97 lines
3.8 KiB
Python
97 lines
3.8 KiB
Python
"""
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Manual wire routing tutorial: RenderPather an PathTool
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"""
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from collections.abc import Callable
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from masque import RenderPather, Library, Pattern, Port, layer_t, map_layers
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from masque.builder.tools import PathTool
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from masque.file.gdsii import writefile
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from basic_shapes import GDS_OPTS
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from pather import M1_WIDTH, V1_WIDTH, M2_WIDTH, map_layer, make_pad, make_via
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def main() -> None:
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#
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# To illustrate the advantages of using `RenderPather`, we use `PathTool` instead
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# of `BasicTool`. `PathTool` lacks some sophistication (e.g. no automatic transitions)
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# but when used with `RenderPather`, it can consolidate multiple routing steps into
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# a single `Path` shape.
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#
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# We'll try to nearly replicate the layout from the `Pather` tutorial; see `pather.py`
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# for more detailed descriptions of the individual pathing steps.
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#
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# First, we make a library and generate some of the same patterns as in the pather tutorial
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library = Library()
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library['pad'] = make_pad()
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library['v1_via'] = make_via(
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layer_top='M2',
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layer_via='V1',
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layer_bot='M1',
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width_top=M2_WIDTH,
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width_via=V1_WIDTH,
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width_bot=M1_WIDTH,
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ptype_bot='m1wire',
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ptype_top='m2wire',
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)
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# `PathTool` is more limited than `BasicTool`. It only generates one type of shape
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# (`Path`), so it only needs to know what layer to draw on, what width to draw with,
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# and what port type to present.
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M1_ptool = PathTool(layer='M1', width=M1_WIDTH, ptype='m1wire')
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M2_ptool = PathTool(layer='M2', width=M2_WIDTH, ptype='m2wire')
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rpather = RenderPather(tools=M2_ptool, library=library)
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# As in the pather tutorial, we make soem pads and labels...
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rpather.place('pad', offset=(18_000, 30_000), port_map={'wire_port': 'VCC'})
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rpather.place('pad', offset=(18_000, 60_000), port_map={'wire_port': 'GND'})
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rpather.pattern.label(layer='M2', string='VCC', offset=(18e3, 30e3))
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rpather.pattern.label(layer='M2', string='GND', offset=(18e3, 60e3))
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# ...and start routing the signals.
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rpather.path('VCC', ccw=False, length=6_000)
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rpather.path_to('VCC', ccw=None, x=0)
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rpather.path('GND', 0, 5_000)
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rpather.path_to('GND', None, x=rpather['VCC'].offset[0])
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# `PathTool` doesn't know how to transition betwen metal layers, so we have to
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# `plug` the via into the GND wire ourselves.
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rpather.plug('v1_via', {'GND': 'top'})
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rpather.retool(M1_ptool, keys=['GND'])
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rpather.mpath(['GND', 'VCC'], ccw=True, xmax=-10_000, spacing=5_000)
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# Same thing on the VCC wire when it goes down to M1.
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rpather.plug('v1_via', {'VCC': 'top'})
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rpather.retool(M1_ptool)
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rpather.mpath(['GND', 'VCC'], ccw=True, emax=50_000, spacing=1_200)
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rpather.mpath(['GND', 'VCC'], ccw=False, emin=1_000, spacing=1_200)
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rpather.mpath(['GND', 'VCC'], ccw=False, emin=2_000, spacing=4_500)
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# And again when VCC goes back up to M2.
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rpather.plug('v1_via', {'VCC': 'bottom'})
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rpather.retool(M2_ptool)
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rpather.mpath(['GND', 'VCC'], None, xmin=-28_000)
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# Finally, since PathTool has no conception of transitions, we can't
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# just ask it to transition to an 'm1wire' port at the end of the final VCC segment.
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# Instead, we have to calculate the via size ourselves, and adjust the final position
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# to account for it.
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via_size = abs(
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library['v1_via'].ports['top'].offset[0]
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- library['v1_via'].ports['bottom'].offset[0]
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)
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rpather.path_to('VCC', None, -50_000 + via_size)
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rpather.plug('v1_via', {'VCC': 'top'})
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rpather.render()
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library['RenderPather_and_PathTool'] = rpather.pattern
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# Convert from text-based layers to numeric layers for GDS, and output the file
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library.map_layers(map_layer)
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writefile(library, 'render_pather.gds', **GDS_OPTS)
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if __name__ == '__main__':
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main()
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