Simplify formatter update methodology

Don't expect values (array + slice) to be returned and applied by
`.incr_update_xy_nd()` and instead presume this will implemented
internally in each (sub)formatter.

Attempt to simplify some incr-update routines, (particularly in the step
curve formatter, though most of it was reverted to just a simpler form
of the original implementation XD) including:
- dropping the need for the `slice_to_head: int` control.
- using the `xy_nd_start/stop` index counters over custom lookups.

piker/data/_pathops.py

@@ -271,15 +271,7 @@ class IncrementalFormatter(msgspec.Struct):
             profiler('allocated xy history')
 
         if prepend_len:
-            y_prepend = shm._array[pre_slice]
-            # if read_src_from_key:
-            #     y_prepend = y_prepend[array_key]
-
-            (
-                new_y_nd,
-                y_nd_slc,
-
-            ) = self.incr_update_xy_nd(
+            self.incr_update_xy_nd(
                 shm,
                 array_key,
 
@@ -289,7 +281,7 @@ class IncrementalFormatter(msgspec.Struct):
                 # step curves) the updater routine may want to do
                 # the source history-data reading itself, so we pass
                 # both here.
-                y_prepend,
+                shm._array[pre_slice],
                 pre_slice,
                 prepend_len,
 
@@ -298,30 +290,16 @@ class IncrementalFormatter(msgspec.Struct):
                 is_append=False,
             )
 
-            # y_nd_view = self.y_nd[y_nd_slc]
-            self.y_nd[y_nd_slc] = new_y_nd
-            # if read_src_from_key:
-            #     y_nd_view[:][array_key] = new_y_nd
-            # else:
-            #     y_nd_view[:] = new_y_nd
-
+            # self.y_nd[y_nd_slc] = new_y_nd
             self.xy_nd_start = shm._first.value
             profiler('prepended xy history: {prepend_length}')
 
         if append_len:
-            y_append = shm._array[post_slice]
-            # if read_src_from_key:
-            #     y_append = y_append[array_key]
-
-            (
-                new_y_nd,
-                y_nd_slc,
-
-            ) = self.incr_update_xy_nd(
+            self.incr_update_xy_nd(
                 shm,
                 array_key,
 
-                y_append,
+                shm._array[post_slice],
                 post_slice,
                 append_len,
 
@@ -329,10 +307,6 @@ class IncrementalFormatter(msgspec.Struct):
                 self.xy_nd_stop,
                 is_append=True,
             )
-            # self.y_nd[post_slice] = new_y_nd
-            # self.y_nd[xy_slice or post_slice] = xy_data
-            self.y_nd[y_nd_slc] = new_y_nd
-
             self.xy_nd_stop = shm._last.value
             profiler('appened xy history: {append_length}')
 
@@ -391,11 +365,11 @@ class IncrementalFormatter(msgspec.Struct):
         # update the last "in view data range"
         if len(x_1d):
             self._last_ivdr = x_1d[0], x_1d[slice_to_head]
-
-        profiler('.format_to_1d()')
             if (x_1d[-1] == 0.5).any():
                 breakpoint()
 
+        profiler('.format_to_1d()')
+
         return (
             x_1d,
             y_1d,
@@ -450,10 +424,7 @@ class IncrementalFormatter(msgspec.Struct):
 
         is_append: bool,
 
-    ) -> tuple[
-        np.ndarray,
-        slice,
-    ]:
+    ) -> None:
         # write pushed data to flattened copy
         new_y_nd = new_from_src[data_field]
 
@@ -466,7 +437,7 @@ class IncrementalFormatter(msgspec.Struct):
             x_nd_new = self.x_nd[read_slc]
             x_nd_new[:] = new_from_src[index_field]
 
-        return new_y_nd, read_slc
+        self.y_nd[read_slc] = new_y_nd
 
     # XXX: was ``.format_xy()``
     def format_xy_nd_to_1d(
@@ -488,8 +459,8 @@ class IncrementalFormatter(msgspec.Struct):
 
         '''
         return (
-            array[self.index_field],
-            array[array_key],
+            array[self.index_field][:-1],
+            array[array_key][:-1],
 
             # 1d connection array or style-key to
             # ``pg.functions.arrayToQPath()``
@@ -672,10 +643,7 @@ class OHLCBarsFmtr(IncrementalFormatter):
 
         is_append: bool,
 
-    ) -> tuple[
-        np.ndarray,
-        slice,
-    ]:
+    ) -> None:
         # write newly pushed data to flattened copy
         # a struct-arr is always passed in.
         new_y_nd = rfn.structured_to_unstructured(
@@ -694,7 +662,7 @@ class OHLCBarsFmtr(IncrementalFormatter):
             if (self.x_nd[self.xy_slice] == 0.5).any():
                 breakpoint()
 
-        return new_y_nd, read_slc
+        self.y_nd[read_slc] = new_y_nd
 
 
 class OHLCBarsAsCurveFmtr(OHLCBarsFmtr):
@@ -764,8 +732,10 @@ class StepCurveFmtr(IncrementalFormatter):
         # fill in (current) values from source shm buffer
         y_out[:] = out[:, np.newaxis]
 
+        # TODO: pretty sure we can drop this?
         # start y at origin level
-        y_out[self.xy_nd_start] = 0
+        # y_out[0, 0] = 0
+        # y_out[self.xy_nd_start] = 0
         return x_out, y_out
 
     def incr_update_xy_nd(
@@ -790,13 +760,29 @@ class StepCurveFmtr(IncrementalFormatter):
         # for a step curve we slice from one datum prior
         # to the current "update slice" to get the previous
         # "level".
-        # if is_append:
-        #     start = max(last - 1, 0)
-        #     end = src_shm._last.value
-        #     new_y = src_shm._array[start:end][array_key]
-        #     append_slc = slice(start, end)
+        last_2 = slice(
+            read_slc.start,
+            read_slc.stop+1,
+        )
+        y_nd_new = self.y_nd[last_2]
+        y_nd_new[:] = src_shm._array[last_2][array_key][:, None]
 
-        new_y = new_from_src[array_key][:, np.newaxis]
+        # NOTE: we can't use the append slice since we need to "look
+        # forward" one step to get the current level and copy it as
+        # well? (though i still don't really grok why..)
+        # y_nd_new[:] = new_from_src[array_key][:, None]
+
+        # XXX: old approach now duplicated above (we can probably drop
+        # this since the key part was the ``nd_stop + 1``
+        # if is_append:
+        #     start = max(nd_stop - 1, 0)
+        #     end = src_shm._last.value
+        #     y_nd_new = src_shm._array[start:end][array_key]#[:, np.newaxis]
+        #     slc = slice(start, end)
+        #     self.y_nd[slc] = np.broadcast_to(
+        #         y_nd_new[:, None],
+        #         (y_nd_new.size, 2),
+        #     )
 
         index_field = self.index_field
         if index_field != 'index':
@@ -806,15 +792,6 @@ class StepCurveFmtr(IncrementalFormatter):
         if (self.x_nd[self.xy_slice][-1] == 0.5).any():
             breakpoint()
 
-        return (
-            new_y,
-            # np.broadcast_to(
-            #     new_x[:, None],
-            #     (new_y.size, 2),
-            # ),
-            read_slc,
-        )
-
     def format_xy_nd_to_1d(
         self,
 
@@ -830,11 +807,7 @@ class StepCurveFmtr(IncrementalFormatter):
         last_t, last = array[-1][[self.index_field, array_key]]
 
         start = self.xy_nd_start
-
-        # 2 more datum-indexes to capture zero at end
-        # XXX: can we drop this ``extra`` bit?
-        extra = 2
-        stop = self.xy_nd_stop + extra
+        stop = self.xy_nd_stop
 
         x_step = self.x_nd[start:stop]
         y_step = self.y_nd[start:stop]
@@ -843,32 +816,44 @@ class StepCurveFmtr(IncrementalFormatter):
         #     breakpoint()
 
         # pack in duplicate final value to complete last step level
-        x_step[-1] = last_t
-        y_step[-1] = last
+        # x_step[-1] = last_t
+        # y_step[-1] = last
+        # x_step[-1, 1] = last_t
+        y_step[-1, 1] = last
+
+        # if y_step.any():
+        #     s = 3
+        #     print(
+        #         f'x_step:\n{x_step[-s:]}\n'
+        #         f'y_step:\n{y_step[-s:]}\n\n'
+        #     )
 
         # slice out in-view data
         ivl, ivr = vr
-        # ys_iv = y_step[ivl:ivr+1]
-        # xs_iv = x_step[ivl:ivr+1]
-        ys_iv = y_step[ivl:ivr]
-        xs_iv = x_step[ivl:ivr]
+        # TODO: WHY do we need the extra +1 index?
+        x_step_iv = x_step[ivl:ivr+1]
+        y_step_iv = y_step[ivl:ivr+1]
 
         # flatten to 1d
-        y_iv = ys_iv.reshape(ys_iv.size)
-        x_iv = xs_iv.reshape(xs_iv.size)
+        x_1d = x_step_iv.reshape(x_step_iv.size)
+        y_1d = y_step_iv.reshape(y_step_iv.size)
 
-        if (x_iv[-1] == 0.5).any():
+        if not x_1d.size == y_1d.size:
             breakpoint()
 
-        # s = 100
+        if x_1d.any() and (x_1d[-1] == 0.5).any():
+            breakpoint()
+
+        # if y_1d.any():
+        #     s = 6
         #     print(
-        #     f'ys_iv : {ys_iv[-s:]}\n'
-        #     f'y_iv: {y_iv[-s:]}\n'
-        #     f'xs_iv: {xs_iv[-s:]}\n'
-        #     f'x_iv: {x_iv[-s:]}\n'
+        #         f'x_step_iv:\n{x_step_iv[-s:]}\n'
+        #         f'y_step_iv:\n{y_step_iv[-s:]}\n\n'
+        #         f'x_1d:\n{x_1d[-s:]}\n'
+        #         f'y_1d:\n{y_1d[-s:]}\n'
         #     )
 
-        return x_iv, y_iv, 'all'
+        return x_1d, y_1d, 'all'
 
 
 def xy_downsample(