mirror of https://github.com/VLSIDA/OpenRAM.git
921 lines
47 KiB
Python
921 lines
47 KiB
Python
# See LICENSE for licensing information.
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#
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#Copyright (c) 2016-2019 Regents of the University of California and The Board
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#of Regents for the Oklahoma Agricultural and Mechanical College
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#(acting for and on behalf of Oklahoma State University)
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#All rights reserved.
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#
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import contact
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import design
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import debug
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from tech import drc, parameter, spice
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from vector import vector
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from ptx import ptx
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from globals import OPTS
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import logical_effort
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class pbitcell(design.design):
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"""
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This module implements a parametrically sized multi-port bitcell,
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with a variable number of read/write, write, and read ports
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"""
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def __init__(self, name, replica_bitcell=False):
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self.num_rw_ports = OPTS.num_rw_ports
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self.num_w_ports = OPTS.num_w_ports
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self.num_r_ports = OPTS.num_r_ports
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self.total_ports = self.num_rw_ports + self.num_w_ports + self.num_r_ports
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self.replica_bitcell = replica_bitcell
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design.design.__init__(self, name)
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debug.info(2, "create a multi-port bitcell with {0} rw ports, {1} w ports and {2} r ports".format(self.num_rw_ports,
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self.num_w_ports,
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self.num_r_ports))
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self.create_netlist()
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# We must always create the bitcell layout because some transistor sizes in the other netlists depend on it
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self.create_layout()
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def create_netlist(self):
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self.add_pins()
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self.add_modules()
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self.create_storage()
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if(self.num_rw_ports > 0):
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self.create_readwrite_ports()
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if(self.num_w_ports > 0):
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self.create_write_ports()
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if(self.num_r_ports > 0):
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self.create_read_ports()
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def create_layout(self):
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self.calculate_spacing()
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self.calculate_postions()
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self.place_storage()
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self.route_storage()
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self.route_rails()
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if(self.num_rw_ports > 0):
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self.place_readwrite_ports()
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self.route_readwrite_access()
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if(self.num_w_ports > 0):
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self.place_write_ports()
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self.route_write_access()
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if(self.num_r_ports > 0):
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self.place_read_ports()
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self.route_read_access()
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self.extend_well()
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self.route_wordlines()
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self.route_bitlines()
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self.route_supply()
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if self.replica_bitcell:
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self.route_rbc_short()
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# in netlist_only mode, calling offset_all_coordinates or translate_all will not be possible
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# this function is not needed to calculate the dimensions of pbitcell in netlist_only mode though
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if not OPTS.netlist_only:
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self.offset_all_coordinates()
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gnd_overlap = vector(0, 0.5*contact.well.width)
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self.translate_all(gnd_overlap)
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def add_pins(self):
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""" add pins and set names for bitlines and wordlines """
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self.rw_bl_names = []
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self.rw_br_names = []
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self.w_bl_names = []
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self.w_br_names = []
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self.r_bl_names = []
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self.r_br_names = []
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self.rw_wl_names = []
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self.w_wl_names = []
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self.r_wl_names = []
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port = 0
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for k in range(self.num_rw_ports):
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self.add_pin("bl{}".format(port), "OUTPUT")
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self.add_pin("br{}".format(port), "OUTPUT")
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self.rw_bl_names.append("bl{}".format(port))
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self.rw_br_names.append("br{}".format(port))
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port += 1
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for k in range(self.num_w_ports):
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self.add_pin("bl{}".format(port), "INPUT")
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self.add_pin("br{}".format(port), "INPUT")
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self.w_bl_names.append("bl{}".format(port))
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self.w_br_names.append("br{}".format(port))
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port += 1
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for k in range(self.num_r_ports):
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self.add_pin("bl{}".format(port), "OUTPUT")
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self.add_pin("br{}".format(port), "OUTPUT")
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self.r_bl_names.append("bl{}".format(port))
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self.r_br_names.append("br{}".format(port))
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port += 1
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port = 0
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for k in range(self.num_rw_ports):
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self.add_pin("wl{}".format(port), "INPUT")
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self.rw_wl_names.append("wl{}".format(port))
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port += 1
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for k in range(self.num_w_ports):
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self.add_pin("wl{}".format(port), "INPUT")
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self.w_wl_names.append("wl{}".format(port))
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port += 1
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for k in range(self.num_r_ports):
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self.add_pin("wl{}".format(port), "INPUT")
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self.r_wl_names.append("wl{}".format(port))
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port += 1
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self.add_pin("vdd", "POWER")
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self.add_pin("gnd", "GROUND")
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# if this is a replica bitcell, replace the instances of Q_bar with vdd
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if self.replica_bitcell:
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self.Q_bar = "vdd"
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else:
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self.Q_bar = "Q_bar"
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self.Q = "Q"
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self.storage_nets = [self.Q, self.Q_bar]
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def add_modules(self):
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""" Determine size of transistors and add ptx modules """
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# if there are any read/write ports, then the inverter nmos is sized based the number of read/write ports
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if(self.num_rw_ports > 0):
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inverter_nmos_width = self.num_rw_ports*parameter["6T_inv_nmos_size"]
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inverter_pmos_width = parameter["6T_inv_pmos_size"]
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readwrite_nmos_width = parameter["6T_access_size"]
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write_nmos_width = parameter["6T_access_size"]
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read_nmos_width = 2*parameter["6T_inv_pmos_size"]
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# if there are no read/write ports, then the inverter nmos is statically sized for the dual port case
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else:
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inverter_nmos_width = 2*parameter["6T_inv_pmos_size"]
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inverter_pmos_width = parameter["6T_inv_pmos_size"]
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readwrite_nmos_width = parameter["6T_access_size"]
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write_nmos_width = parameter["6T_access_size"]
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read_nmos_width = 2*parameter["6T_inv_pmos_size"]
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# create ptx for inverter transistors
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self.inverter_nmos = ptx(width=inverter_nmos_width,
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tx_type="nmos")
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self.add_mod(self.inverter_nmos)
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self.inverter_pmos = ptx(width=inverter_pmos_width,
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tx_type="pmos")
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self.add_mod(self.inverter_pmos)
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# create ptx for readwrite transitors
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self.readwrite_nmos = ptx(width=readwrite_nmos_width,
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tx_type="nmos")
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self.add_mod(self.readwrite_nmos)
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# create ptx for write transitors
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self.write_nmos = ptx(width=write_nmos_width,
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tx_type="nmos")
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self.add_mod(self.write_nmos)
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# create ptx for read transistors
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self.read_nmos = ptx(width=read_nmos_width,
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tx_type="nmos")
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self.add_mod(self.read_nmos)
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def calculate_spacing(self):
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""" Calculate transistor spacings """
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# calculate metal contact extensions over transistor active
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readwrite_nmos_contact_extension = 0.5*(self.readwrite_nmos.active_contact.height - self.readwrite_nmos.active_height)
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write_nmos_contact_extension = 0.5*(self.write_nmos.active_contact.height - self.write_nmos.active_height)
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read_nmos_contact_extension = 0.5*(self.read_nmos.active_contact.height - self.read_nmos.active_height)
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max_contact_extension = max(readwrite_nmos_contact_extension, write_nmos_contact_extension, read_nmos_contact_extension)
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# y-offset for the access transistor's gate contact
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self.gate_contact_yoffset = max_contact_extension + self.m2_space + 0.5*max(contact.poly.height, contact.m1m2.height)
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# y-position of access transistors
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self.port_ypos = self.m1_space + 0.5*contact.m1m2.height + self.gate_contact_yoffset
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# y-position of inverter nmos
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self.inverter_nmos_ypos = self.port_ypos
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# spacing between ports (same for read/write and write ports)
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self.bitline_offset = -0.5*self.readwrite_nmos.active_width + 0.5*contact.m1m2.height + self.m2_space + self.m2_width
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m2_constraint = self.bitline_offset + self.m2_space + 0.5*contact.m1m2.height - 0.5*self.readwrite_nmos.active_width
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self.write_port_spacing = max(self.active_space, self.m1_space, m2_constraint)
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self.read_port_spacing = self.bitline_offset + self.m2_space
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# spacing between cross coupled inverters
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self.inverter_to_inverter_spacing = contact.poly.width + self.m1_space
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# calculations related to inverter connections
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inverter_pmos_contact_extension = 0.5*(self.inverter_pmos.active_contact.height - self.inverter_pmos.active_height)
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inverter_nmos_contact_extension = 0.5*(self.inverter_nmos.active_contact.height - self.inverter_nmos.active_height)
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self.inverter_gap = max(self.poly_to_active, self.m1_space + inverter_nmos_contact_extension) \
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+ self.poly_to_polycontact + 2*contact.poly.width \
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+ self.m1_space + inverter_pmos_contact_extension
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self.cross_couple_lower_ypos = self.inverter_nmos_ypos + self.inverter_nmos.active_height \
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+ max(self.poly_to_active, self.m1_space + inverter_nmos_contact_extension) \
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+ 0.5*contact.poly.width
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self.cross_couple_upper_ypos = self.inverter_nmos_ypos + self.inverter_nmos.active_height \
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+ max(self.poly_to_active, self.m1_space + inverter_nmos_contact_extension) \
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+ self.poly_to_polycontact \
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+ 1.5*contact.poly.width
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# spacing between wordlines (and gnd)
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self.rowline_spacing = self.m1_space + contact.m1m2.width
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self.rowline_offset = -0.5*self.m1_width
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# spacing for vdd
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implant_constraint = max(inverter_pmos_contact_extension, 0) + 2*self.implant_enclose_active + 0.5*(contact.well.width - self.m1_width)
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metal1_constraint = max(inverter_pmos_contact_extension, 0) + self.m1_space
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self.vdd_offset = max(implant_constraint, metal1_constraint) + 0.5*self.m1_width
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# read port dimensions
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width_reduction = self.read_nmos.active_width - self.read_nmos.get_pin("D").cx()
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self.read_port_width = 2*self.read_nmos.active_width - 2*width_reduction
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def calculate_postions(self):
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""" Calculate positions that describe the edges and dimensions of the cell """
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self.botmost_ypos = -0.5*self.m1_width - self.total_ports*self.rowline_spacing
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self.topmost_ypos = self.inverter_nmos_ypos + self.inverter_nmos.active_height + self.inverter_gap + self.inverter_pmos.active_height + self.vdd_offset
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self.leftmost_xpos = -0.5*self.inverter_to_inverter_spacing - self.inverter_nmos.active_width \
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- self.num_rw_ports*(self.readwrite_nmos.active_width + self.write_port_spacing) \
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- self.num_w_ports*(self.write_nmos.active_width + self.write_port_spacing) \
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- self.num_r_ports*(self.read_port_width + self.read_port_spacing) \
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- self.bitline_offset - 0.5*contact.m1m2.width
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self.width = -2*self.leftmost_xpos
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self.height = self.topmost_ypos - self.botmost_ypos
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self.center_ypos = 0.5*(self.topmost_ypos + self.botmost_ypos)
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def create_storage(self):
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"""
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Creates the crossed coupled inverters that act as storage for the bitcell.
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The stored value of the cell is denoted as "Q", and the inverted value as "Q_bar".
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"""
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# create active for nmos
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self.inverter_nmos_left = self.add_inst(name="inverter_nmos_left",
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mod=self.inverter_nmos)
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self.connect_inst([self.Q, self.Q_bar, "gnd", "gnd"])
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self.inverter_nmos_right = self.add_inst(name="inverter_nmos_right",
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mod=self.inverter_nmos)
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self.connect_inst(["gnd", self.Q, self.Q_bar, "gnd"])
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# create active for pmos
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self.inverter_pmos_left = self.add_inst(name="inverter_pmos_left",
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mod=self.inverter_pmos)
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self.connect_inst([self.Q, self.Q_bar, "vdd", "vdd"])
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self.inverter_pmos_right = self.add_inst(name="inverter_pmos_right",
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mod=self.inverter_pmos)
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self.connect_inst(["vdd", self.Q, self.Q_bar, "vdd"])
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def place_storage(self):
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""" Places the transistors for the crossed coupled inverters in the bitcell """
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# calculate transistor offsets
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left_inverter_xpos = -0.5*self.inverter_to_inverter_spacing - self.inverter_nmos.active_width
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right_inverter_xpos = 0.5*self.inverter_to_inverter_spacing
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inverter_pmos_ypos = self.inverter_nmos_ypos + self.inverter_nmos.active_height + self.inverter_gap
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# create active for nmos
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self.inverter_nmos_left.place([left_inverter_xpos, self.inverter_nmos_ypos])
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self.inverter_nmos_right.place([right_inverter_xpos, self.inverter_nmos_ypos])
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# create active for pmos
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self.inverter_pmos_left.place([left_inverter_xpos, inverter_pmos_ypos])
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self.inverter_pmos_right.place([right_inverter_xpos, inverter_pmos_ypos])
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# update furthest left and right transistor edges (this will propagate to further transistor offset calculations)
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self.left_building_edge = left_inverter_xpos
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self.right_building_edge = right_inverter_xpos + self.inverter_nmos.active_width
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def route_storage(self):
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""" Routes inputs and outputs of inverters to cross couple them """
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# connect input (gate) of inverters
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self.add_path("poly", [self.inverter_nmos_left.get_pin("G").uc(), self.inverter_pmos_left.get_pin("G").bc()])
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self.add_path("poly", [self.inverter_nmos_right.get_pin("G").uc(), self.inverter_pmos_right.get_pin("G").bc()])
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# connect output (drain/source) of inverters
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self.add_path("metal1",
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[self.inverter_nmos_left.get_pin("D").uc(), self.inverter_pmos_left.get_pin("D").bc()],
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width=contact.active.second_layer_width)
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self.add_path("metal1",
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[self.inverter_nmos_right.get_pin("S").uc(), self.inverter_pmos_right.get_pin("S").bc()],
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width=contact.active.second_layer_width)
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# add contacts to connect gate poly to drain/source metal1 (to connect Q to Q_bar)
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contact_offset_left = vector(self.inverter_nmos_left.get_pin("D").rc().x + 0.5*contact.poly.height, self.cross_couple_upper_ypos)
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self.add_via_center(layers=("poly", "contact", "metal1"),
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offset=contact_offset_left,
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directions=("H","H"))
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contact_offset_right = vector(self.inverter_nmos_right.get_pin("S").lc().x - 0.5*contact.poly.height, self.cross_couple_lower_ypos)
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self.add_via_center(layers=("poly", "contact", "metal1"),
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offset=contact_offset_right,
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directions=("H","H"))
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# connect contacts to gate poly (cross couple connections)
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gate_offset_right = vector(self.inverter_nmos_right.get_pin("G").lc().x, contact_offset_left.y)
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self.add_path("poly", [contact_offset_left, gate_offset_right])
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gate_offset_left = vector(self.inverter_nmos_left.get_pin("G").rc().x, contact_offset_right.y)
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self.add_path("poly", [contact_offset_right, gate_offset_left])
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def route_rails(self):
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""" Adds gnd and vdd rails and connects them to the inverters """
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# Add rails for vdd and gnd
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gnd_ypos = self.rowline_offset - self.total_ports*self.rowline_spacing
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self.gnd_position = vector(0, gnd_ypos)
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self.add_rect_center(layer="metal1",
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offset=self.gnd_position,
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width=self.width,
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height=self.m1_width)
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self.add_power_pin("gnd", vector(0,gnd_ypos))
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vdd_ypos = self.inverter_nmos_ypos + self.inverter_nmos.active_height + self.inverter_gap + self.inverter_pmos.active_height + self.vdd_offset
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self.vdd_position = vector(0, vdd_ypos)
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self.add_rect_center(layer="metal1",
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offset=self.vdd_position,
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width=self.width,
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height=self.m1_width)
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self.add_power_pin("vdd", vector(0,vdd_ypos))
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def create_readwrite_ports(self):
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"""
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Creates read/write ports to the bit cell. A differential pair of transistor can both read and write, like in a 6T cell.
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A read or write is enabled by setting a Read-Write-Wordline (RWWL) high, subsequently turning on the transistor.
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The transistor is connected between a Read-Write-Bitline (RWBL) and the storage component of the cell (Q).
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In a write operation, driving RWBL high or low sets the value of the cell.
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In a read operation, RWBL is precharged, then is either remains high or is discharged depending on the value of the cell.
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This is a differential design, so each write port has a mirrored port that connects RWBR to Q_bar.
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"""
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# define read/write transistor variables as empty arrays based on the number of read/write ports
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self.readwrite_nmos_left = [None] * self.num_rw_ports
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self.readwrite_nmos_right = [None] * self.num_rw_ports
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# iterate over the number of read/write ports
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for k in range(0,self.num_rw_ports):
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# add read/write transistors
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self.readwrite_nmos_left[k] = self.add_inst(name="readwrite_nmos_left{}".format(k),
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mod=self.readwrite_nmos)
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self.connect_inst([self.rw_bl_names[k], self.rw_wl_names[k], self.Q, "gnd"])
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self.readwrite_nmos_right[k] = self.add_inst(name="readwrite_nmos_right{}".format(k),
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mod=self.readwrite_nmos)
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self.connect_inst([self.Q_bar, self.rw_wl_names[k], self.rw_br_names[k], "gnd"])
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def place_readwrite_ports(self):
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""" Places read/write ports in the bit cell """
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# define read/write transistor variables as empty arrays based on the number of read/write ports
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self.rwwl_positions = [None] * self.num_rw_ports
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self.rwbl_positions = [None] * self.num_rw_ports
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self.rwbr_positions = [None] * self.num_rw_ports
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# iterate over the number of read/write ports
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for k in range(0,self.num_rw_ports):
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# calculate read/write transistor offsets
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left_readwrite_transistor_xpos = self.left_building_edge \
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- (k+1)*self.write_port_spacing \
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- (k+1)*self.readwrite_nmos.active_width
|
|
|
|
right_readwrite_transistor_xpos = self.right_building_edge \
|
|
+ (k+1)*self.write_port_spacing \
|
|
+ k*self.readwrite_nmos.active_width
|
|
|
|
# place read/write transistors
|
|
self.readwrite_nmos_left[k].place(offset=[left_readwrite_transistor_xpos, self.port_ypos])
|
|
|
|
self.readwrite_nmos_right[k].place(offset=[right_readwrite_transistor_xpos, self.port_ypos])
|
|
|
|
# add pin for RWWL
|
|
rwwl_ypos = self.rowline_offset - k*self.rowline_spacing
|
|
self.rwwl_positions[k] = vector(0, rwwl_ypos)
|
|
self.add_layout_pin_rect_center(text=self.rw_wl_names[k],
|
|
layer="metal1",
|
|
offset=self.rwwl_positions[k],
|
|
width=self.width,
|
|
height=self.m1_width)
|
|
|
|
# add pins for RWBL and RWBR
|
|
rwbl_xpos = left_readwrite_transistor_xpos - self.bitline_offset + 0.5*self.m2_width
|
|
self.rwbl_positions[k] = vector(rwbl_xpos, self.center_ypos)
|
|
self.add_layout_pin_rect_center(text=self.rw_bl_names[k],
|
|
layer="metal2",
|
|
offset=self.rwbl_positions[k],
|
|
height=self.height)
|
|
|
|
rwbr_xpos = right_readwrite_transistor_xpos + self.readwrite_nmos.active_width + self.bitline_offset - 0.5*self.m2_width
|
|
self.rwbr_positions[k] = vector(rwbr_xpos, self.center_ypos)
|
|
self.add_layout_pin_rect_center(text=self.rw_br_names[k],
|
|
layer="metal2",
|
|
offset=self.rwbr_positions[k],
|
|
height=self.height)
|
|
|
|
# update furthest left and right transistor edges
|
|
self.left_building_edge = left_readwrite_transistor_xpos
|
|
self.right_building_edge = right_readwrite_transistor_xpos + self.readwrite_nmos.active_width
|
|
|
|
def create_write_ports(self):
|
|
"""
|
|
Creates write ports in the bit cell. A differential pair of transistors can write only.
|
|
A write is enabled by setting a Write-Rowline (WWL) high, subsequently turning on the transistor.
|
|
The transistor is connected between a Write-Bitline (WBL) and the storage component of the cell (Q).
|
|
In a write operation, driving WBL high or low sets the value of the cell.
|
|
This is a differential design, so each write port has a mirrored port that connects WBR to Q_bar.
|
|
"""
|
|
# define write transistor variables as empty arrays based on the number of write ports
|
|
self.write_nmos_left = [None] * self.num_w_ports
|
|
self.write_nmos_right = [None] * self.num_w_ports
|
|
|
|
# iterate over the number of write ports
|
|
for k in range(0,self.num_w_ports):
|
|
# add write transistors
|
|
self.write_nmos_left[k] = self.add_inst(name="write_nmos_left{}".format(k),
|
|
mod=self.write_nmos)
|
|
self.connect_inst([self.w_bl_names[k], self.w_wl_names[k], self.Q, "gnd"])
|
|
|
|
self.write_nmos_right[k] = self.add_inst(name="write_nmos_right{}".format(k),
|
|
mod=self.write_nmos)
|
|
self.connect_inst([self.Q_bar, self.w_wl_names[k], self.w_br_names[k], "gnd"])
|
|
|
|
def place_write_ports(self):
|
|
""" Places write ports in the bit cell """
|
|
# define write transistor variables as empty arrays based on the number of write ports
|
|
self.wwl_positions = [None] * self.num_w_ports
|
|
self.wbl_positions = [None] * self.num_w_ports
|
|
self.wbr_positions = [None] * self.num_w_ports
|
|
|
|
# iterate over the number of write ports
|
|
for k in range(0,self.num_w_ports):
|
|
# Add transistors
|
|
# calculate write transistor offsets
|
|
left_write_transistor_xpos = self.left_building_edge \
|
|
- (k+1)*self.write_port_spacing \
|
|
- (k+1)*self.write_nmos.active_width
|
|
|
|
right_write_transistor_xpos = self.right_building_edge \
|
|
+ (k+1)*self.write_port_spacing \
|
|
+ k*self.write_nmos.active_width
|
|
|
|
# add write transistors
|
|
self.write_nmos_left[k].place(offset=[left_write_transistor_xpos, self.port_ypos])
|
|
|
|
self.write_nmos_right[k].place(offset=[right_write_transistor_xpos, self.port_ypos])
|
|
|
|
# add pin for WWL
|
|
wwl_ypos = rwwl_ypos = self.rowline_offset - self.num_rw_ports*self.rowline_spacing - k*self.rowline_spacing
|
|
self.wwl_positions[k] = vector(0, wwl_ypos)
|
|
self.add_layout_pin_rect_center(text=self.w_wl_names[k],
|
|
layer="metal1",
|
|
offset=self.wwl_positions[k],
|
|
width=self.width,
|
|
height=self.m1_width)
|
|
|
|
# add pins for WBL and WBR
|
|
wbl_xpos = left_write_transistor_xpos - self.bitline_offset + 0.5*self.m2_width
|
|
self.wbl_positions[k] = vector(wbl_xpos, self.center_ypos)
|
|
self.add_layout_pin_rect_center(text=self.w_bl_names[k],
|
|
layer="metal2",
|
|
offset=self.wbl_positions[k],
|
|
height=self.height)
|
|
|
|
wbr_xpos = right_write_transistor_xpos + self.write_nmos.active_width + self.bitline_offset - 0.5*self.m2_width
|
|
self.wbr_positions[k] = vector(wbr_xpos, self.center_ypos)
|
|
self.add_layout_pin_rect_center(text=self.w_br_names[k],
|
|
layer="metal2",
|
|
offset=self.wbr_positions[k],
|
|
height=self.height)
|
|
|
|
# update furthest left and right transistor edges
|
|
self.left_building_edge = left_write_transistor_xpos
|
|
self.right_building_edge = right_write_transistor_xpos + self.write_nmos.active_width
|
|
|
|
def create_read_ports(self):
|
|
"""
|
|
Creates read ports in the bit cell. A differential pair of ports can read only.
|
|
Two transistors function as a read port, denoted as the "read transistor" and the "read-access transistor".
|
|
The read transistor is connected to RWL (gate), RBL (drain), and the read-access transistor (source).
|
|
The read-access transistor is connected to Q_bar (gate), gnd (source), and the read transistor (drain).
|
|
A read is enabled by setting a Read-Rowline (RWL) high, subsequently turning on the read transistor.
|
|
The Read-Bitline (RBL) is precharged to high, and when the value of Q_bar is high, the read-access transistor
|
|
is turned on, creating a connection between RBL and gnd. RBL subsequently discharges allowing for a differential read
|
|
using sense amps. This is a differential design, so each read port has a mirrored port that connects RBL_bar to Q.
|
|
"""
|
|
|
|
# define read transistor variables as empty arrays based on the number of read ports
|
|
self.read_nmos_left = [None] * self.num_r_ports
|
|
self.read_nmos_right = [None] * self.num_r_ports
|
|
self.read_access_nmos_left = [None] * self.num_r_ports
|
|
self.read_access_nmos_right = [None] * self.num_r_ports
|
|
|
|
# iterate over the number of read ports
|
|
for k in range(0,self.num_r_ports):
|
|
# add read-access transistors
|
|
self.read_access_nmos_left[k] = self.add_inst(name="read_access_nmos_left{}".format(k),
|
|
mod=self.read_nmos)
|
|
self.connect_inst(["RA_to_R_left{}".format(k), self.Q_bar, "gnd", "gnd"])
|
|
|
|
self.read_access_nmos_right[k] = self.add_inst(name="read_access_nmos_right{}".format(k),
|
|
mod=self.read_nmos)
|
|
self.connect_inst(["gnd", self.Q, "RA_to_R_right{}".format(k), "gnd"])
|
|
|
|
# add read transistors
|
|
self.read_nmos_left[k] = self.add_inst(name="read_nmos_left{}".format(k),
|
|
mod=self.read_nmos)
|
|
self.connect_inst([self.r_bl_names[k], self.r_wl_names[k], "RA_to_R_left{}".format(k), "gnd"])
|
|
|
|
self.read_nmos_right[k] = self.add_inst(name="read_nmos_right{}".format(k),
|
|
mod=self.read_nmos)
|
|
self.connect_inst(["RA_to_R_right{}".format(k), self.r_wl_names[k], self.r_br_names[k], "gnd"])
|
|
|
|
def place_read_ports(self):
|
|
""" Places the read ports in the bit cell """
|
|
# define read transistor variables as empty arrays based on the number of read ports
|
|
self.rwl_positions = [None] * self.num_r_ports
|
|
self.rbl_positions = [None] * self.num_r_ports
|
|
self.rbr_positions = [None] * self.num_r_ports
|
|
|
|
# calculate offset to overlap the drain of the read-access transistor with the source of the read transistor
|
|
overlap_offset = self.read_nmos.get_pin("D").cx() - self.read_nmos.get_pin("S").cx()
|
|
|
|
# iterate over the number of read ports
|
|
for k in range(0,self.num_r_ports):
|
|
# calculate transistor offsets
|
|
left_read_transistor_xpos = self.left_building_edge \
|
|
- (k+1)*self.read_port_spacing \
|
|
- (k+1)*self.read_port_width
|
|
|
|
right_read_transistor_xpos = self.right_building_edge \
|
|
+ (k+1)*self.read_port_spacing \
|
|
+ k*self.read_port_width
|
|
|
|
# add read-access transistors
|
|
self.read_access_nmos_left[k].place(offset=[left_read_transistor_xpos+overlap_offset, self.port_ypos])
|
|
|
|
self.read_access_nmos_right[k].place(offset=[right_read_transistor_xpos, self.port_ypos])
|
|
|
|
# add read transistors
|
|
self.read_nmos_left[k].place(offset=[left_read_transistor_xpos, self.port_ypos])
|
|
|
|
self.read_nmos_right[k].place(offset=[right_read_transistor_xpos+overlap_offset, self.port_ypos])
|
|
|
|
# add pin for RWL
|
|
rwl_ypos = rwwl_ypos = self.rowline_offset - self.num_rw_ports*self.rowline_spacing - self.num_w_ports*self.rowline_spacing - k*self.rowline_spacing
|
|
self.rwl_positions[k] = vector(0, rwl_ypos)
|
|
self.add_layout_pin_rect_center(text=self.r_wl_names[k],
|
|
layer="metal1",
|
|
offset=self.rwl_positions[k],
|
|
width=self.width,
|
|
height=self.m1_width)
|
|
|
|
# add pins for RBL and RBR
|
|
rbl_xpos = left_read_transistor_xpos - self.bitline_offset + 0.5*self.m2_width
|
|
self.rbl_positions[k] = vector(rbl_xpos, self.center_ypos)
|
|
self.add_layout_pin_rect_center(text=self.r_bl_names[k],
|
|
layer="metal2",
|
|
offset=self.rbl_positions[k],
|
|
height=self.height)
|
|
|
|
rbr_xpos = right_read_transistor_xpos + self.read_port_width + self.bitline_offset - 0.5*self.m2_width
|
|
self.rbr_positions[k] = vector(rbr_xpos, self.center_ypos)
|
|
self.add_layout_pin_rect_center(text=self.r_br_names[k],
|
|
layer="metal2",
|
|
offset=self.rbr_positions[k],
|
|
height=self.height)
|
|
|
|
def route_wordlines(self):
|
|
""" Routes gate of transistors to their respective wordlines """
|
|
port_transistors = []
|
|
for k in range(self.num_rw_ports):
|
|
port_transistors.append(self.readwrite_nmos_left[k])
|
|
port_transistors.append(self.readwrite_nmos_right[k])
|
|
for k in range(self.num_w_ports):
|
|
port_transistors.append(self.write_nmos_left[k])
|
|
port_transistors.append(self.write_nmos_right[k])
|
|
for k in range(self.num_r_ports):
|
|
port_transistors.append(self.read_nmos_left[k])
|
|
port_transistors.append(self.read_nmos_right[k])
|
|
|
|
wl_positions = []
|
|
for k in range(self.num_rw_ports):
|
|
wl_positions.append(self.rwwl_positions[k])
|
|
wl_positions.append(self.rwwl_positions[k])
|
|
for k in range(self.num_w_ports):
|
|
wl_positions.append(self.wwl_positions[k])
|
|
wl_positions.append(self.wwl_positions[k])
|
|
for k in range(self.num_r_ports):
|
|
wl_positions.append(self.rwl_positions[k])
|
|
wl_positions.append(self.rwl_positions[k])
|
|
|
|
for k in range(2*self.total_ports):
|
|
gate_offset = port_transistors[k].get_pin("G").bc()
|
|
port_contact_offset = gate_offset + vector(0, -self.gate_contact_yoffset + self.poly_extend_active)
|
|
wl_contact_offset = vector(gate_offset.x, wl_positions[k].y)
|
|
|
|
# first transistor on either side of the cross coupled inverters does not need to route to wordline on metal2
|
|
if (k == 0) or (k == 1):
|
|
self.add_via_center(layers=("poly", "contact", "metal1"),
|
|
offset=port_contact_offset)
|
|
|
|
self.add_path("poly", [gate_offset, port_contact_offset])
|
|
self.add_path("metal1", [port_contact_offset, wl_contact_offset])
|
|
|
|
else:
|
|
self.add_via_center(layers=("poly", "contact", "metal1"),
|
|
offset=port_contact_offset)
|
|
self.add_via_center(layers=("metal1", "via1", "metal2"),
|
|
offset=port_contact_offset)
|
|
|
|
self.add_via_center(layers=("metal1", "via1", "metal2"),
|
|
offset=wl_contact_offset,
|
|
directions=("H","H"))
|
|
|
|
self.add_path("poly", [gate_offset, port_contact_offset])
|
|
self.add_path("metal2", [port_contact_offset, wl_contact_offset])
|
|
|
|
def route_bitlines(self):
|
|
""" Routes read/write transistors to their respective bitlines """
|
|
left_port_transistors = []
|
|
right_port_transistors = []
|
|
for k in range(self.num_rw_ports):
|
|
left_port_transistors.append(self.readwrite_nmos_left[k])
|
|
right_port_transistors.append(self.readwrite_nmos_right[k])
|
|
for k in range(self.num_w_ports):
|
|
left_port_transistors.append(self.write_nmos_left[k])
|
|
right_port_transistors.append(self.write_nmos_right[k])
|
|
for k in range(self.num_r_ports):
|
|
left_port_transistors.append(self.read_nmos_left[k])
|
|
right_port_transistors.append(self.read_nmos_right[k])
|
|
|
|
bl_positions = []
|
|
br_positions = []
|
|
for k in range(self.num_rw_ports):
|
|
bl_positions.append(self.rwbl_positions[k])
|
|
br_positions.append(self.rwbr_positions[k])
|
|
for k in range(self.num_w_ports):
|
|
bl_positions.append(self.wbl_positions[k])
|
|
br_positions.append(self.wbr_positions[k])
|
|
for k in range(self.num_r_ports):
|
|
bl_positions.append(self.rbl_positions[k])
|
|
br_positions.append(self.rbr_positions[k])
|
|
|
|
for k in range(self.total_ports):
|
|
port_contact_offest = left_port_transistors[k].get_pin("S").center()
|
|
bl_offset = vector(bl_positions[k].x, port_contact_offest.y)
|
|
|
|
self.add_via_center(layers=("metal1", "via1", "metal2"),
|
|
offset=port_contact_offest)
|
|
|
|
self.add_path("metal2", [port_contact_offest, bl_offset], width=contact.m1m2.height)
|
|
|
|
for k in range(self.total_ports):
|
|
port_contact_offest = right_port_transistors[k].get_pin("D").center()
|
|
br_offset = vector(br_positions[k].x, port_contact_offest.y)
|
|
|
|
self.add_via_center(layers=("metal1", "via1", "metal2"),
|
|
offset=port_contact_offest)
|
|
|
|
self.add_path("metal2", [port_contact_offest, br_offset], width=contact.m1m2.height)
|
|
|
|
def route_supply(self):
|
|
""" Route inverter nmos and read-access nmos to gnd. Route inverter pmos to vdd. """
|
|
# route inverter nmos and read-access nmos to gnd
|
|
nmos_contact_positions = []
|
|
nmos_contact_positions.append(self.inverter_nmos_left.get_pin("S").center())
|
|
nmos_contact_positions.append(self.inverter_nmos_right.get_pin("D").center())
|
|
for k in range(self.num_r_ports):
|
|
nmos_contact_positions.append(self.read_access_nmos_left[k].get_pin("D").center())
|
|
nmos_contact_positions.append(self.read_access_nmos_right[k].get_pin("S").center())
|
|
|
|
for position in nmos_contact_positions:
|
|
self.add_via_center(layers=("metal1", "via1", "metal2"),
|
|
offset=position)
|
|
|
|
if position.x > 0:
|
|
contact_correct = 0.5*contact.m1m2.height
|
|
else:
|
|
contact_correct = -0.5*contact.m1m2.height
|
|
supply_offset = vector(position.x + contact_correct, self.gnd_position.y)
|
|
self.add_via_center(layers=("metal1", "via1", "metal2"),
|
|
offset=supply_offset,
|
|
directions=("H","H"))
|
|
|
|
self.add_path("metal2", [position, supply_offset])
|
|
|
|
# route inverter pmos to vdd
|
|
vdd_pos_left = vector(self.inverter_nmos_left.get_pin("S").uc().x, self.vdd_position.y)
|
|
self.add_path("metal1", [self.inverter_pmos_left.get_pin("S").uc(), vdd_pos_left])
|
|
|
|
vdd_pos_right = vector(self.inverter_nmos_right.get_pin("D").uc().x, self.vdd_position.y)
|
|
self.add_path("metal1", [self.inverter_pmos_right.get_pin("D").uc(), vdd_pos_right])
|
|
|
|
def route_readwrite_access(self):
|
|
""" Routes read/write transistors to the storage component of the bitcell """
|
|
for k in range(self.num_rw_ports):
|
|
mid = vector(self.readwrite_nmos_left[k].get_pin("D").uc().x, self.cross_couple_lower_ypos)
|
|
Q_pos = vector(self.inverter_nmos_left.get_pin("D").lx(), self.cross_couple_lower_ypos)
|
|
self.add_path("metal1", [self.readwrite_nmos_left[k].get_pin("D").uc(), mid, Q_pos])
|
|
|
|
mid = vector(self.readwrite_nmos_right[k].get_pin("S").uc().x, self.cross_couple_lower_ypos)
|
|
Q_bar_pos = vector(self.inverter_nmos_right.get_pin("S").rx(), self.cross_couple_lower_ypos)
|
|
self.add_path("metal1", [self.readwrite_nmos_right[k].get_pin("S").uc(), mid, Q_bar_pos])
|
|
|
|
def route_write_access(self):
|
|
""" Routes read/write transistors to the storage component of the bitcell """
|
|
for k in range(self.num_w_ports):
|
|
mid = vector(self.write_nmos_left[k].get_pin("D").uc().x, self.cross_couple_lower_ypos)
|
|
Q_pos = vector(self.inverter_nmos_left.get_pin("D").lx(), self.cross_couple_lower_ypos)
|
|
self.add_path("metal1", [self.write_nmos_left[k].get_pin("D").uc(), mid, Q_pos])
|
|
|
|
mid = vector(self.write_nmos_right[k].get_pin("S").uc().x, self.cross_couple_lower_ypos)
|
|
Q_bar_pos = vector(self.inverter_nmos_right.get_pin("S").rx(), self.cross_couple_lower_ypos)
|
|
self.add_path("metal1", [self.write_nmos_right[k].get_pin("S").uc(), mid, Q_bar_pos])
|
|
|
|
def route_read_access(self):
|
|
""" Routes read access transistors to the storage component of the bitcell """
|
|
# add poly to metal1 contacts for gates of the inverters
|
|
left_storage_contact = vector(self.inverter_nmos_left.get_pin("G").lc().x - self.poly_to_polycontact - 0.5*contact.poly.width, self.cross_couple_upper_ypos)
|
|
self.add_via_center(layers=("poly", "contact", "metal1"),
|
|
offset=left_storage_contact,
|
|
directions=("H","H"))
|
|
|
|
right_storage_contact = vector(self.inverter_nmos_right.get_pin("G").rc().x + self.poly_to_polycontact + 0.5*contact.poly.width, self.cross_couple_upper_ypos)
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self.add_via_center(layers=("poly", "contact", "metal1"),
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offset=right_storage_contact,
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directions=("H","H"))
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inverter_gate_offset_left = vector(self.inverter_nmos_left.get_pin("G").lc().x, self.cross_couple_upper_ypos)
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self.add_path("poly", [left_storage_contact, inverter_gate_offset_left])
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|
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inverter_gate_offset_right = vector(self.inverter_nmos_right.get_pin("G").rc().x, self.cross_couple_upper_ypos)
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self.add_path("poly", [right_storage_contact, inverter_gate_offset_right])
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# add poly to metal1 contacts for gates of read-access transistors
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# route from read-access contacts to inverter contacts on metal1
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for k in range(self.num_r_ports):
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port_contact_offset = self.read_access_nmos_left[k].get_pin("G").uc() + vector(0, self.gate_contact_yoffset - self.poly_extend_active)
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|
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self.add_via_center(layers=("poly", "contact", "metal1"),
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offset=port_contact_offset)
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|
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self.add_path("poly", [self.read_access_nmos_left[k].get_pin("G").uc(), port_contact_offset])
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|
|
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mid = vector(self.read_access_nmos_left[k].get_pin("G").uc().x, self.cross_couple_upper_ypos)
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self.add_path("metal1", [port_contact_offset, mid, left_storage_contact])
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|
|
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port_contact_offset = self.read_access_nmos_right[k].get_pin("G").uc() + vector(0, self.gate_contact_yoffset - self.poly_extend_active)
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|
|
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self.add_via_center(layers=("poly", "contact", "metal1"),
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offset=port_contact_offset)
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|
|
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self.add_path("poly", [self.read_access_nmos_right[k].get_pin("G").uc(), port_contact_offset])
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|
|
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mid = vector(self.read_access_nmos_right[k].get_pin("G").uc().x, self.cross_couple_upper_ypos)
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self.add_path("metal1", [port_contact_offset, mid, right_storage_contact])
|
|
|
|
def extend_well(self):
|
|
"""
|
|
Connects wells between ptx modules and places well contacts"""
|
|
# extend pwell to encompass entire nmos region of the cell up to the height of the tallest nmos transistor
|
|
max_nmos_well_height = max(self.inverter_nmos.cell_well_height,
|
|
self.readwrite_nmos.cell_well_height,
|
|
self.write_nmos.cell_well_height,
|
|
self.read_nmos.cell_well_height)
|
|
well_height = max_nmos_well_height + self.port_ypos - self.well_enclose_active - self.gnd_position.y
|
|
offset = vector(self.leftmost_xpos, self.botmost_ypos)
|
|
self.add_rect(layer="pwell",
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|
offset=offset,
|
|
width=self.width,
|
|
height=well_height)
|
|
|
|
# extend nwell to encompass inverter_pmos
|
|
# calculate offset of the left pmos well
|
|
inverter_well_xpos = -(self.inverter_nmos.active_width + 0.5*self.inverter_to_inverter_spacing) - self.well_enclose_active
|
|
inverter_well_ypos = self.inverter_nmos_ypos + self.inverter_nmos.active_height + self.inverter_gap - self.well_enclose_active
|
|
|
|
# calculate width of the two combined nwells
|
|
# calculate height to encompass nimplant connected to vdd
|
|
well_width = 2*(self.inverter_nmos.active_width + 0.5*self.inverter_to_inverter_spacing) + 2*self.well_enclose_active
|
|
well_height = self.vdd_position.y - inverter_well_ypos + self.well_enclose_active + drc["minwidth_tx"]
|
|
|
|
offset = [inverter_well_xpos,inverter_well_ypos]
|
|
self.add_rect(layer="nwell",
|
|
offset=offset,
|
|
width=well_width,
|
|
height=well_height)
|
|
|
|
# add well contacts
|
|
# connect pimplants to gnd
|
|
offset = vector(0, self.gnd_position.y)
|
|
self.add_via_center(layers=("active", "contact", "metal1"),
|
|
offset=offset,
|
|
directions=("H","H"),
|
|
implant_type="p",
|
|
well_type="p")
|
|
|
|
# connect nimplants to vdd
|
|
offset = vector(0, self.vdd_position.y)
|
|
self.add_via_center(layers=("active", "contact", "metal1"),
|
|
offset=offset,
|
|
directions=("H","H"),
|
|
implant_type="n",
|
|
well_type="n")
|
|
|
|
def list_bitcell_pins(self, col, row):
|
|
""" Creates a list of connections in the bitcell, indexed by column and row, for instance use in bitcell_array """
|
|
bitcell_pins = []
|
|
for port in range(self.total_ports):
|
|
bitcell_pins.append("bl{0}_{1}".format(port,col))
|
|
bitcell_pins.append("br{0}_{1}".format(port,col))
|
|
for port in range(self.total_ports):
|
|
bitcell_pins.append("wl{0}_{1}".format(port,row))
|
|
bitcell_pins.append("vdd")
|
|
bitcell_pins.append("gnd")
|
|
return bitcell_pins
|
|
|
|
def list_all_wl_names(self):
|
|
""" Creates a list of all wordline pin names """
|
|
wordline_names = self.rw_wl_names + self.w_wl_names + self.r_wl_names
|
|
return wordline_names
|
|
|
|
def list_all_bitline_names(self):
|
|
""" Creates a list of all bitline pin names (both bl and br) """
|
|
bitline_pins = []
|
|
for port in range(self.total_ports):
|
|
bitline_pins.append("bl{0}".format(port))
|
|
bitline_pins.append("br{0}".format(port))
|
|
return bitline_pins
|
|
|
|
def list_all_bl_names(self):
|
|
""" Creates a list of all bl pins names """
|
|
bl_pins = self.rw_bl_names + self.w_bl_names + self.r_bl_names
|
|
return bl_pins
|
|
|
|
def list_all_br_names(self):
|
|
""" Creates a list of all br pins names """
|
|
br_pins = self.rw_br_names + self.w_br_names + self.r_br_names
|
|
return br_pins
|
|
|
|
def route_rbc_short(self):
|
|
""" route the short from Q_bar to gnd necessary for the replica bitcell """
|
|
Q_bar_pos = self.inverter_pmos_right.get_pin("S").center()
|
|
vdd_pos = self.inverter_pmos_right.get_pin("D").center()
|
|
self.add_path("metal1", [Q_bar_pos, vdd_pos])
|
|
|
|
def get_storage_net_names(self):
|
|
"""Returns names of storage nodes in bitcell in [non-inverting, inverting] format."""
|
|
return self.storage_nets
|
|
|
|
def get_bl_name(self, port=0):
|
|
"""Get bl name by port"""
|
|
return "bl{}".format(port)
|
|
|
|
def get_br_name(self, port=0):
|
|
"""Get bl name by port"""
|
|
return "br{}".format(port)
|
|
|
|
def analytical_delay(self, corner, slew, load=0, swing = 0.5):
|
|
parasitic_delay = 1
|
|
size = 0.5 #This accounts for bitline being drained thought the access TX and internal node
|
|
cin = 3 #Assumes always a minimum sizes inverter. Could be specified in the tech.py file.
|
|
|
|
#Internal loads due to port configs are halved. This is to account for the size already being halved
|
|
#for stacked TXs, but internal loads do not see this size estimation.
|
|
write_port_load = self.num_w_ports*logical_effort.convert_farad_to_relative_c(parameter['bitcell_drain_cap'])/2
|
|
read_port_load = self.num_r_ports/2 #min size NMOS gate load
|
|
total_load = load+read_port_load+write_port_load
|
|
return logical_effort.logical_effort('bitline', size, cin, load+read_port_load, parasitic_delay, False)
|
|
|
|
def analytical_power(self, corner, load):
|
|
"""Bitcell power in nW. Only characterizes leakage."""
|
|
from tech import spice
|
|
leakage = spice["bitcell_leakage"]
|
|
dynamic = 0 #temporary
|
|
total_power = self.return_power(dynamic, leakage)
|
|
return total_power
|
|
|
|
def get_wl_cin(self):
|
|
"""Return the relative capacitance of the access transistor gates"""
|
|
#pbitcell uses the different sizing for the port access tx's. Not accounted for in this model.
|
|
access_tx_cin = self.readwrite_nmos.get_cin()
|
|
return 2*access_tx_cin
|
|
|
|
def build_graph(self, graph, inst_name, port_nets):
|
|
"""Adds edges to graph for pbitcell. Only readwrite and read ports."""
|
|
pin_dict = {pin:port for pin,port in zip(self.pins, port_nets)}
|
|
# Edges added wl->bl, wl->br for every port except write ports
|
|
rw_pin_names = zip(self.r_wl_names, self.r_bl_names, self.r_br_names)
|
|
r_pin_names = zip(self.rw_wl_names, self.rw_bl_names, self.rw_br_names)
|
|
for pin_zip in zip(rw_pin_names, r_pin_names):
|
|
for wl,bl,br in pin_zip:
|
|
graph.add_edge(pin_dict[wl],pin_dict[bl])
|
|
graph.add_edge(pin_dict[wl],pin_dict[br])
|
|
|