# # EDB: parametric via creation
#
# This example shows how you can use EDB to create a layout.
#
# First import the required Python packages.


import os
import tempfile

import numpy as np

import pyedb

# Create the EDB project.

temp_dir = tempfile.TemporaryDirectory(suffix=".ansys")
aedb_path = os.path.join(temp_dir.name, "parametric_via.aedb")

# ## Create stackup
#
# The ``StackupSimple`` class creates a stackup based on few inputs. This stackup
# is used later.
#
# Define a function to create the ground conductor.


def create_ground_planes(edb, layers):
    plane = edb.modeler.Shape("rectangle", pointA=["-3mm", "-3mm"], pointB=["3mm", "3mm"])
    for i in layers:
        edb.modeler.create_polygon(plane, i, net_name="GND")


# ## Create the EDB
#
# Create the EDB instance.
# If the path doesn't exist, PyEDB automatically generates a new AEDB folder.

# +
# Select EDB version (change it manually if needed, e.g. "2024.2")
edb_version = "2024.2"
print(f"EDB version: {edb_version}")

edb = pyedb.Edb(edbpath=aedb_path, edbversion=edb_version)
# -

# Insert the stackup layers.

layout_count = 12
diel_material_name = "FR4_epoxy"
diel_thickness = "0.15mm"
cond_thickness_outer = "0.05mm"
cond_thickness_inner = "0.017mm"
soldermask_thickness = "0.05mm"
trace_in_layer = "TOP"
trace_out_layer = "L10"
gvia_num = 10
gvia_angle = 30
edb.stackup.create_symmetric_stackup(
    layer_count=layout_count,
    inner_layer_thickness=cond_thickness_inner,
    outer_layer_thickness=cond_thickness_outer,
    soldermask_thickness=soldermask_thickness,
    dielectric_thickness=diel_thickness,
    dielectric_material=diel_material_name,
)

# ## Define parameters
#
# Define parameters to allow changes in the model dimesons. Parameters preceded by
# the ``$`` character have project-wide scope.
# Without the ``$`` prefix, the parameter scope is limited to the design.

# +
giva_angle_rad = gvia_angle / 180 * np.pi

edb["$via_hole_size"] = "0.3mm"
edb["$antipaddiam"] = "0.7mm"
edb["$paddiam"] = "0.5mm"
edb.add_design_variable("via_pitch", "1mm", is_parameter=True)
edb.add_design_variable("trace_in_width", "0.2mm", is_parameter=True)
edb.add_design_variable("trace_out_width", "0.1mm", is_parameter=True)
# -

# ## Define padstacks
#
# Create two padstck definitions, one for the ground via and one for the signal via.

edb.padstacks.create(
    padstackname="SVIA",
    holediam="$via_hole_size",
    antipaddiam="$antipaddiam",
    paddiam="$paddiam",
    start_layer=trace_in_layer,
    stop_layer=trace_out_layer,
)
edb.padstacks.create(padstackname="GVIA", holediam="0.3mm", antipaddiam="0.7mm", paddiam="0.5mm")

# Place the signal via.

edb.padstacks.place([0, 0], "SVIA", net_name="RF")

# Place the ground vias.

# +
gvia_num_side = gvia_num / 2

if gvia_num_side % 2:
    # Even number of ground vias on each side
    edb.padstacks.place(["via_pitch", 0], "GVIA", net_name="GND")
    edb.padstacks.place(["via_pitch*-1", 0], "GVIA", net_name="GND")
    for i in np.arange(1, gvia_num_side / 2):
        xloc = "{}*{}".format(np.cos(giva_angle_rad * i), "via_pitch")
        yloc = "{}*{}".format(np.sin(giva_angle_rad * i), "via_pitch")
        edb.padstacks.place([xloc, yloc], "GVIA", net_name="GND")
        edb.padstacks.place([xloc, yloc + "*-1"], "GVIA", net_name="GND")

        edb.padstacks.place([xloc + "*-1", yloc], "GVIA", net_name="GND")
        edb.padstacks.place([xloc + "*-1", yloc + "*-1"], "GVIA", net_name="GND")
else:
    # Odd number of ground vias on each side
    for i in np.arange(0, gvia_num_side / 2):
        xloc = "{}*{}".format(np.cos(giva_angle_rad * (i + 0.5)), "via_pitch")
        yloc = "{}*{}".format(np.sin(giva_angle_rad * (i + 0.5)), "via_pitch")
        edb.padstacks.place([xloc, yloc], "GVIA", net_name="GND")
        edb.padstacks.place([xloc, yloc + "*-1"], "GVIA", net_name="GND")

        edb.padstacks.place([xloc + "*-1", yloc], "GVIA", net_name="GND")
        edb.padstacks.place([xloc + "*-1", yloc + "*-1"], "GVIA", net_name="GND")
# -

# Draw the traces

# +
edb.modeler.create_trace(
    [[0, 0], [0, "-3mm"]],
    layer_name=trace_in_layer,
    net_name="RF",
    width="trace_in_width",
    start_cap_style="Flat",
    end_cap_style="Flat",
)

edb.modeler.create_trace(
    [[0, 0], [0, "3mm"]],
    layer_name=trace_out_layer,
    net_name="RF",
    width="trace_out_width",
    start_cap_style="Flat",
    end_cap_style="Flat",
)
# -

# Draw ground conductors

ground_layers = [i for i in edb.stackup.signal_layers.keys()]
ground_layers.remove(trace_in_layer)
ground_layers.remove(trace_out_layer)
create_ground_planes(edb=edb, layers=ground_layers)

# Display the layout

edb.stackup.plot(plot_definitions=["GVIA", "SVIA"])

# Save EDB and close the EDB.

edb.save_edb()
edb.close_edb()
print("aedb Saved in {}".format(aedb_path))

# Clean up the temporary directory.

temp_dir.cleanup()