7 changed files with 470 additions and 534 deletions
--- a/piker/brokers/ib.py
+++ b/piker/brokers/ib.py
@ -1791,7 +1791,7 @@ async def _setup_quote_stream(
    to_trio.send_nowait(None)
    async with load_aio_clients() as accts2clients:
-        caccount_name, client = get_preferred_data_client(accts2clients)
+        client = get_preferred_data_client(accts2clients)
        contract = contract or (await client.find_contract(symbol))
        ticker: Ticker = client.ib.reqMktData(contract, ','.join(opts))
--- a/piker/data/_source.py
+++ b/piker/data/_source.py
@ -33,7 +33,7 @@ ohlc_fields = [
    ('high', float),
    ('low', float),
    ('close', float),
-    ('volume', float),
+    ('volume', int),
    ('bar_wap', float),
 ]
--- a/piker/data/marketstore.py
+++ b/piker/data/marketstore.py
@ -230,8 +230,8 @@ _ohlcv_dt = [
    # ohlcv sampling
    ('Open', 'f4'),
    ('High', 'f4'),
-    ('Low', 'f4'),
+    ('Low', 'i8'),
-    ('Close', 'f4'),
+    ('Close', 'i8'),
    ('Volume', 'f4'),
 ]
@ -547,17 +547,6 @@ class Storage:
                if err:
                    raise MarketStoreError(err)
    # XXX: currently the only way to do this is through the CLI:
    # sudo ./marketstore connect --dir ~/.config/piker/data
    # >> \show mnq.globex.20220617.ib/1Sec/OHLCV 2022-05-15
    # and this seems to block and use up mem..
    # >> \trim mnq.globex.20220617.ib/1Sec/OHLCV 2022-05-15
    # relevant source code for this is here:
    # https://github.com/alpacahq/marketstore/blob/master/cmd/connect/session/trim.go#L14
    # def delete_range(self, start_dt, end_dt) -> None:
    #     ...
@acm
 async def open_storage_client(
--- a/piker/ui/_curve.py
+++ b/piker/ui/_curve.py
@ -34,11 +34,10 @@ from PyQt5.QtCore import (
 from .._profile import pg_profile_enabled, ms_slower_then
 from ._style import hcolor
-# from ._compression import (
+from ._compression import (
-#     # ohlc_to_m4_line,
+    # ohlc_to_m4_line,
-#     ds_m4,
+    ds_m4,
-# )
+)
 from ._pathops import xy_downsample
 from ..log import get_logger
@ -175,6 +174,32 @@ class FastAppendCurve(pg.GraphicsObject):
            QLineF(lbar, 0, rbar, 0)
        ).length()
    def downsample(
        self,
        x,
        y,
        px_width,
        uppx,
    ) -> tuple[np.ndarray, np.ndarray]:
        # downsample whenever more then 1 pixels per datum can be shown.
        # always refresh data bounds until we get diffing
        # working properly, see above..
        bins, x, y = ds_m4(
            x,
            y,
            px_width=px_width,
            uppx=uppx,
            # log_scale=bool(uppx)
        )
        x = np.broadcast_to(x[:, None], y.shape)
        # x = (x + np.array([-0.43, 0, 0, 0.43])).flatten()
        x = (x + np.array([-0.5, 0, 0, 0.5])).flatten()
        y = y.flatten()
        return x, y
    def update_from_array(
        self,
@ -371,8 +396,7 @@ class FastAppendCurve(pg.GraphicsObject):
                self._in_ds = False
            elif should_ds and uppx and px_width > 1:
-
+                x_out, y_out = self.downsample(
                x_out, y_out = xy_downsample(
                    x_out,
                    y_out,
                    px_width,
@ -437,7 +461,7 @@ class FastAppendCurve(pg.GraphicsObject):
            )
            # if should_ds:
-            #     new_x, new_y = xy_downsample(
+            #     new_x, new_y = self.downsample(
            #         new_x,
            #         new_y,
            #         px_width,
--- a/piker/ui/_flows.py
+++ b/piker/ui/_flows.py
@ -48,18 +48,19 @@ from ..data._sharedmem import (
 )
 from .._profile import (
    pg_profile_enabled,
-    # ms_slower_then,
+    ms_slower_then,
 )
 from ._pathops import (
    gen_ohlc_qpath,
    ohlc_to_line,
    to_step_format,
 )
 from ._ohlc import (
    BarItems,
    gen_qpath,
 )
 from ._curve import (
    FastAppendCurve,
    # step_path_arrays_from_1d,
 )
 from ._compression import (
    # ohlc_flatten,
    ds_m4,
 )
 from ..log import get_logger
@ -113,241 +114,32 @@ def rowarr_to_path(
    )
-def render_baritems(
+def mk_ohlc_flat_copy(
-    flow: Flow,
+    ohlc_shm: ShmArray,
    graphics: BarItems,
    read: tuple[
        int, int, np.ndarray,
        int, int, np.ndarray,
    ],
    profiler: pg.debug.Profiler,
    **kwargs,
-) -> None:
+    # XXX: we bind this in currently..
    # x_basis: np.ndarray,
    # vr: Optional[slice] = None,
 ) -> tuple[np.ndarray, np.ndarray]:
    '''
-    Graphics management logic for a ``BarItems`` object.
+    Return flattened-non-copy view into an OHLC shm array.
    Mostly just logic to determine when and how to downsample an OHLC
    lines curve into a flattened line graphic and when to display one
    graphic or the other.
    TODO: this should likely be moved into some kind of better abstraction
    layer, if not a `Renderer` then something just above it?
    '''
-    (
+    ohlc = ohlc_shm._array[['open', 'high', 'low', 'close']]
-        xfirst, xlast, array,
+    # if vr:
-        ivl, ivr, in_view,
+    #     ohlc = ohlc[vr]
-    ) = read
+    #     x = x_basis[vr]
-    # if no source data renderer exists create one.
+    unstructured = rfn.structured_to_unstructured(
-    self = flow
+        ohlc,
-    r = self._src_r
+        copy=False,
    if not r:
        # OHLC bars path renderer
        r = self._src_r = Renderer(
            flow=self,
            # TODO: rename this to something with ohlc
            draw_path=gen_ohlc_qpath,
            last_read=read,
    )
-
+    # breakpoint()
-        ds_curve_r = Renderer(
+    y = unstructured.flatten()
-            flow=self,
+    # x = x_basis[:y.size]
-
+    return y
            # just swap in the flat view
            # data_t=lambda array: self.gy.array,
            last_read=read,
            draw_path=partial(
                rowarr_to_path,
                x_basis=None,
            ),
        )
        curve = FastAppendCurve(
            name='OHLC',
            color=graphics._color,
        )
        curve.hide()
        self.plot.addItem(curve)
        # baseline "line" downsampled OHLC curve that should
        # kick on only when we reach a certain uppx threshold.
        self._render_table[0] = (
            ds_curve_r,
            curve,
        )
    dsc_r, curve = self._render_table[0]
    # do checks for whether or not we require downsampling:
    # - if we're **not** downsampling then we simply want to
    #   render the bars graphics curve and update..
    # - if insteam we are in a downsamplig state then we to
    x_gt = 6
    uppx = curve.x_uppx()
    in_line = should_line = curve.isVisible()
    if (
        should_line
        and uppx < x_gt
    ):
        print('FLIPPING TO BARS')
        should_line = False
    elif (
        not should_line
        and uppx >= x_gt
    ):
        print('FLIPPING TO LINE')
        should_line = True
    profiler(f'ds logic complete line={should_line}')
    # do graphics updates
    if should_line:
        fields = ['open', 'high', 'low', 'close']
        if self.gy is None:
            # create a flattened view onto the OHLC array
            # which can be read as a line-style format
            shm = self.shm
            (
                self._iflat_first,
                self._iflat_last,
                self.gx,
                self.gy,
            ) = ohlc_to_line(
                shm,
                fields=fields,
            )
        # print(f'unstruct diff: {time.time() - start}')
        gy = self.gy
        # update flatted ohlc copy
        (
            iflat_first,
            iflat,
            ishm_last,
            ishm_first,
        ) = (
            self._iflat_first,
            self._iflat_last,
            self.shm._last.value,
            self.shm._first.value
        )
        # check for shm prepend updates since last read.
        if iflat_first != ishm_first:
            # write newly prepended data to flattened copy
            gy[
                ishm_first:iflat_first
            ] = rfn.structured_to_unstructured(
                self.shm._array[fields][ishm_first:iflat_first]
            )
            self._iflat_first = ishm_first
        to_update = rfn.structured_to_unstructured(
            self.shm._array[iflat:ishm_last][fields]
        )
        gy[iflat:ishm_last][:] = to_update
        profiler('updated ustruct OHLC data')
        # slice out up-to-last step contents
        y_flat = gy[ishm_first:ishm_last]
        x_flat = self.gx[ishm_first:ishm_last]
        # update local last-index tracking
        self._iflat_last = ishm_last
        # reshape to 1d for graphics rendering
        y = y_flat.reshape(-1)
        x = x_flat.reshape(-1)
        profiler('flattened ustruct OHLC data')
        # do all the same for only in-view data
        y_iv_flat = y_flat[ivl:ivr]
        x_iv_flat = x_flat[ivl:ivr]
        y_iv = y_iv_flat.reshape(-1)
        x_iv = x_iv_flat.reshape(-1)
        profiler('flattened ustruct in-view OHLC data')
        # pass into curve graphics processing
        curve.update_from_array(
            x,
            y,
            x_iv=x_iv,
            y_iv=y_iv,
            view_range=(ivl, ivr),  # hack
            profiler=profiler,
            # should_redraw=False,
            # NOTE: already passed through by display loop?
            # do_append=uppx < 16,
            **kwargs,
        )
        curve.show()
        profiler('updated ds curve')
    else:
        # render incremental or in-view update
        # and apply ouput (path) to graphics.
        path, last = r.render(
            read,
            only_in_view=True,
        )
        graphics.path = path
        graphics.draw_last(last)
        # NOTE: on appends we used to have to flip the coords
        # cache thought it doesn't seem to be required any more?
        # graphics.setCacheMode(QtWidgets.QGraphicsItem.NoCache)
        # graphics.setCacheMode(QtWidgets.QGraphicsItem.DeviceCoordinateCache)
        # graphics.prepareGeometryChange()
        graphics.update()
    if (
        not in_line
        and should_line
    ):
        # change to line graphic
        log.info(
            f'downsampling to line graphic {self.name}'
        )
        graphics.hide()
        # graphics.update()
        curve.show()
        curve.update()
    elif in_line and not should_line:
        log.info(f'showing bars graphic {self.name}')
        curve.hide()
        graphics.show()
        graphics.update()
    #   update our pre-downsample-ready data and then pass that
    #   new data the downsampler algo for incremental update.
        # graphics.update_from_array(
        #     array,
        #     in_view,
        #     view_range=(ivl, ivr) if use_vr else None,
        #     **kwargs,
        # )
        # generate and apply path to graphics obj
        # graphics.path, last = r.render(
        #     read,
        #     only_in_view=True,
        # )
        # graphics.draw_last(last)
 class Flow(msgspec.Struct):  # , frozen=True):
@ -565,30 +357,271 @@ class Flow(msgspec.Struct):  # , frozen=True):
        graphics = self.graphics
        if isinstance(graphics, BarItems):
-            render_baritems(
+
-                self,
+            # if no source data renderer exists create one.
-                graphics,
+            r = self._src_r
-                read,
+            if not r:
-                profiler,
+                # OHLC bars path renderer
                r = self._src_r = Renderer(
                    flow=self,
                    # TODO: rename this to something with ohlc
                    draw_path=gen_qpath,
                    last_read=read,
                )
                ds_curve_r = Renderer(
                    flow=self,
                    # just swap in the flat view
                    # data_t=lambda array: self.gy.array,
                    last_read=read,
                    draw_path=partial(
                        rowarr_to_path,
                        x_basis=None,
                    ),
                )
                curve = FastAppendCurve(
                    name='OHLC',
                    color=graphics._color,
                )
                curve.hide()
                self.plot.addItem(curve)
                # baseline "line" downsampled OHLC curve that should
                # kick on only when we reach a certain uppx threshold.
                self._render_table[0] = (
                    ds_curve_r,
                    curve,
                )
            dsc_r, curve = self._render_table[0]
            # do checks for whether or not we require downsampling:
            # - if we're **not** downsampling then we simply want to
            #   render the bars graphics curve and update..
            # - if insteam we are in a downsamplig state then we to
            x_gt = 6
            uppx = curve.x_uppx()
            in_line = should_line = curve.isVisible()
            if (
                should_line
                and uppx < x_gt
            ):
                print('FLIPPING TO BARS')
                should_line = False
            elif (
                not should_line
                and uppx >= x_gt
            ):
                print('FLIPPING TO LINE')
                should_line = True
            profiler(f'ds logic complete line={should_line}')
            # do graphics updates
            if should_line:
                fields = ['open', 'high', 'low', 'close']
                if self.gy is None:
                    # create a flattened view onto the OHLC array
                    # which can be read as a line-style format
                    shm = self.shm
                    # flat = self.gy = self.shm.unstruct_view(fields)
                    self.gy = self.shm.ustruct(fields)
                    first = self._iflat_first = self.shm._first.value
                    last = self._iflat_last = self.shm._last.value
                    # write pushed data to flattened copy
                    self.gy[first:last] = rfn.structured_to_unstructured(
                        self.shm.array[fields]
                    )
                    # generate an flat-interpolated x-domain
                    self.gx = (
                        np.broadcast_to(
                            shm._array['index'][:, None],
                            (
                                shm._array.size,
                                # 4,  # only ohlc
                                self.gy.shape[1],
                            ),
                        ) + np.array([-0.5, 0, 0, 0.5])
                    )
                    assert self.gy.any()
                # print(f'unstruct diff: {time.time() - start}')
                # profiler('read unstr view bars to line')
                # start = self.gy._first.value
                # update flatted ohlc copy
                (
                    iflat_first,
                    iflat,
                    ishm_last,
                    ishm_first,
                ) = (
                    self._iflat_first,
                    self._iflat_last,
                    self.shm._last.value,
                    self.shm._first.value
                )
                # check for shm prepend updates since last read.
                if iflat_first != ishm_first:
                    # write newly prepended data to flattened copy
                    self.gy[
                        ishm_first:iflat_first
                    ] = rfn.structured_to_unstructured(
                        self.shm._array[fields][ishm_first:iflat_first]
                    )
                    self._iflat_first = ishm_first
                #     # flat = self.gy = self.shm.unstruct_view(fields)
                #     self.gy = self.shm.ustruct(fields)
                #     # self._iflat_last = self.shm._last.value
                #     # self._iflat_first = self.shm._first.value
                #     # do an update for the most recent prepend
                #     # index
                #     iflat = ishm_first
                to_update = rfn.structured_to_unstructured(
                    self.shm._array[iflat:ishm_last][fields]
                )
                self.gy[iflat:ishm_last][:] = to_update
                profiler('updated ustruct OHLC data')
                # slice out up-to-last step contents
                y_flat = self.gy[ishm_first:ishm_last]
                x_flat = self.gx[ishm_first:ishm_last]
                # update local last-index tracking
                self._iflat_last = ishm_last
                # reshape to 1d for graphics rendering
                y = y_flat.reshape(-1)
                x = x_flat.reshape(-1)
                profiler('flattened ustruct OHLC data')
                # do all the same for only in-view data
                y_iv_flat = y_flat[ivl:ivr]
                x_iv_flat = x_flat[ivl:ivr]
                y_iv = y_iv_flat.reshape(-1)
                x_iv = x_iv_flat.reshape(-1)
                profiler('flattened ustruct in-view OHLC data')
                # legacy full-recompute-everytime method
                # x, y = ohlc_flatten(array)
                # x_iv, y_iv = ohlc_flatten(in_view)
                # profiler('flattened OHLC data')
                curve.update_from_array(
                    x,
                    y,
                    x_iv=x_iv,
                    y_iv=y_iv,
                    view_range=(ivl, ivr),  # hack
                    profiler=profiler,
                    # should_redraw=False,
                    # NOTE: already passed through by display loop?
                    # do_append=uppx < 16,
                    **kwargs,
                )
                curve.show()
                profiler('updated ds curve')
            else:
                # render incremental or in-view update
                # and apply ouput (path) to graphics.
                path, last = r.render(
                    read,
                    only_in_view=True,
                )
                graphics.path = path
                graphics.draw_last(last)
                # NOTE: on appends we used to have to flip the coords
                # cache thought it doesn't seem to be required any more?
                # graphics.setCacheMode(QtWidgets.QGraphicsItem.NoCache)
                # graphics.setCacheMode(QtWidgets.QGraphicsItem.DeviceCoordinateCache)
                # graphics.prepareGeometryChange()
                graphics.update()
            if (
                not in_line
                and should_line
            ):
                # change to line graphic
                log.info(
                    f'downsampling to line graphic {self.name}'
                )
                graphics.hide()
                # graphics.update()
                curve.show()
                curve.update()
            elif in_line and not should_line:
                log.info(f'showing bars graphic {self.name}')
                curve.hide()
                graphics.show()
                graphics.update()
            #   update our pre-downsample-ready data and then pass that
            #   new data the downsampler algo for incremental update.
                # graphics.update_from_array(
                #     array,
                #     in_view,
                #     view_range=(ivl, ivr) if use_vr else None,
                #     **kwargs,
                # )
                # generate and apply path to graphics obj
                # graphics.path, last = r.render(
                #     read,
                #     only_in_view=True,
                # )
                # graphics.draw_last(last)
        else:
            # ``FastAppendCurve`` case:
            array_key = array_key or self.name
            uppx = graphics.x_uppx()
-            profiler(f'read uppx {uppx}')
+            profiler('read uppx')
            if graphics._step_mode and self.gy is None:
                self._iflat_first = self.shm._first.value
                # create a flattened view onto the OHLC array
                # which can be read as a line-style format
                shm = self.shm
-                (
+
-                    self._iflat_first,
+                # fields = ['index', array_key]
-                    self.gx,
+                i = shm._array['index'].copy()
-                    self.gy,
+                out = shm._array[array_key].copy()
-                ) = to_step_format(
+
-                    shm,
+                self.gx = np.broadcast_to(
-                    array_key,
+                    i[:, None],
-                )
+                    (i.size, 2),
                ) + np.array([-0.5, 0.5])
                # self.gy = np.broadcast_to(
                #     out[:, None], (out.size, 2),
                # )
                self.gy = np.empty((len(out), 2), dtype=out.dtype)
                self.gy[:] = out[:, np.newaxis]
                # start y at origin level
                self.gy[0, 0] = 0
                profiler('generated step mode data')
            if graphics._step_mode:
@ -751,11 +784,42 @@ class Flow(msgspec.Struct):  # , frozen=True):
                    profiler=profiler,
                    **kwargs
                )
-                profiler('`graphics.update_from_array()` complete')
+                profiler(f'`graphics.update_from_array()` complete')
        return graphics
 def xy_downsample(
    x,
    y,
    px_width,
    uppx,
    x_spacer: float = 0.5,
 ) -> tuple[np.ndarray, np.ndarray]:
    # downsample whenever more then 1 pixels per datum can be shown.
    # always refresh data bounds until we get diffing
    # working properly, see above..
    bins, x, y = ds_m4(
        x,
        y,
        px_width=px_width,
        uppx=uppx,
        log_scale=bool(uppx)
    )
    # flatten output to 1d arrays suitable for path-graphics generation.
    x = np.broadcast_to(x[:, None], y.shape)
    x = (x + np.array(
        [-x_spacer, 0, 0, x_spacer]
    )).flatten()
    y = y.flatten()
    return x, y
 class Renderer(msgspec.Struct):
    flow: Flow
--- a/piker/ui/_ohlc.py
+++ b/piker/ui/_ohlc.py
@ -25,15 +25,17 @@ from typing import (
 import numpy as np
 import pyqtgraph as pg
 from numba import njit, float64, int64  # , optional
 from PyQt5 import QtCore, QtGui, QtWidgets
 from PyQt5.QtCore import QLineF, QPointF
 # from numba import types as ntypes
 # from ..data._source import numba_ohlc_dtype
 from .._profile import pg_profile_enabled, ms_slower_then
 from ._style import hcolor
 from ..log import get_logger
 from ._curve import FastAppendCurve
 from ._compression import ohlc_flatten
 from ._pathops import gen_ohlc_qpath
 if TYPE_CHECKING:
    from ._chart import LinkedSplits
@ -82,6 +84,119 @@ def bar_from_ohlc_row(
    return [hl, o, c]
@njit(
    # TODO: for now need to construct this manually for readonly arrays, see
    # https://github.com/numba/numba/issues/4511
    # ntypes.tuple((float64[:], float64[:], float64[:]))(
    #     numba_ohlc_dtype[::1],  # contiguous
    #     int64,
    #     optional(float64),
    # ),
    nogil=True
 )
 def path_arrays_from_ohlc(
    data: np.ndarray,
    start: int64,
    bar_gap: float64 = 0.43,
 ) -> np.ndarray:
    '''
    Generate an array of lines objects from input ohlc data.
    '''
    size = int(data.shape[0] * 6)
    x = np.zeros(
        # data,
        shape=size,
        dtype=float64,
    )
    y, c = x.copy(), x.copy()
    # TODO: report bug for assert @
    # /home/goodboy/repos/piker/env/lib/python3.8/site-packages/numba/core/typing/builtins.py:991
    for i, q in enumerate(data[start:], start):
        # TODO: ask numba why this doesn't work..
        # open, high, low, close, index = q[
        #     ['open', 'high', 'low', 'close', 'index']]
        open = q['open']
        high = q['high']
        low = q['low']
        close = q['close']
        index = float64(q['index'])
        istart = i * 6
        istop = istart + 6
        # x,y detail the 6 points which connect all vertexes of a ohlc bar
        x[istart:istop] = (
            index - bar_gap,
            index,
            index,
            index,
            index,
            index + bar_gap,
        )
        y[istart:istop] = (
            open,
            open,
            low,
            high,
            close,
            close,
        )
        # specifies that the first edge is never connected to the
        # prior bars last edge thus providing a small "gap"/"space"
        # between bars determined by ``bar_gap``.
        c[istart:istop] = (1, 1, 1, 1, 1, 0)
    return x, y, c
 def gen_qpath(
    data: np.ndarray,
    start: int = 0,  # XXX: do we need this?
    # 0.5 is no overlap between arms, 1.0 is full overlap
    w: float = 0.43,
    path: Optional[QtGui.QPainterPath] = None,
 ) -> QtGui.QPainterPath:
    path_was_none = path is None
    profiler = pg.debug.Profiler(
        msg='gen_qpath ohlc',
        disabled=not pg_profile_enabled(),
        ms_threshold=ms_slower_then,
    )
    x, y, c = path_arrays_from_ohlc(
        data,
        start,
        bar_gap=w,
    )
    profiler("generate stream with numba")
    # TODO: numba the internals of this!
    path = pg.functions.arrayToQPath(
        x,
        y,
        connect=c,
        path=path,
    )
    # avoid mem allocs if possible
    if path_was_none:
        path.reserve(path.capacity())
    profiler("generate path with arrayToQPath")
    return path
 class BarItems(pg.GraphicsObject):
    '''
    "Price range" bars graphics rendered from a OHLC sampled sequence.
@ -159,7 +274,7 @@ class BarItems(pg.GraphicsObject):
        '''
        hist, last = ohlc[:-1], ohlc[-1]
-        self.path = gen_ohlc_qpath(hist, start, self.w)
+        self.path = gen_qpath(hist, start, self.w)
        # save graphics for later reference and keep track
        # of current internal "last index"
--- a/piker/ui/_pathops.py
+++ b/piker/ui/_pathops.py
@ -1,256 +0,0 @@
 # piker: trading gear for hackers
 # Copyright (C) 2018-present  Tyler Goodlet (in stewardship of piker0)
 # This program is free software: you can redistribute it and/or modify
 # it under the terms of the GNU Affero General Public License as published by
 # the Free Software Foundation, either version 3 of the License, or
 # (at your option) any later version.
 # This program is distributed in the hope that it will be useful,
 # but WITHOUT ANY WARRANTY; without even the implied warranty of
 # MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 # GNU Affero General Public License for more details.
 # You should have received a copy of the GNU Affero General Public License
 # along with this program.  If not, see <https://www.gnu.org/licenses/>.
 """
 Super fast ``QPainterPath`` generation related operator routines.
 """
 from typing import (
    Optional,
 )
 import numpy as np
 from numpy.lib import recfunctions as rfn
 from numba import njit, float64, int64  # , optional
 import pyqtgraph as pg
 from PyQt5 import QtGui
 # from PyQt5.QtCore import QLineF, QPointF
 from ..data._sharedmem import (
    ShmArray,
 )
 from .._profile import pg_profile_enabled, ms_slower_then
 from ._compression import (
    # ohlc_flatten,
    ds_m4,
 )
 def xy_downsample(
    x,
    y,
    px_width,
    uppx,
    x_spacer: float = 0.5,
 ) -> tuple[np.ndarray, np.ndarray]:
    # downsample whenever more then 1 pixels per datum can be shown.
    # always refresh data bounds until we get diffing
    # working properly, see above..
    bins, x, y = ds_m4(
        x,
        y,
        px_width=px_width,
        uppx=uppx,
        # log_scale=bool(uppx)
    )
    # flatten output to 1d arrays suitable for path-graphics generation.
    x = np.broadcast_to(x[:, None], y.shape)
    x = (x + np.array(
        [-x_spacer, 0, 0, x_spacer]
    )).flatten()
    y = y.flatten()
    return x, y
@njit(
    # TODO: for now need to construct this manually for readonly arrays, see
    # https://github.com/numba/numba/issues/4511
    # ntypes.tuple((float64[:], float64[:], float64[:]))(
    #     numba_ohlc_dtype[::1],  # contiguous
    #     int64,
    #     optional(float64),
    # ),
    nogil=True
 )
 def path_arrays_from_ohlc(
    data: np.ndarray,
    start: int64,
    bar_gap: float64 = 0.43,
 ) -> np.ndarray:
    '''
    Generate an array of lines objects from input ohlc data.
    '''
    size = int(data.shape[0] * 6)
    x = np.zeros(
        # data,
        shape=size,
        dtype=float64,
    )
    y, c = x.copy(), x.copy()
    # TODO: report bug for assert @
    # /home/goodboy/repos/piker/env/lib/python3.8/site-packages/numba/core/typing/builtins.py:991
    for i, q in enumerate(data[start:], start):
        # TODO: ask numba why this doesn't work..
        # open, high, low, close, index = q[
        #     ['open', 'high', 'low', 'close', 'index']]
        open = q['open']
        high = q['high']
        low = q['low']
        close = q['close']
        index = float64(q['index'])
        istart = i * 6
        istop = istart + 6
        # x,y detail the 6 points which connect all vertexes of a ohlc bar
        x[istart:istop] = (
            index - bar_gap,
            index,
            index,
            index,
            index,
            index + bar_gap,
        )
        y[istart:istop] = (
            open,
            open,
            low,
            high,
            close,
            close,
        )
        # specifies that the first edge is never connected to the
        # prior bars last edge thus providing a small "gap"/"space"
        # between bars determined by ``bar_gap``.
        c[istart:istop] = (1, 1, 1, 1, 1, 0)
    return x, y, c
 def gen_ohlc_qpath(
    data: np.ndarray,
    start: int = 0,  # XXX: do we need this?
    # 0.5 is no overlap between arms, 1.0 is full overlap
    w: float = 0.43,
    path: Optional[QtGui.QPainterPath] = None,
 ) -> QtGui.QPainterPath:
    path_was_none = path is None
    profiler = pg.debug.Profiler(
        msg='gen_qpath ohlc',
        disabled=not pg_profile_enabled(),
        ms_threshold=ms_slower_then,
    )
    x, y, c = path_arrays_from_ohlc(
        data,
        start,
        bar_gap=w,
    )
    profiler("generate stream with numba")
    # TODO: numba the internals of this!
    path = pg.functions.arrayToQPath(
        x,
        y,
        connect=c,
        path=path,
    )
    # avoid mem allocs if possible
    if path_was_none:
        path.reserve(path.capacity())
    profiler("generate path with arrayToQPath")
    return path
 def ohlc_to_line(
    ohlc_shm: ShmArray,
    fields: list[str] = ['open', 'high', 'low', 'close']
 ) -> tuple[
    int,  # flattened first index
    int,  # flattened last index
    np.ndarray,
    np.ndarray,
 ]:
    '''
    Convert an input struct-array holding OHLC samples into a pair of
    flattened x, y arrays with the same size (datums wise) as the source
    data.
    '''
    y_out = ohlc_shm.ustruct(fields)
    first = ohlc_shm._first.value
    last = ohlc_shm._last.value
    # write pushed data to flattened copy
    y_out[first:last] = rfn.structured_to_unstructured(
        ohlc_shm.array[fields]
    )
    # generate an flat-interpolated x-domain
    x_out = (
        np.broadcast_to(
            ohlc_shm._array['index'][:, None],
            (
                ohlc_shm._array.size,
                # 4,  # only ohlc
                y_out.shape[1],
            ),
        ) + np.array([-0.5, 0, 0, 0.5])
    )
    assert y_out.any()
    return (
        first,
        last,
        x_out,
        y_out,
    )
 def to_step_format(
    shm: ShmArray,
    data_field: str,
    index_field: str = 'index',
 ) -> tuple[int, np.ndarray, np.ndarray]:
    '''
    Convert an input 1d shm array to a "step array" format
    for use by path graphics generation.
    '''
    first = shm._first.value
    i = shm._array['index'].copy()
    out = shm._array[data_field].copy()
    x_out = np.broadcast_to(
        i[:, None],
        (i.size, 2),
    ) + np.array([-0.5, 0.5])
    y_out = np.empty((len(out), 2), dtype=out.dtype)
    y_out[:] = out[:, np.newaxis]
    # start y at origin level
    y_out[0, 0] = 0
    return first, x_out, y_out