OpenRAM/compiler/modules/port_data.py

# See LICENSE for licensing information.
#
# Copyright (c) 2016-2019 Regents of the University of California
# All rights reserved.
#
from tech import drc
import debug
import design
from sram_factory import factory
from collections import namedtuple
from vector import vector
from globals import OPTS


class port_data(design.design):
    """
    Create the data port (column mux, sense amps, write driver, etc.) for the given port number.
    Port 0 always has the RBL on the left while port 1 is on the right.
    """

    def __init__(self, sram_config, port, name=""):
        
        sram_config.set_local_config(self)
        self.port = port
        if self.write_size is not None:
            self.num_wmasks = int(self.word_size / self.write_size)
        else:
            self.num_wmasks = 0

        if name == "":
            name = "port_data_{0}".format(self.port)
        design.design.__init__(self, name)
        debug.info(2,
                   "create data port of size {0} with {1} words per row".format(self.word_size,
                                                                                   self.words_per_row))

        self.create_netlist()
        if not OPTS.netlist_only:
            debug.check(len(self.all_ports)<=2,
                        "Bank layout cannot handle more than two ports.")
            self.create_layout()
            self.add_boundary()

    def get_bl_names(self):
        # bl lines are connect from the precharger
        return self.precharge.get_bl_names()

    def get_br_names(self):
        # br lines are connect from the precharger
        return self.precharge.get_br_names()

    def get_bl_name(self, port=0):
        bl_name = "bl"
        if len(self.all_ports) == 1:
            return bl_name
        else:
            return bl_name + "{}".format(port)

    def get_br_name(self, port=0):
        br_name = "br"
        if len(self.all_ports) == 1:
            return br_name
        else:
            return br_name + "{}".format(port)

    def create_netlist(self):
        self.precompute_constants()
        self.add_pins()
        self.add_modules()
        self.create_instances()

    def create_instances(self):
        if self.precharge_array:
            self.create_precharge_array()
        else:
            self.precharge_array_inst = None

        if self.sense_amp_array:
            self.create_sense_amp_array()
        else:
            self.sense_amp_array_inst = None

        if self.write_driver_array:
            self.create_write_driver_array()
            if self.write_size is not None:
                self.create_write_mask_and_array()
            else:
                self.write_mask_and_array_inst = None
        else:
            self.write_driver_array_inst = None
            self.write_mask_and_array_inst = None

        if self.column_mux_array:
            self.create_column_mux_array()
        else:
            self.column_mux_array_inst = None

    def create_layout(self):
        self.compute_instance_offsets()
        self.place_instances()
        self.route_layout()
        self.DRC_LVS()

    def add_pins(self):
        """ Adding pins for port address module"""

        self.add_pin("rbl_bl", "INOUT")
        self.add_pin("rbl_br", "INOUT")
        for bit in range(self.num_cols):
            bl_name = self.get_bl_name(self.port)
            br_name = self.get_br_name(self.port)
            self.add_pin("{0}_{1}".format(bl_name, bit), "INOUT")
            self.add_pin("{0}_{1}".format(br_name, bit), "INOUT")
        if self.port in self.read_ports:
            for bit in range(self.word_size):
                self.add_pin("dout_{}".format(bit), "OUTPUT")
        if self.port in self.write_ports:
            for bit in range(self.word_size):
                self.add_pin("din_{}".format(bit), "INPUT")
        # Will be empty if no col addr lines
        sel_names = ["sel_{}".format(x) for x in range(self.num_col_addr_lines)]
        for pin_name in sel_names:
            self.add_pin(pin_name, "INPUT")
        if self.port in self.read_ports:
            self.add_pin("s_en", "INPUT")
        self.add_pin("p_en_bar", "INPUT")
        if self.port in self.write_ports:
            self.add_pin("w_en", "INPUT")
            for bit in range(self.num_wmasks):
                self.add_pin("bank_wmask_{}".format(bit), "INPUT")
        self.add_pin("vdd", "POWER")
        self.add_pin("gnd", "GROUND")

    def route_layout(self):
        """ Create routing among the modules """
        self.route_data_lines()
        self.route_layout_pins()
        self.route_supplies()

    def route_layout_pins(self):
        """ Add the pins """
        self.route_bitline_pins()
        self.route_control_pins()

    def route_data_lines(self):
        """ Route the bitlines depending on the port type rw, w, or r. """

        if self.port in self.readwrite_ports:
            # (write_mask_and ->) write_driver -> sense_amp -> (column_mux ->) precharge -> bitcell_array
            self.route_write_mask_and_array_in(self.port)
            self.route_write_mask_and_array_to_write_driver(self.port)
            self.route_write_driver_in(self.port)
            self.route_sense_amp_out(self.port)
            self.route_write_driver_to_sense_amp(self.port)
            self.route_sense_amp_to_column_mux_or_precharge_array(self.port)
            self.route_column_mux_to_precharge_array(self.port)
        elif self.port in self.read_ports:
            # sense_amp -> (column_mux) -> precharge -> bitcell_array
            self.route_sense_amp_out(self.port)
            self.route_sense_amp_to_column_mux_or_precharge_array(self.port)
            self.route_column_mux_to_precharge_array(self.port)
        else:
            # (write_mask_and ->) write_driver -> (column_mux ->) precharge -> bitcell_array
            self.route_write_mask_and_array_in(self.port)
            self.route_write_mask_and_array_to_write_driver(self.port)
            self.route_write_driver_in(self.port)
            self.route_write_driver_to_column_mux_or_precharge_array(self.port)
            self.route_column_mux_to_precharge_array(self.port)

    def route_supplies(self):
        """ Propagate all vdd/gnd pins up to this level for all modules """

        for inst in self.insts:
            self.copy_power_pins(inst, "vdd")
            self.copy_power_pins(inst, "gnd")

    def add_modules(self):

        # Extra column +1 is for RBL
        # Precharge will be shifted left if needed
        self.precharge_array = factory.create(module_type="precharge_array",
                                              columns=self.num_cols + 1,
                                              bitcell_bl=self.bl_names[self.port],
                                              bitcell_br=self.br_names[self.port])
        self.add_mod(self.precharge_array)

        if self.port in self.read_ports:
            self.sense_amp_array = factory.create(module_type="sense_amp_array",
                                                  word_size=self.word_size,
                                                  words_per_row=self.words_per_row)
            self.add_mod(self.sense_amp_array)
        else:
            self.sense_amp_array = None

        if self.col_addr_size > 0:
            self.column_mux_array = factory.create(module_type="column_mux_array",
                                                   columns=self.num_cols,
                                                   word_size=self.word_size,
                                                   bitcell_bl=self.bl_names[self.port],
                                                   bitcell_br=self.br_names[self.port])
            self.add_mod(self.column_mux_array)
        else:
            self.column_mux_array = None

        if self.port in self.write_ports:
            self.write_driver_array = factory.create(module_type="write_driver_array",
                                                     columns=self.num_cols,
                                                     word_size=self.word_size,
                                                     write_size=self.write_size)
            self.add_mod(self.write_driver_array)
            if self.write_size is not None:
                self.write_mask_and_array = factory.create(module_type="write_mask_and_array",
                                                           columns=self.num_cols,
                                                           word_size=self.word_size,
                                                           write_size=self.write_size,
                                                           port = self.port)
                self.add_mod(self.write_mask_and_array)
            else:
                self.write_mask_and_array = None

        else:
            self.write_driver_array = None
            self.write_mask_and_array = None

    def precompute_constants(self):
        """  Get some preliminary data ready """

        # The central bus is the column address (one hot) and row address (binary)
        if self.col_addr_size>0:
            self.num_col_addr_lines = 2**self.col_addr_size
        else:
            self.num_col_addr_lines = 0

        # A space for wells or jogging m2 between modules
        self.m2_gap = max(2 * drc("pwell_to_nwell") + drc("nwell_enclose_active"),
                          3 * self.m2_pitch)


        # create arrays of bitline and bitline_bar names for read,
        # write, or all ports
        self.bitcell = factory.create(module_type="bitcell")
        self.bl_names = self.bitcell.get_all_bl_names()
        self.br_names = self.bitcell.get_all_br_names()
        self.wl_names = self.bitcell.get_all_wl_names()
        # used for bl/br names
        self.precharge = factory.create(module_type="precharge",
                                        bitcell_bl=self.bl_names[0],
                                        bitcell_br=self.br_names[0])
        # We create a dummy here to get bl/br names to add those pins to this
        # module, which happens before we create the real precharge_array
        self.precharge_array = factory.create(module_type="precharge_array",
                                              columns=self.num_cols + 1,
                                              bitcell_bl=self.bl_names[self.port],
                                              bitcell_br=self.br_names[self.port])

    def create_precharge_array(self):
        """ Creating Precharge """
        if not self.precharge_array:
            self.precharge_array_inst = None
            return

        self.precharge_array_inst = self.add_inst(name="precharge_array{}".format(self.port),
                                                  mod=self.precharge_array)
        bl_name = self.get_bl_name(self.port)
        br_name = self.get_br_name(self.port)

        temp = []
        # Use left BLs for RBL
        if self.port==0:
            temp.append("rbl_bl")
            temp.append("rbl_br")
        for bit in range(self.num_cols):
            temp.append("{0}_{1}".format(bl_name, bit))
            temp.append("{0}_{1}".format(br_name, bit))

        # Use right BLs for RBL
        if self.port==1:
            temp.append("rbl_bl")
            temp.append("rbl_br")
        temp.extend(["p_en_bar", "vdd"])
        self.connect_inst(temp)

    def place_precharge_array(self, offset):
        """ Placing Precharge """

        self.precharge_array_inst.place(offset=offset, mirror="MX")

    def create_column_mux_array(self):
        """ Creating Column Mux when words_per_row > 1 . """

        self.column_mux_array_inst = self.add_inst(name="column_mux_array{}".format(self.port),
                                                   mod=self.column_mux_array)

        bl_name = self.get_bl_name(self.port)
        br_name = self.get_br_name(self.port)
        temp = []
        for col in range(self.num_cols):
            temp.append("{0}_{1}".format(bl_name, col))
            temp.append("{0}_{1}".format(br_name, col))

        for word in range(self.words_per_row):
            temp.append("sel_{}".format(word))
        for bit in range(self.word_size):
            temp.append("{0}_out_{1}".format(bl_name, bit))
            temp.append("{0}_out_{1}".format(br_name, bit))

        temp.append("gnd")
        self.connect_inst(temp)

    def place_column_mux_array(self, offset):
        """ Placing Column Mux when words_per_row > 1 . """
        if self.col_addr_size == 0:
            return

        self.column_mux_array_inst.place(offset=offset, mirror="MX")

    def create_sense_amp_array(self):
        """ Creating Sense amp  """
        self.sense_amp_array_inst = self.add_inst(name="sense_amp_array{}".format(self.port),
                                                  mod=self.sense_amp_array)

        bl_name = self.get_bl_name(self.port)
        br_name = self.get_br_name(self.port)
        temp = []
        for bit in range(self.word_size):
            temp.append("dout_{}".format(bit))
            if self.words_per_row == 1:
                temp.append("{0}_{1}".format(bl_name, bit))
                temp.append("{0}_{1}".format(br_name, bit))
            else:
                temp.append("{0}_out_{1}".format(bl_name, bit))
                temp.append("{0}_out_{1}".format(br_name, bit))

        temp.extend(["s_en", "vdd", "gnd"])
        self.connect_inst(temp)

    def place_sense_amp_array(self, offset):
        """ Placing Sense amp  """
        self.sense_amp_array_inst.place(offset=offset, mirror="MX")

    def create_write_driver_array(self):
        """ Creating Write Driver  """
        self.write_driver_array_inst = self.add_inst(name="write_driver_array{}".format(self.port),
                                                     mod=self.write_driver_array)
        bl_name = self.get_bl_name(self.port)
        br_name = self.get_br_name(self.port)

        temp = []
        for bit in range(self.word_size):
            temp.append("din_{}".format(bit))

        for bit in range(self.word_size):
            if (self.words_per_row == 1):
                temp.append("{0}_{1}".format(bl_name, bit))
                temp.append("{0}_{1}".format(br_name, bit))
            else:
                temp.append("{0}_out_{1}".format(bl_name, bit))
                temp.append("{0}_out_{1}".format(br_name, bit))

        if self.write_size is not None:
            for i in range(self.num_wmasks):
                temp.append("wdriver_sel_{}".format(i))
        else:
            temp.append("w_en")
        temp.extend(["vdd", "gnd"])

        self.connect_inst(temp)

    def place_write_driver_array(self, offset):
        """ Placing Write Driver  """
        self.write_driver_array_inst.place(offset=offset, mirror="MX")

    def create_write_mask_and_array(self):
        """ Creating Write Mask AND Array  """
        self.write_mask_and_array_inst = self.add_inst(name="write_mask_and_array{}".format(self.port),
                                                       mod=self.write_mask_and_array)

        temp = []
        for bit in range(self.num_wmasks):
            temp.append("bank_wmask_{}".format(bit))
        temp.extend(["w_en"])
        for bit in range(self.num_wmasks):
            temp.append("wdriver_sel_{}".format(bit))
        temp.extend(["vdd", "gnd"])
        self.connect_inst(temp)

    def place_write_mask_and_array(self, offset):
        """ Placing Write Mask AND array  """
        self.write_mask_and_array_inst.place(offset=offset, mirror="MX")

    def compute_instance_offsets(self):
        """
        Compute the empty instance offsets for port0 and port1 (if needed)
        """

        vertical_port_order = []
        vertical_port_order.append(self.precharge_array_inst)
        vertical_port_order.append(self.column_mux_array_inst)
        vertical_port_order.append(self.sense_amp_array_inst)
        vertical_port_order.append(self.write_driver_array_inst)
        vertical_port_order.append(self.write_mask_and_array_inst)

        # Add one column for the the RBL
        if self.port==0:
            x_offset = self.bitcell.width
        else:
            x_offset = 0

        vertical_port_offsets = 5 * [None]
        self.width = x_offset
        self.height = 0
        for i, p in enumerate(vertical_port_order):
            if p == None:
                continue
            self.height += (p.height + self.m2_gap)
            self.width = max(self.width, p.width)
            vertical_port_offsets[i] = vector(x_offset, self.height)

        # Reversed order
        self.write_mask_and_offset = vertical_port_offsets[4]
        self.write_driver_offset = vertical_port_offsets[3]
        self.sense_amp_offset = vertical_port_offsets[2]
        self.column_mux_offset = vertical_port_offsets[1]
        self.precharge_offset = vertical_port_offsets[0]
        # Shift the precharge left if port 0
        if self.precharge_offset and self.port == 0:
            self.precharge_offset -= vector(x_offset, 0)

    def place_instances(self):
        """ Place the instances. """

        # These are fixed in the order: write mask ANDs, write driver, sense amp, column mux, precharge,
        # even if the item is not used in a given port (it will be None then)
        if self.write_mask_and_offset:
            self.place_write_mask_and_array(self.write_mask_and_offset)
        if self.write_driver_offset:
            self.place_write_driver_array(self.write_driver_offset)
        if self.sense_amp_offset:
            self.place_sense_amp_array(self.sense_amp_offset)
        if self.precharge_offset:
            self.place_precharge_array(self.precharge_offset)
        if self.column_mux_offset:
            self.place_column_mux_array(self.column_mux_offset)

    def route_sense_amp_out(self, port):
        """ Add pins for the sense amp output """
        
        for bit in range(self.word_size):
            data_pin = self.sense_amp_array_inst.get_pin("data_{}".format(bit))
            self.add_layout_pin_rect_center(text="dout_{0}".format(bit),
                                            layer=data_pin.layer,
                                            offset=data_pin.center(),
                                            height=data_pin.height(),
                                            width=data_pin.width())

    def route_write_driver_in(self, port):
        """ Connecting write driver   """

        for row in range(self.word_size):
            data_name = "data_{}".format(row)
            din_name = "din_{}".format(row)
            self.copy_layout_pin(self.write_driver_array_inst, data_name, din_name)

    def route_write_mask_and_array_in(self, port):
        """ Add pins for the write mask and array input """

        for bit in range(self.num_wmasks):
            wmask_in_name = "wmask_in_{}".format(bit)
            bank_wmask_name = "bank_wmask_{}".format(bit)
            self.copy_layout_pin(self.write_mask_and_array_inst, wmask_in_name, bank_wmask_name)

    def route_write_mask_and_array_to_write_driver(self,port):
        """ Routing of wdriver_sel_{} between write mask AND array and write driver array. Adds layout pin for write
            mask AND array output and via for write driver enable """

        inst1 = self.write_mask_and_array_inst
        inst2 = self.write_driver_array_inst

        loc = 0
        for bit in range(self.num_wmasks):
            # Bring write mask AND array output pin to port data level
            self.copy_layout_pin(inst1, "wmask_out_{0}".format(bit), "wdriver_sel_{0}".format(bit))

            wmask_out_pin = inst1.get_pin("wmask_out_{0}".format(bit))
            wdriver_en_pin = inst2.get_pin("en_{0}".format(bit))

            # The metal2 wdriver_sel_{} wire must hit the en_{} pin after the closest bitline pin that's right of the
            # the wdriver_sel_{} pin in the write driver AND array.
            if bit == 0:
                # When the write mask output pin is right of the bitline, the target is found
                while (wmask_out_pin.lx() + self.m2_pitch > inst2.get_pin("data_{0}".format(loc)).rx()):
                    loc += 1
                length = inst2.get_pin("data_{0}".format(loc)).rx() + self.m2_pitch
                debug.check(loc<=self.num_wmasks,
                            "Couldn't route the write mask select.")
            else:
                # Stride by the write size rather than finding the next pin to the right
                loc += self.write_size
                length = inst2.get_pin("data_{0}".format(loc)).rx() + self.m2_pitch

            beg_pos = wmask_out_pin.center()
            middle_pos = vector(length, wmask_out_pin.cy())
            end_pos = vector(length, wdriver_en_pin.cy())

            # Add via for the write driver array's enable input
            self.add_via_center(layers=self.m1_stack,
                                offset=end_pos)

            # Route between write mask AND array and write driver array
            self.add_wire(self.m1_stack, [beg_pos, middle_pos, end_pos])

    def route_column_mux_to_precharge_array(self, port):
        """ Routing of BL and BR between col mux and precharge array """

        # Only do this if we have a column mux!
        if self.col_addr_size==0:
            return

        inst1 = self.column_mux_array_inst
        inst2 = self.precharge_array_inst

        insn2_start_bit = 1 if self.port == 0 else 0

        self.connect_bitlines(inst1=inst1,
                              inst2=inst2,
                              num_bits=self.num_cols,
                              inst2_start_bit=insn2_start_bit)

    def route_sense_amp_to_column_mux_or_precharge_array(self, port):
        """ Routing of BL and BR between sense_amp and column mux or precharge array """
        inst2 = self.sense_amp_array_inst

        if self.col_addr_size>0:
            # Sense amp is connected to the col mux
            inst1 = self.column_mux_array_inst
            inst1_bls_templ = "{inst}_out_{bit}"
            start_bit = 0
        else:
            # Sense amp is directly connected to the precharge array
            inst1 = self.precharge_array_inst
            inst1_bls_templ="{inst}_{bit}"

            if self.port==0:
                start_bit=1
            else:
                start_bit=0

        self.channel_route_bitlines(inst1=inst1,
                                    inst1_bls_template=inst1_bls_templ,
                                    inst2=inst2,
                                    num_bits=self.word_size,
                                    inst1_start_bit=start_bit)

    def route_write_driver_to_column_mux_or_precharge_array(self, port):
        """ Routing of BL and BR between sense_amp and column mux or precharge array """
        inst2 = self.write_driver_array_inst

        if self.col_addr_size>0:
            # Write driver is connected to the col mux
            inst1 = self.column_mux_array_inst
            inst1_bls_templ = "{inst}_out_{bit}"
            start_bit = 0
        else:
            # Sense amp is directly connected to the precharge array
            inst1 = self.precharge_array_inst
            inst1_bls_templ="{inst}_{bit}"
            if self.port==0:
                start_bit=1
            else:
                start_bit=0

        self.channel_route_bitlines(inst1=inst1, inst2=inst2,
                                    num_bits=self.word_size,
                                    inst1_bls_template=inst1_bls_templ,
                                    inst1_start_bit=start_bit)

    def route_write_driver_to_sense_amp(self, port):
        """ Routing of BL and BR between write driver and sense amp """

        inst1 = self.write_driver_array_inst
        inst2 = self.sense_amp_array_inst

        # These should be pitch matched in the cell library,
        # but just in case, do a channel route.
        self.channel_route_bitlines(inst1=inst1,
                                    inst2=inst2,
                                    num_bits=self.word_size)

    def route_bitline_pins(self):
        """ Add the bitline pins for the given port """

        # Connect one bitline to the RBL and offset the indices for the other BLs
        if self.port==0:
            self.copy_layout_pin(self.precharge_array_inst, "bl_0", "rbl_bl")
            self.copy_layout_pin(self.precharge_array_inst, "br_0", "rbl_br")
            bit_offset=1
        elif self.port==1:
            self.copy_layout_pin(self.precharge_array_inst, "bl_{}".format(self.num_cols), "rbl_bl")
            self.copy_layout_pin(self.precharge_array_inst, "br_{}".format(self.num_cols), "rbl_br")
            bit_offset=0
        else:
            bit_offset=0

        for bit in range(self.num_cols):
            if self.precharge_array_inst:
                self.copy_layout_pin(self.precharge_array_inst,
                                     "bl_{}".format(bit + bit_offset),
                                     "bl_{}".format(bit))
                self.copy_layout_pin(self.precharge_array_inst,
                                     "br_{}".format(bit + bit_offset),
                                     "br_{}".format(bit))
            else:
                debug.error("Didn't find precharge array.")

    def route_control_pins(self):
        """ Add the control pins: s_en, p_en_bar, w_en """
        if self.precharge_array_inst:
            self.copy_layout_pin(self.precharge_array_inst, "en_bar", "p_en_bar")
        if self.column_mux_array_inst:
            sel_names = ["sel_{}".format(x) for x in range(self.num_col_addr_lines)]
            for pin_name in sel_names:
                self.copy_layout_pin(self.column_mux_array_inst, pin_name)
        if self.sense_amp_array_inst:
            self.copy_layout_pin(self.sense_amp_array_inst, "en", "s_en")
        if self.write_driver_array_inst:
            if self.write_mask_and_array_inst:
                for bit in range(self.num_wmasks):
                    # Add write driver's en_{} pins
                    self.copy_layout_pin(self.write_driver_array_inst, "en_{}".format(bit), "wdriver_sel_{}".format(bit))
            else:
                self.copy_layout_pin(self.write_driver_array_inst, "en", "w_en")
        if self.write_mask_and_array_inst:
            self.copy_layout_pin(self.write_mask_and_array_inst, "en", "w_en")

    def _group_bitline_instances(self, inst1, inst2, num_bits,
                                 inst1_bls_template,
                                 inst1_start_bit,
                                 inst2_bls_template,
                                 inst2_start_bit):
        """
        Groups all the parameters into a named tuple and seperates them into
        top and bottom instances.
        """
        inst_group = namedtuple('InstanceGroup', ('inst', 'bls_template',
                                                  'bl_name', 'br_name', 'start_bit'))

        inst1_group = inst_group(inst1, inst1_bls_template,
                                 inst1.mod.get_bl_name(),
                                 inst1.mod.get_br_name(),
                                 inst1_start_bit)
        inst2_group = inst_group(inst2, inst2_bls_template,
                                 inst2.mod.get_bl_name(),
                                 inst2.mod.get_br_name(),
                                 inst2_start_bit)
        # determine top and bottom automatically.
        # since they don't overlap, we can just check the bottom y coordinate.
        if inst1.by() < inst2.by():
            bot_inst_group = inst1_group
            top_inst_group = inst2_group
        else:
            bot_inst_group = inst2_group
            top_inst_group = inst1_group

        return (bot_inst_group, top_inst_group)

    def _get_bitline_pins(self, inst_group, bit):
        """
        Extracts bl/br pins from an InstanceGroup based on the bit modifier.
        """
        full_bl_name = inst_group.bls_template.format(
            **{'inst': inst_group.bl_name,
               'bit': inst_group.start_bit + bit}
        )
        full_br_name = inst_group.bls_template.format(
            **{'inst': inst_group.br_name,
               'bit': inst_group.start_bit + bit}
        )
        return (inst_group.inst.get_pin(full_bl_name),
                inst_group.inst.get_pin(full_br_name))

    def channel_route_bitlines(self, inst1, inst2, num_bits,
                               inst1_bls_template="{inst}_{bit}",
                               inst1_start_bit=0,
                               inst2_bls_template="{inst}_{bit}",
                               inst2_start_bit=0):
        """
        Route the bl and br of two modules using the channel router.
        """

        bot_inst_group, top_inst_group = self._group_bitline_instances(
                                           inst1, inst2, num_bits,
                                           inst1_bls_template, inst1_start_bit,
                                           inst2_bls_template, inst2_start_bit)

        # Channel route each mux separately since we don't minimize the number
        # of tracks in teh channel router yet. If we did, we could route all the bits at once!
        offset = bot_inst_group.inst.ul() + vector(0, self.m1_nonpref_pitch)
        for bit in range(num_bits):
            bottom_names = self._get_bitline_pins(bot_inst_group, bit)
            top_names = self._get_bitline_pins(top_inst_group, bit)

            if bottom_names[0].layer == "m2":
                bitline_dirs = ("H", "V")
            elif bottom_names[0].layer == "m1":
                bitline_dirs = ("V", "H")
            
            route_map = list(zip(bottom_names, top_names))
            self.create_horizontal_channel_route(route_map, offset, self.m1_stack, bitline_dirs)

    def connect_bitlines(self, inst1, inst2, num_bits,
                         inst1_bls_template="{inst}_{bit}",
                         inst1_start_bit=0,
                         inst2_bls_template="{inst}_{bit}",
                         inst2_start_bit=0):
        """
        Connect the bl and br of two modules.
        This assumes that they have sufficient space to create a jog
        in the middle between the two modules (if needed).
        """
        
        bot_inst_group, top_inst_group = self._group_bitline_instances(
            inst1, inst2, num_bits,
            inst1_bls_template, inst1_start_bit,
            inst2_bls_template, inst2_start_bit)

        for col in range(num_bits):
            bot_bl_pin, bot_br_pin = self._get_bitline_pins(bot_inst_group, col)
            top_bl_pin, top_br_pin = self._get_bitline_pins(top_inst_group, col)
            bot_bl, bot_br = bot_bl_pin.uc(), bot_br_pin.uc()
            top_bl, top_br = top_bl_pin.bc(), top_br_pin.bc()

            yoffset = 0.5 * (top_bl.y + bot_bl.y)
            self.add_path("m2", [bot_bl,
                                 vector(bot_bl.x, yoffset),
                                 vector(top_bl.x, yoffset),
                                 top_bl])
            self.add_path("m2", [bot_br,
                                 vector(bot_br.x, yoffset),
                                 vector(top_br.x, yoffset),
                                 top_br])
        
    def graph_exclude_precharge(self):
        """Precharge adds a loop between bitlines, can be excluded to reduce complexity"""
        if self.precharge_array_inst:
            self.graph_inst_exclude.add(self.precharge_array_inst)