sawg: clean up Config

* unify I and Q data limiters. there is no conceivable way why they
would be different.
* reorder clr bits to be like consistent
* move the sat add limiter to before the hbf again

artiq/coredevice/sawg.py

@@ -10,12 +10,10 @@ _SAWG_DIV = 0
 _SAWG_CLR = 1
 _SAWG_IQ_EN = 2
 # _SAWF_PAD = 3  # reserved
-_SAWG_DUC_I_MIN = 4
-_SAWG_DUC_I_MAX = 5
-_SAWG_DUC_Q_MIN = 6
-_SAWG_DUC_Q_MAX = 7
-_SAWG_OUT_MIN = 8
-_SAWG_OUT_MAX = 9
+_SAWG_OUT_MIN = 4
+_SAWG_OUT_MAX = 5
+_SAWG_DUC_MIN = 6
+_SAWG_DUC_MAX = 7
 
 
 class Config:
@@ -92,8 +90,8 @@ class Config:
         :param clr2: Auto-clear phase accumulator of the ``phase2``/
           ``frequency2`` DDS. Default: ``True``
         """
-        rtio_output(now_mu(), self.channel, _SAWG_CLR, clr1 |
-                (clr2 << 1) | (clr0 << 2))
+        rtio_output(now_mu(), self.channel, _SAWG_CLR, clr0 |
+                (clr1 << 1) | (clr2 << 2))
 
     @kernel
     def set_iq_en(self, i_enable: TInt32, q_enable: TInt32):
@@ -122,48 +120,38 @@ class Config:
                 (q_enable << 1))
 
     @kernel
-    def set_duc_i_max_mu(self, limit: TInt32):
-        """Set the digital up-converter (DUC) I data summing junction upper
-        limit. In machine units.
+    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_i_max`
+        .. seealso:: :meth:`set_duc_max`
         """
-        rtio_output(now_mu(), self.channel, _SAWG_DUC_I_MAX, limit)
+        rtio_output(now_mu(), self.channel, _SAWG_DUC_MAX, limit)
 
     @kernel
-    def set_duc_i_min_mu(self, limit: TInt32):
-        """.. seealso:: :meth:`set_duc_i_max_mu`"""
-        rtio_output(now_mu(), self.channel, _SAWG_DUC_I_MIN, limit)
-
-    @kernel
-    def set_duc_q_max_mu(self, limit: TInt32):
-        """.. seealso:: :meth:`set_duc_i_max_mu`"""
-        rtio_output(now_mu(), self.channel, _SAWG_DUC_Q_MAX, limit)
-
-    @kernel
-    def set_duc_q_min_mu(self, limit: TInt32):
-        """.. seealso:: :meth:`set_duc_i_max_mu`"""
-        rtio_output(now_mu(), self.channel, _SAWG_DUC_Q_MIN, limit)
+    def set_duc_min_mu(self, limit: TInt32):
+        """.. seealso:: :meth:`set_duc_max_mu`"""
+        rtio_output(now_mu(), self.channel, _SAWG_DUC_MIN, limit)
 
     @kernel
     def set_out_max_mu(self, limit: TInt32):
-        """.. seealso:: :meth:`set_duc_i_max_mu`"""
+        """.. seealso:: :meth:`set_duc_max_mu`"""
         rtio_output(now_mu(), self.channel, _SAWG_OUT_MAX, limit)
 
     @kernel
     def set_out_min_mu(self, limit: TInt32):
-        """.. seealso:: :meth:`set_duc_i_max_mu`"""
+        """.. seealso:: :meth:`set_duc_max_mu`"""
         rtio_output(now_mu(), self.channel, _SAWG_OUT_MIN, limit)
 
     @kernel
-    def set_duc_i_max(self, limit: TFloat):
-        """Set the digital up-converter (DUC) I data summing junction upper
-        limit.
+    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:
@@ -171,7 +159,8 @@ class Config:
             * 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.
+              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:
 
@@ -190,42 +179,28 @@ class Config:
             ``[-1, 1]``.
 
         .. seealso::
-            * :meth:`set_duc_i_max`: Upper limit of the in-phase input to
-              the DUC.
-            * :meth:`set_duc_i_min`: Lower limit of the in-phase input to
-              the DUC.
-            * :meth:`set_duc_q_max`: Upper limit of the quadrature input to
-              the DUC.
-            * :meth:`set_duc_q_min`: Lower limit of the quadrature input to
-              the DUC.
+            * :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_i_max_mu(int32(round(limit*self._duc_scale)))
+        self.set_duc_max_mu(int32(round(limit*self._duc_scale)))
 
     @kernel
-    def set_duc_i_min(self, limit: TFloat):
-        """.. seealso:: :meth:`set_duc_i_max`"""
-        self.set_duc_i_min_mu(int32(round(limit*self._duc_scale)))
-
-    @kernel
-    def set_duc_q_max(self, limit: TFloat):
-        """.. seealso:: :meth:`set_duc_i_max`"""
-        self.set_duc_q_max_mu(int32(round(limit*self._duc_scale)))
-
-    @kernel
-    def set_duc_q_min(self, limit: TFloat):
-        """.. seealso:: :meth:`set_duc_i_max`"""
-        self.set_duc_q_min_mu(int32(round(limit*self._duc_scale)))
+    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_i_max`"""
+        """.. 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_i_max`"""
+        """.. seealso:: :meth:`set_duc_max`"""
         self.set_out_min_mu(int32(round(limit*self._out_scale)))
 
 
@@ -306,6 +281,7 @@ class SAWG:
         width = 16
         time_width = 16
         cordic_gain = 1.646760258057163  # Cordic(width=16, guard=None).gain
+        cordic_gain *= 1.01  # leave a bit of headroom
         self.config = Config(channel_base, self.core, cordic_gain)
         self.offset = Spline(width, time_width, channel_base + 1,
                              self.core, 2.)
@@ -335,7 +311,7 @@ class SAWG:
         settings.
 
         This method advances the timeline by the time required to perform all
-        eight writes to the configuration channel.
+        six writes to the configuration channel.
         """
         self.frequency0.set_mu(0)
         self.frequency1.set_mu(0)
@@ -350,13 +326,9 @@ class SAWG:
         delay_mu(self.config._rtio_interval)
         self.config.set_iq_en(1, 0)
         delay_mu(self.config._rtio_interval)
-        self.config.set_duc_i_min(-1.)
+        self.config.set_duc_min(-1.)
         delay_mu(self.config._rtio_interval)
-        self.config.set_duc_i_max(1.)
-        delay_mu(self.config._rtio_interval)
-        self.config.set_duc_q_min(-1.)
-        delay_mu(self.config._rtio_interval)
-        self.config.set_duc_q_max(1.)
+        self.config.set_duc_max(1.)
         delay_mu(self.config._rtio_interval)
         self.config.set_out_min(-1.)
         delay_mu(self.config._rtio_interval)

artiq/gateware/dsp/sawg.py

@@ -83,35 +83,43 @@ class SplineParallelDDS(SplineParallelDUC):
 
 
 class Config(Module):
-    def __init__(self, width):
+    def __init__(self, width, cordic_gain):
         self.clr = Signal(3, reset=0b111)
         self.iq_en = Signal(2, reset=0b01)
-        self.limits = [[Signal((width, True), reset=-(1 << width - 1)),
-                       Signal((width, True), reset=(1 << width - 1) - 1)]
-                      for i in range(3)]
-        self.clipped = [Signal(2) for i in range(3)]  # TODO
-        self.i = Endpoint([("addr", bits_for(4 + 2*len(self.limits))),
-                           ("data", 16)])
+        self.limits = [[Signal((width, True)), Signal((width, True))]
+                for i in range(2)]
+        limit = 1 << width - 1
+        self.limits[0][0].reset = -limit
+        self.limits[0][1].reset = limit - 1
+        self.limits[1][0].reset = int(-limit/cordic_gain)
+        self.limits[1][1].reset = int((limit - 1)/cordic_gain)
+        # TODO make persistent, add read-out/notification/clear
+        self.clipped = [Signal(2) for i in range(2)]
+        self.i = Endpoint([("addr", bits_for(4 + 2*len(self.limits) - 1)),
+                           ("data", width)])
+        assert len(self.i.addr) == 3
         self.ce = Signal()
 
         ###
 
         div = Signal(16, reset=0)
         n = Signal.like(div)
-        pad = Signal()
 
-        reg = Array([Cat(div, n), self.clr, self.iq_en, pad] +
-                    sum(self.limits, []))
-
-        self.comb += [
-            self.i.ack.eq(1),
-            self.ce.eq(n == 0),
-        ]
+        self.comb += self.ce.eq(n == 0)
         self.sync += [
             n.eq(n - 1),
             If(self.ce,
                 n.eq(div),
-            ),
+            )
+        ]
+
+        pad = Signal()
+
+        reg = Array(sum(self.limits,
+            [Cat(div, n), self.clr, self.iq_en, pad]))
+
+        self.comb += self.i.ack.eq(1)
+        self.sync += [
             If(self.i.stb,
                 reg[self.i.addr].eq(self.i.data),
             ),
@@ -131,26 +139,26 @@ class Channel(Module, SatAddMixin):
         coeff = halfgen4_cascade(parallelism, width=.4, order=8)
         hbf = [ParallelHBFUpsampler(coeff, width=width + 1) for i in range(2)]
         self.submodules.b = b = SplineParallelDUC(
-            widths._replace(a=len(hbf[0].o[0]), f=widths.f - width), orders,
+            widths._replace(a=width + 1, f=widths.f - width), orders,
             parallelism=parallelism)
-        cfg = Config(width)
+        cfg = Config(width, b.gain)
         u = Spline(width=widths.a, order=orders.a)
         self.submodules += cfg, u, hbf
         self.u = u.tri(widths.t)
         self.i = [cfg.i, self.u, a1.a, a1.f, a1.p, a2.a, a2.f, a2.p, b.f, b.p]
         self.i_names = "cfg u a1 f1 p1 a2 f2 p2 f0 p0".split()
         self.i_named = dict(zip(self.i_names, self.i))
-        self.y_in = [Signal((width, True)) for i in range(parallelism)]
+        self.y_in = [Signal.like(b.yo[0]) for i in range(parallelism)]
         self.o = [Signal((width, True)) for i in range(parallelism)]
         self.widths = widths
         self.orders = orders
         self.parallelism = parallelism
-        self.cordic_gain = a1.gain*b.gain
+        self.cordic_gain = a2.gain*b.gain
 
         self.u.latency += 1
         b.p.latency += 2
         b.f.latency += 2
-        a_latency_delta = hbf[0].latency + b.latency + 3
+        a_latency_delta = hbf[0].latency + b.latency + 2
         for a in a1, a2:
             a.a.latency += a_latency_delta
             a.p.latency += a_latency_delta
@@ -169,26 +177,19 @@ class Channel(Module, SatAddMixin):
             a2.ce.eq(cfg.ce),
             b.ce.eq(cfg.ce),
             u.o.ack.eq(cfg.ce),
-            Cat(a1.clr, a2.clr, b.clr).eq(cfg.clr),
+            Cat(b.clr, a1.clr, a2.clr).eq(cfg.clr),
+        ]
+        self.sync += [
+            hbf[0].i.eq(self.sat_add(a1.xo[0], a2.xo[0],
+                limits=cfg.limits[1], clipped=cfg.clipped[1])),
+            hbf[1].i.eq(self.sat_add(a1.yo[0], a2.yo[0],
+                limits=cfg.limits[1], clipped=None)),  # ignore Q clip data
         ]
         for i in range(parallelism):
-            self.sync += [
-                b.xi[i].eq(self.sat_add(hbf[0].o[i],
-                                     limits=cfg.limits[0],
-                                     clipped=cfg.clipped[0])),
-                b.yi[i].eq(self.sat_add(hbf[1].o[i],
-                                     limits=cfg.limits[1],
-                                     clipped=cfg.clipped[1])),
+            self.comb += [
+                b.xi[i].eq(hbf[0].o[i]),
+                b.yi[i].eq(hbf[1].o[i]),
             ]
-        for i in range(2):
-            for j in range(2):
-                # correct pre-DUC limiter by cordic gain
-                v = cfg.limits[i][j].reset.value
-                cfg.limits[i][j].reset.value = int(v / b.gain)
-        self.sync += [
-            hbf[0].i.eq(a1.xo[0] + a2.xo[0]),
-            hbf[1].i.eq(a1.yo[0] + a2.yo[0])
-        ]
         # wire up outputs and q_{i,o} exchange
         for o, x, y in zip(self.o, b.xo, self.y_in):
             self.sync += [
@@ -196,8 +197,8 @@ class Channel(Module, SatAddMixin):
                     u.o.a0[-len(o):],
                     Mux(cfg.iq_en[0], x, 0),
                     Mux(cfg.iq_en[1], y, 0),
-                    limits=cfg.limits[2],
-                    clipped=cfg.clipped[2])),
+                    limits=cfg.limits[0],
+                    clipped=cfg.clipped[0])),
             ]
 
     def connect_y(self, buddy):