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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
/*
*-------------------------------------------------------------
*
* 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.
*
* THIS FILE HAS BEEN GENERATED USING multi_tools_project CODEGEN
* IF YOU NEED TO MAKE EDITS TO IT, EDIT codegen/caravel_iface_header.txt
*
*-------------------------------------------------------------
*/
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
);
// generate active wires
wire [31: 0] active;
assign active = la_data_in[31:0];
// split remaining 96 logic analizer wires into 3 chunks
wire [31: 0] la1_data_in, la1_data_out, la1_oenb;
assign la1_data_in = la_data_in[63:32];
assign la1_data_out = la_data_out[63:32];
assign la1_oenb = la_oenb[63:32];
wire [31: 0] la2_data_in, la2_data_out, la2_oenb;
assign la2_data_in = la_data_in[95:64];
assign la2_data_out = la_data_out[95:64];
assign la2_oenb = la_oenb[95:64];
wire [31: 0] la3_data_in, la3_data_out, la3_oenb;
assign la3_data_in = la_data_in[127:96];
assign la3_data_out = la_data_out[127:96];
assign la3_oenb = la_oenb[127:96];
// Signals connecting user project to wishbone bridge
wire wbs_uprj_stb_i;
wire wbs_uprj_cyc_i;
wire wbs_uprj_we_i;
wire [3:0] wbs_uprj_sel_i;
wire [31:0] wbs_uprj_dat_i;
wire [31:0] wbs_uprj_adr_i;
wire wbs_uprj_ack_o;
wire [31:0] wbs_uprj_dat_o;
// Signals connecting user project to OpenRAM via its wrapper
// shared openram wishbone bus wires
wire rambus_wb_clk_o; // clock
wire rambus_wb_rst_o; // reset
wire rambus_wb_stb_o; // write strobe
wire rambus_wb_cyc_o; // cycle
wire rambus_wb_we_o ; // write enable
wire [3:0] rambus_wb_sel_o; // write word select
wire [31:0] rambus_wb_dat_o; // ram data out
wire [9:0] rambus_wb_adr_o; // 10bit address
wire rambus_wb_ack_i; // ack
wire [31:0] rambus_wb_dat_i; // ram data in
// Signals connecting OpenRAM wrapper to wishbone bridge
wire wbs_oram_stb_i;
wire wbs_oram_cyc_i;
wire wbs_oram_we_i;
wire [3:0] wbs_oram_sel_i;
wire [31:0] wbs_oram_dat_i;
wire [10:0] wbs_oram_adr_i; // 11bit address (latencies CSR + 1kB OpenRAM)
wire wbs_oram_ack_o;
wire [31:0] wbs_oram_dat_o;
// Bridge splitting caravel wishbone traffic into two streams: user project and OpenRAM wrapper
wb_bridge_2way #(
.BUSB_ADDR_WIDTH(11)
) wb_bridge_2way(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
// Wishbone UFP (Upward Facing Port) => caravel / picorv32
.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[3:0]),
.wbs_dat_i (wbs_dat_i),
.wbs_adr_i (wbs_adr_i),
.wbs_ack_o (wbs_ack_o),
.wbs_dat_o (wbs_dat_o),
// Wishbone A (Downward Facing Port) => user project
.wbm_a_stb_o (wbs_uprj_stb_i),
.wbm_a_cyc_o (wbs_uprj_cyc_i),
.wbm_a_we_o (wbs_uprj_we_i),
.wbm_a_sel_o (wbs_uprj_sel_i[3:0]),
.wbm_a_dat_i (wbs_uprj_dat_o[31:0]),
.wbm_a_adr_o (wbs_uprj_adr_i[31:0]),
.wbm_a_ack_i (wbs_uprj_ack_o),
.wbm_a_dat_o (wbs_uprj_dat_i[31:0]),
// Wishbone B (Downward Facing Port) => OpenRAM wrapper/shim
.wbm_b_stb_o (wbs_oram_stb_i),
.wbm_b_cyc_o (wbs_oram_cyc_i),
.wbm_b_we_o (wbs_oram_we_i),
.wbm_b_sel_o (wbs_oram_sel_i[3:0]),
.wbm_b_dat_i (wbs_oram_dat_o[31:0]),
.wbm_b_adr_o (wbs_oram_adr_i[10:0]),
.wbm_b_ack_i (wbs_oram_ack_o),
.wbm_b_dat_o (wbs_oram_dat_i[31:0])
);
// Signals connecting OpenRAM memory block to OpenRAM wrapper
wire oram_clk0; // clock
wire oram_csb0; // active low chip select
wire oram_web0; // active low write control
wire [3:0] oram_wmask0; // write (byte) mask
wire [7:0] oram_addr0; // address
wire [31:0] oram_din0; // data in
wire [31:0] oram_dout0; // data out
wire oram_clk1; // clock
wire oram_csb1; // active low chip select
wire [7:0] oram_addr1; // address
wire [31:0] oram_dout1; // data out
// Dual port OpenRAM wrapper for wishbone
wb_openram_wrapper #(
.RAM_ADDR_WIDTH(8)
) wb_openram_wrapper(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
// Selecting which port will be writable (0 -> A, 1 -> B)
.writable_port_req (active[31]),
// Wishbone port A <= caravel (via wb_bridge)
.wb_a_clk_i (wb_clk_i),
.wb_a_rst_i (wb_rst_i),
.wbs_a_stb_i (wbs_oram_stb_i),
.wbs_a_cyc_i (wbs_oram_cyc_i),
.wbs_a_we_i (wbs_oram_we_i),
.wbs_a_sel_i (wbs_oram_sel_i[3:0]),
.wbs_a_dat_i (wbs_oram_dat_i[31:0]),
.wbs_a_adr_i (wbs_oram_adr_i[10:0]),
.wbs_a_ack_o (wbs_oram_ack_o),
.wbs_a_dat_o (wbs_oram_dat_o[31:0]),
// Wishbone port B <= user project (rambus)
.wb_b_clk_i (rambus_wb_clk_o),
.wb_b_rst_i (rambus_wb_rst_o),
.wbs_b_stb_i (rambus_wb_stb_o),
.wbs_b_cyc_i (rambus_wb_cyc_o),
.wbs_b_we_i (rambus_wb_we_o),
.wbs_b_sel_i (rambus_wb_sel_o[3:0]),
.wbs_b_dat_i (rambus_wb_dat_o[31:0]),
.wbs_b_adr_i (rambus_wb_adr_o[9:0]),
.wbs_b_ack_o (rambus_wb_ack_i),
.wbs_b_dat_o (rambus_wb_dat_i[31:0]),
// OpenRAM interface - almost dual port: RW + R
// Port 0: RW
.ram_clk0 (oram_clk0),
.ram_csb0 (oram_csb0),
.ram_web0 (oram_web0),
.ram_wmask0 (oram_wmask0[3:0]),
.ram_addr0 (oram_addr0[7:0]),
.ram_din0 (oram_din0[31:0]),
.ram_dout0 (oram_dout0[31:0]),
// Port 1: R
.ram_clk1 (oram_clk1),
.ram_csb1 (oram_csb1),
.ram_addr1 (oram_addr1[7:0]),
.ram_dout1 (oram_dout1[31:0])
);
// OpenRAM block
sky130_sram_1kbyte_1rw1r_32x256_8 openram_1kB
(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.clk0 (oram_clk0),
.csb0 (oram_csb0),
.web0 (oram_web0),
.wmask0 (oram_wmask0[3:0]),
.addr0 (oram_addr0[7:0]),
.din0 (oram_din0[31:0]),
.dout0 (oram_dout0[31:0]),
.clk1 (oram_clk1),
.csb1 (oram_csb1),
.addr1 (oram_addr1[7:0]),
.dout1 (oram_dout1[31:0])
);
// start of user project module instantiation
wrapped_function_generator wrapped_function_generator_0(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0]),
.wb_rst_i (wb_rst_i),
.wbs_stb_i (wbs_uprj_stb_i),
.wbs_cyc_i (wbs_uprj_cyc_i),
.wbs_we_i (wbs_uprj_we_i),
.wbs_sel_i (wbs_uprj_sel_i[3:0]),
.wbs_dat_i (wbs_uprj_dat_i[31:0]),
.wbs_adr_i (wbs_uprj_adr_i[31:0]),
.wbs_ack_o (wbs_uprj_ack_o),
.wbs_dat_o (wbs_uprj_dat_o[31:0]),
.rambus_wb_clk_o (rambus_wb_clk_o),
.rambus_wb_rst_o (rambus_wb_rst_o),
.rambus_wb_stb_o (rambus_wb_stb_o),
.rambus_wb_cyc_o (rambus_wb_cyc_o),
.rambus_wb_we_o (rambus_wb_we_o),
.rambus_wb_sel_o (rambus_wb_sel_o[3:0]),
.rambus_wb_dat_o (rambus_wb_dat_o[31:0]),
.rambus_wb_adr_o (rambus_wb_adr_o[9:0]),
.rambus_wb_ack_i (rambus_wb_ack_i),
.rambus_wb_dat_i (rambus_wb_dat_i[31:0])
);
wrapped_vga_clock wrapped_vga_clock_1(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[1]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
wrapped_frequency_counter wrapped_frequency_counter_2(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[2]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
wrapped_rgb_mixer wrapped_rgb_mixer_3(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[3]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
wrapped_hack_soc_dffram wrapped_hack_soc_dffram_11(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[11]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
wrapped_teras wrapped_teras_13(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[13]),
.wb_rst_i (wb_rst_i),
.wbs_stb_i (wbs_uprj_stb_i),
.wbs_cyc_i (wbs_uprj_cyc_i),
.wbs_we_i (wbs_uprj_we_i),
.wbs_sel_i (wbs_uprj_sel_i[3:0]),
.wbs_dat_i (wbs_uprj_dat_i[31:0]),
.wbs_adr_i (wbs_uprj_adr_i[31:0]),
.wbs_ack_o (wbs_uprj_ack_o),
.wbs_dat_o (wbs_uprj_dat_o[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
wrapped_alu74181 wrapped_alu74181_7(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[7]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
wrapped_vgademo_on_fpga wrapped_vgademo_on_fpga_5(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[5]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
wrapped_silife wrapped_silife_4(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[4]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0]),
.wb_rst_i (wb_rst_i),
.wbs_stb_i (wbs_uprj_stb_i),
.wbs_cyc_i (wbs_uprj_cyc_i),
.wbs_we_i (wbs_uprj_we_i),
.wbs_sel_i (wbs_uprj_sel_i[3:0]),
.wbs_dat_i (wbs_uprj_dat_i[31:0]),
.wbs_adr_i (wbs_uprj_adr_i[31:0]),
.wbs_ack_o (wbs_uprj_ack_o),
.wbs_dat_o (wbs_uprj_dat_o[31:0])
);
wrapped_acorn_prng wrapped_acorn_prng_9(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[9]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
wrapped_hsv_mixer wrapped_hsv_mixer_10(
`ifdef USE_POWER_PINS
.vccd1 (vccd1),
.vssd1 (vssd1),
`endif
.wb_clk_i (wb_clk_i),
.active (active[10]),
.la1_data_in (la1_data_in[31:0]),
.la1_data_out (la1_data_out[31:0]),
.la1_oenb (la1_oenb[31:0]),
.io_in (io_in[37:0]),
.io_out (io_out[37:0]),
.io_oeb (io_oeb[37:0])
);
// end of module instantiation
endmodule // user_project_wrapper
`default_nettype wire