# See LICENSE for licensing information. # # Copyright (c) 2016-2022 Regents of the University of California, Santa Cruz # All rights reserved. # from openram import debug from openram.base import vector from openram.base import contact from openram.sram_factory import factory from openram.tech import drc, spice from openram.tech import cell_properties as props from openram import OPTS from .bitcell_base_array import bitcell_base_array class replica_bitcell_array(bitcell_base_array): """ Creates a bitcell array of cols x rows and then adds the replica and dummy columns and rows. Replica columns are on the left and right, respectively and connected to the given bitcell ports. Dummy are the outside columns/rows with WL and BL tied to gnd. Requires a regular bitcell array, replica bitcell, and dummy bitcell (BL/BR disconnected). """ def __init__(self, rows, cols, rbl=None, left_rbl=None, right_rbl=None, name=""): super().__init__(name=name, rows=rows, cols=cols, column_offset=0) debug.info(1, "Creating {0} {1} x {2} rbls: {3} left_rbl: {4} right_rbl: {5}".format(self.name, rows, cols, rbl, left_rbl, right_rbl)) self.add_comment("rows: {0} cols: {1}".format(rows, cols)) self.add_comment("rbl: {0} left_rbl: {1} right_rbl: {2}".format(rbl, left_rbl, right_rbl)) self.column_size = cols self.row_size = rows # This is how many RBLs are in all the arrays self.rbl = rbl # This specifies which RBL to put on the left or right by port number # This could be an empty list if left_rbl is not None: self.left_rbl = left_rbl else: self.left_rbl = [] # This could be an empty list if right_rbl is not None: self.right_rbl = right_rbl else: self.right_rbl=[] self.rbls = self.left_rbl + self.right_rbl debug.check(sum(self.rbl) >= len(self.left_rbl) + len(self.right_rbl), "Invalid number of RBLs for port configuration.") self.create_netlist() if not OPTS.netlist_only: self.create_layout() def create_netlist(self): """ Create and connect the netlist """ self.add_modules() self.add_pins() self.create_instances() def add_modules(self): """ Array and dummy/replica columns d or D = dummy cell (caps to distinguish grouping) r or R = replica cell (caps to distinguish grouping) b or B = bitcell replica columns 1 v v bdDDDDDDDDDDDDDDdb <- Dummy row bdDDDDDDDDDDDDDDrb <- Dummy row br--------------rb br| Array |rb br| row x col |rb br--------------rb brDDDDDDDDDDDDDDdb <- Dummy row bdDDDDDDDDDDDDDDdb <- Dummy row ^^^^^^^^^^^^^^^ dummy rows cols x 1 ^ dummy columns ^ 1 x (rows + 4) """ # Bitcell array self.bitcell_array = factory.create(module_type="bitcell_array", column_offset=1 + len(self.left_rbl), cols=self.column_size, rows=self.row_size) # Replica bitlines self.replica_columns = {} for port in self.all_ports: if port in self.left_rbl: # We will always have self.rbl[0] rows of replica wordlines below # the array. # These go from the top (where the bitcell array starts ) down replica_bit = self.rbl[0] - port - 1 column_offset = self.rbl[0] elif port in self.right_rbl: # We will always have self.rbl[0] rows of replica wordlines below # the array. # These go from the bottom up replica_bit = self.rbl[0] + self.row_size + port - 1 column_offset = self.rbl[0] + self.column_size + 1 else: continue self.replica_columns[port] = factory.create(module_type="replica_column", rows=self.row_size, rbl=self.rbl, column_offset=column_offset, replica_bit=replica_bit) # Dummy row self.dummy_row = factory.create(module_type="dummy_array", cols=self.column_size, rows=1, # dummy column + left replica column column_offset=1 + len(self.left_rbl), mirror=0) def add_pins(self): # Arrays are always: # bitlines (column first then port order) # word lines (row first then port order) # dummy wordlines # replica wordlines # regular wordlines (bottom to top) # # dummy bitlines # replica bitlines (port order) # regular bitlines (left to right port order) # # vdd # gnd self.add_bitline_pins() self.add_wordline_pins() self.add_pin("vdd", "POWER") self.add_pin("gnd", "GROUND") def add_bitline_pins(self): # The bit is which port the RBL is for for bit in self.rbls: for port in self.all_ports: self.rbl_bitline_names[bit].append("rbl_bl_{0}_{1}".format(port, bit)) for port in self.all_ports: self.rbl_bitline_names[bit].append("rbl_br_{0}_{1}".format(port, bit)) # Make a flat list too self.all_rbl_bitline_names = [x for sl in self.rbl_bitline_names for x in sl] self.bitline_names = self.bitcell_array.bitline_names # Make a flat list too self.all_bitline_names = [x for sl in zip(*self.bitline_names) for x in sl] self.bitline_pin_list = [] for port in self.left_rbl: self.bitline_pin_list.extend(self.rbl_bitline_names[port]) self.bitline_pin_list.extend(self.all_bitline_names) for port in self.right_rbl: self.bitline_pin_list.extend(self.rbl_bitline_names[port]) self.add_pin_list(self.bitline_pin_list, "INOUT") def add_wordline_pins(self): # Unused wordlines are connected to ground at the next level of hierarchy self.unused_wordline_names = [] for port in self.all_ports: for bit in self.all_ports: self.rbl_wordline_names[port].append("rbl_wl_{0}_{1}".format(port, bit)) if bit != port: self.unused_wordline_names.append("rbl_wl_{0}_{1}".format(port, bit)) self.all_rbl_wordline_names = [x for sl in self.rbl_wordline_names for x in sl] self.wordline_names = self.bitcell_array.wordline_names self.all_wordline_names = self.bitcell_array.all_wordline_names # All wordlines including RBL self.wordline_pin_list = [] for bit in range(self.rbl[0]): self.wordline_pin_list.extend(self.rbl_wordline_names[bit]) self.wordline_pin_list.extend(self.all_wordline_names) for bit in range(self.rbl[1]): self.wordline_pin_list.extend(self.rbl_wordline_names[self.rbl[0] + bit]) self.used_wordline_names = [] for port in range(self.rbl[0]): self.used_wordline_names.append(self.rbl_wordline_names[port][port]) self.used_wordline_names.extend(self.all_wordline_names) for port in range(self.rbl[0], self.rbl[0] + self.rbl[1]): self.used_wordline_names.append(self.rbl_wordline_names[port][port]) self.add_pin_list(self.wordline_pin_list, "INPUT") def create_instances(self): """ Create the module instances used in this design """ self.supplies = ["vdd", "gnd"] # Main array self.bitcell_array_inst=self.add_inst(name="bitcell_array", mod=self.bitcell_array) self.connect_inst(self.all_bitline_names + self.all_wordline_names + self.supplies) # Replica columns self.replica_col_insts = [] for port in self.all_ports: if port in self.rbls: self.replica_col_insts.append(self.add_inst(name="replica_col_{}".format(port), mod=self.replica_columns[port])) self.connect_inst(self.rbl_bitline_names[port] + self.wordline_pin_list + self.supplies) else: self.replica_col_insts.append(None) # Dummy rows above/below the bitcell array (connected with the replica cell wl) self.dummy_row_replica_insts = [] # Note, this is the number of left and right even if we aren't adding the columns to this bitcell array! for port in self.all_ports: # TODO: tie to self.rbl or whatever self.dummy_row_replica_insts.append(self.add_inst(name="dummy_row_{}".format(port), mod=self.dummy_row)) self.connect_inst(self.all_bitline_names + self.rbl_wordline_names[port] + self.supplies) def create_layout(self): # This creates space for the unused wordline connections as well as the # row-based or column based power and ground lines. self.vertical_pitch = 1.1 * getattr(self, "{}_pitch".format(self.supply_stack[0])) self.horizontal_pitch = 1.1 * getattr(self, "{}_pitch".format(self.supply_stack[2])) # This is a bitcell x bitcell offset to scale self.bitcell_offset = vector(self.cell.width, self.cell.height) self.col_end_offset = vector(self.cell.width, self.cell.height) self.row_end_offset = vector(self.cell.width, self.cell.height) # Everything is computed with the main array self.bitcell_array_inst.place(offset=0) self.add_replica_columns() # Array was at (0, 0) but move everything so it is at the lower left # We move DOWN the number of left RBL even if we didn't add the column to this bitcell array # Note that this doesn't include the row/col cap array_offset = self.bitcell_offset.scale(len(self.left_rbl), self.rbl[0]) self.translate_all(array_offset.scale(-1, -1)) self.add_layout_pins() self.route_supplies() self.height = (sum(self.rbl) + self.row_size) * self.cell.height self.width = (len(self.rbls) + self.column_size) * self.cell.width self.add_boundary() self.DRC_LVS() def get_main_array_top(self): """ Return the top of the main bitcell array. """ return self.bitcell_array_inst.uy() def get_main_array_bottom(self): """ Return the bottom of the main bitcell array. """ return self.bitcell_array_inst.by() def get_main_array_left(self): """ Return the left of the main bitcell array. """ return self.bitcell_array_inst.lx() def get_main_array_right(self): """ Return the right of the main bitcell array. """ return self.bitcell_array_inst.rx() def get_replica_top(self): """ Return the top of all replica columns. """ return self.dummy_row_insts[1].by() def get_replica_bottom(self): """ Return the bottom of all replica columns. """ return self.dummy_row_insts[0].uy() def get_replica_left(self): """ Return the left of all replica columns. """ return self.dummy_col_insts[0].lx() def get_replica_right(self): """ Return the right of all replica columns. """ return self.dummy_col_insts[1].rx() def get_column_offsets(self): """ Return an array of the x offsets of all the regular bits """ offsets = [x + self.bitcell_array_inst.lx() for x in self.bitcell_array.get_column_offsets()] return offsets def add_replica_columns(self): """ Add replica columns on left and right of array """ # Grow from left to right, toward the array for bit, port in enumerate(self.left_rbl): offset = self.bitcell_offset.scale(-len(self.left_rbl) + bit, -self.rbl[0]) self.replica_col_insts[bit].place(offset) # Grow to the right of the bitcell array, array outward for bit, port in enumerate(self.right_rbl): offset = self.bitcell_array_inst.lr() + self.bitcell_offset.scale(bit, -self.rbl[0]) self.replica_col_insts[self.rbl[0] + bit].place(offset) # Replica dummy rows # Add the dummy rows even if we aren't adding the replica column to this bitcell array # These grow up, toward the array for bit in range(self.rbl[0]): dummy_offset = self.bitcell_offset.scale(0, -self.rbl[0] + bit + (-self.rbl[0] + bit) % 2) self.dummy_row_replica_insts[bit].place(offset=dummy_offset, mirror="MX" if (-self.rbl[0] + bit) % 2 else "R0") # These grow up, away from the array for bit in range(self.rbl[1]): dummy_offset = self.bitcell_offset.scale(0, bit + bit % 2) + self.bitcell_array_inst.ul() self.dummy_row_replica_insts[self.rbl[0] + bit].place(offset=dummy_offset, mirror="MX" if (self.row_size + bit) % 2 else "R0") def add_layout_pins(self): """ Add the layout pins """ # All wordlines # Main array wl for pin_name in self.all_wordline_names: pin_list = self.bitcell_array_inst.get_pins(pin_name) for pin in pin_list: self.add_layout_pin(text=pin_name, layer=pin.layer, offset=pin.ll().scale(0, 1), width=self.width, height=pin.height()) # Replica wordlines (go by the row instead of replica column because we may have to add a pin # even though the column is in another local bitcell array) for (names, inst) in zip(self.rbl_wordline_names, self.dummy_row_replica_insts): for (wl_name, pin_name) in zip(names, self.dummy_row.get_wordline_names()): pin = inst.get_pin(pin_name) self.add_layout_pin(text=wl_name, layer=pin.layer, offset=pin.ll().scale(0, 1), width=self.width, height=pin.height()) # Main array bl/br for pin_name in self.all_bitline_names: pin_list = self.bitcell_array_inst.get_pins(pin_name) for pin in pin_list: self.add_layout_pin(text=pin_name, layer=pin.layer, offset=pin.ll().scale(1, 0), width=pin.width(), height=self.height) # Replica bitlines if len(self.rbls) > 0: for (names, inst) in zip(self.rbl_bitline_names, self.replica_col_insts): pin_names = self.replica_columns[self.rbls[0]].all_bitline_names for (bl_name, pin_name) in zip(names, pin_names): pin = inst.get_pin(pin_name) self.add_layout_pin(text=bl_name, layer=pin.layer, offset=pin.ll().scale(1, 0), width=pin.width(), height=self.height) def route_supplies(self): for inst in self.insts: for pin_name in ["vdd", "gnd"]: self.copy_layout_pin(inst, pin_name) def analytical_power(self, corner, load): """Power of Bitcell array and bitline in nW.""" # Dynamic Power from Bitline bl_wire = self.gen_bl_wire() cell_load = 2 * bl_wire.return_input_cap() bl_swing = OPTS.rbl_delay_percentage freq = spice["default_event_frequency"] bitline_dynamic = self.calc_dynamic_power(corner, cell_load, freq, swing=bl_swing) # Calculate the bitcell power which currently only includes leakage cell_power = self.cell.analytical_power(corner, load) # Leakage power grows with entire array and bitlines. total_power = self.return_power(cell_power.dynamic + bitline_dynamic * self.column_size, cell_power.leakage * self.column_size * self.row_size) return total_power def gen_bl_wire(self): if OPTS.netlist_only: height = 0 else: height = self.height bl_pos = 0 bl_wire = self.generate_rc_net(int(self.row_size - bl_pos), height, drc("minwidth_m1")) bl_wire.wire_c =spice["min_tx_drain_c"] + bl_wire.wire_c # 1 access tx d/s per cell return bl_wire def graph_exclude_bits(self, targ_row=None, targ_col=None): """ Excludes bits in column from being added to graph except target """ self.bitcell_array.graph_exclude_bits(targ_row, targ_col) def graph_exclude_replica_col_bits(self): """ Exclude all replica/dummy cells in the replica columns except the replica bit. """ for port in self.left_rbl + self.right_rbl: self.replica_columns[port].exclude_all_but_replica() def get_cell_name(self, inst_name, row, col): """ Gets the spice name of the target bitcell. """ return self.bitcell_array.get_cell_name(inst_name + "{}x".format(OPTS.hier_seperator) + self.bitcell_array_inst.name, row, col) def clear_exclude_bits(self): """ Clears the bit exclusions """ self.bitcell_array.init_graph_params()