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// SPDX-FileCopyrightText: 2020 Efabless Corporation
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// SPDX-License-Identifier: Apache-2.0
`default_nettype none
`include "openram_defines.v"
/*
*-------------------------------------------------------------
*
* user_project_wrapper
*
* This wrapper enumerates all of the pins available to the
* user for the user project.
*
* An example user project is provided in this wrapper. The
* example should be removed and replaced with the actual
* user project.
*
*-------------------------------------------------------------
*/
module user_project_wrapper #(
parameter BITS = 32
) (
`ifdef USE_POWER_PINS
inout vdda1, // User area 1 3.3V supply
inout vdda2, // User area 2 3.3V supply
inout vssa1, // User area 1 analog ground
inout vssa2, // User area 2 analog ground
inout vccd1, // User area 1 1.8V supply
inout vccd2, // User area 2 1.8v supply
inout vssd1, // User area 1 digital ground
inout vssd2, // User area 2 digital ground
`endif
// Wishbone Slave ports (WB MI A)
input wb_clk_i,
input wb_rst_i,
input wbs_stb_i,
input wbs_cyc_i,
input wbs_we_i,
input [3:0] wbs_sel_i,
input [31:0] wbs_dat_i,
input [31:0] wbs_adr_i,
output wbs_ack_o,
output [31:0] wbs_dat_o,
// Logic Analyzer Signals
input [127:0] la_data_in,
output [127:0] la_data_out,
input [127:0] la_oenb,
// IOs
input [`MPRJ_IO_PADS-1:0] io_in,
output [`MPRJ_IO_PADS-1:0] io_out,
output [`MPRJ_IO_PADS-1:0] io_oeb,
// Analog (direct connection to GPIO pad---use with caution)
// Note that analog I/O is not available on the 7 lowest-numbered
// GPIO pads, and so the analog_io indexing is offset from the
// GPIO indexing by 7 (also upper 2 GPIOs do not have analog_io).
inout [`MPRJ_IO_PADS-10:0] analog_io,
// Independent clock (on independent integer divider)
input user_clock2,
// User maskable interrupt signals
output [2:0] user_irq
);
assign la_data_out[127:112] = 0;
// Shared control/data to the SRAMs
wire [`ADDR_SIZE-1:0] addr0;
wire [`DATA_SIZE-1:0] din0;
wire web0;
wire [`WMASK_SIZE-1:0] wmask0;
wire [`ADDR_SIZE-1:0] addr1;
wire [`DATA_SIZE-1:0] din1;
wire web1;
wire [`WMASK_SIZE-1:0] wmask1;
// One CSB for each SRAM
wire [`MAX_CHIPS-1:0] csb0;
wire [`MAX_CHIPS-1:0] csb1;
wire [1:0] in_select = {io_in[23],io_in[16]};
wire gpio_resetn = io_in[15];
wire gpio_clk = io_in[17];
wire gpio_scan = io_in[19];
wire gpio_sram_load = io_in[20];
wire gpio_global_csb = io_in[21];
wire gpio_in = io_in[18];
wire la_clk = la_data_in[127];
wire la_reset = la_data_in[126];
wire la_in_load = la_data_in[125];
wire la_sram_load = la_data_in[124];
wire la_global_cs = la_data_in[123];
// Only io_out[22] is output
assign io_oeb = ~(1'b1 << 22);
// Assign other outputs to 0
assign io_out[`MPRJ_IO_PADS-1:23] = 0;
wire gpio_out;
assign io_out[22] = gpio_out;
assign io_out[21:0] = 0;
// Selecting clock pin
reg clk;
always @(*) begin
case (in_select)
2'b00 : clk = la_clk;
2'b01 : clk = gpio_clk;
2'b10 : clk = wb_clk_i;
default : clk = 0;
endcase
end
// global csb is low with either GPIO or LA csb
// la_global_cs is low because default LA values are 0
wire global_csb = gpio_global_csb & ~la_global_cs;
// rstn is low with either GPIO or LA reset
// la_reset is not active low because default LA values are 0
wire rstn = gpio_resetn & ~la_reset;
openram_testchip CONTROL_LOGIC(
.resetn(rstn),
.clk(clk),
.global_csb(global_csb),
// gpio related control signals
.gpio_scan(gpio_scan),
.gpio_sram_load(gpio_sram_load),
.gpio_in(gpio_in),
.gpio_out(gpio_out),
// la related control signals
.la_in_load(la_in_load),
.la_sram_load(la_sram_load),
.la_data_in(la_data_in[111:0]),
.la_data_out(la_data_out[111:0]),
// wishbone related control signals
.wb_clk_i(wb_clk_i),
.wb_rst_i(wb_rst_i),
.wbs_stb_i(wbs_stb_i),
.wbs_cyc_i(wbs_cyc_i),
.wbs_we_i(wbs_we_i),
.wbs_sel_i(wbs_sel_i),
.wbs_dat_i(wbs_dat_i),
.wbs_adr_i(wbs_adr_i),
.wbs_ack_o(wbs_ack_o),
.wbs_dat_o(wbs_dat_o),
.wbs_sram8_data(sram8_dout0),
.wbs_sram9_data(sram9_dout0),
.wbs_sram10_data(sram10_dout0),
.wbs_sram11_data(sram11_dout0),
.wbs_sram12_data(sram12_dout0),
// Shared control/data to the SRAMs
.addr0(addr0),
.din0(din0),
// One CSB for each SRAM
.csb0(csb0),
.web0(web0),
.wmask0(wmask0),
.addr1(addr1),
.din1(din1),
// One CSB for each SRAM
.csb1(csb1),
.web1(web1),
.wmask1(wmask1),
// SRAM data outputs to be captured
.sram0_data0(sram0_data0),
.sram0_data1(sram0_data1),
.sram1_data0(sram1_data0),
.sram1_data1(sram1_data1),
.sram2_data0(sram2_data0),
.sram2_data1(sram2_data1),
.sram3_data0(sram3_data0),
.sram3_data1(sram3_data1),
.sram4_data0(sram4_data0),
.sram4_data1(sram4_data1),
.sram5_data0(sram5_data0),
.sram5_data1(sram5_data1),
.sram6_data0(sram6_data0),
.sram6_data1(sram6_data1),
.sram7_data0(sram7_data0),
.sram7_data1(sram7_data1),
.sram8_data0(sram8_data0),
.sram8_data1(sram8_data1),
.sram9_data0(sram9_data0),
.sram9_data1(sram9_data1),
.sram10_data0(sram10_data0),
.sram10_data1(sram10_data1),
.sram11_data0(sram11_data0),
.sram11_data1(sram11_data1),
.sram12_data0(sram12_data0),
.sram12_data1(sram12_data1),
.sram13_data0(sram13_data0),
.sram13_data1(sram13_data1),
.sram14_data0(sram14_data0),
.sram14_data1(sram14_data1),
.sram15_data0(sram15_data0),
.sram15_data1(sram15_data1)
);
wire [`DATA_SIZE-1:0] sram0_dout0;
wire [`DATA_SIZE-1:0] sram0_dout1;
wire [`DATA_SIZE-1:0] sram1_dout0;
wire [`DATA_SIZE-1:0] sram1_dout1;
wire [`DATA_SIZE-1:0] sram2_dout0;
wire [`DATA_SIZE-1:0] sram2_dout1;
wire [`DATA_SIZE-1:0] sram3_dout0;
wire [`DATA_SIZE-1:0] sram3_dout1;
wire [`DATA_SIZE-1:0] sram4_dout0;
wire [`DATA_SIZE-1:0] sram4_dout1;
wire [`DATA_SIZE-1:0] sram5_dout0 = 0;
wire [`DATA_SIZE-1:0] sram5_dout1 = 0;
wire [`DATA_SIZE-1:0] sram6_dout0 = 0;
wire [`DATA_SIZE-1:0] sram6_dout1 = 0;
wire [`DATA_SIZE-1:0] sram7_dout0 = 0;
wire [`DATA_SIZE-1:0] sram7_dout1 = 0;
wire [`DATA_SIZE-1:0] sram8_dout0;
wire [`DATA_SIZE-1:0] sram8_dout1 = 0;
wire [`DATA_SIZE-1:0] sram9_dout0;
wire [`DATA_SIZE-1:0] sram9_dout1 = 0;
wire [`DATA_SIZE-1:0] sram10_dout0;
wire [`DATA_SIZE-1:0] sram10_dout1 = 0;
wire [`DATA_SIZE-1:0] sram11_dout0;
wire [`DATA_SIZE-1:0] sram11_dout1 = 0;
wire [`DATA_SIZE-1:0] sram12_dout0;
wire [`DATA_SIZE-1:0] sram12_dout1 = 0;
wire [`DATA_SIZE-1:0] sram13_dout0 = 0;
wire [`DATA_SIZE-1:0] sram13_dout1 = 0;
wire [`DATA_SIZE-1:0] sram14_dout0 = 0;
wire [`DATA_SIZE-1:0] sram14_dout1 = 0;
wire [`DATA_SIZE-1:0] sram15_dout0 = 0;
wire [`DATA_SIZE-1:0] sram15_dout1 = 0;
sky130_sram_1kbyte_1rw1r_8x1024_8 SRAM0
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[0]),
.web0 (web0),
.wmask0 (wmask0),
.addr0 (addr0),
.din0 (din0),
.dout0 (sram0_dout0[7:0]),
.clk1 (clk),
.csb1 (csb1[0]),
.addr1 (addr1),
.dout1 (sram0_dout1[7:0])
);
assign sram0_dout0[`DATA_SIZE-1:8] = 0;
assign sram0_dout1[`DATA_SIZE-1:8] = 0;
sky130_sram_1kbyte_1rw1r_32x256_8 SRAM1
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[1]),
.web0 (web0),
.wmask0 (wmask0),
.addr0 (addr0),
.din0 (din0),
.dout0 (sram1_dout0),
.clk1 (clk),
.csb1 (csb1[1]),
.addr1 (addr1),
.dout1 (sram1_dout1)
);
sky130_sram_2kbyte_1rw1r_32x512_8 SRAM2
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[2]),
.web0 (web0),
.wmask0 (wmask0),
.addr0 (addr0),
.din0 (din0),
.dout0 (sram2_dout0),
.clk1 (clk),
.csb1 (csb1[2]),
.addr1 (addr1),
.dout1 (sram2_dout1)
);
sky130_sram_4kbyte_1rw1r_32x1024_8 SRAM3
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[3]),
.web0 (web0),
.wmask0 (wmask0),
.addr0 (addr0),
.din0 (din0),
.dout0 (sram3_dout0),
.clk1 (clk),
.csb1 (csb1[3]),
.addr1 (addr1),
.dout1 (sram3_dout1)
);
sky130_sram_8kbyte_1rw1r_32x2048_8 SRAM4
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[4]),
.web0 (web0),
.wmask0 (wmask0),
.addr0 (addr0),
.din0 (din0),
.dout0 (sram4_dout0),
.clk1 (clk),
.csb1 (csb1[4]),
.addr1 (addr1),
.dout1 (sram4_dout1)
);
// Not working yet
// sky130_sram_16kbyte_1rw1r_32x4096_8 SRAM6
// (
// `ifdef USE_POWER_PINS
// .vccd1(vccd1),
// .vssd1(vssd1),
// `endif
// .clk0 (clk),
// .csb0 (csb0[6]),
// .web0 (web0),
// .wmask0 (wmask0),
// .addr0 (addr0),
// .din0 (din0),
// .dout0 (sram6_dout0),
// .clk1 (clk),
// .csb1 (csb1[6]),
// .addr1 (addr1),
// .dout1 (sram6_dout1)
// );
// Single port memories
wire disconn8, disconn9, disconn10, disconn11, disconn12;
sky130_sram_1kbyte_1rw_32x256_8 SRAM8
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[8]),
.web0 (web0),
.wmask0 (wmask0),
.addr0 (addr0),
.din0 ({1'b0, din0}),
.dout0 ({disconn8, sram8_dout0}),
.spare_wen0(1'b0)
);
sky130_sram_2kbyte_1rw_32x512_8 SRAM9
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[9]),
.web0 (web0),
.wmask0 (wmask0),
.addr0 (addr0),
.din0 ({1'b0, din0}),
.dout0 ({disconn9, sram9_dout0}),
.spare_wen0(1'b0)
);
sky130_sram_4kbyte_1rw_32x1024_8 SRAM10
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[10]),
.web0 (web0),
.wmask0 (wmask0),
.addr0 (addr0),
.din0 ({1'b0, din0}),
.dout0 ({disconn10, sram10_dout0}),
.spare_wen0(1'b0)
);
wire [63:0] temp_sram11_dout0;
sky130_sram_4kbyte_1rw_64x512_8 SRAM11
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[11]),
.web0 (web0),
.wmask0 ({wmask0[3:2],4'hF,wmask0[1:0]}),
.addr0 (addr0),
.din0 ({1'b0, din0, din0}),
.dout0 ({disconn11, temp_sram11_dout0}),
.spare_wen0(1'b0)
);
assign sram11_dout0 = {temp_sram11_dout0[63:48], temp_sram11_dout0[15:0]};
wire [63:0] temp_sram12_dout0;
sky130_sram_8kbyte_1rw_64x1024_8 SRAM12
(
`ifdef USE_POWER_PINS
.vccd1(vccd1),
.vssd1(vssd1),
`endif
.clk0 (clk),
.csb0 (csb0[12]),
.web0 (web0),
.wmask0 ({wmask0[3:2],4'hF,wmask0[1:0]}),
.addr0 (addr0),
.din0 ({1'b0, din0, din0}),
.dout0 ({disconn12, temp_sram12_dout0}),
.spare_wen0(1'b0)
);
assign sram12_dout0 = {temp_sram12_dout0[63:48], temp_sram12_dout0[15:0]};
// Hold dout from SRAM
// clocked by SRAM clk
reg [`DATA_SIZE-1:0] sram0_data0;
reg [`DATA_SIZE-1:0] sram0_data1;
reg [`DATA_SIZE-1:0] sram1_data0;
reg [`DATA_SIZE-1:0] sram1_data1;
reg [`DATA_SIZE-1:0] sram2_data0;
reg [`DATA_SIZE-1:0] sram2_data1;
reg [`DATA_SIZE-1:0] sram3_data0;
reg [`DATA_SIZE-1:0] sram3_data1;
reg [`DATA_SIZE-1:0] sram4_data0;
reg [`DATA_SIZE-1:0] sram4_data1;
reg [`DATA_SIZE-1:0] sram5_data0;
reg [`DATA_SIZE-1:0] sram5_data1;
reg [`DATA_SIZE-1:0] sram6_data0;
reg [`DATA_SIZE-1:0] sram6_data1;
reg [`DATA_SIZE-1:0] sram7_data0;
reg [`DATA_SIZE-1:0] sram7_data1;
reg [`DATA_SIZE-1:0] sram8_data0;
reg [`DATA_SIZE-1:0] sram8_data1;
reg [`DATA_SIZE-1:0] sram9_data0;
reg [`DATA_SIZE-1:0] sram9_data1;
reg [`DATA_SIZE-1:0] sram10_data0;
reg [`DATA_SIZE-1:0] sram10_data1;
reg [`DATA_SIZE-1:0] sram11_data0;
reg [`DATA_SIZE-1:0] sram11_data1;
reg [`DATA_SIZE-1:0] sram12_data0;
reg [`DATA_SIZE-1:0] sram12_data1;
reg [`DATA_SIZE-1:0] sram13_data0;
reg [`DATA_SIZE-1:0] sram13_data1;
reg [`DATA_SIZE-1:0] sram14_data0;
reg [`DATA_SIZE-1:0] sram14_data1;
reg [`DATA_SIZE-1:0] sram15_data0;
reg [`DATA_SIZE-1:0] sram15_data1;
always @(posedge clk) begin
if (!rstn) begin
sram0_data0 <= 0;
sram0_data1 <= 0;
sram1_data0 <= 0;
sram1_data1 <= 0;
sram2_data0 <= 0;
sram2_data1 <= 0;
sram3_data0 <= 0;
sram3_data1 <= 0;
sram4_data0 <= 0;
sram4_data1 <= 0;
sram5_data0 <= 0;
sram5_data1 <= 0;
sram6_data0 <= 0;
sram6_data1 <= 0;
sram7_data0 <= 0;
sram7_data1 <= 0;
sram8_data0 <= 0;
sram8_data1 <= 0;
sram9_data0 <= 0;
sram9_data1 <= 0;
sram10_data0 <= 0;
sram10_data1 <= 0;
sram11_data0 <= 0;
sram11_data1 <= 0;
sram12_data0 <= 0;
sram12_data1 <= 0;
sram13_data0 <= 0;
sram13_data1 <= 0;
sram14_data0 <= 0;
sram14_data1 <= 0;
sram15_data0 <= 0;
sram15_data1 <= 0;
end
else begin
sram0_data0 <= sram0_dout0;
sram0_data1 <= sram0_dout1;
sram1_data0 <= sram1_dout0;
sram1_data1 <= sram1_dout1;
sram2_data0 <= sram2_dout0;
sram2_data1 <= sram2_dout1;
sram3_data0 <= sram3_dout0;
sram3_data1 <= sram3_dout1;
sram4_data0 <= sram4_dout0;
sram4_data1 <= sram4_dout1;
sram5_data0 <= sram5_dout0;
sram5_data1 <= sram5_dout1;
sram6_data0 <= sram6_dout0;
sram6_data1 <= sram6_dout1;
sram7_data0 <= sram7_dout0;
sram7_data1 <= sram7_dout1;
sram8_data0 <= sram8_dout0;
sram8_data1 <= sram8_dout1;
sram9_data0 <= sram9_dout0;
sram9_data1 <= sram9_dout1;
sram10_data0 <= sram10_dout0;
sram10_data1 <= sram10_dout1;
sram11_data0 <= sram11_dout0;
sram11_data1 <= sram11_dout1;
sram12_data0 <= sram12_dout0;
sram12_data1 <= sram12_dout1;
sram13_data0 <= sram13_dout0;
sram13_data1 <= sram13_dout1;
sram14_data0 <= sram14_dout0;
sram14_data1 <= sram14_dout1;
sram15_data0 <= sram15_dout0;
sram15_data1 <= sram15_dout1;
end
end
endmodule // user_project_wrapper
`default_nettype wire