# See LICENSE for licensing information. # # Copyright (c) 2016-2021 Regents of the University of California and The Board # of Regents for the Oklahoma Agricultural and Mechanical College # (acting for and on behalf of Oklahoma State University) # All rights reserved. # from math import ceil, log from openram.sram_factory import factory from openram.base import vector, design from openram import OPTS from openram.tech import drc class rom_decoder(design): def __init__(self, num_outputs, cols, strap_spacing, name="", route_layer="m1", output_layer="m2"): # word lines/ rows / inputs in the base array become the address lines / cols / inputs in the decoder # bit lines / cols / outputs in the base array become the word lines / rows / outputs in the decoder # array gets rotated 90deg so that rows/cols switch self.strap_spacing=strap_spacing self.num_outputs = num_outputs self.num_inputs = ceil(log(num_outputs, 2)) self.create_decode_map() # for i in range(2 * self.num_inputs): print(self.decode_map[i]) super().__init__(name) b = factory.create(module_type=OPTS.bitcell) self.cell_height = b.height self.route_layer = route_layer self.output_layer = output_layer self.inv_route_layer = "m2" self.cols=cols self.create_netlist() self.create_layout() def create_netlist(self): self.add_modules() self.add_pins() self.create_instances() def create_layout(self): self.setup_layout_constants() self.place_array() self.place_input_buffer() self.place_driver() self.route_outputs() self.width = self.array_inst.height + self.wordline_buf_inst.width self.height = self.array_inst.width + self.buf_inst.height self.connect_inputs() # self.route_supplies() self.add_boundary() def setup_layout_constants(self): self.inv_route_width = drc["minwidth_{}".format(self.inv_route_layer)] def create_decode_map(self): self.decode_map = [] # create decoding map that will be the bitmap for the rom decoder # row/col order in the map will be switched in the placed decoder/ for col in range(self.num_inputs): # odd cols are address # even cols are address bar col_array = [] inv_col_array = [] for row in range(self.num_outputs): addr_idx = -col - 1 addr = format(row, 'b') if col >= len(addr) : bin_digit = 0 else: bin_digit = int(addr[addr_idx]) col_array.append(bin_digit) # print("addr {0}, at indx {1}, digit {2}".format(addr, addr_idx, bin_digit)) if bin_digit == 0 : inv_col_array.append(1) else : inv_col_array.append(0) self.decode_map.append(col_array) self.decode_map.append(inv_col_array) self.decode_map.reverse() def add_pins(self): for i in range(self.num_inputs): self.add_pin("A{0}".format(i), "INPUT") for j in range(self.num_outputs): self.add_pin("wl_{0}".format(j), "OUTPUT") self.add_pin("precharge_gate", "INPUT") self.add_pin("vdd", "POWER") self.add_pin("gnd", "GROUND") def add_modules(self): self.control_array = factory.create(module_type="rom_address_control_array", cols=self.num_inputs) self.wordline_buf = factory.create(module_type="rom_wordline_driver_array", module_name="{}_wordline_buffer".format(self.name), \ rows=self.num_outputs, \ cols=self.cols) self.array_mod = factory.create(module_type="rom_base_array", \ module_name="{}_array".format(self.name), \ cols=self.num_outputs, \ rows=2 * self.num_inputs, \ bitmap=self.decode_map, strap_spacing = self.strap_spacing, route_layer=self.route_layer, output_layer=self.output_layer) def create_instances(self): self.create_array_inst() self.create_input_buffer() self.create_wordline_buffer() def create_input_buffer(self): name = "pre_control_array" self.buf_inst = self.add_inst(name=name, mod=self.control_array) control_pins = [] for i in range(self.num_inputs): control_pins.append("A{0}".format(i)) control_pins.append("A{0}_int".format(i)) control_pins.append("Abar{0}_int".format(i)) control_pins.append("clk") control_pins.append("vdd") control_pins.append("gnd") self.connect_inst(control_pins) def create_array_inst(self): self.array_inst = self.add_inst(name="decode_array_inst", mod=self.array_mod) array_pins = [] for j in range(self.num_outputs): name = "wl_int{0}".format(j) array_pins.append(name) for i in reversed(range(self.num_inputs)): array_pins.append("inbar_{0}".format(i)) array_pins.append("in_{0}".format(i)) array_pins.append("precharge_gate") array_pins.append("vdd") array_pins.append("gnd") self.connect_inst(array_pins) def create_wordline_buffer(self): self.wordline_buf_inst = self.add_inst("rom_wordline_driver", mod=self.wordline_buf) in_pins = ["wl_int{}".format(wl) for wl in range(self.num_outputs)] out_pins = ["wl_{}".format(wl) for wl in range(self.num_outputs)] pwr_pins = ["vdd", "gnd"] self.connect_inst(in_pins + out_pins + pwr_pins) def place_input_buffer(self): wl = self.array_mod.row_size - 1 align = self.array_inst.get_pin(self.array_mod.wordline_names[0][wl]).cx() - self.buf_inst.get_pin("A0_out").cx() print("align: {}".format(align)) self.buf_inst.place(vector(align, 0)) def place_array(self): offset = vector(self.array_mod.height, self.control_array.height + self.m1_width + self.poly_contact.width) self.array_inst.place(offset, rotate=90) def place_driver(self): offset = vector(self.array_inst.height + self.m1_width, self.array_inst.by()) self.wordline_buf_inst.place(offset) # calculate the offset between the decode array and the buffer inputs now that their zeros are aligned pin_offset = self.array_inst.get_pin("bl_0_0").cy() - self.wordline_buf_inst.get_pin("in_0").cy() self.wordline_buf_inst.place(offset + vector(0, pin_offset)) def route_outputs(self): for j in range(self.num_outputs): self.copy_layout_pin(self.wordline_buf_inst, "out_{}".format(j), "wl_{}".format(j)) array_pins = [self.array_inst.get_pin("bl_0_{}".format(bl)) for bl in range(self.num_outputs)] driver_pins = [self.wordline_buf_inst.get_pin("in_{}".format(bl)) for bl in range(self.num_outputs)] route_pins = array_pins + driver_pins self.connect_row_pins(self.output_layer, route_pins, round=True) def connect_inputs(self): self.copy_layout_pin(self.array_inst, "precharge") for i in range(self.num_inputs): wl = (self.num_inputs - i) * 2 - 1 wl_bar = wl - 1 addr_pin = self.array_inst.get_pin(self.array_mod.wordline_names[0][wl]) addr_bar_pin = self.array_inst.get_pin(self.array_mod.wordline_names[0][wl_bar]) addr_out_pin = self.buf_inst.get_pin("A{}_out".format(i)) addr_bar_out_pin = self.buf_inst.get_pin("Abar{}_out".format(i)) addr_middle = vector(addr_pin.cx(), addr_out_pin.cy()) addr_bar_middle = vector(addr_bar_pin.cx(), addr_bar_out_pin.cy()) self.add_path(self.inv_route_layer, [addr_out_pin.center(), addr_middle, addr_pin.center()]) self.add_path(self.inv_route_layer, [addr_bar_out_pin.center(), addr_bar_middle, addr_bar_pin.center()]) # self.add_segment_center(self.inv_route_layer, addr_bar_middle + vector(0, self.inv_route_width * 0.5), addr_bar_out_pin.center() + vector(0, self.inv_route_width * 0.5), self.inv_route_width) def route_supplies(self): minwidth = drc["minwidth_{}".format(self.inv_route_layer)] pitch = drc["{0}_to_{0}".format(self.inv_route_layer)] # route decode array vdd and inv array vdd together array_vdd = self.array_inst.get_pin("vdd") inv_vdd = self.buf_inst.get_pins("vdd")[-1] end = vector(array_vdd.cx(), inv_vdd.cy() - 0.5 * minwidth) self.add_segment_center("m1", array_vdd.center(), end) end = vector(array_vdd.cx() + 0.5 * minwidth, inv_vdd.cy()) self.add_segment_center(self.route_layer, inv_vdd.center(), end) end = vector(array_vdd.cx(), inv_vdd.cy()) self.add_via_stack_center(end, self.route_layer, "m1") self.add_layout_pin_rect_center("vdd", "m1", end) # route pin on inv gnd inv_gnd = self.buf_inst.get_pins("gnd")[0] array_gnd = self.array_inst.get_pins("gnd") # add x jog start = vector(array_gnd[0].cx(), inv_gnd.cy()) self.add_via_stack_center(start, self.route_layer, "m1") self.add_layout_pin_rect_center("gnd", "m1", start) end = array_gnd[0].center() self.add_segment_center("m1", start, end) # add y jog width = minwidth height = array_gnd[0].uy() - array_gnd[-1].uy() + minwidth offset = vector(-0.5 *width ,0.5 * (array_gnd[0].cy() + array_gnd[-1].cy())) start = end - vector(0, 0.5 * minwidth) end = vector(start.x, array_gnd[1].uy())