            return [(channel_base, "base"), (channel_base + 1, "ch0"), (channel_base + 2, "ch1")]
        elif gw_rev == PHASER_GW_BASE:
            return [(channel_base, "base"),
                    (channel_base + 1, "ch0 frequency"),
                    (channel_base + 2, "ch0 phase amplitude"),
                    (channel_base + 3, "ch1 frequency"),
                    (channel_base + 4, "ch1 phase amplitude")]
        raise ValueError("invalid gw_rev `{}`".format(gw_rev))
    @kernel
    def init(self, debug=False):
        """Initialize the board.
@ -184,6 +280,10 @@ class Phaser:
        is_baseband = hw_rev & PHASER_HW_REV_VARIANT
        gw_rev = self.read8(PHASER_ADDR_GW_REV)
        if debug:
            print("gw_rev:", self.gw_rev)
            self.core.break_realtime()
        assert gw_rev == self.gw_rev
        delay(.1*ms)  # slack
        # allow a few errors during startup and alignment since boot
@ -191,6 +291,12 @@ class Phaser:
            raise ValueError("large number of frame CRC errors")
        delay(.1*ms)  # slack
        # determine the origin for frame-aligned timestamps
        self.measure_frame_timestamp()
        if self.frame_tstamp < 0:
            raise ValueError("frame timestamp measurement timed out")
        delay(.1*ms)
        # reset
        self.set_cfg(dac_resetb=0, dac_sleep=1, dac_txena=0,
                     trf0_ps=1, trf1_ps=1,
@ -223,6 +329,8 @@ class Phaser:
        for data in self.dac_mmap:
            self.dac_write(data >> 16, data)
            delay(120*us)
        self.dac_sync()
        delay(40*us)
        # pll_ndivsync_ena disable
@ -254,7 +362,7 @@ class Phaser:
        if self.tune_fifo_offset:
            fifo_offset = self.dac_tune_fifo_offset()
            if debug:
-                print(fifo_offset)
+                print("fifo_offset:", fifo_offset)
                self.core.break_realtime()
        # self.dac_write(0x20, 0x0000)  # stop fifo sync
@ -266,12 +374,22 @@ class Phaser:
        delay(.1*ms)  # slack
        if alarms & ~0x0040:  # ignore PLL alarms (see DS)
            if debug:
-                print(alarms)
+                print("alarms:", alarms)
                self.core.break_realtime()
                # ignore alarms
            else:
                raise ValueError("DAC alarm")
        # avoid malformed output for: mixer_ena=1, nco_ena=0 after power up
        self.dac_write(self.dac_mmap[2] >> 16, self.dac_mmap[2] | (1 << 4))
        delay(40*us)
        self.dac_sync()
        delay(100*us)
        self.dac_write(self.dac_mmap[2] >> 16, self.dac_mmap[2])
        delay(40*us)
        self.dac_sync()
        delay(100*us)
        # power up trfs, release att reset
        self.set_cfg(clk_sel=self.clk_sel, dac_txena=0)
@ -282,8 +400,11 @@ class Phaser:
            if channel.get_att_mu() != 0x5a:
                raise ValueError("attenuator test failed")
            delay(.1*ms)
-            channel.set_att_mu(0x00)  # minimum attenuation
+            channel.set_att_mu(0x00)  # maximum attenuation
            channel.set_servo(profile=0, enable=0, hold=1)
            if self.gw_rev == PHASER_GW_BASE:
                # test oscillators and DUC
                for i in range(len(channel.oscillator)):
                    oscillator = channel.oscillator[i]
@ -299,6 +420,9 @@ class Phaser:
                self.duc_stb()
                delay(.1*ms)  # settle link, pipeline and impulse response
                data = channel.get_dac_data()
                delay(1*us)
                channel.oscillator[0].set_amplitude_phase_mu(asf=0, pow=0xc000,
                                                            clr=1)
                delay(.1*ms)
                sqrt2 = 0x5a81  # 0x7fff/sqrt(2)
                data_i = data & 0xffff
@ -308,6 +432,9 @@ class Phaser:
                        abs(data_i - data_q) > 2):
                    raise ValueError("DUC+oscillator phase/amplitude test failed")
            if self.gw_rev == PHASER_GW_MIQRO:
                channel.miqro.reset()
            if is_baseband:
                continue
@ -318,6 +445,7 @@ class Phaser:
            delay(.2*ms)
            for data in channel.trf_mmap:
                channel.trf_write(data)
            channel.cal_trf_vco()
            delay(2*ms)  # lock
            if not (self.get_sta() & (PHASER_STA_TRF0_LD << ch)):
@ -326,6 +454,7 @@ class Phaser:
            if channel.trf_read(0) & 0x1000:
                raise ValueError("TRF R_SAT_ERR")
            delay(.1*ms)
            channel.en_trf_out()
        # enable dac tx
        self.set_cfg(clk_sel=self.clk_sel)
@ -351,6 +480,12 @@ class Phaser:
        response = rtio_input_data(self.channel_base)
        return response >> self.miso_delay
    @kernel
    def write16(self, addr, data: TInt32):
        """Write 16 bit to a sequence of FPGA registers."""
        self.write8(addr, data >> 8)
        self.write8(addr + 1, data)
    @kernel
    def write32(self, addr, data: TInt32):
        """Write 32 bit to a sequence of FPGA registers."""
@ -429,8 +564,7 @@ class Phaser:
        * :const:`PHASER_STA_TRF1_LD`: Quadrature upconverter 1 lock detect
        * :const:`PHASER_STA_TERM0`: ADC channel 0 termination indicator
        * :const:`PHASER_STA_TERM1`: ADC channel 1 termination indicator
-        * :const:`PHASER_STA_SPI_IDLE`: SPI machine is idle and data registers
+        * :const:`PHASER_STA_SPI_IDLE`: SPI machine is idle and data registers can be read/written
            can be read/written
        :return: Status register
        """
@ -445,6 +579,27 @@ class Phaser:
        """
        return self.read8(PHASER_ADDR_CRC_ERR)
    @kernel
    def measure_frame_timestamp(self):
        """Measure the timestamp of an arbitrary frame and store it in `self.frame_tstamp`.
        To be used as reference for aligning updates to the FastLink frames.
        See `get_next_frame_mu()`.
        """
        rtio_output(self.channel_base << 8, 0)  # read any register
        self.frame_tstamp = rtio_input_timestamp(now_mu() + 4 * self.t_frame, self.channel_base)
        delay(100 * us)
    @kernel
    def get_next_frame_mu(self):
        """Return the timestamp of the frame strictly after `now_mu()`.
        Register updates (DUC, DAC, TRF, etc.) scheduled at this timestamp and multiples
        of `self.t_frame` later will have deterministic latency to output.
        """
        n = int64((now_mu() - self.frame_tstamp) / self.t_frame)
        return self.frame_tstamp + (n + 1) * self.t_frame
    @kernel
    def set_sync_dly(self, dly):
        """Set SYNC delay.
@ -549,6 +704,48 @@ class Phaser:
        """
        return self.dac_read(0x06, div=257) >> 8
    @kernel
    def dac_sync(self):
        """Trigger DAC synchronisation for both output channels.
        The DAC sif_sync is de-asserts, then asserted. The synchronisation is
        triggered on assertion.
        By default, the fine-mixer (NCO) and QMC are synchronised. This
        includes applying the latest register settings.
        The synchronisation sources may be configured through the `syncsel_x`
        fields in the `dac` configuration dictionary (see `__init__()`).
        .. note:: Synchronising the NCO clears the phase-accumulator
        """
        config1f = self.dac_read(0x1f)
        delay(.4*ms)
        self.dac_write(0x1f, config1f & ~int32(1 << 1))
        self.dac_write(0x1f, config1f | (1 << 1))
    @kernel
    def set_dac_cmix(self, fs_8_step):
        """Set the DAC coarse mixer frequency for both channels
        Use of the coarse mixer requires the DAC mixer to be enabled. The mixer
        can be configured via the `dac` configuration dictionary (see
        `__init__()`).
        The selected coarse mixer frequency becomes active without explicit
        synchronisation.
        :param fs_8_step: coarse mixer frequency shift in 125 MHz steps. This
            should be an integer between -3 and 4 (inclusive).
        """
        # values recommended in data-sheet
        #         0       1       2       3       4       -3      -2      -1
        vals = [0b0000, 0b1000, 0b0100, 0b1100, 0b0010, 0b1010, 0b0001, 0b1110]
        cmix = vals[fs_8_step%8]
        config0d = self.dac_read(0x0d)
        delay(.1*ms)
        self.dac_write(0x0d, (config0d & ~(0b1111 << 12)) | (cmix << 12))
    @kernel
    def get_dac_alarms(self):
        """Read the DAC alarm flags.
@ -566,7 +763,7 @@ class Phaser:
    def dac_iotest(self, pattern) -> TInt32:
        """Performs a DAC IO test according to the datasheet.
-        :param patterm: List of four int32 containing the pattern
+        :param pattern: List of four int32 containing the pattern
        :return: Bit error mask (16 bits)
        """
        if len(pattern) != 4:
@ -643,6 +840,8 @@ class Phaser:
            if good & (1 << o):
                sum += o
                count += 1
        if count == 0:
            raise ValueError("no good fifo offset")
        best = ((sum // count) + offset) % 8
        self.dac_write(0x09, (config9 & 0x1fff) | (best << 13))
        return best
@ -653,18 +852,21 @@ class PhaserChannel:
    A Phaser channel contains:
-    * multiple oscillators (in the coredevice phy),
+    * multiple :class:`PhaserOscillator` (in the coredevice phy),
    * an interpolation chain and digital upconverter (DUC) on Phaser,
    * a :class:`Miqro` instance on Phaser,
    * several channel-specific settings in the DAC:
        * quadrature modulation compensation QMC
        * numerically controlled oscillator NCO or coarse mixer CMIX,
-    * the analog quadrature upconverter (in the Phaser-Upconverter hardware
+
-        variant), and
+    * the analog quadrature upconverter (in the Phaser-Upconverter hardware variant), and
    * a digitally controlled step attenuator.
    Attributes:
    * :attr:`oscillator`: List of five :class:`PhaserOscillator`.
    * :attr:`miqro`: A :class:`Miqro`.
    .. note:: The amplitude sum of the oscillators must be less than one to
        avoid clipping or overflow. If any of the DDS or DUC frequencies are
@ -677,6 +879,8 @@ class PhaserChannel:
        changes in oscillator parameters, the overshoot can lead to clipping
        or overflow after the interpolation. Either band-limit any changes
        in the oscillator parameters or back off the amplitude sufficiently.
        Miqro is not affected by this. But both the oscillators and Miqro can
        be affected by intrinsic overshoot of the interpolator on the DAC.
    """
    kernel_invariants = {"index", "phaser", "trf_mmap"}
@ -684,7 +888,9 @@ class PhaserChannel:
        self.phaser = phaser
        self.index = index
        self.trf_mmap = TRF372017(trf).get_mmap()
        self.oscillator = [PhaserOscillator(self, osc) for osc in range(5)]
        self.miqro = Miqro(self)
    @kernel
    def get_dac_data(self) -> TInt32:
@ -761,6 +967,12 @@ class PhaserChannel:
    def set_nco_frequency_mu(self, ftw):
        """Set the NCO frequency.
        This method stages the new NCO frequency, but does not apply it.
        Use of the DAC-NCO requires the DAC mixer and NCO to be enabled. These
        can be configured via the `dac` configuration dictionary (see
        `__init__()`).
        :param ftw: NCO frequency tuning word (32 bit)
        """
        self.phaser.dac_write(0x15 + (self.index << 1), ftw >> 16)
@ -770,6 +982,12 @@ class PhaserChannel:
    def set_nco_frequency(self, frequency):
        """Set the NCO frequency in SI units.
        This method stages the new NCO frequency, but does not apply it.
        Use of the DAC-NCO requires the DAC mixer and NCO to be enabled. These
        can be configured via the `dac` configuration dictionary (see
        `__init__()`).
        :param frequency: NCO frequency in Hz (passband from -400 MHz
            to 400 MHz, wrapping around at +- 500 MHz)
        """
@ -780,6 +998,16 @@ class PhaserChannel:
    def set_nco_phase_mu(self, pow):
        """Set the NCO phase offset.
        By default, the new NCO phase applies on completion of the SPI
        transfer. This also causes a staged NCO frequency to be applied.
        Different triggers for applying NCO settings may be configured through
        the `syncsel_mixerxx` fields in the `dac` configuration dictionary (see
        `__init__()`).
        Use of the DAC-NCO requires the DAC mixer and NCO to be enabled. These
        can be configured via the `dac` configuration dictionary (see
        `__init__()`).
        :param pow: NCO phase offset word (16 bit)
        """
        self.phaser.dac_write(0x12 + self.index, pow)
@ -788,10 +1016,20 @@ class PhaserChannel:
    def set_nco_phase(self, phase):
        """Set the NCO phase in SI units.
        By default, the new NCO phase applies on completion of the SPI
        transfer. This also causes a staged NCO frequency to be applied.
        Different triggers for applying NCO settings may be configured through
        the `syncsel_mixerxx` fields in the `dac` configuration dictionary (see
        `__init__()`).
        Use of the DAC-NCO requires the DAC mixer and NCO to be enabled. These
        can be configured via the `dac` configuration dictionary (see
        `__init__()`).
        :param phase: NCO phase in turns
        """
        pow = int32(round(phase*(1 << 16)))
-        self.set_duc_phase_mu(pow)
+        self.set_nco_phase_mu(pow)
    @kernel
    def set_att_mu(self, data):
@ -886,12 +1124,165 @@ class PhaserChannel:
        return self.trf_write(0x00000008 | (cnt_mux_sel << 27),
                              readback=True)
    @kernel
    def cal_trf_vco(self):
        """Start calibration of the upconverter (hardware variant) VCO.
        TRF outputs should be disabled during VCO calibration.
        """
        self.trf_write(self.trf_mmap[1] | (1 << 31))
    @kernel
    def en_trf_out(self, rf=1, lo=0):
        """Enable the rf/lo outputs of the upconverter (hardware variant).
        :param rf: 1 to enable RF output, 0 to disable
        :param lo: 1 to enable LO output, 0 to disable
        """
        data = self.trf_read(0xc)
        delay(0.1 * ms)
        # set RF and LO output bits
        data = data | (1 << 12) | (1 << 13) | (1 << 14)
        # clear to enable output
        if rf == 1:
            data = data ^ (1 << 14)
        if lo == 1:
            data = data ^ ((1 << 12) | (1 << 13))
        self.trf_write(data)
    @kernel
    def set_servo(self, profile=0, enable=0, hold=0):
        """Set the servo configuration.
        :param enable: 1 to enable servo, 0 to disable servo (default). If disabled,
            the servo is bypassed and hold is enforced since the control loop is broken.
        :param hold: 1 to hold the servo IIR filter output constant, 0 for normal operation.
        :param profile: Profile index to select for channel. (0 to 3)
        """
        if (profile < 0) or (profile > 3):
            raise ValueError("invalid profile index")
        addr = PHASER_ADDR_SERVO_CFG0 + self.index
        # enforce hold if the servo is disabled
        data = (profile << 2) | (((hold | ~enable) & 1) << 1) | (enable & 1)
        self.phaser.write8(addr, data)
    @kernel
    def set_iir_mu(self, profile, b0, b1, a1, offset):
        """Load a servo profile consiting of the three filter coefficients and an output offset.
        Avoid setting the IIR parameters of the currently active profile.
        The recurrence relation is (all data signed and MSB aligned):
        .. math::
            a_0 y_n = a_1 y_{n - 1} + b_0 x_n + b_1 x_{n - 1} + o
        Where:
            * :math:`y_n` and :math:`y_{n-1}` are the current and previous
              filter outputs, clipped to :math:`[0, 1[`.
            * :math:`x_n` and :math:`x_{n-1}` are the current and previous
              filter inputs in :math:`[-1, 1[`.
            * :math:`o` is the offset
            * :math:`a_0` is the normalization factor :math:`2^{14}`
            * :math:`a_1` is the feedback gain
            * :math:`b_0` and :math:`b_1` are the feedforward gains for the two
              delays
        .. seealso:: :meth:`set_iir`
        :param profile: Profile to set (0 to 3)
        :param b0: b0 filter coefficient (16 bit signed)
        :param b1: b1 filter coefficient (16 bit signed)
        :param a1: a1 filter coefficient (16 bit signed)
        :param offset: Output offset (16 bit signed)
        """
        if (profile < 0) or (profile > 3):
            raise ValueError("invalid profile index")
        # 32 byte-sized data registers per channel and 8 (2 bytes * (3 coefficients + 1 offset)) registers per profile
        addr = PHASER_ADDR_SERVO_DATA_BASE + (8 * profile) + (self.index * 32)
        for data in [b0, b1, a1, offset]:
            self.phaser.write16(addr, data)
            addr += 2
    @kernel
    def set_iir(self, profile, kp, ki=0., g=0., x_offset=0., y_offset=0.):
        """Set servo profile IIR coefficients.
        Avoid setting the IIR parameters of the currently active profile.
        Gains are given in units of output full per scale per input full scale.
        .. note:: Due to inherent constraints of the fixed point datatypes and IIR
            filters, the ``x_offset`` (setpoint) resolution depends on the selected
            gains. Low ``ki`` gains will lead to a low ``x_offset`` resolution.
        The transfer function is (up to time discretization and
        coefficient quantization errors):
        .. math::
            H(s) = k_p + \\frac{k_i}{s + \\frac{k_i}{g}}
        Where:
            * :math:`s = \\sigma + i\\omega` is the complex frequency
            * :math:`k_p` is the proportional gain
            * :math:`k_i` is the integrator gain
            * :math:`g` is the integrator gain limit
        :param profile: Profile number (0-3)
        :param kp: Proportional gain. This is usually negative (closed
            loop, positive ADC voltage, positive setpoint). When 0, this
            implements a pure I controller.
        :param ki: Integrator gain (rad/s). Equivalent to the gain at 1 Hz.
            When 0 (the default) this implements a pure P controller.
            Same sign as ``kp``.
        :param g: Integrator gain limit (1). When 0 (the default) the
            integrator gain limit is infinite. Same sign as ``ki``.
        :param x_offset: IIR input offset. Used as the negative
            setpoint when stabilizing to a desired input setpoint. Will
            be converted to an equivalent output offset and added to y_offset.
        :param y_offset: IIR output offset.
        """
        NORM = 1 << SERVO_COEFF_SHIFT
        COEFF_MAX = 1 << SERVO_COEFF_WIDTH - 1
        DATA_MAX = 1 << SERVO_DATA_WIDTH - 1
        kp *= NORM
        if ki == 0.:
            # pure P
            a1 = 0
            b1 = 0
            b0 = int(round(kp))
        else:
            # I or PI
            ki *= NORM*SERVO_T_CYCLE/2.
            if g == 0.:
                c = 1.
                a1 = NORM
            else:
                c = 1./(1. + ki/(g*NORM))
                a1 = int(round((2.*c - 1.)*NORM))
            b0 = int(round(kp + ki*c))
            b1 = int(round(kp + (ki - 2.*kp)*c))
            if b1 == -b0:
                raise ValueError("low integrator gain and/or gain limit")
        if (b0 >= COEFF_MAX or b0 < -COEFF_MAX or
                b1 >= COEFF_MAX or b1 < -COEFF_MAX):
            raise ValueError("high gains")
        forward_gain = (b0 + b1) * (1 << SERVO_DATA_WIDTH - 1 - SERVO_COEFF_SHIFT)
        effective_offset = int(round(DATA_MAX * y_offset + forward_gain * x_offset))
        self.set_iir_mu(profile, b0, b1, a1, effective_offset)
 class PhaserOscillator:
    """Phaser IQ channel oscillator (NCO/DDS).
    .. note:: Latencies between oscillators within a channel and between
-        oscillator paramters (amplitude and phase/frequency) are deterministic
+        oscillator parameters (amplitude and phase/frequency) are deterministic
        (with respect to the 25 MS/s sample clock) but not matched.
    """
    kernel_invariants = {"channel", "base_addr"}
@ -943,3 +1334,305 @@ class PhaserOscillator:
            raise ValueError("amplitude out of bounds")
        pow = int32(round(phase*(1 << 16)))
        self.set_amplitude_phase_mu(asf, pow, clr)
 class Miqro:
    """
    Miqro pulse generator.
    A Miqro instance represents one RF output. The DSP components are fully
    contained in the Phaser gateware. The output is generated by with
    the following data flow:
    **Oscillators**
    * There are n_osc = 16 oscillators with oscillator IDs 0..n_osc-1.
    * Each oscillator outputs one tone at any given time
        * I/Q (quadrature, a.k.a. complex) 2x16 bit signed data
          at tau = 4 ns sample intervals, 250 MS/s, Nyquist 125 MHz, bandwidth 200 MHz
          (from f = -100..+100 MHz, taking into account the interpolation anti-aliasing
          filters in subsequent interpolators),
        * 32 bit frequency (f) resolution (~ 1/16 Hz),
        * 16 bit unsigned amplitude (a) resolution
        * 16 bit phase offset (p) resolution
    * The output phase p' of each oscillator at time t (boot/reset/initialization of the
      device at t=0) is then p' = f*t + p (mod 1 turn) where f and p are the (currently
      active) profile frequency and phase offset.
    * Note: The terms  "phase coherent" and "phase tracking" are defined to refer to this
      choice of oscillator output phase p'. Note that the phase offset p is not relative to
      (on top of previous phase/profiles/oscillator history).
      It is "absolute" in the sense that frequency f and phase offset p fully determine
      oscillator output phase p' at time t. This is unlike typical DDS behavior.
    * Frequency, phase, and amplitude of each oscillator are configurable by selecting one of
      n_profile = 32 profiles 0..n_profile-1. This selection is fast and can be done for
      each pulse. The phase coherence defined above is guaranteed for each
      profile individually.
    * Note: one profile per oscillator (usually profile index 0) should be reserved
      for the NOP (no operation, identity) profile, usually with zero amplitude.
    * Data for each profile for each oscillator can be configured
      individually. Storing profile data should be considered "expensive".
    * Note: The annotation that some operation is "expensive" does not mean it is
      impossible, just that it may take a significant amount of time and
      resources to execute such that it may be impractical when used often or
      during fast pulse sequences. They are intended for use in calibration and
      initialization.
    **Summation**
    * The oscillator outputs are added together (wrapping addition).
    * The user must ensure that the sum of oscillators outputs does not exceed the
      data range. In general that means that the sum of the amplitudes must not
      exceed one.
    **Shaper**
    * The summed complex output stream is then multiplied with a the complex-valued
      output of a triggerable shaper.
    * Triggering the shaper corresponds to passing a pulse from all oscillators to
      the RF output.
    * Selected profiles become active simultaneously (on the same output sample) when
      triggering the shaper with the first shaper output sample.
    * The shaper reads (replays) window samples from a memory of size n_window = 1 << 10.
    * The window memory can be segmented by choosing different start indices
      to support different windows.
    * Each window memory segment starts with a header determining segment
      length and interpolation parameters.
    * The window samples are interpolated by a factor (rate change) between 1 and
      r = 1 << 12.
    * The interpolation order is constant, linear, quadratic, or cubic. This
      corresponds to interpolation modes from rectangular window (1st order CIC)
      or zero order hold) to Parzen window (4th order CIC or cubic spline).
    * This results in support for single shot pulse lengths (envelope support) between
      tau and a bit more than r * n_window * tau = (1 << 12 + 10) tau ~ 17 ms.
    * Windows can be configured to be head-less and/or tail-less, meaning, they
      do not feed zero-amplitude samples into the shaper before and after
      each window respectively. This is used to implement pulses with arbitrary
      length or CW output.
    **Overall properties**
    * The DAC may upconvert the signal by applying a frequency offset f1 with
      phase p1.
    * In the Upconverter Phaser variant, the analog quadrature upconverter
      applies another frequency of f2 and phase p2.
    * The resulting phase of the signal from one oscillator at the SMA output is
      (f + f1 + f2)*t + p + s(t - t0) + p1 + p2 (mod 1 turn)
      where s(t - t0) is the phase of the interpolated
      shaper output, and t0 is the trigger time (fiducial of the shaper).
      Unsurprisingly the frequency is the derivative of the phase.
    * Group delays between pulse parameter updates are matched across oscillators,
      shapers, and channels.
    * The minimum time to change profiles and phase offsets is ~128 ns (estimate, TBC).
      This is the minimum pulse interval.
      The sustained pulse rate of the RTIO PHY/Fastlink is one pulse per Fastlink frame
      (may be increased, TBC).
    """
    def __init__(self, channel):
        self.channel = channel
        self.base_addr = (self.channel.phaser.channel_base + 1 +
                self.channel.index) << 8
    @kernel
    def reset(self):
        """Establish no-output profiles and no-output window and execute them.
        This establishes the first profile (index 0) on all oscillators as zero
        amplitude, creates a trivial window (one sample with zero amplitude,
        minimal interpolation), and executes a corresponding pulse.
        """
        for osc in range(16):
            self.set_profile_mu(osc, profile=0, ftw=0, asf=0)
            delay(20*us)
        self.set_window_mu(start=0, iq=[0], order=0)
        self.pulse(window=0, profiles=[0])
    @kernel
    def set_profile_mu(self, oscillator, profile, ftw, asf, pow_=0):
        """Store an oscillator profile (machine units).
        :param oscillator: Oscillator index (0 to 15)
        :param profile: Profile index (0 to 31)
        :param ftw: Frequency tuning word (32 bit signed integer on a 250 MHz clock)
        :param asf: Amplitude scale factor (16 bit unsigned integer)
        :param pow_: Phase offset word (16 bit integer)
        """
        if oscillator >= 16:
            raise ValueError("invalid oscillator index")
        if profile >= 32:
            raise ValueError("invalid profile index")
        self.channel.phaser.write16(PHASER_ADDR_MIQRO_MEM_ADDR,
                (self.channel.index << 15) | PHASER_MIQRO_SEL_PROFILE |
                (oscillator << 6) | (profile << 1))
        self.channel.phaser.write32(PHASER_ADDR_MIQRO_MEM_DATA, ftw)
        self.channel.phaser.write32(PHASER_ADDR_MIQRO_MEM_DATA,
            (asf & 0xffff) | (pow_ << 16))
    @kernel
    def set_profile(self, oscillator, profile, frequency, amplitude, phase=0.):
        """Store an oscillator profile.
        :param oscillator: Oscillator index (0 to 15)
        :param profile: Profile index (0 to 31)
        :param frequency: Frequency in Hz (passband -100 to 100 MHz).
            Interpreted in the Nyquist sense, i.e. aliased.
        :param amplitude: Amplitude in units of full scale (0. to 1.)
        :param phase: Phase in turns. See :class:`Miqro` for a definition of
            phase in this context.
        :return: The quantized 32 bit frequency tuning word
        """
        ftw = int32(round(frequency*((1 << 30)/(62.5*MHz))))
        asf = int32(round(amplitude*0xffff))
        if asf < 0 or asf > 0xffff:
            raise ValueError("amplitude out of bounds")
        pow_ = int32(round(phase*(1 << 16)))
        self.set_profile_mu(oscillator, profile, ftw, asf, pow_)
        return ftw
    @kernel
    def set_window_mu(self, start, iq, rate=1, shift=0, order=3, head=1, tail=1):
        """Store a window segment (machine units)
        :param start: Window start address (0 to 0x3ff)
        :param iq: List of IQ window samples. Each window sample is an integer
            containing the signed I part in the 16 LSB and the signed Q part in
            the 16 MSB. The maximum window length is 0x3fe. The user must
            ensure that this window does not overlap with other windows in the
            memory.
        :param rate: Interpolation rate change (1 to 1 << 12)
        :param shift: Interpolator amplitude gain compensation in powers of 2 (0 to 63)
        :param order: Interpolation order from 0 (corresponding to
            constant/rectangular window/zero-order-hold/1st order CIC interpolation)
            to 3 (corresponding to cubic/Parzen window/4th order CIC interpolation)
        :param head: Update the interpolator settings and clear its state at the start
            of the window. This also implies starting the envelope from zero.
        :param tail: Feed zeros into the interpolator after the window samples.
            In the absence of further pulses this will return the output envelope
            to zero with the chosen interpolation.
        :return: Next available window memory address after this segment.
        """
        if start >= 1 << 10:
            raise ValueError("start out of bounds")
        if len(iq) >= 1 << 10:
            raise ValueError("window length out of bounds")
        if rate < 1 or rate > 1 << 12:
            raise ValueError("rate out of bounds")
        if shift > 0x3f:
            raise ValueError("shift out of bounds")
        if order > 3:
            raise ValueError("order out of bounds")
        self.channel.phaser.write16(PHASER_ADDR_MIQRO_MEM_ADDR,
                (self.channel.index << 15) | start)
        self.channel.phaser.write32(PHASER_ADDR_MIQRO_MEM_DATA,
            (len(iq) & 0x3ff) |
            ((rate - 1) << 10) |
            (shift << 22) |
            (order << 28) |
            ((head & 1) << 30) |
            ((tail & 1) << 31)
        )
        for iqi in iq:
            self.channel.phaser.write32(PHASER_ADDR_MIQRO_MEM_DATA, iqi)
            delay(20*us)  # slack for long windows
        return (start + 1 + len(iq)) & 0x3ff
    @kernel
    def set_window(self, start, iq, period=4*ns, order=3, head=1, tail=1):
        """Store a window segment
        :param start: Window start address (0 to 0x3ff)
        :param iq: List of IQ window samples. Each window sample is a pair of
            two float numbers -1 to 1, one for each I and Q in units of full scale.
            The maximum window length is 0x3fe. The user must ensure that this window
            does not overlap with other windows in the memory.
        :param period: Desired window sample period in SI units (4*ns to (4 << 12)*ns).
        :param order: Interpolation order from 0 (corresponding to
            constant/zero-order-hold/1st order CIC interpolation) to 3 (corresponding
            to cubic/Parzen/4th order CIC interpolation)
        :param head: Update the interpolator settings and clear its state at the start
            of the window. This also implies starting the envelope from zero.
        :param tail: Feed zeros into the interpolator after the window samples.
            In the absence of further pulses this will return the output envelope
            to zero with the chosen interpolation.
        :return: Actual sample period in SI units
        """
        rate = int32(round(period/(4*ns)))
        gain = 1.
        for _ in range(order):
            gain *= rate
        shift = 0
        while gain >= 2.:
            shift += 1
            gain *= .5
        scale = ((1 << 15) - 1)/gain
        iq_mu = [
            (int32(round(iqi[0]*scale)) & 0xffff) |
            (int32(round(iqi[1]*scale)) << 16)
            for iqi in iq
        ]
        self.set_window_mu(start, iq_mu, rate, shift, order, head, tail)
        return (len(iq) + order)*rate*4*ns
    @kernel
    def encode(self, window, profiles, data):
        """Encode window and profile selection
        :param window: Window start address (0 to 0x3ff)
        :param profiles: List of profile indices for the oscillators. Maximum
            length 16. Unused oscillators will be set to profile 0.
        :param data: List of integers to store the encoded data words into.
            Unused entries will remain untouched. Must contain at least three
            lements if all oscillators are used and should be initialized to
            zeros.
        :return: Number of words from `data` used.
        """
        if len(profiles) > 16:
            raise ValueError("too many oscillators")
        if window > 0x3ff:
            raise ValueError("window start out of bounds")
        data[0] = window
        word = 0
        idx = 10
        for profile in profiles:
            if profile > 0x1f:
                raise ValueError("profile out of bounds")
            if idx > 32 - 5:
                word += 1
                idx = 0
            data[word] |= profile << idx
            idx += 5
        return word + 1
    @kernel
    def pulse_mu(self, data):
        """Emit a pulse (encoded)
        The pulse fiducial timing resolution is 4 ns.
        :param data: List of up to 3 words containing an encoded MIQRO pulse as
            returned by :meth:`encode`.
        """
        word = len(data)
        delay_mu(-8*word)  # back shift to align
        while word > 0:
            word -= 1
            delay_mu(8)
            # final write sets pulse stb
            rtio_output(self.base_addr + word, data[word])
    @kernel
    def pulse(self, window, profiles):
        """Emit a pulse
        This encodes the window and profiles (see :meth:`encode`) and emits them
        (see :meth:`pulse_mu`).
        :param window: Window start address (0 to 0x3ff)
        :param profiles: List of profile indices for the oscillators. Maximum
            length 16. Unused oscillators will select profile 0.
        """
        data = [0, 0, 0]
        words = self.encode(window, profiles, data)
        self.pulse_mu(data[:words])
--- a/artiq/coredevice/profiler.py
+++ b/artiq/coredevice/profiler.py
@ -1,92 +0,0 @@
 from collections import defaultdict
 import subprocess
 class Symbolizer:
    def __init__(self, binary, triple, demangle=True):
        cmdline = [
            triple + "-addr2line", "--exe=" + binary,
            "--addresses", "--functions", "--inlines"
        ]
        if demangle:
            cmdline.append("--demangle=rust")
        self._addr2line = subprocess.Popen(cmdline, stdin=subprocess.PIPE, stdout=subprocess.PIPE,
                                           universal_newlines=True)
    def symbolize(self, addr):
        self._addr2line.stdin.write("0x{:08x}\n0\n".format(addr))
        self._addr2line.stdin.flush()
        self._addr2line.stdout.readline() # 0x[addr]
        result = []
        while True:
            function = self._addr2line.stdout.readline().rstrip()
            # check for end marker
            if function == "0x00000000":          # 0x00000000
                self._addr2line.stdout.readline() # ??
                self._addr2line.stdout.readline() # ??:0
                return result
            file, line = self._addr2line.stdout.readline().rstrip().split(":")
            result.append((function, file, line, addr))
 class CallgrindWriter:
    def __init__(self, output, binary, triple, compression=True, demangle=True):
        self._output = output
        self._binary = binary
        self._current = defaultdict(lambda: None)
        self._ids = defaultdict(lambda: {})
        self._compression = compression
        self._symbolizer = Symbolizer(binary, triple, demangle=demangle)
    def _write(self, fmt, *args, **kwargs):
        self._output.write(fmt.format(*args, **kwargs))
        self._output.write("\n")
    def _spec(self, spec, value):
        if self._current[spec] == value:
            return
        self._current[spec] = value
        if not self._compression or value == "??":
            self._write("{}={}", spec, value)
            return
        spec_ids = self._ids[spec]
        if value in spec_ids:
            self._write("{}=({})", spec, spec_ids[value])
        else:
            spec_ids[value] = len(spec_ids) + 1
            self._write("{}=({}) {}", spec, spec_ids[value], value)
    def header(self):
        self._write("# callgrind format")
        self._write("version: 1")
        self._write("creator: ARTIQ")
        self._write("positions: instr line")
        self._write("events: Hits")
        self._write("")
        self._spec("ob", self._binary)
        self._spec("cob", self._binary)
    def hit(self, addr, count):
        for function, file, line, addr in self._symbolizer.symbolize(addr):
            self._spec("fl", file)
            self._spec("fn", function)
            self._write("0x{:08x} {} {}", addr, line, count)
    def edge(self, caller, callee, count):
        edges = self._symbolizer.symbolize(callee) + self._symbolizer.symbolize(caller)
        for (callee, caller) in zip(edges, edges[1:]):
            function, file, line, addr = callee
            self._spec("cfl", file)
            self._spec("cfn", function)
            self._write("calls={} 0x{:08x} {}", count, addr, line)
            function, file, line, addr = caller
            self._spec("fl", file)
            self._spec("fn", function)
            self._write("0x{:08x} {} {}", addr, line, count)
--- a/artiq/coredevice/sampler.py
+++ b/artiq/coredevice/sampler.py
@ -15,21 +15,23 @@ SPI_CS_PGIA = 1  # separate SPI bus, CS used as RCLK
@portable
-def adc_mu_to_volt(data, gain=0):
+def adc_mu_to_volt(data, gain=0, corrected_fs=True):
    """Convert ADC data in machine units to Volts.
    :param data: 16 bit signed ADC word
    :param gain: PGIA gain setting (0: 1, ..., 3: 1000)
    :param corrected_fs: use corrected ADC FS reference.
    Should be True for Samplers' revisions after v2.1. False for v2.1 and earlier.
    :return: Voltage in Volts
    """
    if gain == 0:
-        volt_per_lsb = 20./(1 << 16)
+        volt_per_lsb = 20.48 / (1 << 16) if corrected_fs else 20. / (1 << 16)
    elif gain == 1:
-        volt_per_lsb = 2./(1 << 16)
+        volt_per_lsb = 2.048 / (1 << 16) if corrected_fs else 2. / (1 << 16)
    elif gain == 2:
-        volt_per_lsb = .2/(1 << 16)
+        volt_per_lsb = .2048 / (1 << 16) if corrected_fs else .2 / (1 << 16)
    elif gain == 3:
-        volt_per_lsb = .02/(1 << 16)
+        volt_per_lsb = 0.02048 / (1 << 16) if corrected_fs else .02 / (1 << 16)
    else:
        raise ValueError("invalid gain")
    return data * volt_per_lsb
@ -48,12 +50,13 @@ class Sampler:
    :param gains: Initial value for PGIA gains shift register
        (default: 0x0000). Knowledge of this state is not transferred
        between experiments.
    :param hw_rev: Sampler's hardware revision string (default 'v2.2')
    :param core_device: Core device name
    """
-    kernel_invariants = {"bus_adc", "bus_pgia", "core", "cnv", "div"}
+    kernel_invariants = {"bus_adc", "bus_pgia", "core", "cnv", "div", "corrected_fs"}
    def __init__(self, dmgr, spi_adc_device, spi_pgia_device, cnv_device,
-                 div=8, gains=0x0000, core_device="core"):
+                 div=8, gains=0x0000, hw_rev="v2.2", core_device="core"):
        self.bus_adc = dmgr.get(spi_adc_device)
        self.bus_adc.update_xfer_duration_mu(div, 32)
        self.bus_pgia = dmgr.get(spi_pgia_device)
@ -62,6 +65,11 @@ class Sampler:
        self.cnv = dmgr.get(cnv_device)
        self.div = div
        self.gains = gains
        self.corrected_fs = self.use_corrected_fs(hw_rev)
    @staticmethod
    def use_corrected_fs(hw_rev):
        return hw_rev != "v2.1"
    @kernel
    def init(self):
@ -144,4 +152,4 @@ class Sampler:
        for i in range(n):
            channel = i + 8 - len(data)
            gain = (self.gains >> (channel*2)) & 0b11
-            data[i] = adc_mu_to_volt(adc_data[i], gain)
+            data[i] = adc_mu_to_volt(adc_data[i], gain, self.corrected_fs)
--- a/artiq/coredevice/sawg.py
+++ b/artiq/coredevice/sawg.py
@ -1,372 +0,0 @@
 """
 Driver for the Smart Arbitrary Waveform Generator (SAWG) on RTIO.
 The SAWG is an "improved DDS" built in gateware and interfacing to
 high-speed DACs.
 Output event replacement is supported except on the configuration channel.
 """
 from artiq.language.types import TInt32, TFloat
 from numpy import int32, int64
 from artiq.language.core import kernel
 from artiq.coredevice.spline import Spline
 from artiq.coredevice.rtio import rtio_output
 # sawg.Config addresses
 _SAWG_DIV = 0
 _SAWG_CLR = 1
 _SAWG_IQ_EN = 2
 # _SAWF_PAD = 3  # reserved
 _SAWG_OUT_MIN = 4
 _SAWG_OUT_MAX = 5
 _SAWG_DUC_MIN = 6
 _SAWG_DUC_MAX = 7
 class Config:
    """SAWG configuration.
    Exposes the configurable quantities of a single SAWG channel.
    Access to the configuration registers for a SAWG channel can not
    be concurrent. There must be at least :attr:`_rtio_interval` machine
    units of delay between accesses. Replacement is not supported and will be
    lead to an ``RTIOCollision`` as this is likely a programming error.
    All methods therefore advance the timeline by the duration of one
    configuration register transfer.
    :param channel: RTIO channel number of the channel.
    :param core: Core device.
    """
    kernel_invariants = {"channel", "core", "_out_scale", "_duc_scale",
            "_rtio_interval"}
    def __init__(self, channel, core, cordic_gain=1.):
        self.channel = channel
        self.core = core
        # normalized DAC output
        self._out_scale = (1 << 15) - 1.
        # normalized DAC output including DUC cordic gain
        self._duc_scale = self._out_scale/cordic_gain
        # configuration channel access interval
        self._rtio_interval = int64(3*self.core.ref_multiplier)
    @kernel
    def set_div(self, div: TInt32, n: TInt32=0):
        """Set the spline evolution divider and current counter value.
        The divider and the spline evolution are synchronized across all
        spline channels within a SAWG channel. The DDS/DUC phase accumulators
        always evolves at full speed.
        .. note:: The spline evolution divider has not been tested extensively
            and is currently considered a technological preview only.
        :param div: Spline evolution divider, such that
            ``t_sawg_spline/t_rtio_coarse = div + 1``. Default: ``0``.
        :param n: Current value of the counter. Default: ``0``.
        """
        rtio_output((self.channel << 8) | _SAWG_DIV, div | (n << 16))
        delay_mu(self._rtio_interval)
    @kernel
    def set_clr(self, clr0: TInt32, clr1: TInt32, clr2: TInt32):
        """Set the accumulator clear mode for the three phase accumulators.
        When the ``clr`` bit for a given DDS/DUC phase accumulator is
        set, that phase accumulator will be cleared with every phase offset
        RTIO command and the output phase of the DDS/DUC will be
        exactly the phase RTIO value ("absolute phase update mode").
        .. math::
            q^\prime(t) = p^\prime + (t - t^\prime) f^\prime
        In turn, when the bit is cleared, the phase RTIO channels
        determine a phase offset to the current (carrier-) value of the
        DDS/DUC phase accumulator. This "relative phase update mode" is
        sometimes also called “continuous phase mode”.
        .. math::
            q^\prime(t) = q(t^\prime) + (p^\prime - p) +
                (t - t^\prime) f^\prime
        Where:
            * :math:`q`, :math:`q^\prime`: old/new phase accumulator
            * :math:`p`, :math:`p^\prime`: old/new phase offset
            * :math:`f^\prime`: new frequency
            * :math:`t^\prime`: timestamp of setting new :math:`p`, :math:`f`
            * :math:`t`: running time
        :param clr0: Auto-clear phase accumulator of the ``phase0``/
          ``frequency0`` DUC. Default: ``True``
        :param clr1: Auto-clear phase accumulator of the ``phase1``/
          ``frequency1`` DDS. Default: ``True``
        :param clr2: Auto-clear phase accumulator of the ``phase2``/
          ``frequency2`` DDS. Default: ``True``
        """
        rtio_output((self.channel << 8) | _SAWG_CLR, clr0 |
                (clr1 << 1) | (clr2 << 2))
        delay_mu(self._rtio_interval)
    @kernel
    def set_iq_en(self, i_enable: TInt32, q_enable: TInt32):
        """Enable I/Q data on this DAC channel.
        Every pair of SAWG channels forms a buddy pair.
        The ``iq_en`` configuration controls which DDS data is emitted to the
        DACs.
        Refer to the documentation of :class:`SAWG` for a mathematical
        description of ``i_enable`` and ``q_enable``.
        .. note:: Quadrature data from the buddy channel is currently
            a technological preview only. The data is ignored in the SAWG
            gateware and not added to the DAC output.
            This is equivalent to the ``q_enable`` switch always being ``0``.
        :param i_enable: Controls adding the in-phase
              DUC-DDS data of *this* SAWG channel to *this* DAC channel.
              Default: ``1``.
        :param q_enable: controls adding the quadrature
              DUC-DDS data of this SAWG's *buddy* channel to *this* DAC
              channel. Default: ``0``.
        """
        rtio_output((self.channel << 8) | _SAWG_IQ_EN, i_enable |
                (q_enable << 1))
        delay_mu(self._rtio_interval)
    @kernel
    def set_duc_max_mu(self, limit: TInt32):
        """Set the digital up-converter (DUC) I and Q data summing junctions
        upper limit. In machine units.
        The default limits are chosen to reach maximum and minimum DAC output
        amplitude.
        For a description of the limiter functions in normalized units see:
        .. seealso:: :meth:`set_duc_max`
        """
        rtio_output((self.channel << 8) | _SAWG_DUC_MAX, limit)
        delay_mu(self._rtio_interval)
    @kernel
    def set_duc_min_mu(self, limit: TInt32):
        """.. seealso:: :meth:`set_duc_max_mu`"""
        rtio_output((self.channel << 8) | _SAWG_DUC_MIN, limit)
        delay_mu(self._rtio_interval)
    @kernel
    def set_out_max_mu(self, limit: TInt32):
        """.. seealso:: :meth:`set_duc_max_mu`"""
        rtio_output((self.channel << 8) | _SAWG_OUT_MAX, limit)
        delay_mu(self._rtio_interval)
    @kernel
    def set_out_min_mu(self, limit: TInt32):
        """.. seealso:: :meth:`set_duc_max_mu`"""
        rtio_output((self.channel << 8) | _SAWG_OUT_MIN, limit)
        delay_mu(self._rtio_interval)
    @kernel
    def set_duc_max(self, limit: TFloat):
        """Set the digital up-converter (DUC) I and Q data summing junctions
        upper limit.
        Each of the three summing junctions has a saturating adder with
        configurable upper and lower limits. The three summing junctions are:
            * At the in-phase input to the ``phase0``/``frequency0`` fast DUC,
              after the anti-aliasing FIR filter.
            * At the quadrature input to the ``phase0``/``frequency0``
              fast DUC, after the anti-aliasing FIR filter. The in-phase and
              quadrature data paths both use the same limits.
            * Before the DAC, where the following three data streams
              are added together:
                * the output of the ``offset`` spline,
                * (optionally, depending on ``i_enable``) the in-phase output
                  of the ``phase0``/``frequency0`` fast DUC, and
                * (optionally, depending on ``q_enable``) the quadrature
                  output of the ``phase0``/``frequency0`` fast DUC of the
                  buddy channel.
        Refer to the documentation of :class:`SAWG` for a mathematical
        description of the summing junctions.
        :param limit: Limit value ``[-1, 1]``. The output of the limiter will
            never exceed this limit. The default limits are the full range
            ``[-1, 1]``.
        .. seealso::
            * :meth:`set_duc_max`: Upper limit of the in-phase and quadrature
              inputs to the DUC.
            * :meth:`set_duc_min`: Lower limit of the in-phase and quadrature
              inputs to the DUC.
            * :meth:`set_out_max`: Upper limit of the DAC output.
            * :meth:`set_out_min`: Lower limit of the DAC output.
        """
        self.set_duc_max_mu(int32(round(limit*self._duc_scale)))
    @kernel
    def set_duc_min(self, limit: TFloat):
        """.. seealso:: :meth:`set_duc_max`"""
        self.set_duc_min_mu(int32(round(limit*self._duc_scale)))
    @kernel
    def set_out_max(self, limit: TFloat):
        """.. seealso:: :meth:`set_duc_max`"""
        self.set_out_max_mu(int32(round(limit*self._out_scale)))
    @kernel
    def set_out_min(self, limit: TFloat):
        """.. seealso:: :meth:`set_duc_max`"""
        self.set_out_min_mu(int32(round(limit*self._out_scale)))
 class SAWG:
    """Smart arbitrary waveform generator channel.
    The channel is parametrized as: ::
        oscillators = exp(2j*pi*(frequency0*t + phase0))*(
            amplitude1*exp(2j*pi*(frequency1*t + phase1)) +
            amplitude2*exp(2j*pi*(frequency2*t + phase2)))
        output = (offset +
            i_enable*Re(oscillators) +
            q_enable*Im(buddy_oscillators))
    This parametrization can be viewed as two complex (quadrature) oscillators
    (``frequency1``/``phase1`` and ``frequency2``/``phase2``) that are
    executing and sampling at the coarse RTIO frequency. They can represent
    frequencies within the first Nyquist zone from ``-f_rtio_coarse/2`` to
    ``f_rtio_coarse/2``.
    .. note:: The coarse RTIO frequency ``f_rtio_coarse`` is the inverse of
      ``ref_period*multiplier``. Both are arguments of the ``Core`` device,
      specified in the device database ``device_db.py``.
    The sum of their outputs is then interpolated by a factor of
    :attr:`parallelism` (2, 4, 8 depending on the bitstream) using a
    finite-impulse-response (FIR) anti-aliasing filter (more accurately
    a half-band filter).
    The filter is followed by a configurable saturating limiter.
    After the limiter, the data is shifted in frequency using a complex
    digital up-converter (DUC, ``frequency0``/``phase0``) running at
    :attr:`parallelism` times the coarse RTIO frequency. The first Nyquist
    zone of the DUC extends from ``-f_rtio_coarse*parallelism/2`` to
    ``f_rtio_coarse*parallelism/2``. Other Nyquist zones are usable depending
    on the interpolation/modulation options configured in the DAC.
    The real/in-phase data after digital up-conversion can be offset using
    another spline interpolator ``offset``.
    The ``i_enable``/``q_enable`` switches enable emission of quadrature
    signals for later analog quadrature mixing distinguishing upper and lower
    sidebands and thus doubling the bandwidth. They can also be used to emit
    four-tone signals.
    .. note:: Quadrature data from the buddy channel is currently
       ignored in the SAWG gateware and not added to the DAC output.
       This is equivalent to the ``q_enable`` switch always being ``0``.
    The configuration channel and the nine
    :class:`artiq.coredevice.spline.Spline` interpolators are accessible as
    attributes:
    * :attr:`config`: :class:`Config`
    * :attr:`offset`, :attr:`amplitude1`, :attr:`amplitude2`: in units
      of full scale
    * :attr:`phase0`, :attr:`phase1`, :attr:`phase2`: in units of turns
    * :attr:`frequency0`, :attr:`frequency1`, :attr:`frequency2`: in units
      of Hz
    .. note:: The latencies (pipeline depths) of the nine data channels (i.e.
        all except :attr:`config`) are matched. Equivalent channels (e.g.
        :attr:`phase1` and :attr:`phase2`) are exactly matched. Channels of
        different type or functionality (e.g. :attr:`offset` vs
        :attr:`amplitude1`, DDS vs DUC, :attr:`phase0` vs :attr:`phase1`) are
        only matched to within one coarse RTIO cycle.
    :param channel_base: RTIO channel number of the first channel (amplitude).
        The configuration channel and frequency/phase/amplitude channels are
        then assumed to be successive channels.
    :param parallelism: Number of output samples per coarse RTIO clock cycle.
    :param core_device: Name of the core device that this SAWG is on.
    """
    kernel_invariants = {"channel_base", "core", "parallelism",
                         "amplitude1", "frequency1", "phase1",
                         "amplitude2", "frequency2", "phase2",
                         "frequency0", "phase0", "offset"}
    def __init__(self, dmgr, channel_base, parallelism, core_device="core"):
        self.core = dmgr.get(core_device)
        self.channel_base = channel_base
        self.parallelism = parallelism
        width = 16
        time_width = 16
        cordic_gain = 1.646760258057163  # Cordic(width=16, guard=None).gain
        head_room = 1.001
        self.config = Config(channel_base, self.core, cordic_gain)
        self.offset = Spline(width, time_width, channel_base + 1,
                             self.core, 2.*head_room)
        self.amplitude1 = Spline(width, time_width, channel_base + 2,
                                 self.core, 2*head_room*cordic_gain**2)
        self.frequency1 = Spline(3*width, time_width, channel_base + 3,
                                 self.core, 1/self.core.coarse_ref_period)
        self.phase1 = Spline(width, time_width, channel_base + 4,
                             self.core, 1.)
        self.amplitude2 = Spline(width, time_width, channel_base + 5,
                                 self.core, 2*head_room*cordic_gain**2)
        self.frequency2 = Spline(3*width, time_width, channel_base + 6,
                                 self.core, 1/self.core.coarse_ref_period)
        self.phase2 = Spline(width, time_width, channel_base + 7,
                             self.core, 1.)
        self.frequency0 = Spline(2*width, time_width, channel_base + 8,
                                 self.core,
                                 parallelism/self.core.coarse_ref_period)
        self.phase0 = Spline(width, time_width, channel_base + 9,
                             self.core, 1.)
    @kernel
    def reset(self):
        """Re-establish initial conditions.
        This clears all spline interpolators, accumulators and configuration
        settings.
        This method advances the timeline by the time required to perform all
        7 writes to the configuration channel, plus 9 coarse RTIO cycles.
        """
        self.config.set_div(0, 0)
        self.config.set_clr(1, 1, 1)
        self.config.set_iq_en(1, 0)
        self.config.set_duc_min(-1.)
        self.config.set_duc_max(1.)
        self.config.set_out_min(-1.)
        self.config.set_out_max(1.)
        self.frequency0.set_mu(0)
        coarse_cycle = int64(self.core.ref_multiplier)
        delay_mu(coarse_cycle)
        self.frequency1.set_mu(0)
        delay_mu(coarse_cycle)
        self.frequency2.set_mu(0)
        delay_mu(coarse_cycle)
        self.phase0.set_mu(0)
        delay_mu(coarse_cycle)
        self.phase1.set_mu(0)
        delay_mu(coarse_cycle)
        self.phase2.set_mu(0)
        delay_mu(coarse_cycle)
        self.amplitude1.set_mu(0)
        delay_mu(coarse_cycle)
        self.amplitude2.set_mu(0)
        delay_mu(coarse_cycle)
        self.offset.set_mu(0)
        delay_mu(coarse_cycle)
--- a/artiq/coredevice/shiftreg.py
+++ b/artiq/coredevice/shiftreg.py
@ -1,54 +0,0 @@
 from artiq.language.core import kernel, delay
 from artiq.language.units import us
 class ShiftReg:
    """Driver for shift registers/latch combos connected to TTLs"""
    kernel_invariants = {"dt", "n"}
    def __init__(self, dmgr, clk, ser, latch, n=32, dt=10*us, ser_in=None):
        self.core = dmgr.get("core")
        self.clk = dmgr.get(clk)
        self.ser = dmgr.get(ser)
        self.latch = dmgr.get(latch)
        self.n = n
        self.dt = dt
        if ser_in is not None:
            self.ser_in = dmgr.get(ser_in)
    @kernel
    def set(self, data):
        """Sets the values of the latch outputs. This does not
        advance the timeline and the waveform is generated before
        `now`."""
        delay(-2*(self.n + 1)*self.dt)
        for i in range(self.n):
            if (data >> (self.n-i-1)) & 1 == 0:
                self.ser.off()
            else:
                self.ser.on()
            self.clk.off()
            delay(self.dt)
            self.clk.on()
            delay(self.dt)
        self.clk.off()
        self.latch.on()
        delay(self.dt)
        self.latch.off()
        delay(self.dt)
    @kernel
    def get(self):
        delay(-2*(self.n + 1)*self.dt)
        data = 0
        for i in range(self.n):
            data <<= 1
            self.ser_in.sample_input()
            if self.ser_in.sample_get():
                data |= 1
            delay(self.dt)
            self.clk.on()
            delay(self.dt)
            self.clk.off()
        delay(self.dt)
        return data
--- a/artiq/coredevice/shuttler.py
+++ b/artiq/coredevice/shuttler.py
@ -0,0 +1,623 @@
 from artiq.language.core import *
 from artiq.language.types import *
 from artiq.coredevice.rtio import rtio_output, rtio_input_data
 from artiq.coredevice import spi2 as spi
 from artiq.language.units import us
@portable
 def shuttler_volt_to_mu(volt):
    """Return the equivalent DAC code. Valid input range is from -10 to
    10 - LSB.
    """
    return round((1 << 16) * (volt / 20.0)) & 0xffff
 class Config:
    """Shuttler configuration registers interface.
    The configuration registers control waveform phase auto-clear, and pre-DAC
    gain & offset values for calibration with ADC on the Shuttler AFE card.
    To find the calibrated DAC code, the Shuttler Core first multiplies the
    output data with pre-DAC gain, then adds the offset.
    .. note::
        The DAC code is capped at 0x7fff and 0x8000.
    :param channel: RTIO channel number of this interface.
    :param core_device: Core device name.
    """
    kernel_invariants = {
        "core", "channel", "target_base", "target_read",
        "target_gain", "target_offset", "target_clr"
    }
    def __init__(self, dmgr, channel, core_device="core"):
        self.core = dmgr.get(core_device)
        self.channel = channel
        self.target_base   = channel << 8
        self.target_read   = 1 << 6
        self.target_gain   = 0 * (1 << 4)
        self.target_offset = 1 * (1 << 4)
        self.target_clr    = 1 * (1 << 5)
    @kernel
    def set_clr(self, clr):
        """Set/Unset waveform phase clear bits.
        Each bit corresponds to a Shuttler waveform generator core. Setting a
        clear bit forces the Shuttler Core to clear the phase accumulator on
        waveform trigger (See :class:`Trigger` for the trigger method).
        Otherwise, the phase accumulator increments from its original value.
        :param clr: Waveform phase clear bits. The MSB corresponds to Channel
            15, LSB corresponds to Channel 0.
        """
        rtio_output(self.target_base | self.target_clr, clr)
    @kernel
    def set_gain(self, channel, gain):
        """Set the 16-bits pre-DAC gain register of a Shuttler Core channel.
        The `gain` parameter represents the decimal portion of the gain
        factor. The MSB represents 0.5 and the sign bit. Hence, the valid
        total gain value (1 +/- 0.gain) ranges from 0.5 to 1.5 - LSB.
        :param channel: Shuttler Core channel to be configured.
        :param gain: Shuttler Core channel gain.
        """
        rtio_output(self.target_base | self.target_gain | channel, gain)
    @kernel
    def get_gain(self, channel):
        """Return the pre-DAC gain value of a Shuttler Core channel.
        :param channel: The Shuttler Core channel.
        :return: Pre-DAC gain value. See :meth:`set_gain`.
        """
        rtio_output(self.target_base | self.target_gain |
            self.target_read | channel, 0)
        return rtio_input_data(self.channel)
    @kernel
    def set_offset(self, channel, offset):
        """Set the 16-bits pre-DAC offset register of a Shuttler Core channel.
        .. seealso::
            :meth:`shuttler_volt_to_mu`
        :param channel: Shuttler Core channel to be configured.
        :param offset: Shuttler Core channel offset.
        """
        rtio_output(self.target_base | self.target_offset | channel, offset)
    @kernel
    def get_offset(self, channel):
        """Return the pre-DAC offset value of a Shuttler Core channel.
        :param channel: The Shuttler Core channel.
        :return: Pre-DAC offset value. See :meth:`set_offset`.
        """
        rtio_output(self.target_base | self.target_offset |
            self.target_read | channel, 0)
        return rtio_input_data(self.channel)
 class DCBias:
    """Shuttler Core cubic DC-bias spline.
    A Shuttler channel can generate a waveform `w(t)` that is the sum of a
    cubic spline `a(t)` and a sinusoid modulated in amplitude by a cubic
    spline `b(t)` and in phase/frequency by a quadratic spline `c(t)`, where
    .. math::
        w(t) = a(t) + b(t) * cos(c(t))
    And `t` corresponds to time in seconds.
    This class controls the cubic spline `a(t)`, in which
    .. math::
        a(t) = p_0 + p_1t + \\frac{p_2t^2}{2} + \\frac{p_3t^3}{6}
    And `a(t)` is in Volt.
    :param channel: RTIO channel number of this DC-bias spline interface.
    :param core_device: Core device name.
    """
    kernel_invariants = {"core", "channel", "target_o"}
    def __init__(self, dmgr, channel, core_device="core"):
        self.core = dmgr.get(core_device)
        self.channel = channel
        self.target_o = channel << 8
    @kernel
    def set_waveform(self, a0: TInt32, a1: TInt32, a2: TInt64, a3: TInt64):
        """Set the DC-bias spline waveform.
        Given `a(t)` as defined in :class:`DCBias`, the coefficients should be
        configured by the following formulae.
        .. math::
            T &= 8*10^{-9}
            a_0 &= p_0
            a_1 &= p_1T + \\frac{p_2T^2}{2} + \\frac{p_3T^3}{6}
            a_2 &= p_2T^2 + p_3T^3
            a_3 &= p_3T^3
        :math:`a_0`, :math:`a_1`, :math:`a_2` and :math:`a_3` are 16, 32, 48
        and 48 bits in width respectively. See :meth:`shuttler_volt_to_mu` for
        machine unit conversion.
        Note: The waveform is not updated to the Shuttler Core until
        triggered. See :class:`Trigger` for the update triggering mechanism.
        :param a0: The :math:`a_0` coefficient in machine unit.
        :param a1: The :math:`a_1` coefficient in machine unit.
        :param a2: The :math:`a_2` coefficient in machine unit.
        :param a3: The :math:`a_3` coefficient in machine unit.
        """
        coef_words = [
            a0,
            a1,
            a1 >> 16,
            a2 & 0xFFFF,
            (a2 >> 16) & 0xFFFF,
            (a2 >> 32) & 0xFFFF,
            a3 & 0xFFFF,
            (a3 >> 16) & 0xFFFF,
            (a3 >> 32) & 0xFFFF,
        ]
        for i in range(len(coef_words)):
            rtio_output(self.target_o | i, coef_words[i])
            delay_mu(int64(self.core.ref_multiplier))
 class DDS:
    """Shuttler Core DDS spline.
    A Shuttler channel can generate a waveform `w(t)` that is the sum of a
    cubic spline `a(t)` and a sinusoid modulated in amplitude by a cubic
    spline `b(t)` and in phase/frequency by a quadratic spline `c(t)`, where
    .. math::
        w(t) = a(t) + b(t) * cos(c(t))
    And `t` corresponds to time in seconds.
    This class controls the cubic spline `b(t)` and quadratic spline `c(t)`,
    in which
    .. math::
        b(t) &= g * (q_0 + q_1t + \\frac{q_2t^2}{2} + \\frac{q_3t^3}{6})
        c(t) &= r_0 + r_1t + \\frac{r_2t^2}{2}
    And `b(t)` is in Volt, `c(t)` is in number of turns. Note that `b(t)`
    contributes to a constant gain of :math:`g=1.64676`.
    :param channel: RTIO channel number of this DC-bias spline interface.
    :param core_device: Core device name.
    """
    kernel_invariants = {"core", "channel", "target_o"}
    def __init__(self, dmgr, channel, core_device="core"):
        self.core = dmgr.get(core_device)
        self.channel = channel
        self.target_o = channel << 8
    @kernel
    def set_waveform(self, b0: TInt32, b1: TInt32, b2: TInt64, b3: TInt64,
            c0: TInt32, c1: TInt32, c2: TInt32):
        """Set the DDS spline waveform.
        Given `b(t)` and `c(t)` as defined in :class:`DDS`, the coefficients
        should be configured by the following formulae.
        .. math::
            T &= 8*10^{-9}
            b_0 &= q_0
            b_1 &= q_1T + \\frac{q_2T^2}{2} + \\frac{q_3T^3}{6}
            b_2 &= q_2T^2 + q_3T^3
            b_3 &= q_3T^3
            c_0 &= r_0
            c_1 &= r_1T + \\frac{r_2T^2}{2}
            c_2 &= r_2T^2
        :math:`b_0`, :math:`b_1`, :math:`b_2` and :math:`b_3` are 16, 32, 48
        and 48 bits in width respectively. See :meth:`shuttler_volt_to_mu` for
        machine unit conversion. :math:`c_0`, :math:`c_1` and :math:`c_2` are
        16, 32 and 32 bits in width respectively.
        Note: The waveform is not updated to the Shuttler Core until
        triggered. See :class:`Trigger` for the update triggering mechanism.
        :param b0: The :math:`b_0` coefficient in machine unit.
        :param b1: The :math:`b_1` coefficient in machine unit.
        :param b2: The :math:`b_2` coefficient in machine unit.
        :param b3: The :math:`b_3` coefficient in machine unit.
        :param c0: The :math:`c_0` coefficient in machine unit.
        :param c1: The :math:`c_1` coefficient in machine unit.
        :param c2: The :math:`c_2` coefficient in machine unit.
        """
        coef_words = [
            b0,
            b1,
            b1 >> 16,
            b2 & 0xFFFF,
            (b2 >> 16) & 0xFFFF,
            (b2 >> 32) & 0xFFFF,
            b3 & 0xFFFF,
            (b3 >> 16) & 0xFFFF,
            (b3 >> 32) & 0xFFFF,
            c0,
            c1,
            c1 >> 16,
            c2,
            c2 >> 16,
        ]
        for i in range(len(coef_words)):
            rtio_output(self.target_o | i, coef_words[i])
            delay_mu(int64(self.core.ref_multiplier))
 class Trigger:
    """Shuttler Core spline coefficients update trigger.
    :param channel: RTIO channel number of the trigger interface.
    :param core_device: Core device name.
    """
    kernel_invariants = {"core", "channel", "target_o"}
    def __init__(self, dmgr, channel, core_device="core"):
        self.core = dmgr.get(core_device)
        self.channel = channel
        self.target_o = channel << 8
    @kernel
    def trigger(self, trig_out):
        """Triggers coefficient update of (a) Shuttler Core channel(s).
        Each bit corresponds to a Shuttler waveform generator core. Setting
        `trig_out` bits commits the pending coefficient update (from
        `set_waveform` in :class:`DCBias` and :class:`DDS`) to the Shuttler Core
        synchronously.
        :param trig_out: Coefficient update trigger bits. The MSB corresponds
            to Channel 15, LSB corresponds to Channel 0.
        """
        rtio_output(self.target_o, trig_out)
 RELAY_SPI_CONFIG = (0*spi.SPI_OFFLINE | 1*spi.SPI_END |
                    0*spi.SPI_INPUT | 0*spi.SPI_CS_POLARITY |
                    0*spi.SPI_CLK_POLARITY | 0*spi.SPI_CLK_PHASE |
                    0*spi.SPI_LSB_FIRST | 0*spi.SPI_HALF_DUPLEX)
 ADC_SPI_CONFIG = (0*spi.SPI_OFFLINE | 0*spi.SPI_END |
                  0*spi.SPI_INPUT | 0*spi.SPI_CS_POLARITY |
                  1*spi.SPI_CLK_POLARITY | 1*spi.SPI_CLK_PHASE |
                  0*spi.SPI_LSB_FIRST | 0*spi.SPI_HALF_DUPLEX)
 # SPI clock write and read dividers
 # CS should assert at least 9.5 ns after clk pulse
 SPIT_RELAY_WR = 4
 # 25 ns high/low pulse hold (limiting for write)
 SPIT_ADC_WR = 4
 SPIT_ADC_RD = 16
 # SPI CS line
 CS_RELAY = 1 << 0
 CS_LED = 1 << 1
 CS_ADC = 1 << 0
 # Referenced AD4115 registers
 _AD4115_REG_STATUS = 0x00
 _AD4115_REG_ADCMODE = 0x01
 _AD4115_REG_DATA = 0x04
 _AD4115_REG_ID = 0x07
 _AD4115_REG_CH0 = 0x10
 _AD4115_REG_SETUPCON0 = 0x20
 class Relay:
    """Shuttler AFE relay switches.
    It controls the AFE relay switches and the LEDs. Switch on the relay to
    enable AFE output; And off to disable the output. The LEDs indicates the
    relay status.
    .. note::
        The relay does not disable ADC measurements. Voltage of any channels
        can still be read by the ADC even after switching off the relays.
    :param spi_device: SPI bus device name.
    :param core_device: Core device name.
    """
    kernel_invariant = {"core", "bus"}
    def __init__(self, dmgr, spi_device, core_device="core"):
        self.core = dmgr.get(core_device)
        self.bus = dmgr.get(spi_device)
    @kernel
    def init(self):
        """Initialize SPI device.
        Configures the SPI bus to 16-bits, write-only, simultaneous relay
        switches and LED control.
        """
        self.bus.set_config_mu(
            RELAY_SPI_CONFIG, 16, SPIT_RELAY_WR, CS_RELAY | CS_LED)
    @kernel
    def enable(self, en: TInt32):
        """Enable/Disable relay switches of corresponding channels.
        Each bit corresponds to the relay switch of a channel. Asserting a bit
        turns on the corresponding relay switch; Deasserting the same bit
        turns off the switch instead.
        :param en: Switch enable bits. The MSB corresponds to Channel 15, LSB
            corresponds to Channel 0.
        """
        self.bus.write(en << 16)
 class ADC:
    """Shuttler AFE ADC (AD4115) driver.
    :param spi_device: SPI bus device name.
    :param core_device: Core device name.
    """
    kernel_invariant = {"core", "bus"}
    def __init__(self, dmgr, spi_device, core_device="core"):
        self.core = dmgr.get(core_device)
        self.bus = dmgr.get(spi_device)
    @kernel
    def read_id(self) -> TInt32:
        """Read the product ID of the ADC.
        The expected return value is 0x38DX, the 4 LSbs are don't cares.
        :return: The read-back product ID.
        """
        return self.read16(_AD4115_REG_ID)
    @kernel
    def reset(self):
        """AD4115 reset procedure.
        This performs a write operation of 96 serial clock cycles with DIN
        held at high. It resets the entire device, including the register
        contents.
        .. note::
            The datasheet only requires 64 cycles, but reasserting `CS_n` right
            after the transfer appears to interrupt the start-up sequence.
        """
        self.bus.set_config_mu(ADC_SPI_CONFIG, 32, SPIT_ADC_WR, CS_ADC)
        self.bus.write(0xffffffff)
        self.bus.write(0xffffffff)
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END, 32, SPIT_ADC_WR, CS_ADC)
        self.bus.write(0xffffffff)
    @kernel
    def read8(self, addr: TInt32) -> TInt32:
        """Read from 8 bit register.
        :param addr: Register address.
        :return: Read-back register content.
        """
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END | spi.SPI_INPUT,
            16, SPIT_ADC_RD, CS_ADC)
        self.bus.write((addr | 0x40) << 24)
        return self.bus.read() & 0xff
    @kernel
    def read16(self, addr: TInt32) -> TInt32:
        """Read from 16 bit register.
        :param addr: Register address.
        :return: Read-back register content.
        """
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END | spi.SPI_INPUT,
            24, SPIT_ADC_RD, CS_ADC)
        self.bus.write((addr | 0x40) << 24)
        return self.bus.read() & 0xffff
    @kernel
    def read24(self, addr: TInt32) -> TInt32:
        """Read from 24 bit register.
        :param addr: Register address.
        :return: Read-back register content.
        """
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END | spi.SPI_INPUT,
            32, SPIT_ADC_RD, CS_ADC)
        self.bus.write((addr | 0x40) << 24)
        return self.bus.read() & 0xffffff
    @kernel
    def write8(self, addr: TInt32, data: TInt32):
        """Write to 8 bit register.
        :param addr: Register address.
        :param data: Data to be written.
        """
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END, 16, SPIT_ADC_WR, CS_ADC)
        self.bus.write(addr << 24 | (data & 0xff) << 16)
    @kernel
    def write16(self, addr: TInt32, data: TInt32):
        """Write to 16 bit register.
        :param addr: Register address.
        :param data: Data to be written.
        """
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END, 24, SPIT_ADC_WR, CS_ADC)
        self.bus.write(addr << 24 | (data & 0xffff) << 8)
    @kernel
    def write24(self, addr: TInt32, data: TInt32):
        """Write to 24 bit register.
        :param addr: Register address.
        :param data: Data to be written.
        """
        self.bus.set_config_mu(
            ADC_SPI_CONFIG | spi.SPI_END, 32, SPIT_ADC_WR, CS_ADC)
        self.bus.write(addr << 24 | (data & 0xffffff))
    @kernel
    def read_ch(self, channel: TInt32) -> TFloat:
        """Sample a Shuttler channel on the AFE.
        It performs a single conversion using profile 0 and setup 0, on the
        selected channel. The sample is then recovered and converted to volt.
        :param channel: Shuttler channel to be sampled.
        :return: Voltage sample in volt.
        """
        # Always configure Profile 0 for single conversion
        self.write16(_AD4115_REG_CH0, 0x8000 | ((channel * 2 + 1) << 4))
        self.write16(_AD4115_REG_SETUPCON0, 0x1300)
        self.single_conversion()
        delay(100*us)
        adc_code = self.read24(_AD4115_REG_DATA)
        return ((adc_code / (1 << 23)) - 1) * 2.5 / 0.1
    @kernel
    def single_conversion(self):
        """Place the ADC in single conversion mode.
        The ADC returns to standby mode after the conversion is complete.
        """
        self.write16(_AD4115_REG_ADCMODE, 0x8010)
    @kernel
    def standby(self):
        """Place the ADC in standby mode and disables power down the clock.
        The ADC can be returned to single conversion mode by calling
        :meth:`single_conversion`.
        """
        # Selecting internal XO (0b00) also disables clock during standby
        self.write16(_AD4115_REG_ADCMODE, 0x8020)
    @kernel
    def power_down(self):
        """Place the ADC in power-down mode.
        The ADC must be reset before returning to other modes.
        .. note::
            The AD4115 datasheet suggests placing the ADC in standby mode
            before power-down. This is to prevent accidental entry into the
            power-down mode.
        .. seealso::
            :meth:`standby`
            :meth:`power_up`
        """
        self.write16(_AD4115_REG_ADCMODE, 0x8030)
    @kernel
    def power_up(self):
        """Exit the ADC power-down mode.
        The ADC should be in power-down mode before calling this method.
        .. seealso::
            :meth:`power_down`
        """
        self.reset()
        # Although the datasheet claims 500 us reset wait time, only waiting
        # for ~500 us can result in DOUT pin stuck in high
        delay(2500*us)
    @kernel
    def calibrate(self, volts, trigger, config, samples=[-5.0, 0.0, 5.0]):
        """Calibrate the Shuttler waveform generator using the ADC on the AFE.
        It finds the average slope rate and average offset by samples, and
        compensate by writing the pre-DAC gain and offset registers in the
        configuration registers.
        .. note::
            If the pre-calibration slope rate < 1, the calibration procedure
            will introduce a pre-DAC gain compensation. However, this may
            saturate the pre-DAC voltage code. (See :class:`Config` notes).
            Shuttler cannot cover the entire +/- 10 V range in this case.
        .. seealso::
            :meth:`Config.set_gain`
            :meth:`Config.set_offset`
        :param volts: A list of all 16 cubic DC-bias spline.
            (See :class:`DCBias`)
        :param trigger: The Shuttler spline coefficient update trigger.
        :param config: The Shuttler Core configuration registers.
        :param samples: A list of sample voltages for calibration. There must
            be at least 2 samples to perform slope rate calculation.
        """
        assert len(volts) == 16
        assert len(samples) > 1
        measurements = [0.0] * len(samples)
        for ch in range(16):
            # Find the average slope rate and offset
            for i in range(len(samples)):
                self.core.break_realtime()
                volts[ch].set_waveform(
                    shuttler_volt_to_mu(samples[i]), 0, 0, 0)
                trigger.trigger(1 << ch)
                measurements[i] = self.read_ch(ch)
            # Find the average output slope
            slope_sum = 0.0
            for i in range(len(samples) - 1):
                slope_sum += (measurements[i+1] - measurements[i])/(samples[i+1] - samples[i])
            slope_avg = slope_sum / (len(samples) - 1)
            gain_code = int32(1 / slope_avg * (2 ** 16)) & 0xffff
            # Scale the measurements by 1/slope, find average offset
            offset_sum = 0.0
            for i in range(len(samples)):
                offset_sum += (measurements[i] / slope_avg) - samples[i]
            offset_avg = offset_sum / len(samples)
            offset_code = shuttler_volt_to_mu(-offset_avg)
            self.core.break_realtime()
            config.set_gain(ch, gain_code)
            delay_mu(int64(self.core.ref_multiplier))
            config.set_offset(ch, offset_code)
--- a/artiq/coredevice/spi2.py
+++ b/artiq/coredevice/spi2.py
@ -72,6 +72,10 @@ class SPIMaster:
        self.channel = channel
        self.update_xfer_duration_mu(div, length)
    @staticmethod
    def get_rtio_channels(channel, **kwargs):
        return [(channel, None)]
    @portable
    def frequency_to_div(self, f):
        """Convert a SPI clock frequency to the closest SPI clock divider."""
@ -273,9 +277,8 @@ class NRTSPIMaster:
    def set_config_mu(self, flags=0, length=8, div=6, cs=1):
        """Set the ``config`` register.
-        Note that the non-realtime SPI cores are usually clocked by the system
+        In many cases, the SPI configuration is already set by the firmware
-        clock and not the RTIO clock. In many cases, the SPI configuration is
+        and you do not need to call this method.
        already set by the firmware and you do not need to call this method.
        """
        spi_set_config(self.busno, flags, length, div, cs)
--- a/artiq/coredevice/spline.py
+++ b/artiq/coredevice/spline.py
@ -1,228 +0,0 @@
 from numpy import int32, int64
 from artiq.language.core import kernel, portable, delay
 from artiq.coredevice.rtio import rtio_output, rtio_output_wide
 from artiq.language.types import TInt32, TInt64, TFloat
 class Spline:
    r"""Spline interpolating RTIO channel.
    One knot of a polynomial basis spline (B-spline) :math:`u(t)`
    is defined by the coefficients :math:`u_n` up to order :math:`n = k`.
    If the coefficients are evaluated starting at time :math:`t_0`,
    the output :math:`u(t)` for :math:`t > t_0, t_0` is:
    .. math::
        u(t) &= \sum_{n=0}^k \frac{u_n}{n!} (t - t_0)^n \\
             &= u_0 + u_1 (t - t_0) + \frac{u_2}{2} (t - t_0)^2 + \dots
    This class contains multiple methods to convert spline knot data from SI
    to machine units and multiple methods that set the current spline
    coefficient data. None of these advance the timeline. The :meth:`smooth`
    method is the only method that advances the timeline.
    :param width: Width in bits of the quantity that this spline controls
    :param time_width: Width in bits of the time counter of this spline
    :param channel: RTIO channel number
    :param core_device: Core device that this spline is attached to
    :param scale: Scale for conversion between machine units and physical
        units; to be given as the "full scale physical value".
    """
    kernel_invariants = {"channel", "core", "scale", "width",
                         "time_width", "time_scale"}
    def __init__(self, width, time_width, channel, core_device, scale=1.):
        self.core = core_device
        self.channel = channel
        self.width = width
        self.scale = float((int64(1) << width) / scale)
        self.time_width = time_width
        self.time_scale = float((1 << time_width) *
                                core_device.coarse_ref_period)
    @portable(flags={"fast-math"})
    def to_mu(self, value: TFloat) -> TInt32:
        """Convert floating point ``value`` from physical units to 32 bit
        integer machine units."""
        return int32(round(value*self.scale))
    @portable(flags={"fast-math"})
    def from_mu(self, value: TInt32) -> TFloat:
        """Convert 32 bit integer ``value`` from machine units to floating
        point physical units."""
        return value/self.scale
    @portable(flags={"fast-math"})
    def to_mu64(self, value: TFloat) -> TInt64:
        """Convert floating point ``value`` from physical units to 64 bit
        integer machine units."""
        return int64(round(value*self.scale))
    @kernel
    def set_mu(self, value: TInt32):
        """Set spline value (machine units).
        :param value: Spline value in integer machine units.
        """
        rtio_output(self.channel << 8, value)
    @kernel(flags={"fast-math"})
    def set(self, value: TFloat):
        """Set spline value.
        :param value: Spline value relative to full-scale.
        """
        if self.width > 32:
            l = [int32(0)] * 2
            self.pack_coeff_mu([self.to_mu64(value)], l)
            rtio_output_wide(self.channel << 8, l)
        else:
            rtio_output(self.channel << 8, self.to_mu(value))
    @kernel
    def set_coeff_mu(self, value):  # TList(TInt32)
        """Set spline raw values.
        :param value: Spline packed raw values.
        """
        rtio_output_wide(self.channel << 8, value)
    @portable(flags={"fast-math"})
    def pack_coeff_mu(self, coeff, packed):  # TList(TInt64), TList(TInt32)
        """Pack coefficients into RTIO data
        :param coeff: TList(TInt64) list of machine units spline coefficients.
            Lowest (zeroth) order first. The coefficient list is zero-extended
            by the RTIO gateware.
        :param packed: TList(TInt32) list for packed RTIO data. Must be
            pre-allocated. Length in bits is
            ``n*width + (n - 1)*n//2*time_width``
        """
        pos = 0
        for i in range(len(coeff)):
            wi = self.width + i*self.time_width
            ci = coeff[i]
            while wi != 0:
                j = pos//32
                used = pos - 32*j
                avail = 32 - used
                if avail > wi:
                    avail = wi
                cij = int32(ci)
                if avail != 32:
                    cij &= (1 << avail) - 1
                packed[j] |= cij << used
                ci >>= avail
                wi -= avail
                pos += avail
    @portable(flags={"fast-math"})
    def coeff_to_mu(self, coeff, coeff64):  # TList(TFloat), TList(TInt64)
        """Convert a floating point list of coefficients into a 64 bit
        integer (preallocated).
        :param coeff: TList(TFloat) list of coefficients in physical units.
        :param coeff64: TList(TInt64) preallocated list of coefficients in
            machine units.
        """
        for i in range(len(coeff)):
            vi = coeff[i] * self.scale
            for j in range(i):
                vi *= self.time_scale
            ci = int64(round(vi))
            coeff64[i] = ci
            # artiq.wavesynth.coefficients.discrete_compensate:
            if i == 2:
                coeff64[1] += ci >> self.time_width + 1
            elif i == 3:
                coeff64[2] += ci >> self.time_width
                coeff64[1] += ci // 6 >> 2*self.time_width
    def coeff_as_packed_mu(self, coeff64):
        """Pack 64 bit integer machine units coefficients into 32 bit integer
        RTIO data list.
        This is a host-only method that can be used to generate packed
        spline coefficient data to be frozen into kernels at compile time.
        """
        n = len(coeff64)
        width = n*self.width + (n - 1)*n//2*self.time_width
        packed = [int32(0)] * ((width + 31)//32)
        self.pack_coeff_mu(coeff64, packed)
        return packed
    def coeff_as_packed(self, coeff):
        """Convert floating point spline coefficients into 32 bit integer
        packed data.
        This is a host-only method that can be used to generate packed
        spline coefficient data to be frozen into kernels at compile time.
        """
        coeff64 = [int64(0)] * len(coeff)
        self.coeff_to_mu(coeff, coeff64)
        return self.coeff_as_packed_mu(coeff64)
    @kernel(flags={"fast-math"})
    def set_coeff(self, coeff):  # TList(TFloat)
        """Set spline coefficients.
        Missing coefficients (high order) are zero-extended byt the RTIO
        gateware.
        If more coefficients are supplied than the gateware supports the extra
        coefficients are ignored.
        :param value: List of floating point spline coefficients,
            lowest order (constant) coefficient first. Units are the
            unit of this spline's value times increasing powers of 1/s.
        """
        n = len(coeff)
        coeff64 = [int64(0)] * n
        self.coeff_to_mu(coeff, coeff64)
        width = n*self.width + (n - 1)*n//2*self.time_width
        packed = [int32(0)] * ((width + 31)//32)
        self.pack_coeff_mu(coeff64, packed)
        self.set_coeff_mu(packed)
    @kernel(flags={"fast-math"})
    def smooth(self, start: TFloat, stop: TFloat, duration: TFloat,
               order: TInt32):
        """Initiate an interpolated value change.
        For zeroth order (step) interpolation, the step is at
        ``start + duration/2``.
        First order interpolation corresponds to a linear value ramp from
        ``start`` to ``stop`` over ``duration``.
        The third order interpolation is constrained to have zero first
        order derivative at both `start` and `stop`.
        For first order and third order interpolation (linear and cubic)
        the interpolator needs to be stopped explicitly at the stop time
        (e.g. by setting spline coefficient data or starting a new
        :meth:`smooth` interpolation).
        This method advances the timeline by ``duration``.
        :param start: Initial value of the change. In physical units.
        :param stop: Final value of the change. In physical units.
        :param duration: Duration of the interpolation. In physical units.
        :param order: Order of the interpolation. Only 0, 1,
            and 3 are valid: step, linear, cubic.
        """
        if order == 0:
            delay(duration/2.)
            self.set_coeff([stop])
            delay(duration/2.)
        elif order == 1:
            self.set_coeff([start, (stop - start)/duration])
            delay(duration)
        elif order == 3:
            v2 = 6.*(stop - start)/(duration*duration)
            self.set_coeff([start, 0., v2, -2.*v2/duration])
            delay(duration)
        else:
            raise ValueError("Invalid interpolation order. "
                             "Supported orders are: 0, 1, 3.")
--- a/artiq/coredevice/spr.py
+++ b/artiq/coredevice/spr.py
@ -1,12 +0,0 @@
 from artiq.language.core import syscall
 from artiq.language.types import TInt32, TNone
@syscall(flags={"nounwind", "nowrite"})
 def mfspr(spr: TInt32) -> TInt32:
    raise NotImplementedError("syscall not simulated")
@syscall(flags={"nowrite", "nowrite"})
 def mtspr(spr: TInt32, value: TInt32) -> TNone:
    raise NotImplementedError("syscall not simulated")
--- a/artiq/coredevice/suservo.py
+++ b/artiq/coredevice/suservo.py
@ -23,12 +23,12 @@ def y_mu_to_full_scale(y):
@portable
-def adc_mu_to_volts(x, gain):
+def adc_mu_to_volts(x, gain, corrected_fs=True):
    """Convert servo ADC data from machine units to Volt."""
    val = (x >> 1) & 0xffff
    mask = 1 << 15
    val = -(val & mask) + (val & ~mask)
-    return sampler.adc_mu_to_volt(val, gain)
+    return sampler.adc_mu_to_volt(val, gain, corrected_fs)
 class SUServo:
@ -57,38 +57,38 @@ class SUServo:
    :param channel: RTIO channel number
    :param pgia_device: Name of the Sampler PGIA gain setting SPI bus
-    :param cpld0_device: Name of the first Urukul CPLD SPI bus
+    :param cpld_devices: Names of the Urukul CPLD SPI buses
-    :param cpld1_device: Name of the second Urukul CPLD SPI bus
+    :param dds_devices: Names of the AD9910 devices
    :param dds0_device: Name of the AD9910 device for the DDS on the first
        Urukul
    :param dds1_device: Name of the AD9910 device for the DDS on the second
        Urukul
    :param gains: Initial value for PGIA gains shift register
        (default: 0x0000). Knowledge of this state is not transferred
        between experiments.
    :param sampler_hw_rev: Sampler's revision string
    :param core_device: Core device name
    """
-    kernel_invariants = {"channel", "core", "pgia", "cpld0", "cpld1",
+    kernel_invariants = {"channel", "core", "pgia", "cplds", "ddses",
-                         "dds0", "dds1", "ref_period_mu"}
+                         "ref_period_mu", "corrected_fs"}
    def __init__(self, dmgr, channel, pgia_device,
-                 cpld0_device, cpld1_device,
+                 cpld_devices, dds_devices,
-                 dds0_device, dds1_device,
+                 gains=0x0000, sampler_hw_rev="v2.2", core_device="core"):
                 gains=0x0000, core_device="core"):
        self.core = dmgr.get(core_device)
        self.pgia = dmgr.get(pgia_device)
        self.pgia.update_xfer_duration_mu(div=4, length=16)
-        self.dds0 = dmgr.get(dds0_device)
+        assert len(dds_devices) == len(cpld_devices)
-        self.dds1 = dmgr.get(dds1_device)
+        self.ddses = [dmgr.get(dds) for dds in dds_devices]
-        self.cpld0 = dmgr.get(cpld0_device)
+        self.cplds = [dmgr.get(cpld) for cpld in cpld_devices]
        self.cpld1 = dmgr.get(cpld1_device)
        self.channel = channel
        self.gains = gains
        self.ref_period_mu = self.core.seconds_to_mu(
            self.core.coarse_ref_period)
        self.corrected_fs = sampler.Sampler.use_corrected_fs(sampler_hw_rev)
        assert self.ref_period_mu == self.core.ref_multiplier
    @staticmethod
    def get_rtio_channels(channel, **kwargs):
        return [(channel, None)]
    @kernel
    def init(self):
        """Initialize the servo, Sampler and both Urukuls.
@ -109,17 +109,15 @@ class SUServo:
            sampler.SPI_CONFIG | spi.SPI_END,
            16, 4, sampler.SPI_CS_PGIA)
-        self.cpld0.init(blind=True)
+        for i in range(len(self.cplds)):
-        cfg0 = self.cpld0.cfg_reg
+            cpld = self.cplds[i]
-        self.cpld0.cfg_write(cfg0 | (0xf << urukul.CFG_MASK_NU))
+            dds = self.ddses[i]
        self.dds0.init(blind=True)
        self.cpld0.cfg_write(cfg0)
-        self.cpld1.init(blind=True)
+            cpld.init(blind=True)
-        cfg1 = self.cpld1.cfg_reg
+            prev_cpld_cfg = cpld.cfg_reg
-        self.cpld1.cfg_write(cfg1 | (0xf << urukul.CFG_MASK_NU))
+            cpld.cfg_write(prev_cpld_cfg | (0xf << urukul.CFG_MASK_NU))
-        self.dds1.init(blind=True)
+            dds.init(blind=True)
-        self.cpld1.cfg_write(cfg1)
+            cpld.cfg_write(prev_cpld_cfg)
    @kernel
    def write(self, addr, value):
@ -242,7 +240,7 @@ class SUServo:
        """
        val = self.get_adc_mu(channel)
        gain = (self.gains >> (channel*2)) & 0b11
-        return adc_mu_to_volts(val, gain)
+        return adc_mu_to_volts(val, gain, self.corrected_fs)
 class Channel:
@ -257,9 +255,15 @@ class Channel:
        self.servo = dmgr.get(servo_device)
        self.core = self.servo.core
        self.channel = channel
-        # FIXME: this assumes the mem channel is right after the control
+        # This assumes the mem channel is right after the control channels
-        # channels
+        # Make sure this is always the case in eem.py
-        self.servo_channel = self.channel + 8 - self.servo.channel
+        self.servo_channel = (self.channel + 4 * len(self.servo.cplds) -
                              self.servo.channel)
        self.dds = self.servo.ddses[self.servo_channel // 4]
    @staticmethod
    def get_rtio_channels(channel, **kwargs):
        return [(channel, None)]
    @kernel
    def set(self, en_out, en_iir=0, profile=0):
@ -311,12 +315,8 @@ class Channel:
            see :meth:`dds_offset_to_mu`
        :param phase: DDS phase in turns
        """
-        if self.servo_channel < 4:
+        ftw = self.dds.frequency_to_ftw(frequency)
-            dds = self.servo.dds0
+        pow_ = self.dds.turns_to_pow(phase)
        else:
            dds = self.servo.dds1
        ftw = dds.frequency_to_ftw(frequency)
        pow_ = dds.turns_to_pow(phase)
        offs = self.dds_offset_to_mu(offset)
        self.set_dds_mu(profile, ftw, offs, pow_)
--- a/artiq/coredevice/trf372017.py
+++ b/artiq/coredevice/trf372017.py
@ -4,20 +4,21 @@ class TRF372017:
    For possible values, documentation, and explanation, see the datasheet.
    https://www.ti.com/lit/gpn/trf372017
    """
-    rdiv = 21  # 13b
+    rdiv = 2  # 13b - highest valid f_PFD
    ref_inv = 0
    neg_vco = 1
    icp = 0  # 1.94 mA, 5b
    icp_double = 0
-    cal_clk_sel = 12  # /16, 4b
+    cal_clk_sel = 0b1110  # div64, 4b
-    ndiv = 420  # 16b
+    # default f_vco is 2.875 GHz
-    pll_div_sel = 0  # /1, 2b
+    nint = 23  # 16b - lowest value suitable for fractional & integer mode
-    prsc_sel = 1  # 8/9
+    pll_div_sel = 0b01  # div2, 2b
    prsc_sel = 0  # 4/5
    vco_sel = 2  # 2b
    vcosel_mode = 0
    cal_acc = 0b00  # 2b
-    en_cal = 1
+    en_cal = 0  # leave at 0 - calibration is performed in `Phaser.init()`
    nfrac = 0  # 25b
@ -27,9 +28,9 @@ class TRF372017:
    pwd_vcomux = 0
    pwd_div124 = 0
    pwd_presc = 0
-    pwd_out_buff = 1
+    pwd_out_buff = 1  # leave at 1 - only enable outputs after calibration
-    pwd_lo_div = 1
+    pwd_lo_div = 1  # leave at 1 - only enable outputs after calibration
-    pwd_tx_div = 0
+    pwd_tx_div = 1  # leave at 1 - only enable outputs after calibration
    pwd_bb_vcm = 0
    pwd_dc_off = 0
    en_extvco = 0
@ -59,8 +60,8 @@ class TRF372017:
    ioff = 0x80  # 8b
    qoff = 0x80  # 8b
    vref_sel = 4  # 0.85 V, 3b
-    tx_div_sel = 1  # div2, 2b
+    tx_div_sel = 0  # div1, 2b
-    lo_div_sel = 3  # div8, 2b
+    lo_div_sel = 0  # div1, 2b
    tx_div_bias = 1  # 37.5 µA, 2b
    lo_div_bias = 2  # 50 µA, 2b
@ -84,6 +85,7 @@ class TRF372017:
            setattr(self, key, value)
    def get_mmap(self):
        """Memory map for TRF372017"""
        mmap = []
        mmap.append(
            0x9 |
@ -92,9 +94,10 @@ class TRF372017:
            (self.cal_clk_sel << 27))
        mmap.append(
            0xa |
-            (self.ndiv << 5) | (self.pll_div_sel << 21) | (self.prsc_sel << 23) |
+            (self.nint << 5) | (self.pll_div_sel << 21) |
-            (self.vco_sel << 26) | (self.vcosel_mode << 28) |
+            (self.prsc_sel << 23) | (self.vco_sel << 26) |
-            (self.cal_acc << 29) | (self.en_cal << 31))
+            (self.vcosel_mode << 28) | (self.cal_acc << 29) |
            (self.en_cal << 31))
        mmap.append(0xb | (self.nfrac << 5))
        mmap.append(
            0xc |
--- a/artiq/coredevice/ttl.py
+++ b/artiq/coredevice/ttl.py
@ -36,6 +36,10 @@ class TTLOut:
        self.channel = channel
        self.target_o = channel << 8
    @staticmethod
    def get_rtio_channels(channel, **kwargs):
        return [(channel, None)]
    @kernel
    def output(self):
        pass
@ -128,6 +132,10 @@ class TTLInOut:
        self.target_sens   = (channel << 8) + 2
        self.target_sample = (channel << 8) + 3
    @staticmethod
    def get_rtio_channels(channel, **kwargs):
        return [(channel, None)]
    @kernel
    def set_oe(self, oe):
        rtio_output(self.target_oe, 1 if oe else 0)
@ -465,6 +473,10 @@ class TTLClockGen:
        self.acc_width = numpy.int64(acc_width)
    @staticmethod
    def get_rtio_channels(channel, **kwargs):
        return [(channel, None)]
    @portable
    def frequency_to_ftw(self, frequency):
        """Returns the frequency tuning word corresponding to the given
--- a/artiq/coredevice/urukul.py
+++ b/artiq/coredevice/urukul.py
@ -1,10 +1,10 @@
 from artiq.language.core import kernel, delay, portable, at_mu, now_mu
 from artiq.language.units import us, ms
 from numpy import int32, int64
-from artiq.coredevice import spi2 as spi
+from artiq.language.core import kernel, delay, portable, at_mu, now_mu
 from artiq.language.units import us, ms
 from artiq.language.types import TInt32, TFloat, TBool
 from artiq.coredevice import spi2 as spi
 SPI_CONFIG = (0 * spi.SPI_OFFLINE | 0 * spi.SPI_END |
              0 * spi.SPI_INPUT | 1 * spi.SPI_CS_POLARITY |
@ -52,6 +52,9 @@ CS_DDS_CH1 = 5
 CS_DDS_CH2 = 6
 CS_DDS_CH3 = 7
 # Default profile
 DEFAULT_PROFILE = 7
@portable
 def urukul_cfg(rf_sw, led, profile, io_update, mask_nu,
@ -105,7 +108,7 @@ class _RegIOUpdate:
        self.cpld = cpld
    @kernel
-    def pulse(self, t):
+    def pulse(self, t: TFloat):
        cfg = self.cpld.cfg_reg
        self.cpld.cfg_write(cfg | (1 << CFG_IO_UPDATE))
        delay(t)
@ -117,7 +120,7 @@ class _DummySync:
        self.cpld = cpld
    @kernel
-    def set_mu(self, ftw):
+    def set_mu(self, ftw: TInt32):
        pass
@ -188,7 +191,7 @@ class CPLD:
            assert sync_div is None
            sync_div = 0
-        self.cfg_reg = urukul_cfg(rf_sw=rf_sw, led=0, profile=0,
+        self.cfg_reg = urukul_cfg(rf_sw=rf_sw, led=0, profile=DEFAULT_PROFILE,
                                  io_update=0, mask_nu=0, clk_sel=clk_sel,
                                  sync_sel=sync_sel,
                                  rst=0, io_rst=0, clk_div=clk_div)
@ -196,12 +199,12 @@ class CPLD:
        self.sync_div = sync_div
    @kernel
-    def cfg_write(self, cfg):
+    def cfg_write(self, cfg: TInt32):
        """Write to the configuration register.
        See :func:`urukul_cfg` for possible flags.
-        :param data: 24 bit data to be written. Will be stored at
+        :param cfg: 24 bit data to be written. Will be stored at
            :attr:`cfg_reg`.
        """
        self.bus.set_config_mu(SPI_CONFIG | spi.SPI_END, 24,
@ -210,7 +213,7 @@ class CPLD:
        self.cfg_reg = cfg
    @kernel
-    def sta_read(self):
+    def sta_read(self) -> TInt32:
        """Read the status register.
        Use any of the following functions to extract values:
@ -229,7 +232,7 @@ class CPLD:
        return self.bus.read()
    @kernel
-    def init(self, blind=False):
+    def init(self, blind: TBool = False):
        """Initialize and detect Urukul.
        Resets the DDS I/O interface and verifies correct CPLD gateware
@ -261,7 +264,7 @@ class CPLD:
        self.cfg_write(self.cfg_reg & ~(1 << CFG_IO_RST))
    @kernel
-    def cfg_sw(self, channel, on):
+    def cfg_sw(self, channel: TInt32, on: TBool):
        """Configure the RF switches through the configuration register.
        These values are logically OR-ed with the LVDS lines on EEM1.
@ -277,19 +280,41 @@ class CPLD:
        self.cfg_write(c)
    @kernel
-    def cfg_switches(self, state):
+    def cfg_switches(self, state: TInt32):
        """Configure all four RF switches through the configuration register.
        :param state: RF switch state as a 4 bit integer.
        """
        self.cfg_write((self.cfg_reg & ~0xf) | state)
    @portable(flags={"fast-math"})
    def mu_to_att(self, att_mu: TInt32) -> TFloat:
        """Convert a digital attenuation setting to dB.
        :param att_mu: Digital attenuation setting.
        :return: Attenuation setting in dB.
        """
        return (255 - (att_mu & 0xff)) / 8
    @portable(flags={"fast-math"})
    def att_to_mu(self, att: TFloat) -> TInt32:
        """Convert an attenuation setting in dB to machine units.
        :param att: Attenuation setting in dB.
        :return: Digital attenuation setting.
        """
        code = int32(255) - int32(round(att * 8))
        if code < 0 or code > 255:
            raise ValueError("Invalid urukul.CPLD attenuation!")
        return code
    @kernel
-    def set_att_mu(self, channel, att):
+    def set_att_mu(self, channel: TInt32, att: TInt32):
        """Set digital step attenuator in machine units.
-        This method will also write the attenuator settings of the three other channels. Use
+        This method will also write the attenuator settings of the three
-        :meth:`get_att_mu` to retrieve the hardware state set in previous experiments.
+        other channels. Use :meth:`get_att_mu` to retrieve the hardware
        state set in previous experiments.
        :param channel: Attenuator channel (0-3).
        :param att: 8-bit digital attenuation setting:
@ -300,7 +325,7 @@ class CPLD:
        self.set_all_att_mu(a)
    @kernel
-    def set_all_att_mu(self, att_reg):
+    def set_all_att_mu(self, att_reg: TInt32):
        """Set all four digital step attenuators (in machine units).
        .. seealso:: :meth:`set_att_mu`
@ -313,7 +338,7 @@ class CPLD:
        self.att_reg = att_reg
    @kernel
-    def set_att(self, channel, att):
+    def set_att(self, channel: TInt32, att: TFloat):
        """Set digital step attenuator in SI units.
        This method will write the attenuator settings of all four channels.
@ -325,16 +350,16 @@ class CPLD:
            attenuation. Minimum attenuation is 0*dB, maximum attenuation is
            31.5*dB.
        """
-        code = 255 - int32(round(att*8))
+        self.set_att_mu(channel, self.att_to_mu(att))
        if code < 0 or code > 255:
            raise ValueError("Invalid urukul.CPLD attenuation!")
        self.set_att_mu(channel, code)
    @kernel
-    def get_att_mu(self):
+    def get_att_mu(self) -> TInt32:
        """Return the digital step attenuator settings in machine units.
-        The result is stored and will be used in future calls of :meth:`set_att_mu`.
+        The result is stored and will be used in future calls of
        :meth:`set_att_mu` and :meth:`set_att`.
        .. seealso:: :meth:`get_channel_att_mu`
        :return: 32 bit attenuator settings
        """
@ -349,7 +374,35 @@ class CPLD:
        return self.att_reg
    @kernel
-    def set_sync_div(self, div):
+    def get_channel_att_mu(self, channel: TInt32) -> TInt32:
        """Get digital step attenuator value for a channel in machine units.
        The result is stored and will be used in future calls of
        :meth:`set_att_mu` and :meth:`set_att`.
        .. seealso:: :meth:`get_att_mu`
        :param channel: Attenuator channel (0-3).
        :return: 8-bit digital attenuation setting:
            255 minimum attenuation, 0 maximum attenuation (31.5 dB)
        """
        return int32((self.get_att_mu() >> (channel * 8)) & 0xff)
    @kernel
    def get_channel_att(self, channel: TInt32) -> TFloat:
        """Get digital step attenuator value for a channel in SI units.
        .. seealso:: :meth:`get_channel_att_mu`
        :param channel: Attenuator channel (0-3).
        :return: Attenuation setting in dB. Higher value is more
            attenuation. Minimum attenuation is 0*dB, maximum attenuation is
            31.5*dB.
        """
        return self.mu_to_att(self.get_channel_att_mu(channel))
    @kernel
    def set_sync_div(self, div: TInt32):
        """Set the SYNC_IN AD9910 pulse generator frequency
        and align it to the current RTIO timestamp.
@ -366,7 +419,7 @@ class CPLD:
        self.sync.set_mu(ftw)
    @kernel
-    def set_profile(self, profile):
+    def set_profile(self, profile: TInt32):
        """Set the PROFILE pins.
        The PROFILE pins are common to all four DDS channels.
--- a/artiq/coredevice/zotino.py
+++ b/artiq/coredevice/zotino.py
@ -27,15 +27,15 @@ class Zotino(AD53xx):
    :param clr_device: CLR RTIO TTLOut channel name.
    :param div_write: SPI clock divider for write operations (default: 4,
      50MHz max SPI clock)
-    :param div_read: SPI clock divider for read operations (default: 8, not
+    :param div_read: SPI clock divider for read operations (default: 16, not
-      optimized for speed, but cf data sheet t22: 25ns min SCLK edge to SDO
+      optimized for speed; datasheet says t22: 25ns min SCLK edge to SDO
-      valid)
+      valid, and suggests the SPI speed for reads should be <=20 MHz)
    :param vref: DAC reference voltage (default: 5.)
    :param core_device: Core device name (default: "core")
    """
    def __init__(self, dmgr, spi_device, ldac_device=None, clr_device=None,
-                 div_write=4, div_read=8, vref=5., core="core"):
+                 div_write=4, div_read=16, vref=5., core="core"):
        AD53xx.__init__(self, dmgr=dmgr, spi_device=spi_device,
                        ldac_device=ldac_device, clr_device=clr_device,
                        chip_select=_SPI_CS_DAC, div_write=div_write,
--- a/artiq/dashboard/applets_ccb.py
+++ b/artiq/dashboard/applets_ccb.py
@ -45,6 +45,7 @@ class AppletsCCBDock(applets.AppletsDock):
        self.ccbp_group_action.setMenu(ccbp_group_menu)
        self.table.addAction(self.ccbp_group_action)
        self.table.itemSelectionChanged.connect(self.update_group_ccbp_menu)
        self.update_group_ccbp_menu()
        ccbp_global_menu = QtWidgets.QMenu()
        actiongroup = QtWidgets.QActionGroup(self.table)
--- a/artiq/dashboard/datasets.py
+++ b/artiq/dashboard/datasets.py
@ -3,8 +3,9 @@ import logging
 import numpy as np
 from PyQt5 import QtCore, QtWidgets
 from sipyco import pyon
-from artiq.tools import short_format
+from artiq.tools import scale_from_metadata, short_format, exc_to_warning
 from artiq.gui.tools import LayoutWidget, QRecursiveFilterProxyModel
 from artiq.gui.models import DictSyncTreeSepModel
 from artiq.gui.scientific_spinbox import ScientificSpinBox
@ -13,73 +14,152 @@ from artiq.gui.scientific_spinbox import ScientificSpinBox
 logger = logging.getLogger(__name__)
-class Editor(QtWidgets.QDialog):
+async def rename(key, new_key, value, metadata, persist, dataset_ctl):
-    def __init__(self, parent, dataset_ctl, key, value):
+    if key != new_key:
        await dataset_ctl.delete(key)
    await dataset_ctl.set(new_key, value, metadata=metadata, persist=persist)
 class CreateEditDialog(QtWidgets.QDialog):
    def __init__(self, parent, dataset_ctl, key=None, value=None, metadata=None, persist=False):
        QtWidgets.QDialog.__init__(self, parent=parent)
        self.dataset_ctl = dataset_ctl
        self.key = key
        self.initial_type = type(value)
-        self.setWindowTitle("Edit dataset")
+        self.setWindowTitle("Create dataset" if key is None else "Edit dataset")
        grid = QtWidgets.QGridLayout()
        grid.setRowMinimumHeight(1, 40)
        grid.setColumnMinimumWidth(2, 60)
        self.setLayout(grid)
        grid.addWidget(QtWidgets.QLabel("Name:"), 0, 0)
-        grid.addWidget(QtWidgets.QLabel(key), 0, 1)
+        self.name_widget = QtWidgets.QLineEdit()
        grid.addWidget(self.name_widget, 0, 1)
        grid.addWidget(QtWidgets.QLabel("Value:"), 1, 0)
-        grid.addWidget(self.get_edit_widget(value), 1, 1)
+        self.value_widget = QtWidgets.QLineEdit()
        self.value_widget.setPlaceholderText('PYON (Python)')
        grid.addWidget(self.value_widget, 1, 1)
        self.data_type = QtWidgets.QLabel("data type")
        grid.addWidget(self.data_type, 1, 2)
        self.value_widget.textChanged.connect(self.dtype)
-        buttons = QtWidgets.QDialogButtonBox(
+        grid.addWidget(QtWidgets.QLabel("Unit:"), 2, 0)
-            QtWidgets.QDialogButtonBox.Ok | QtWidgets.QDialogButtonBox.Cancel)
+        self.unit_widget = QtWidgets.QLineEdit()
-        grid.setRowStretch(2, 1)
+        grid.addWidget(self.unit_widget, 2, 1)
-        grid.addWidget(buttons, 3, 0, 1, 2)
+
-        buttons.accepted.connect(self.accept)
+        grid.addWidget(QtWidgets.QLabel("Scale:"), 3, 0)
-        buttons.rejected.connect(self.reject)
+        self.scale_widget = QtWidgets.QLineEdit()
        grid.addWidget(self.scale_widget, 3, 1)
        grid.addWidget(QtWidgets.QLabel("Precision:"), 4, 0)
        self.precision_widget = QtWidgets.QLineEdit()
        grid.addWidget(self.precision_widget, 4, 1)
        grid.addWidget(QtWidgets.QLabel("Persist:"), 5, 0)
        self.box_widget = QtWidgets.QCheckBox()
        grid.addWidget(self.box_widget, 5, 1)
        self.ok = QtWidgets.QPushButton('&Ok')
        self.ok.setEnabled(False)
        self.cancel = QtWidgets.QPushButton('&Cancel')
        self.buttons = QtWidgets.QDialogButtonBox(self)
        self.buttons.addButton(
            self.ok, QtWidgets.QDialogButtonBox.AcceptRole)
        self.buttons.addButton(
            self.cancel, QtWidgets.QDialogButtonBox.RejectRole)
        grid.setRowStretch(6, 1)
        grid.addWidget(self.buttons, 7, 0, 1, 3, alignment=QtCore.Qt.AlignHCenter)
        self.buttons.accepted.connect(self.accept)
        self.buttons.rejected.connect(self.reject)
        self.key = key
        self.name_widget.setText(key)
        value_edit_string = self.value_to_edit_string(value)
        if metadata is not None:
            scale = scale_from_metadata(metadata)
            t = value.dtype if value is np.ndarray else type(value)
            if scale != 1 and np.issubdtype(t, np.number):
                # degenerates to float type
                value_edit_string = self.value_to_edit_string(
                        np.float64(value / scale))
            self.unit_widget.setText(metadata.get('unit', ''))
            self.scale_widget.setText(str(metadata.get('scale', '')))
            self.precision_widget.setText(str(metadata.get('precision', '')))
        self.value_widget.setText(value_edit_string)
        self.box_widget.setChecked(persist)
    def accept(self):
-        value = self.initial_type(self.get_edit_widget_value())
+        key = self.name_widget.text()
-        asyncio.ensure_future(self.dataset_ctl.set(self.key, value))
+        value = self.value_widget.text()
        persist = self.box_widget.isChecked()
        unit = self.unit_widget.text()
        scale = self.scale_widget.text()
        precision = self.precision_widget.text()
        metadata = {}
        if unit != "":
            metadata['unit'] = unit
        if scale != "":
            metadata['scale'] = float(scale)
        if precision != "":
            metadata['precision'] = int(precision)
        scale = scale_from_metadata(metadata)
        value = self.parse_edit_string(value)
        t = value.dtype if value is np.ndarray else type(value)
        if scale != 1 and np.issubdtype(t, np.number):
            # degenerates to float type
            value = np.float64(value * scale)
        if self.key and self.key != key:
            asyncio.ensure_future(exc_to_warning(rename(self.key, key, value, metadata, persist, self.dataset_ctl)))
        else:
            asyncio.ensure_future(exc_to_warning(self.dataset_ctl.set(key, value, metadata=metadata, persist=persist)))
        self.key = key
        QtWidgets.QDialog.accept(self)
-    def get_edit_widget(self, initial_value):
+    def dtype(self):
-        raise NotImplementedError
+        txt = self.value_widget.text()
        try:
            result = self.parse_edit_string(txt)
            # ensure only pyon compatible types are permissable
            pyon.encode(result)
        except:
            pixmap = self.style().standardPixmap(
                QtWidgets.QStyle.SP_MessageBoxWarning)
            self.data_type.setPixmap(pixmap)
            self.ok.setEnabled(False)
        else:
            self.data_type.setText(type(result).__name__)
            self.ok.setEnabled(True)
-    def get_edit_widget_value(self):
+    @staticmethod
-        raise NotImplementedError
+    def parse_edit_string(s):
        if s == "":
            raise TypeError
        _eval_dict = {
            "__builtins__": {},
            "array": np.array,
            "null": np.nan,
            "inf": np.inf
        }
        for t_ in pyon._numpy_scalar:
            _eval_dict[t_] = eval("np.{}".format(t_), {"np": np})
        return eval(s, _eval_dict, {})
-
+    @staticmethod
-class NumberEditor(Editor):
+    def value_to_edit_string(v):
-    def get_edit_widget(self, initial_value):
+        t = type(v)
-        self.edit_widget = ScientificSpinBox()
+        r = ""
-        self.edit_widget.setDecimals(13)
+        if isinstance(v, np.generic):
-        self.edit_widget.setPrecision()
+            r += t.__name__
-        self.edit_widget.setRelativeStep()
+            r += "("
-        self.edit_widget.setValue(float(initial_value))
+            r += repr(v)
-        return self.edit_widget
+            r += ")"
-
+        elif v is None:
-    def get_edit_widget_value(self):
+            return r
-        return self.edit_widget.value()
+        else:
-
+            r += repr(v)
-
+        return r
 class BoolEditor(Editor):
    def get_edit_widget(self, initial_value):
        self.edit_widget = QtWidgets.QCheckBox()
        self.edit_widget.setChecked(bool(initial_value))
        return self.edit_widget
    def get_edit_widget_value(self):
        return self.edit_widget.isChecked()
 class StringEditor(Editor):
    def get_edit_widget(self, initial_value):
        self.edit_widget = QtWidgets.QLineEdit()
        self.edit_widget.setText(initial_value)
        return self.edit_widget
    def get_edit_widget_value(self):
        return self.edit_widget.text()
 class Model(DictSyncTreeSepModel):
@ -92,13 +172,13 @@ class Model(DictSyncTreeSepModel):
        if column == 1:
            return "Y" if v[0] else "N"
        elif column == 2:
-            return short_format(v[1])
+            return short_format(v[1], v[2])
        else:
            raise ValueError
 class DatasetsDock(QtWidgets.QDockWidget):
-    def __init__(self, datasets_sub, dataset_ctl):
+    def __init__(self, dataset_sub, dataset_ctl):
        QtWidgets.QDockWidget.__init__(self, "Datasets")
        self.setObjectName("Datasets")
        self.setFeatures(QtWidgets.QDockWidget.DockWidgetMovable |
@ -120,6 +200,11 @@ class DatasetsDock(QtWidgets.QDockWidget):
        grid.addWidget(self.table, 1, 0)
        self.table.setContextMenuPolicy(QtCore.Qt.ActionsContextMenu)
        create_action = QtWidgets.QAction("New dataset", self.table)
        create_action.triggered.connect(self.create_clicked)
        create_action.setShortcut("CTRL+N")
        create_action.setShortcutContext(QtCore.Qt.WidgetShortcut)
        self.table.addAction(create_action)
        edit_action = QtWidgets.QAction("Edit dataset", self.table)
        edit_action.triggered.connect(self.edit_clicked)
        edit_action.setShortcut("RETURN")
@ -133,7 +218,7 @@ class DatasetsDock(QtWidgets.QDockWidget):
        self.table.addAction(delete_action)
        self.table_model = Model(dict())
-        datasets_sub.add_setmodel_callback(self.set_model)
+        dataset_sub.add_setmodel_callback(self.set_model)
    def _search_datasets(self):
        if hasattr(self, "table_model_filter"):
@ -146,25 +231,17 @@ class DatasetsDock(QtWidgets.QDockWidget):
        self.table_model_filter.setSourceModel(self.table_model)
        self.table.setModel(self.table_model_filter)
    def create_clicked(self):
        CreateEditDialog(self, self.dataset_ctl).open()
    def edit_clicked(self):
        idx = self.table.selectedIndexes()
        if idx:
            idx = self.table_model_filter.mapToSource(idx[0])
            key = self.table_model.index_to_key(idx)
            if key is not None:
-                persist, value = self.table_model.backing_store[key]
+                persist, value, metadata = self.table_model.backing_store[key]
-                t = type(value)
+                CreateEditDialog(self, self.dataset_ctl, key, value, metadata, persist).open()
                if np.issubdtype(t, np.number):
                    dialog_cls = NumberEditor
                elif np.issubdtype(t, np.bool_):
                    dialog_cls = BoolEditor
                elif np.issubdtype(t, np.unicode_):
                    dialog_cls = StringEditor
                else:
                    logger.error("Cannot edit dataset %s: "
                                 "type %s is not supported", key, t)
                    return
                dialog_cls(self, self.dataset_ctl, key, value).open()
    def delete_clicked(self):
        idx = self.table.selectedIndexes()
--- a/artiq/dashboard/experiments.py
+++ b/artiq/dashboard/experiments.py
@ -11,7 +11,9 @@ from sipyco import pyon
 from artiq.gui.entries import procdesc_to_entry, ScanEntry
 from artiq.gui.fuzzy_select import FuzzySelectWidget
-from artiq.gui.tools import LayoutWidget, log_level_to_name, get_open_file_name
+from artiq.gui.tools import (LayoutWidget, WheelFilter, 
                             log_level_to_name, get_open_file_name)
 from artiq.tools import parse_devarg_override, unparse_devarg_override
 logger = logging.getLogger(__name__)
@ -23,15 +25,6 @@ logger = logging.getLogger(__name__)
 # 2. file:<class name>@<file name>
 class _WheelFilter(QtCore.QObject):
    def eventFilter(self, obj, event):
        if (event.type() == QtCore.QEvent.Wheel and
                event.modifiers() != QtCore.Qt.NoModifier):
            event.ignore()
            return True
        return False
 class _ArgumentEditor(QtWidgets.QTreeWidget):
    def __init__(self, manager, dock, expurl):
        self.manager = manager
@ -55,7 +48,7 @@ class _ArgumentEditor(QtWidgets.QTreeWidget):
        self.setStyleSheet("QTreeWidget {background: " +
                           self.palette().midlight().color().name() + " ;}")
-        self.viewport().installEventFilter(_WheelFilter(self.viewport()))
+        self.viewport().installEventFilter(WheelFilter(self.viewport(), True))
        self._groups = dict()
        self._arg_to_widgets = dict()
@ -159,12 +152,29 @@ class _ArgumentEditor(QtWidgets.QTreeWidget):
        self._groups[name] = group
        return group
    def update_argument(self, name, argument):
        widgets = self._arg_to_widgets[name]
        # Qt needs a setItemWidget() to handle layout correctly,
        # simply replacing the entry inside the LayoutWidget
        # results in a bug.
        widgets["entry"].deleteLater()
        widgets["entry"] = procdesc_to_entry(argument["desc"])(argument)
        widgets["disable_other_scans"].setVisible(
            isinstance(widgets["entry"], ScanEntry))
        widgets["fix_layout"].deleteLater()
        widgets["fix_layout"] = LayoutWidget()
        widgets["fix_layout"].addWidget(widgets["entry"])
        self.setItemWidget(widgets["widget_item"], 1, widgets["fix_layout"])
        self.updateGeometries()
    def _recompute_argument_clicked(self, name):
        asyncio.ensure_future(self._recompute_argument(name))
    async def _recompute_argument(self, name):
        try:
-            expdesc = await self.manager.compute_expdesc(self.expurl)
+            expdesc, _ = await self.manager.compute_expdesc(self.expurl)
        except:
            logger.error("Could not recompute argument '%s' of '%s'",
                         name, self.expurl, exc_info=True)
@ -175,22 +185,7 @@ class _ArgumentEditor(QtWidgets.QTreeWidget):
        state = procdesc_to_entry(procdesc).default_state(procdesc)
        argument["desc"] = procdesc
        argument["state"] = state
-
+        self.update_argument(name, argument)
        # Qt needs a setItemWidget() to handle layout correctly,
        # simply replacing the entry inside the LayoutWidget
        # results in a bug.
        widgets = self._arg_to_widgets[name]
        widgets["entry"].deleteLater()
        widgets["entry"] = procdesc_to_entry(procdesc)(argument)
        widgets["disable_other_scans"].setVisible(
            isinstance(widgets["entry"], ScanEntry))
        widgets["fix_layout"].deleteLater()
        widgets["fix_layout"] = LayoutWidget()
        widgets["fix_layout"].addWidget(widgets["entry"])
        self.setItemWidget(widgets["widget_item"], 1, widgets["fix_layout"])
        self.updateGeometries()
    def _disable_other_scans(self, current_name):
        for name, widgets in self._arg_to_widgets.items():
@ -216,6 +211,15 @@ class _ArgumentEditor(QtWidgets.QTreeWidget):
                pass
        self.verticalScrollBar().setValue(state["scroll"])
    # Hooks that allow user-supplied argument editors to react to imminent user
    # actions. Here, we always keep the manager-stored submission arguments
    # up-to-date, so no further action is required.
    def about_to_submit(self):
        pass
    def about_to_close(self):
        pass
 log_levels = ["DEBUG", "INFO", "WARNING", "ERROR", "CRITICAL"]
@ -241,7 +245,8 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
        self.manager = manager
        self.expurl = expurl
-        self.argeditor = _ArgumentEditor(self.manager, self, self.expurl)
+        editor_class = self.manager.get_argument_editor_class(expurl)
        self.argeditor = editor_class(self.manager, self, self.expurl)
        self.layout.addWidget(self.argeditor, 0, 0, 1, 5)
        self.layout.setRowStretch(0, 1)
@ -258,7 +263,7 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
            datetime.setDate(QtCore.QDate.currentDate())
        else:
            datetime.setDateTime(QtCore.QDateTime.fromMSecsSinceEpoch(
-                scheduling["due_date"]*1000))
+                int(scheduling["due_date"]*1000)))
        datetime_en.setChecked(scheduling["due_date"] is not None)
        def update_datetime(dt):
@ -301,7 +306,7 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
        flush = self.flush
        flush.setToolTip("Flush the pipeline (of current- and higher-priority "
                         "experiments) before starting the experiment")
-        self.layout.addWidget(flush, 2, 2, 1, 2)
+        self.layout.addWidget(flush, 2, 2)
        flush.setChecked(scheduling["flush"])
@ -309,6 +314,20 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
            scheduling["flush"] = bool(checked)
        flush.stateChanged.connect(update_flush)
        devarg_override = QtWidgets.QComboBox()
        devarg_override.setEditable(True)
        devarg_override.lineEdit().setPlaceholderText("Override device arguments")
        devarg_override.lineEdit().setClearButtonEnabled(True)
        devarg_override.insertItem(0, "core:analyze_at_run_end=True")
        self.layout.addWidget(devarg_override, 2, 3)
        devarg_override.setCurrentText(options["devarg_override"])
        def update_devarg_override(text):
            options["devarg_override"] = text
        devarg_override.editTextChanged.connect(update_devarg_override)
        self.devarg_override = devarg_override
        log_level = QtWidgets.QComboBox()
        log_level.addItems(log_levels)
        log_level.setCurrentIndex(1)
@ -329,6 +348,7 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
        if "repo_rev" in options:
            repo_rev = QtWidgets.QLineEdit()
            repo_rev.setPlaceholderText("current")
            repo_rev.setClearButtonEnabled(True)
            repo_rev_label = QtWidgets.QLabel("Revision:")
            repo_rev_label.setToolTip("Experiment repository revision "
                                      "(commit ID) to use")
@ -369,6 +389,7 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
        self.hdf5_load_directory = os.path.expanduser("~")
    def submit_clicked(self):
        self.argeditor.about_to_submit()
        try:
            self.manager.submit(self.expurl)
        except:
@ -391,7 +412,7 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
    async def _recompute_arguments_task(self, overrides=dict()):
        try:
-            expdesc = await self.manager.compute_expdesc(self.expurl)
+            expdesc, ui_name = await self.manager.compute_expdesc(self.expurl)
        except:
            logger.error("Could not recompute experiment description of '%s'",
                         self.expurl, exc_info=True)
@ -404,12 +425,13 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
                arginfo[k][0]["default"].insert(0, v)
            else:
                arginfo[k][0]["default"] = v
-        self.manager.initialize_submission_arguments(self.expurl, arginfo)
+        self.manager.initialize_submission_arguments(self.expurl, arginfo, ui_name)
        argeditor_state = self.argeditor.save_state()
        self.argeditor.deleteLater()
-        self.argeditor = _ArgumentEditor(self.manager, self, self.expurl)
+        editor_class = self.manager.get_argument_editor_class(self.expurl)
        self.argeditor = editor_class(self.manager, self, self.expurl)
        self.argeditor.restore_state(argeditor_state)
        self.layout.addWidget(self.argeditor, 0, 0, 1, 5)
@ -422,7 +444,7 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
    async def _recompute_sched_options_task(self):
        try:
-            expdesc = await self.manager.compute_expdesc(self.expurl)
+            expdesc, _ = await self.manager.compute_expdesc(self.expurl)
        except:
            logger.error("Could not recompute experiment description of '%s'",
                         self.expurl, exc_info=True)
@ -459,6 +481,9 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
            return
        try:
            if "devarg_override" in expid:
                self.devarg_override.setCurrentText(
                    unparse_devarg_override(expid["devarg_override"]))
            self.log_level.setCurrentIndex(log_levels.index(
                log_level_to_name(expid["log_level"])))
            if ("repo_rev" in expid and
@ -473,6 +498,7 @@ class _ExperimentDock(QtWidgets.QMdiSubWindow):
        await self._recompute_arguments_task(arguments)
    def closeEvent(self, event):
        self.argeditor.about_to_close()
        self.sigClosed.emit()
        QtWidgets.QMdiSubWindow.closeEvent(self, event)
@ -544,7 +570,13 @@ class _QuickOpenDialog(QtWidgets.QDialog):
 class ExperimentManager:
-    def __init__(self, main_window,
+    #: Global registry for custom argument editor classes, indexed by the experiment
    #: `argument_ui` string; can be populated by dashboard plugins such as ndscan.
    #: If no handler for a requested UI name is found, the default built-in argument
    #: editor will be used.
    argument_ui_classes = dict()
    def __init__(self, main_window, dataset_sub,
                 explist_sub, schedule_sub,
                 schedule_ctl, experiment_db_ctl):
        self.main_window = main_window
@ -555,7 +587,10 @@ class ExperimentManager:
        self.submission_scheduling = dict()
        self.submission_options = dict()
        self.submission_arguments = dict()
        self.argument_ui_names = dict()
        self.datasets = dict()
        dataset_sub.add_setmodel_callback(self.set_dataset_model)
        self.explist = dict()
        explist_sub.add_setmodel_callback(self.set_explist_model)
        self.schedule = dict()
@ -570,6 +605,9 @@ class ExperimentManager:
        quick_open_shortcut.setContext(QtCore.Qt.ApplicationShortcut)
        quick_open_shortcut.activated.connect(self.show_quick_open)
    def set_dataset_model(self, model):
        self.datasets = model
    def set_explist_model(self, model):
        self.explist = model.backing_store
@ -586,6 +624,17 @@ class ExperimentManager:
        else:
            raise ValueError("Malformed experiment URL")
    def get_argument_editor_class(self, expurl):
        ui_name = self.argument_ui_names.get(expurl, None)
        if not ui_name and expurl[:5] == "repo:":
            ui_name = self.explist.get(expurl[5:], {}).get("argument_ui", None)
        if ui_name:
            result = self.argument_ui_classes.get(ui_name, None)
            if result:
                return result
            logger.warning("Ignoring unknown argument UI '%s'", ui_name)
        return _ArgumentEditor
    def get_submission_scheduling(self, expurl):
        if expurl in self.submission_scheduling:
            return self.submission_scheduling[expurl]
@ -608,14 +657,15 @@ class ExperimentManager:
        else:
            # mutated by _ExperimentDock
            options = {
-                "log_level": logging.WARNING
+                "log_level": logging.WARNING,
                "devarg_override": ""
            }
            if expurl[:5] == "repo:":
                options["repo_rev"] = None
            self.submission_options[expurl] = options
            return options
-    def initialize_submission_arguments(self, expurl, arginfo):
+    def initialize_submission_arguments(self, expurl, arginfo, ui_name):
        arguments = OrderedDict()
        for name, (procdesc, group, tooltip) in arginfo.items():
            state = procdesc_to_entry(procdesc).default_state(procdesc)
@ -626,8 +676,23 @@ class ExperimentManager:
                "state": state,  # mutated by entries
            }
        self.submission_arguments[expurl] = arguments
        self.argument_ui_names[expurl] = ui_name
        return arguments
    def set_argument_value(self, expurl, name, value):
        try:
            argument = self.submission_arguments[expurl][name]
            if argument["desc"]["ty"] == "Scannable":
                ty = value["ty"]
                argument["state"]["selected"] = ty
                argument["state"][ty] = value
            else:
                argument["state"] = value
            if expurl in self.open_experiments.keys():
                self.open_experiments[expurl].argeditor.update_argument(name, argument)
        except:
            logger.warn("Failed to set value for argument \"{}\" in experiment: {}.".format(name, expurl), exc_info=1)
    def get_submission_arguments(self, expurl):
        if expurl in self.submission_arguments:
            return self.submission_arguments[expurl]
@ -635,9 +700,9 @@ class ExperimentManager:
            if expurl[:5] != "repo:":
                raise ValueError("Submission arguments must be preinitialized "
                                 "when not using repository")
-            arginfo = self.explist[expurl[5:]]["arginfo"]
+            class_desc = self.explist[expurl[5:]]
-            arguments = self.initialize_submission_arguments(expurl, arginfo)
+            return self.initialize_submission_arguments(expurl,
-            return arguments
+                class_desc["arginfo"], class_desc.get("argument_ui", None))
    def open_experiment(self, expurl):
        if expurl in self.open_experiments:
@ -688,7 +753,14 @@ class ExperimentManager:
            entry_cls = procdesc_to_entry(argument["desc"])
            argument_values[name] = entry_cls.state_to_value(argument["state"])
        try:
            devarg_override = parse_devarg_override(options["devarg_override"])
        except:
            logger.error("Failed to parse device argument overrides for %s", expurl)
            return
        expid = {
            "devarg_override": devarg_override,
            "log_level": options["log_level"],
            "file": file,
            "class_name": class_name,
@ -726,7 +798,7 @@ class ExperimentManager:
            else:
                repo_match = "repo_rev" not in expid
            if (repo_match and
-                    expid["file"] == file and
+                    ("file" in expid and expid["file"] == file) and
                    expid["class_name"] == class_name):
                rids.append(rid)
        asyncio.ensure_future(self._request_term_multiple(rids))
@ -739,13 +811,15 @@ class ExperimentManager:
            revision = None
        description = await self.experiment_db_ctl.examine(
            file, use_repository, revision)
-        return description[class_name]
+        class_desc = description[class_name]
        return class_desc, class_desc.get("argument_ui", None)
    async def open_file(self, file):
        description = await self.experiment_db_ctl.examine(file, False)
        for class_name, class_desc in description.items():
            expurl = "file:{}@{}".format(class_name, file)
-            self.initialize_submission_arguments(expurl, class_desc["arginfo"])
+            self.initialize_submission_arguments(expurl, class_desc["arginfo"],
                class_desc.get("argument_ui", None))
            if expurl in self.open_experiments:
                self.open_experiments[expurl].close()
            self.open_experiment(expurl)
@ -758,6 +832,7 @@ class ExperimentManager:
            "options": self.submission_options,
            "arguments": self.submission_arguments,
            "docks": self.dock_states,
            "argument_uis": self.argument_ui_names,
            "open_docks": set(self.open_experiments.keys())
        }
@ -768,6 +843,7 @@ class ExperimentManager:
        self.submission_scheduling = state["scheduling"]
        self.submission_options = state["options"]
        self.submission_arguments = state["arguments"]
        self.argument_ui_names = state.get("argument_uis", {})
        for expurl in state["open_docks"]:
            self.open_experiment(expurl)
--- a/artiq/dashboard/explorer.py
+++ b/artiq/dashboard/explorer.py
@ -159,7 +159,7 @@ class WaitingPanel(LayoutWidget):
 class ExplorerDock(QtWidgets.QDockWidget):
    def __init__(self, exp_manager, d_shortcuts,
                 explist_sub, explist_status_sub,
-                 schedule_ctl, experiment_db_ctl):
+                 schedule_ctl, experiment_db_ctl, device_db_ctl):
        QtWidgets.QDockWidget.__init__(self, "Explorer")
        self.setObjectName("Explorer")
        self.setFeatures(QtWidgets.QDockWidget.DockWidgetMovable |
@ -251,6 +251,12 @@ class ExplorerDock(QtWidgets.QDockWidget):
        scan_repository_action.triggered.connect(scan_repository)
        self.el.addAction(scan_repository_action)
        scan_ddb_action = QtWidgets.QAction("Scan device database", self.el)
        def scan_ddb():
            asyncio.ensure_future(device_db_ctl.scan())
        scan_ddb_action.triggered.connect(scan_ddb)
        self.el.addAction(scan_ddb_action)
        self.current_directory = ""
        open_file_action = QtWidgets.QAction("Open file outside repository",
                                             self.el)
--- a/artiq/dashboard/moninj.py
+++ b/artiq/dashboard/moninj.py
@ -1,5 +1,6 @@
 import asyncio
 import logging
 import textwrap
 from collections import namedtuple
 from PyQt5 import QtCore, QtWidgets, QtGui
@ -7,12 +8,27 @@ from PyQt5 import QtCore, QtWidgets, QtGui
 from sipyco.sync_struct import Subscriber
 from artiq.coredevice.comm_moninj import *
 from artiq.coredevice.ad9910 import (
    _AD9910_REG_PROFILE0, _AD9910_REG_PROFILE7, 
    _AD9910_REG_FTW, _AD9910_REG_CFR1
 )
 from artiq.coredevice.ad9912_reg import AD9912_POW1, AD9912_SER_CONF
 from artiq.gui.tools import LayoutWidget
 from artiq.gui.flowlayout import FlowLayout
 logger = logging.getLogger(__name__)
 class _CancellableLineEdit(QtWidgets.QLineEdit):
    def escapePressedConnect(self, cb):
        self.esc_cb = cb
    def keyPressEvent(self, event):
        key = event.key()
        if key == QtCore.Qt.Key_Escape:
            self.esc_cb(event)
        QtWidgets.QLineEdit.keyPressEvent(self, event)
 class _TTLWidget(QtWidgets.QFrame):
    def __init__(self, dm, channel, force_out, title):
@ -168,15 +184,172 @@ class _SimpleDisplayWidget(QtWidgets.QFrame):
        raise NotImplementedError
-class _DDSWidget(_SimpleDisplayWidget):
+class _DDSModel:
-    def __init__(self, dm, bus_channel, channel, title):
+    def __init__(self, dds_type, ref_clk, cpld=None, pll=1, clk_div=0):
        self.cpld = cpld
        self.cur_frequency = 0
        self.cur_reg = 0
        self.dds_type = dds_type
        self.is_urukul = dds_type in ["AD9910", "AD9912"]
        if dds_type == "AD9914":
            self.ftw_per_hz = 2**32 / ref_clk
        else:
            if dds_type == "AD9910":
                max_freq = 1 << 32
                clk_mult = [4, 1, 2, 4]
            elif dds_type == "AD9912":  # AD9912
                max_freq = 1 << 48
                clk_mult = [1, 1, 2, 4]
            else:
                raise NotImplementedError
            sysclk = ref_clk / clk_mult[clk_div] * pll
            self.ftw_per_hz = 1 / sysclk * max_freq
    def monitor_update(self, probe, value):
        if self.dds_type == "AD9912":
            value = value << 16
        self.cur_frequency = self._ftw_to_freq(value)
    def _ftw_to_freq(self, ftw):
        return ftw / self.ftw_per_hz
 class _DDSWidget(QtWidgets.QFrame):
    def __init__(self, dm, title, bus_channel=0, channel=0, dds_model=None):
        self.dm = dm
        self.bus_channel = bus_channel
        self.channel = channel
        self.dds_name = title
        self.cur_frequency = 0
-        _SimpleDisplayWidget.__init__(self, title)
+        self.dds_model = dds_model
        QtWidgets.QFrame.__init__(self)
        self.setFrameShape(QtWidgets.QFrame.Box)
        self.setFrameShadow(QtWidgets.QFrame.Raised)
        grid = QtWidgets.QGridLayout()
        grid.setContentsMargins(0, 0, 0, 0)
        grid.setHorizontalSpacing(0)
        grid.setVerticalSpacing(0)
        self.setLayout(grid)
        label = QtWidgets.QLabel(title)
        label.setAlignment(QtCore.Qt.AlignCenter)
        grid.addWidget(label, 1, 1)
        # FREQ DATA/EDIT FIELD
        self.data_stack = QtWidgets.QStackedWidget()
        # page 1: display data
        grid_disp = LayoutWidget()
        grid_disp.layout.setContentsMargins(0, 0, 0, 0)
        grid_disp.layout.setHorizontalSpacing(0)
        grid_disp.layout.setVerticalSpacing(0)
        self.value_label = QtWidgets.QLabel()
        self.value_label.setAlignment(QtCore.Qt.AlignCenter)
        grid_disp.addWidget(self.value_label, 0, 1, 1, 2)
        unit = QtWidgets.QLabel("MHz")
        unit.setAlignment(QtCore.Qt.AlignCenter)
        grid_disp.addWidget(unit, 0, 3, 1, 1)
        self.data_stack.addWidget(grid_disp)
        # page 2: edit data
        grid_edit = LayoutWidget()
        grid_edit.layout.setContentsMargins(0, 0, 0, 0)
        grid_edit.layout.setHorizontalSpacing(0)
        grid_edit.layout.setVerticalSpacing(0)
        self.value_edit = _CancellableLineEdit(self)
        self.value_edit.setAlignment(QtCore.Qt.AlignRight)
        grid_edit.addWidget(self.value_edit, 0, 1, 1, 2)
        unit = QtWidgets.QLabel("MHz")
        unit.setAlignment(QtCore.Qt.AlignCenter)
        grid_edit.addWidget(unit, 0, 3, 1, 1)
        self.data_stack.addWidget(grid_edit)
        grid.addWidget(self.data_stack, 2, 1)
        # BUTTONS
        self.button_stack = QtWidgets.QStackedWidget()
        # page 1: SET button
        set_grid = LayoutWidget()
        set_btn = QtWidgets.QToolButton()
        set_btn.setText("Set")
        set_btn.setToolTip("Set frequency")
        set_grid.addWidget(set_btn, 0, 1, 1, 1)
        # for urukuls also allow switching off RF
        if self.dds_model.is_urukul:
            off_btn = QtWidgets.QToolButton()
            off_btn.setText("Off")
            off_btn.setToolTip("Switch off the output")
            set_grid.addWidget(off_btn, 0, 2, 1, 1)
        self.button_stack.addWidget(set_grid)
        # page 2: apply/cancel buttons
        apply_grid = LayoutWidget()
        apply = QtWidgets.QToolButton()
        apply.setText("Apply")
        apply.setToolTip("Apply changes")
        apply_grid.addWidget(apply, 0, 1, 1, 1)
        cancel = QtWidgets.QToolButton()
        cancel.setText("Cancel")
        cancel.setToolTip("Cancel changes")
        apply_grid.addWidget(cancel, 0, 2, 1, 1)
        self.button_stack.addWidget(apply_grid)
        grid.addWidget(self.button_stack, 3, 1)
        grid.setRowStretch(1, 1)
        grid.setRowStretch(2, 1)
        grid.setRowStretch(3, 1)
        set_btn.clicked.connect(self.set_clicked)
        apply.clicked.connect(self.apply_changes)
        if self.dds_model.is_urukul:
            off_btn.clicked.connect(self.off_clicked)
            off_btn.setToolTip(textwrap.dedent(
                """Note: If TTL RTIO sw for the channel is switched high,
                this button will not disable the channel.
                Use the TTL override instead."""))
        self.value_edit.returnPressed.connect(lambda: self.apply_changes(None))
        self.value_edit.escapePressedConnect(self.cancel_changes)
        cancel.clicked.connect(self.cancel_changes)
        self.refresh_display()
    def set_clicked(self, set):
        self.data_stack.setCurrentIndex(1)
        self.button_stack.setCurrentIndex(1)
        self.value_edit.setText("{:.7f}"
                .format(self.cur_frequency/1e6))
        self.value_edit.setFocus()
        self.value_edit.selectAll()
    def off_clicked(self, set):
        self.dm.dds_channel_toggle(self.dds_name, self.dds_model, sw=False)
    def apply_changes(self, apply):
        self.data_stack.setCurrentIndex(0)
        self.button_stack.setCurrentIndex(0)
        frequency = float(self.value_edit.text())*1e6
        self.dm.dds_set_frequency(self.dds_name, self.dds_model, frequency)
    def cancel_changes(self, cancel):
        self.data_stack.setCurrentIndex(0)
        self.button_stack.setCurrentIndex(0)
    def refresh_display(self):
-        self.value.setText("<font size=\"4\">{:.7f}</font><font size=\"2\"> MHz</font>"
+        self.cur_frequency = self.dds_model.cur_frequency
        self.value_label.setText("<font size=\"4\">{:.7f}</font>"
                           .format(self.cur_frequency/1e6))
        self.value_edit.setText("{:.7f}"
                           .format(self.cur_frequency/1e6))
    def sort_key(self):
@ -202,19 +375,19 @@ _WidgetDesc = namedtuple("_WidgetDesc", "uid comment cls arguments")
 def setup_from_ddb(ddb):
-    core_addr = None
+    mi_addr = None
    mi_port = None
    dds_sysclk = None
    description = set()
    for k, v in ddb.items():
        comment = None
        if "comment" in v:
            comment = v["comment"]
        try:
-            if isinstance(v, dict) and v["type"] == "local":
+            if isinstance(v, dict):
-                if k == "core":
+                comment = v.get("comment")
-                    core_addr = v["arguments"]["host"]
+                if v["type"] == "local":
-                elif v["module"] == "artiq.coredevice.ttl":
+                    if v["module"] == "artiq.coredevice.ttl":
                        if "ttl_urukul" in k:
                            continue
                        channel = v["arguments"]["channel"]
                        force_out = v["class"] == "TTLOut"
                        widget = _WidgetDesc(k, comment, _TTLWidget, (channel, force_out, k))
@ -224,9 +397,26 @@ def setup_from_ddb(ddb):
                        bus_channel = v["arguments"]["bus_channel"]
                        channel = v["arguments"]["channel"]
                        dds_sysclk = v["arguments"]["sysclk"]
-                    widget = _WidgetDesc(k, comment, _DDSWidget, (bus_channel, channel, k))
+                        model = _DDSModel(v["class"], dds_sysclk)
                        widget = _WidgetDesc(k, comment, _DDSWidget, (k, bus_channel, channel, model))
                        description.add(widget)
-                elif (   (v["module"] == "artiq.coredevice.ad53xx" and v["class"] == "AD53XX")
+                    elif (v["module"] == "artiq.coredevice.ad9910"
                                and v["class"] == "AD9910") or \
                            (v["module"] == "artiq.coredevice.ad9912"
                                and v["class"] == "AD9912"):
                        channel = v["arguments"]["chip_select"] - 4
                        if channel < 0:
                            continue
                        dds_cpld = v["arguments"]["cpld_device"]
                        spi_dev = ddb[dds_cpld]["arguments"]["spi_device"]
                        bus_channel = ddb[spi_dev]["arguments"]["channel"]
                        pll = v["arguments"]["pll_n"]
                        refclk = ddb[dds_cpld]["arguments"]["refclk"]
                        clk_div = v["arguments"].get("clk_div", 0)
                        model = _DDSModel( v["class"], refclk, dds_cpld, pll, clk_div)
                        widget = _WidgetDesc(k, comment, _DDSWidget, (k, bus_channel, channel, model))
                        description.add(widget)       
                    elif (   (v["module"] == "artiq.coredevice.ad53xx" and v["class"] == "AD53xx")
                          or (v["module"] == "artiq.coredevice.zotino" and v["class"] == "Zotino")):
                        spi_device = v["arguments"]["spi_device"]
                        spi_device = ddb[spi_device]
@ -236,17 +426,23 @@ def setup_from_ddb(ddb):
                        for channel in range(32):
                            widget = _WidgetDesc((k, channel), comment, _DACWidget, (spi_channel, channel, k))
                            description.add(widget)
                elif v["type"] == "controller" and k == "core_moninj":
                    mi_addr = v["host"]
                    mi_port = v.get("port_proxy", 1383)
        except KeyError:
            pass
-    return core_addr, dds_sysclk, description
+    return mi_addr, mi_port, description
 class _DeviceManager:
-    def __init__(self):
+    def __init__(self, schedule_ctl):
-        self.core_addr = None
+        self.mi_addr = None
-        self.reconnect_core = asyncio.Event()
+        self.mi_port = None
-        self.core_connection = None
+        self.reconnect_mi = asyncio.Event()
-        self.core_connector_task = asyncio.ensure_future(self.core_connector())
+        self.mi_connection = None
        self.mi_connector_task = asyncio.ensure_future(self.mi_connector())
        self.schedule_ctl = schedule_ctl
        self.ddb = dict()
        self.description = set()
@ -265,13 +461,12 @@ class _DeviceManager:
        return ddb
    def notify(self, mod):
-        core_addr, dds_sysclk, description = setup_from_ddb(self.ddb)
+        mi_addr, mi_port, description = setup_from_ddb(self.ddb)
-        if core_addr != self.core_addr:
+        if (mi_addr, mi_port) != (self.mi_addr, self.mi_port):
-            self.core_addr = core_addr
+            self.mi_addr = mi_addr
-            self.reconnect_core.set()
+            self.mi_port = mi_port
-
+            self.reconnect_mi.set()
        self.dds_sysclk = dds_sysclk
        for to_remove in self.description - description:
            widget = self.widgets_by_uid[to_remove.uid]
@ -319,44 +514,172 @@ class _DeviceManager:
        self.description = description
    def ttl_set_mode(self, channel, mode):
-        if self.core_connection is not None:
+        if self.mi_connection is not None:
            widget = self.ttl_widgets[channel]
            if mode == "0":
                widget.cur_override = True
                widget.cur_level = False
-                self.core_connection.inject(channel, TTLOverride.level.value, 0)
+                self.mi_connection.inject(channel, TTLOverride.level.value, 0)
-                self.core_connection.inject(channel, TTLOverride.oe.value, 1)
+                self.mi_connection.inject(channel, TTLOverride.oe.value, 1)
-                self.core_connection.inject(channel, TTLOverride.en.value, 1)
+                self.mi_connection.inject(channel, TTLOverride.en.value, 1)
            elif mode == "1":
                widget.cur_override = True
                widget.cur_level = True
-                self.core_connection.inject(channel, TTLOverride.level.value, 1)
+                self.mi_connection.inject(channel, TTLOverride.level.value, 1)
-                self.core_connection.inject(channel, TTLOverride.oe.value, 1)
+                self.mi_connection.inject(channel, TTLOverride.oe.value, 1)
-                self.core_connection.inject(channel, TTLOverride.en.value, 1)
+                self.mi_connection.inject(channel, TTLOverride.en.value, 1)
            elif mode == "exp":
                widget.cur_override = False
-                self.core_connection.inject(channel, TTLOverride.en.value, 0)
+                self.mi_connection.inject(channel, TTLOverride.en.value, 0)
            else:
                raise ValueError
            # override state may have changed
            widget.refresh_display()
    async def _submit_by_content(self, content, class_name, title):
        expid = {
            "log_level": logging.WARNING,
            "content": content,
            "class_name": class_name,
            "arguments": {}
        }
        scheduling = {
            "pipeline_name": "main",
            "priority": 0,
            "due_date": None,
            "flush": False
        }
        rid = await self.schedule_ctl.submit(
            scheduling["pipeline_name"],
            expid,
            scheduling["priority"], scheduling["due_date"],
            scheduling["flush"])
        logger.info("Submitted '%s', RID is %d", title, rid)
    def _dds_faux_injection(self, dds_channel, dds_model, action, title, log_msg):
        # create kernel and fill it in and send-by-content
        # initialize CPLD (if applicable)
        if dds_model.is_urukul:
            # urukuls need CPLD init and switch to on
            cpld_dev = """self.setattr_device("core_cache")
                self.setattr_device("{}")""".format(dds_model.cpld)
            # `sta`/`rf_sw`` variables are guaranteed for urukuls 
            # so {action} can use it
            # if there's no RF enabled, CPLD may have not been initialized
            # but if there is, it has been initialised - no need to do again
            cpld_init = """delay(15*ms)
                was_init = self.core_cache.get("_{cpld}_init")
                sta = self.{cpld}.sta_read()
                rf_sw = urukul_sta_rf_sw(sta)
                if rf_sw == 0 and len(was_init) == 0:
                    delay(15*ms)
                    self.{cpld}.init()
                    self.core_cache.put("_{cpld}_init", [1])
            """.format(cpld=dds_model.cpld)
        else:
            cpld_dev = ""
            cpld_init = ""
        # AD9912/9910: init channel (if uninitialized)
        if dds_model.dds_type == "AD9912":
            # 0xFF before init, 0x99 after
            channel_init = """
                if self.{dds_channel}.read({cfgreg}, length=1) == 0xFF:
                    delay(10*ms)
                    self.{dds_channel}.init()
            """.format(dds_channel=dds_channel, cfgreg=AD9912_SER_CONF)
        elif dds_model.dds_type == "AD9910":
            # -1 before init, 2 after
            channel_init = """
                if self.{dds_channel}.read32({cfgreg}) == -1:
                    delay(10*ms)
                    self.{dds_channel}.init()
            """.format(dds_channel=dds_channel, cfgreg=AD9912_SER_CONF)
        else:
            channel_init = "self.{dds_channel}.init()".format(dds_channel=dds_channel)
        dds_exp = textwrap.dedent("""
        from artiq.experiment import *
        from artiq.coredevice.urukul import *
        class {title}(EnvExperiment):
            def build(self):
                self.setattr_device("core")
                self.setattr_device("{dds_channel}")
                {cpld_dev}
            @kernel
            def run(self):
                self.core.break_realtime()
                {cpld_init}
                delay(10*ms)
                {channel_init}
                delay(15*ms)
                {action}
        """.format(title=title, action=action,
                   dds_channel=dds_channel,
                   cpld_dev=cpld_dev, cpld_init=cpld_init,
                   channel_init=channel_init))
        asyncio.ensure_future(
            self._submit_by_content(
                dds_exp, 
                title, 
                log_msg))
    def dds_set_frequency(self, dds_channel, dds_model, freq):
        action = "self.{ch}.set({freq})".format(
            freq=freq, ch=dds_channel)
        if dds_model.is_urukul:
            action += """
                ch_no = self.{ch}.chip_select - 4
                self.{cpld}.cfg_switches(rf_sw | 1 << ch_no)
            """.format(ch=dds_channel, cpld=dds_model.cpld)
        self._dds_faux_injection(
            dds_channel,
            dds_model,
            action,
            "SetDDS", 
            "Set DDS {} {}MHz".format(dds_channel, freq/1e6))
    def dds_channel_toggle(self, dds_channel, dds_model, sw=True):
        # urukul only
        if sw:
            switch = "| 1 << ch_no"
        else:
            switch = "& ~(1 << ch_no)"
        action = """
                ch_no = self.{dds_channel}.chip_select - 4
                self.{cpld}.cfg_switches(rf_sw {switch})
        """.format(
            dds_channel=dds_channel,
            cpld=dds_model.cpld,
            switch=switch
        )
        self._dds_faux_injection(
            dds_channel,
            dds_model,
            action,
            "ToggleDDS", 
            "Toggle DDS {} {}".format(dds_channel, "on" if sw else "off"))
    def setup_ttl_monitoring(self, enable, channel):
-        if self.core_connection is not None:
+        if self.mi_connection is not None:
-            self.core_connection.monitor_probe(enable, channel, TTLProbe.level.value)
+            self.mi_connection.monitor_probe(enable, channel, TTLProbe.level.value)
-            self.core_connection.monitor_probe(enable, channel, TTLProbe.oe.value)
+            self.mi_connection.monitor_probe(enable, channel, TTLProbe.oe.value)
-            self.core_connection.monitor_injection(enable, channel, TTLOverride.en.value)
+            self.mi_connection.monitor_injection(enable, channel, TTLOverride.en.value)
-            self.core_connection.monitor_injection(enable, channel, TTLOverride.level.value)
+            self.mi_connection.monitor_injection(enable, channel, TTLOverride.level.value)
            if enable:
-                self.core_connection.get_injection_status(channel, TTLOverride.en.value)
+                self.mi_connection.get_injection_status(channel, TTLOverride.en.value)
    def setup_dds_monitoring(self, enable, bus_channel, channel):
-        if self.core_connection is not None:
+        if self.mi_connection is not None:
-            self.core_connection.monitor_probe(enable, bus_channel, channel)
+            self.mi_connection.monitor_probe(enable, bus_channel, channel)
    def setup_dac_monitoring(self, enable, spi_channel, channel):
-        if self.core_connection is not None:
+        if self.mi_connection is not None:
-            self.core_connection.monitor_probe(enable, spi_channel, channel)
+            self.mi_connection.monitor_probe(enable, spi_channel, channel)
    def monitor_cb(self, channel, probe, value):
        if channel in self.ttl_widgets:
@ -366,11 +689,11 @@ class _DeviceManager:
            elif probe == TTLProbe.oe.value:
                widget.cur_oe = bool(value)
            widget.refresh_display()
-        if (channel, probe) in self.dds_widgets:
+        elif (channel, probe) in self.dds_widgets:
            widget = self.dds_widgets[(channel, probe)]
-            widget.cur_frequency = value*self.dds_sysclk/2**32
+            widget.dds_model.monitor_update(probe, value)
            widget.refresh_display()
-        if (channel, probe) in self.dac_widgets:
+        elif (channel, probe) in self.dac_widgets:
            widget = self.dac_widgets[(channel, probe)]
            widget.cur_value = value
            widget.refresh_display()
@ -385,29 +708,31 @@ class _DeviceManager:
            widget.refresh_display()
    def disconnect_cb(self):
-        logger.error("lost connection to core device moninj")
+        logger.error("lost connection to moninj")
-        self.reconnect_core.set()
+        self.reconnect_mi.set()
-    async def core_connector(self):
+    async def mi_connector(self):
        while True:
-            await self.reconnect_core.wait()
+            await self.reconnect_mi.wait()
-            self.reconnect_core.clear()
+            self.reconnect_mi.clear()
-            if self.core_connection is not None:
+            if self.mi_connection is not None:
-                await self.core_connection.close()
+                await self.mi_connection.close()
-                self.core_connection = None
+                self.mi_connection = None
-            new_core_connection = CommMonInj(self.monitor_cb, self.injection_status_cb,
+            new_mi_connection = CommMonInj(self.monitor_cb, self.injection_status_cb,
                    self.disconnect_cb)
            try:
-                await new_core_connection.connect(self.core_addr, 1383)
+                await new_mi_connection.connect(self.mi_addr, self.mi_port)
            except asyncio.CancelledError:
-                logger.info("cancelled connection to core device moninj")
+                logger.info("cancelled connection to moninj")
                break
            except:
-                logger.error("failed to connect to core device moninj", exc_info=True)
+                logger.error("failed to connect to moninj. Is aqctl_moninj_proxy running?", exc_info=True)
                await asyncio.sleep(10.)
-                self.reconnect_core.set()
+                self.reconnect_mi.set()
            else:
-                self.core_connection = new_core_connection
+                logger.info("ARTIQ dashboard connected to moninj (%s)",
                            self.mi_addr)
                self.mi_connection = new_mi_connection
                for ttl_channel in self.ttl_widgets.keys():
                    self.setup_ttl_monitoring(True, ttl_channel)
                for bus_channel, channel in self.dds_widgets.keys():
@ -416,13 +741,13 @@ class _DeviceManager:
                    self.setup_dac_monitoring(True, spi_channel, channel)
    async def close(self):
-        self.core_connector_task.cancel()
+        self.mi_connector_task.cancel()
        try:
-            await asyncio.wait_for(self.core_connector_task, None)
+            await asyncio.wait_for(self.mi_connector_task, None)
        except asyncio.CancelledError:
            pass
-        if self.core_connection is not None:
+        if self.mi_connection is not None:
-            await self.core_connection.close()
+            await self.mi_connection.close()
 class _MonInjDock(QtWidgets.QDockWidget):
@ -448,12 +773,12 @@ class _MonInjDock(QtWidgets.QDockWidget):
 class MonInj:
-    def __init__(self):
+    def __init__(self, schedule_ctl):
        self.ttl_dock = _MonInjDock("TTL")
        self.dds_dock = _MonInjDock("DDS")
        self.dac_dock = _MonInjDock("DAC")
-        self.dm = _DeviceManager()
+        self.dm = _DeviceManager(schedule_ctl)
        self.dm.ttl_cb = lambda: self.ttl_dock.layout_widgets(
                            self.dm.ttl_widgets.values())
        self.dm.dds_cb = lambda: self.dds_dock.layout_widgets(
--- a/artiq/dashboard/schedule.py
+++ b/artiq/dashboard/schedule.py
@ -48,7 +48,7 @@ class Model(DictSyncModel):
            else:
                return "Outside repo."
        elif column == 6:
-            return v["expid"]["file"]
+            return v["expid"].get("file", "<none>")
        elif column == 7:
            if v["expid"]["class_name"] is None:
                return ""
--- a/artiq/examples/kasli/device_db.py
+++ b/artiq/examples/kasli/device_db.py
@ -7,7 +7,11 @@ device_db = {
        "type": "local",
        "module": "artiq.coredevice.core",
        "class": "Core",
-        "arguments": {"host": core_addr, "ref_period": 1e-9}
+        "arguments": {
            "host": core_addr,
            "ref_period": 1e-9,
            "analyzer_proxy": "core_analyzer"
        }
    },
    "core_log": {
        "type": "controller",
@ -15,6 +19,20 @@ device_db = {
        "port": 1068,
        "command": "aqctl_corelog -p {port} --bind {bind} " + core_addr
    },
    "core_moninj": {
        "type": "controller",
        "host": "::1",
        "port_proxy": 1383,
        "port": 1384,
        "command": "aqctl_moninj_proxy --port-proxy {port_proxy} --port-control {port} --bind {bind} " + core_addr
    },
    "core_analyzer": {
        "type": "controller",
        "host": "::1",
        "port_proxy": 1385,
        "port": 1386,
        "command": "aqctl_coreanalyzer_proxy --port-proxy {port_proxy} --port-control {port} --bind {bind} " + core_addr
    },
    "core_cache": {
        "type": "local",
        "module": "artiq.coredevice.cache",
@ -29,13 +47,13 @@ device_db = {
    "i2c_switch0": {
        "type": "local",
        "module": "artiq.coredevice.i2c",
-        "class": "PCA9548",
+        "class": "I2CSwitch",
        "arguments": {"address": 0xe0}
    },
    "i2c_switch1": {
        "type": "local",
        "module": "artiq.coredevice.i2c",
-        "class": "PCA9548",
+        "class": "I2CSwitch",
        "arguments": {"address": 0xe2}
    },
 }
--- a/artiq/examples/kasli_drtioswitching/device_db.py
+++ b/artiq/examples/kasli_drtioswitching/device_db.py
@ -5,7 +5,11 @@ device_db = {
        "type": "local",
        "module": "artiq.coredevice.core",
        "class": "Core",
-        "arguments": {"host": core_addr, "ref_period": 1/(8*150e6)}
+        "arguments": {
            "host": core_addr,
            "ref_period": 1e-9,
            "analyzer_proxy": "core_analyzer"
        }
    },
    "core_log": {
        "type": "controller",
@ -13,6 +17,20 @@ device_db = {
        "port": 1068,
        "command": "aqctl_corelog -p {port} --bind {bind} " + core_addr
    },
    "core_moninj": {
        "type": "controller",
        "host": "::1",
        "port_proxy": 1383,
        "port": 1384,
        "command": "aqctl_moninj_proxy --port-proxy {port_proxy} --port-control {port} --bind {bind} " + core_addr
    },
    "core_analyzer": {
        "type": "controller",
        "host": "::1",
        "port_proxy": 1385,
        "port": 1386,
        "command": "aqctl_coreanalyzer_proxy --port-proxy {port_proxy} --port-control {port} --bind {bind} " + core_addr
    },
    "core_cache": {
        "type": "local",
        "module": "artiq.coredevice.cache",
--- a/artiq/examples/kasli_sawgmaster/device_db.py
+++ b/artiq/examples/kasli_sawgmaster/device_db.py
@ -1,177 +0,0 @@
 core_addr = "192.168.1.70"
 device_db = {
    "core": {
        "type": "local",
        "module": "artiq.coredevice.core",
        "class": "Core",
        "arguments": {"host": core_addr, "ref_period": 1/(8*150e6)}
    },
    "core_log": {
        "type": "controller",
        "host": "::1",
        "port": 1068,
        "command": "aqctl_corelog -p {port} --bind {bind} " + core_addr
    },
    "core_cache": {
        "type": "local",
        "module": "artiq.coredevice.cache",
        "class": "CoreCache"
    },
    "core_dma": {
        "type": "local",
        "module": "artiq.coredevice.dma",
        "class": "CoreDMA"
    },
 }
 device_db.update(
    spi_urukul0={
        "type": "local",
        "module": "artiq.coredevice.spi2",
        "class": "SPIMaster",
        "arguments": {"channel": 0}
    },
    ttl_urukul0_io_update={
        "type": "local",
        "module": "artiq.coredevice.ttl",
        "class": "TTLOut",
        "arguments": {"channel": 1}
    },
    ttl_urukul0_sw0={
        "type": "local",
        "module": "artiq.coredevice.ttl",
        "class": "TTLOut",
        "arguments": {"channel": 2}
    },
    ttl_urukul0_sw1={
        "type": "local",
        "module": "artiq.coredevice.ttl",
        "class": "TTLOut",
        "arguments": {"channel": 3}
    },
    ttl_urukul0_sw2={
        "type": "local",
        "module": "artiq.coredevice.ttl",
        "class": "TTLOut",
        "arguments": {"channel": 4}
    },
    ttl_urukul0_sw3={
        "type": "local",
        "module": "artiq.coredevice.ttl",
        "class": "TTLOut",
        "arguments": {"channel": 5}
    },
    urukul0_cpld={
        "type": "local",
        "module": "artiq.coredevice.urukul",
        "class": "CPLD",
        "arguments": {
            "spi_device": "spi_urukul0",
            "io_update_device": "ttl_urukul0_io_update",
            "refclk": 150e6,
            "clk_sel": 2
        }
    }
 )
 for i in range(4):
    device_db["urukul0_ch" + str(i)] = {
        "type": "local",
        "module": "artiq.coredevice.ad9910",
        "class": "AD9910",
        "arguments": {
            "pll_n": 16,  # 600MHz sample rate
            "pll_vco": 2,
            "chip_select": 4 + i,
            "cpld_device": "urukul0_cpld",
            "sw_device": "ttl_urukul0_sw" + str(i)
        }
    }
 """
 artiq_route routing.bin init
 artiq_route routing.bin set 0 0
 artiq_route routing.bin set 1 1 0
 artiq_route routing.bin set 2 1 1 0
 artiq_route routing.bin set 3 2 0
 artiq_route routing.bin set 4 2 1 0
 artiq_coremgmt -D kasli config write -f routing_table routing.bin
 """
 for sayma in range(2):
    amc_base = 0x010000 + sayma*0x020000
    rtm_base = 0x020000 + sayma*0x020000
    for i in range(4):
        device_db["led" + str(4*sayma+i)] = {
            "type": "local",
            "module": "artiq.coredevice.ttl",
            "class": "TTLOut",
            "arguments": {"channel": amc_base + i}
        }
    for i in range(2):
        device_db["ttl_mcx" + str(2*sayma+i)] = {
            "type": "local",
            "module": "artiq.coredevice.ttl",
            "class": "TTLInOut",
            "arguments": {"channel": amc_base + 4 + i}
        }
    for i in range(8):
        device_db["sawg" + str(8*sayma+i)] = {
            "type": "local",
            "module": "artiq.coredevice.sawg",
            "class": "SAWG",
            "arguments": {"channel_base": amc_base + 6 + i*10, "parallelism": 4}
        }
    for basemod in range(2):
        for i in range(4):
            device_db["sawg_sw" + str(8*sayma+4*basemod+i)] = {
                "type": "local",
                "module": "artiq.coredevice.ttl",
                "class": "TTLOut",
                "arguments": {"channel": rtm_base + basemod*9 + i}
            }
        att_idx = 2*sayma + basemod
        device_db["basemod_att_rst_n"+str(att_idx)] = {
            "type": "local",
            "module": "artiq.coredevice.ttl",
            "class": "TTLOut",
            "arguments": {"channel": rtm_base + basemod*9 + 4}
        }
        device_db["basemod_att_clk"+str(att_idx)] = {
            "type": "local",
            "module": "artiq.coredevice.ttl",
            "class": "TTLOut",
            "arguments": {"channel": rtm_base + basemod*9 + 5}
        }
        device_db["basemod_att_le"+str(att_idx)] = {
            "type": "local",
            "module": "artiq.coredevice.ttl",
            "class": "TTLOut",
            "arguments": {"channel": rtm_base + basemod*9 + 6}
        }
        device_db["basemod_att_mosi"+str(att_idx)] = {
            "type": "local",
            "module": "artiq.coredevice.ttl",
            "class": "TTLOut",
            "arguments": {"channel": rtm_base + basemod*9 + 7}
        }
        device_db["basemod_att_miso"+str(att_idx)] = {
            "type": "local",
            "module": "artiq.coredevice.ttl",
            "class": "TTLInOut",
            "arguments": {"channel": rtm_base + basemod*9 + 8}
        }
        device_db["basemod_att"+str(att_idx)] = {
            "type": "local",
            "module": "artiq.coredevice.basemod_att",
            "class": "BaseModAtt",
            "arguments": {
                "rst_n": "basemod_att_rst_n"+str(att_idx),
                "clk": "basemod_att_clk"+str(att_idx),
                "le": "basemod_att_le"+str(att_idx),
                "mosi": "basemod_att_mosi"+str(att_idx),
                "miso": "basemod_att_miso"+str(att_idx),
            }
        }
--- a/artiq/examples/kasli_sawgmaster/repository/basemod.py
+++ b/artiq/examples/kasli_sawgmaster/repository/basemod.py
@ -1,25 +0,0 @@
 from artiq.experiment import *
 class BaseMod(EnvExperiment):
    def build(self):
        self.setattr_device("core")
        self.basemods = [self.get_device("basemod_att0"), self.get_device("basemod_att1")]
        self.rfsws = [self.get_device("sawg_sw"+str(i)) for i in range(8)]
    @kernel
    def run(self):
        self.core.reset()
        for basemod in self.basemods:
            self.core.break_realtime()
            delay(10*ms)
            basemod.reset()
            delay(10*ms)
            basemod.set(0.0, 0.0, 0.0, 0.0)
            delay(10*ms)
            print(basemod.get_mu())
        self.core.break_realtime()
        for rfsw in self.rfsws:
            rfsw.on()
            delay(1*ms)
--- a/artiq/examples/kasli_sawgmaster/repository/sines_2sayma.py
+++ b/artiq/examples/kasli_sawgmaster/repository/sines_2sayma.py
@ -1,37 +0,0 @@
 from artiq.experiment import *
 class Sines2Sayma(EnvExperiment):
    def build(self):
        self.setattr_device("core")
        self.sawgs = [self.get_device("sawg"+str(i)) for i in range(16)]
    @kernel
    def drtio_is_up(self):
        for i in range(5):
            if not self.core.get_rtio_destination_status(i):
                return False
        return True
    @kernel
    def run(self):
        while True:
            print("waiting for DRTIO ready...")
            while not self.drtio_is_up():
                pass
            print("OK")
            self.core.reset()
            for sawg in self.sawgs:
                delay(1*ms)
                sawg.reset()
            for sawg in self.sawgs:
                delay(1*ms)
                sawg.amplitude1.set(.4)
                # Do not use a sub-multiple of oscilloscope sample rates.
                sawg.frequency0.set(9*MHz)
            while self.drtio_is_up():
                pass
--- a/artiq/examples/kasli_sawgmaster/repository/sines_urukul_sayma.py
+++ b/artiq/examples/kasli_sawgmaster/repository/sines_urukul_sayma.py
@ -1,89 +0,0 @@
 from artiq.experiment import *
 class SinesUrukulSayma(EnvExperiment):
    def build(self):
        self.setattr_device("core")
        self.setattr_device("urukul0_cpld")
        # Urukul clock output syntonized to the RTIO clock.
        # Can be used as HMC830 reference on Sayma RTM.
        # When using this reference, Sayma must be recalibrated every time Urukul
        # is rebooted, as Urukul is not synchronized to the Kasli.
        self.urukul_hmc_ref = self.get_device("urukul0_ch3")
        # Urukul measurement channels - compare with SAWG outputs.
        # When testing sync, do not reboot Urukul, as it is not
        # synchronized to the Kasli.
        self.urukul_meas = [self.get_device("urukul0_ch" + str(i)) for i in range(3)]
        # The same waveform is output on all first 4 SAWG channels (first DAC).
        self.sawgs = [self.get_device("sawg"+str(i)) for i in range(4)]
        self.basemod = self.get_device("basemod_att0")
        self.rfsws = [self.get_device("sawg_sw"+str(i)) for i in range(4)]
    # DRTIO destinations:
    # 0: local
    # 1: Sayma AMC
    # 2: Sayma RTM
    @kernel
    def drtio_is_up(self):
        for i in range(3):
            if not self.core.get_rtio_destination_status(i):
                return False
        return True
    @kernel
    def run(self):
        f = 9*MHz
        dds_ftw = self.urukul_meas[0].frequency_to_ftw(f)
        sawg_ftw = self.sawgs[0].frequency0.to_mu(f)
        if dds_ftw != sawg_ftw:
            print("DDS and SAWG FTWs do not match:", dds_ftw, sawg_ftw)
            return
        self.core.reset()
        self.urukul0_cpld.init()
        delay(1*ms)
        self.urukul_hmc_ref.init()
        self.urukul_hmc_ref.set_mu(0x40000000, asf=self.urukul_hmc_ref.amplitude_to_asf(0.6))
        self.urukul_hmc_ref.set_att(6.)
        self.urukul_hmc_ref.sw.on()
        for urukul_ch in self.urukul_meas:
            delay(1*ms)
            urukul_ch.init()
            urukul_ch.set_mu(dds_ftw, asf=urukul_ch.amplitude_to_asf(0.5))
            urukul_ch.set_att(6.)
            urukul_ch.sw.on()
        while True:
            print("waiting for DRTIO ready...")
            while not self.drtio_is_up():
                pass
            print("OK")
            self.core.reset()
            delay(10*ms)
            self.basemod.reset()
            delay(10*ms)
            self.basemod.set(3.0, 3.0, 3.0, 3.0)
            delay(10*ms)
            for rfsw in self.rfsws:
                delay(1*ms)
                rfsw.on()
            for sawg in self.sawgs:
                delay(1*ms)
                sawg.reset()
            for sawg in self.sawgs:
                delay(1*ms)
                sawg.amplitude1.set(.4)
                sawg.frequency0.set_mu(sawg_ftw)
                sawg.phase0.set_mu(sawg_ftw*now_mu() >> 17)
            while self.drtio_is_up():
                pass
--- a/artiq/examples/kasli_shuttler/kasli_shuttler.json
+++ b/artiq/examples/kasli_shuttler/kasli_shuttler.json
@ -0,0 +1,18 @@
 {
    "target": "kasli",
    "variant": "shuttlerdemo",
    "hw_rev": "v2.0",
    "drtio_role": "master",
    "peripherals": [
        {
            "type": "shuttler",
            "ports": [0]
        },
        {
            "type": "dio",
            "ports": [1],
            "bank_direction_low": "input",
            "bank_direction_high": "output"
        }
    ]
 }   
--- a/artiq/examples/kasli_shuttler/repository/shuttler.py
+++ b/artiq/examples/kasli_shuttler/repository/shuttler.py
@ -0,0 +1,330 @@
 from artiq.experiment import *
 from artiq.coredevice.shuttler import shuttler_volt_to_mu
 DAC_Fs_MHZ = 125
 CORDIC_GAIN = 1.64676
@portable
 def shuttler_phase_offset(offset_degree):
    return round(offset_degree / 360 * (2 ** 16))
@portable
 def shuttler_freq_mu(freq_mhz):
    return round(float(2) ** 32 / DAC_Fs_MHZ * freq_mhz)
@portable
 def shuttler_chirp_rate_mu(freq_mhz_per_us):
    return round(float(2) ** 32 * freq_mhz_per_us / (DAC_Fs_MHZ ** 2))
@portable
 def shuttler_freq_sweep(start_f_MHz, end_f_MHz, time_us):
    return shuttler_chirp_rate_mu((end_f_MHz - start_f_MHz)/(time_us))
@portable
 def shuttler_volt_amp_mu(volt):
    return shuttler_volt_to_mu(volt)
@portable
 def shuttler_volt_damp_mu(volt_per_us):
    return round(float(2) ** 32 * (volt_per_us / 20) / DAC_Fs_MHZ)
@portable
 def shuttler_volt_ddamp_mu(volt_per_us_square):
    return round(float(2) ** 48 * (volt_per_us_square / 20) * 2 / (DAC_Fs_MHZ ** 2))
@portable
 def shuttler_volt_dddamp_mu(volt_per_us_cube):
    return round(float(2) ** 48 * (volt_per_us_cube / 20) * 6 / (DAC_Fs_MHZ ** 3))
@portable
 def shuttler_dds_amp_mu(volt):
    return shuttler_volt_amp_mu(volt / CORDIC_GAIN)
@portable
 def shuttler_dds_damp_mu(volt_per_us):
    return shuttler_volt_damp_mu(volt_per_us / CORDIC_GAIN)
@portable
 def shuttler_dds_ddamp_mu(volt_per_us_square):
    return shuttler_volt_ddamp_mu(volt_per_us_square / CORDIC_GAIN)
@portable
 def shuttler_dds_dddamp_mu(volt_per_us_cube):
    return shuttler_volt_dddamp_mu(volt_per_us_cube / CORDIC_GAIN)
 class Shuttler(EnvExperiment):
    def build(self):
        self.setattr_device("core")
        self.setattr_device("core_dma")
        self.setattr_device("scheduler")
        self.shuttler0_leds = [ self.get_device("shuttler0_led{}".format(i)) for i in range(2) ]
        self.setattr_device("shuttler0_config")
        self.setattr_device("shuttler0_trigger")
        self.shuttler0_dcbias = [ self.get_device("shuttler0_dcbias{}".format(i)) for i in range(16) ]
        self.shuttler0_dds = [ self.get_device("shuttler0_dds{}".format(i)) for i in range(16) ]
        self.setattr_device("shuttler0_relay")
        self.setattr_device("shuttler0_adc")
    @kernel
    def record(self):
        with self.core_dma.record("example_waveform"):
            self.example_waveform()
    @kernel
    def init(self):
        self.led()
        self.relay_init()
        self.adc_init()
        self.shuttler_reset()
    @kernel
    def run(self):
        self.core.reset()
        self.core.break_realtime()
        self.init()
        self.record()
        example_waveform_handle = self.core_dma.get_handle("example_waveform")
        print("Example Waveforms are on OUT0 and OUT1")
        self.core.break_realtime()
        while not(self.scheduler.check_termination()):
            delay(1*s)
            self.core_dma.playback_handle(example_waveform_handle)
    @kernel
    def shuttler_reset(self):
        for i in range(16):
            self.shuttler_channel_reset(i)
            # To avoid RTIO Underflow
            delay(50*us)
    @kernel
    def shuttler_channel_reset(self, ch):
        self.shuttler0_dcbias[ch].set_waveform(
            a0=0,
            a1=0,
            a2=0,
            a3=0,
        )
        self.shuttler0_dds[ch].set_waveform(
            b0=0,
            b1=0,
            b2=0,
            b3=0,
            c0=0,
            c1=0,
            c2=0,
        )
        self.shuttler0_trigger.trigger(1 << ch)
    @kernel
    def example_waveform(self):
        # Equation of Output Waveform
        #   w(t_us) = a(t_us) + b(t_us) * cos(c(t_us))
        # Step 1:
        #   Enable the Output Relay of OUT0 and OUT1
        # Step 2: Cosine Wave Frequency Sweep from 10kHz to 50kHz in 500us
        #   OUT0: b(t_us) = 1
        #         c(t_us) = 2 * pi * (0.08 * t_us ^ 2 + 0.01 * t_us)
        #   OUT1: b(t_us) = 1
        #         c(t_us) = 2 * pi * (0.05 * t_us)
        # Step 3(after 500us): Cosine Wave with 180 Degree Phase Offset
        #   OUT0: b(t_us) = 1
        #         c(t_us) = 2 * pi * (0.05 * t_us) + pi
        #   OUT1: b(t_us) = 1
        #         c(t_us) = 2 * pi * (0.05 * t_us)
        # Step 4(after 500us): Cosine Wave with Amplitude Envelop
        #   OUT0: b(t_us) = -0.0001367187 * t_us ^ 2 + 0.06835937 * t_us
        #         c(t_us) = 2 * pi * (0.05 * t_us)
        #   OUT1: b(t_us) = -0.0001367187 * t_us ^ 2 + 0.06835937 * t_us
        #         c(t_us) = 0
        # Step 5(after 500us): Sawtooth Wave Modulated with 50kHz Cosine Wave 
        #   OUT0: a(t_us) = 0.01 * t_us - 5
        #         b(t_us) = 1
        #         c(t_us) = 2 * pi * (0.05 * t_us)
        #   OUT1: a(t_us) = 0.01 * t_us - 5
        # Step 6(after 1000us): A Combination of Previous Waveforms
        #   OUT0: a(t_us) = 0.01 * t_us - 5
        #         b(t_us) = -0.0001367187 * t_us ^ 2 + 0.06835937 * t_us
        #         c(t_us) = 2 * pi * (0.08 * t_us ^ 2 + 0.01 * t_us)
        # Step 7(after 500us): Mirrored Waveform in Step 6
        #   OUT0: a(t_us) = 2.5 + -0.01 * (1000 ^ 2) * t_us
        #         b(t_us) = 0.0001367187 * t_us ^ 2 - 0.06835937 * t_us
        #         c(t_us) = 2 * pi * (-0.08 * t_us ^ 2 + 0.05 * t_us) + pi
        # Step 8(after 500us):
        #   Disable Output Relay of OUT0 and OUT1
        #   Reset OUT0 and OUT1
        ## Step 1 ##
        self.shuttler0_relay.enable(0b11)
        ## Step 2 ##
        start_f_MHz = 0.01
        end_f_MHz = 0.05
        duration_us = 500
        # OUT0 and OUT1 have their frequency and phase aligned at 500us
        self.shuttler0_dds[0].set_waveform(
            b0=shuttler_dds_amp_mu(1.0),
            b1=0,
            b2=0,
            b3=0,
            c0=0,
            c1=shuttler_freq_mu(start_f_MHz),
            c2=shuttler_freq_sweep(start_f_MHz, end_f_MHz, duration_us),
        )
        self.shuttler0_dds[1].set_waveform(
            b0=shuttler_dds_amp_mu(1.0),
            b1=0,
            b2=0,
            b3=0,
            c0=0,
            c1=shuttler_freq_mu(end_f_MHz),
            c2=0,
        )
        self.shuttler0_trigger.trigger(0b11)
        delay(500*us)
        ## Step 3 ##
        # OUT0 and OUT1 has 180 degree phase difference
        self.shuttler0_dds[0].set_waveform(
            b0=shuttler_dds_amp_mu(1.0),
            b1=0,
            b2=0,
            b3=0,
            c0=shuttler_phase_offset(180.0),
            c1=shuttler_freq_mu(end_f_MHz),
            c2=0,
        )
        # Phase and Output Setting of OUT1 is retained 
        #   if the channel is not triggered or config is not cleared
        self.shuttler0_trigger.trigger(0b1)
        delay(500*us)
        ## Step 4 ##
        #     b(0) = 0, b(250) = 8.545, b(500) = 0
        self.shuttler0_dds[0].set_waveform(
            b0=0,
            b1=shuttler_dds_damp_mu(0.06835937),
            b2=shuttler_dds_ddamp_mu(-0.0001367187),
            b3=0,
            c0=0,
            c1=shuttler_freq_mu(end_f_MHz),
            c2=0,
        )
        self.shuttler0_dds[1].set_waveform(
            b0=0,
            b1=shuttler_dds_damp_mu(0.06835937),
            b2=shuttler_dds_ddamp_mu(-0.0001367187),
            b3=0,
            c0=0,
            c1=0,
            c2=0,
        )
        self.shuttler0_trigger.trigger(0b11)
        delay(500*us)
        ## Step 5 ##
        self.shuttler0_dcbias[0].set_waveform(
            a0=shuttler_volt_amp_mu(-5.0),
            a1=int32(shuttler_volt_damp_mu(0.01)),
            a2=0,
            a3=0,
        )
        self.shuttler0_dds[0].set_waveform(
            b0=shuttler_dds_amp_mu(1.0),
            b1=0,
            b2=0,
            b3=0,
            c0=0,
            c1=shuttler_freq_mu(end_f_MHz),
            c2=0,
        )
        self.shuttler0_dcbias[1].set_waveform(
            a0=shuttler_volt_amp_mu(-5.0),
            a1=int32(shuttler_volt_damp_mu(0.01)),
            a2=0,
            a3=0,
        )
        self.shuttler0_dds[1].set_waveform(
            b0=0,
            b1=0,
            b2=0,
            b3=0,
            c0=0,
            c1=0,
            c2=0,
        )
        self.shuttler0_trigger.trigger(0b11)
        delay(1000*us)
        ## Step 6 ##
        self.shuttler0_dcbias[0].set_waveform(
            a0=shuttler_volt_amp_mu(-2.5),
            a1=int32(shuttler_volt_damp_mu(0.01)),
            a2=0,
            a3=0,
        )
        self.shuttler0_dds[0].set_waveform(
            b0=0,
            b1=shuttler_dds_damp_mu(0.06835937),
            b2=shuttler_dds_ddamp_mu(-0.0001367187),
            b3=0,
            c0=0,
            c1=shuttler_freq_mu(start_f_MHz),
            c2=shuttler_freq_sweep(start_f_MHz, end_f_MHz, duration_us),
        )
        self.shuttler0_trigger.trigger(0b1)
        self.shuttler_channel_reset(1)
        delay(500*us)
        ## Step 7 ##
        self.shuttler0_dcbias[0].set_waveform(
            a0=shuttler_volt_amp_mu(2.5),
            a1=int32(shuttler_volt_damp_mu(-0.01)),
            a2=0,
            a3=0,
        )
        self.shuttler0_dds[0].set_waveform(
            b0=0,
            b1=shuttler_dds_damp_mu(-0.06835937),
            b2=shuttler_dds_ddamp_mu(0.0001367187),
            b3=0,
            c0=shuttler_phase_offset(180.0),
            c1=shuttler_freq_mu(end_f_MHz),
            c2=shuttler_freq_sweep(end_f_MHz, start_f_MHz, duration_us),
        )
        self.shuttler0_trigger.trigger(0b1)
        delay(500*us)
        ## Step 8 ##
        self.shuttler0_relay.enable(0)
        self.shuttler_channel_reset(0)
        self.shuttler_channel_reset(1)
    @kernel
    def led(self):
        for i in range(2):
            for j in range(3):
                self.shuttler0_leds[i].pulse(.1*s)
                delay(.1*s)
    @kernel
    def relay_init(self):
        self.shuttler0_relay.init()
        self.shuttler0_relay.enable(0x0000)
    @kernel
    def adc_init(self):
        delay_mu(int64(self.core.ref_multiplier))
        self.shuttler0_adc.power_up()
        delay_mu(int64(self.core.ref_multiplier))
        assert self.shuttler0_adc.read_id() >> 4 == 0x038d
        delay_mu(int64(self.core.ref_multiplier))
        # The actual output voltage is limited by the hardware, the calculated calibration gain and offset.
        # For example, if the system has a calibration gain of 1.06, then the max output voltage = 10 / 1.06 = 9.43V.
        # Setting a value larger than 9.43V will result in overflow.
        self.shuttler0_adc.calibrate(self.shuttler0_dcbias, self.shuttler0_trigger, self.shuttler0_config)
--- a/artiq/examples/kasli_suservo/device_db.py
+++ b/artiq/examples/kasli_suservo/device_db.py
@ -5,7 +5,11 @@ device_db = {
        "type": "local",
        "module": "artiq.coredevice.core",
        "class": "Core",
-        "arguments": {"host": core_addr, "ref_period": 1e-9}
+        "arguments": {
            "host": core_addr,
            "ref_period": 1e-9,
            "analyzer_proxy": "core_analyzer"
        }
    },
    "core_log": {
        "type": "controller",
@ -13,6 +17,20 @@ device_db = {
        "port": 1068,
        "command": "aqctl_corelog -p {port} --bind {bind} " + core_addr
    },
    "core_moninj": {
        "type": "controller",
        "host": "::1",
        "port_proxy": 1383,
        "port": 1384,
        "command": "aqctl_moninj_proxy --port-proxy {port_proxy} --port-control {port} --bind {bind} " + core_addr
    },
    "core_analyzer": {
        "type": "controller",
        "host": "::1",
        "port_proxy": 1385,
        "port": 1386,
        "command": "aqctl_coreanalyzer_proxy --port-proxy {port_proxy} --port-control {port} --bind {bind} " + core_addr
    },
    "core_cache": {
        "type": "local",
        "module": "artiq.coredevice.cache",
@ -27,13 +45,13 @@ device_db = {
    "i2c_switch0": {
        "type": "local",
        "module": "artiq.coredevice.i2c",
-        "class": "PCA9548",
+        "class": "I2CSwitch",
        "arguments": {"address": 0xe0}
    },
    "i2c_switch1": {
        "type": "local",
        "module": "artiq.coredevice.i2c",
-        "class": "PCA9548",
+        "class": "I2CSwitch",
        "arguments": {"address": 0xe2}
    },
@ -191,10 +209,8 @@ device_db = {
        "arguments": {
            "channel": 24,
            "pgia_device": "spi_sampler0_pgia",
-            "cpld0_device": "urukul0_cpld",
+            "cpld_devices": ["urukul0_cpld", "urukul1_cpld"],
-            "cpld1_device": "urukul1_cpld",
+            "dds_devices": ["urukul0_dds", "urukul1_dds"],
            "dds0_device": "urukul0_dds",
            "dds1_device": "urukul1_dds"
        }
    },
--- a/artiq/examples/kc705_nist_clock/device_db.py
+++ b/artiq/examples/kc705_nist_clock/device_db.py
@ -9,7 +9,11 @@ device_db = {
        "type": "local",
        "module": "artiq.coredevice.core",
        "class": "Core",
-        "arguments": {"host": core_addr, "ref_period": 1e-9}
+        "arguments": {
            "host": core_addr,
            "ref_period": 1e-9,
            "analyzer_proxy": "core_analyzer"
        }
    },
    "core_log": {
        "type": "controller",
@ -17,6 +21,20 @@ device_db = {
        "port": 1068,
        "command": "aqctl_corelog -p {port} --bind {bind} " + core_addr
    },
    "core_moninj": {
        "type": "controller",
        "host": "::1",
        "port_proxy": 1383,
        "port": 1384,
        "command": "aqctl_moninj_proxy --port-proxy {port_proxy} --port-control {port} --bind {bind} " + core_addr
    },
    "core_analyzer": {
        "type": "controller",
        "host": "::1",
        "port_proxy": 1385,
        "port": 1386,
        "command": "aqctl_coreanalyzer_proxy --port-proxy {port_proxy} --port-control {port} --bind {bind} " + core_addr
    },
    "core_cache": {
        "type": "local",
        "module": "artiq.coredevice.cache",
@ -31,7 +49,7 @@ device_db = {
    "i2c_switch": {
        "type": "local",
        "module": "artiq.coredevice.i2c",
-        "class": "PCA9548"
+        "class": "I2CSwitch"
    },
    # Generic TTL
--- a/artiq/examples/kc705_nist_clock/repository/dds_setter.py
+++ b/artiq/examples/kc705_nist_clock/repository/dds_setter.py
@ -20,7 +20,7 @@ class DDSSetter(EnvExperiment):
                    "driver": self.get_device(k),
                    "frequency": self.get_argument(
                        "{}_frequency".format(k),
-                        NumberValue(100e6, scale=1e6, unit="MHz", ndecimals=6))
+                        NumberValue(100e6, scale=1e6, unit="MHz", precision=6))
                }
    @kernel
--- a/Show More
+++ b/Show More