| `default_nettype none |
| //---------------------------------------------------------------------------- |
| // Module: simple_spi_master |
| // |
| //---------------------------------------------------------------------------- |
| // Copyright (C) 2019 efabless, inc. |
| // |
| // This source file may be used and distributed without |
| // restriction provided that this copyright statement is not |
| // removed from the file and that any derivative work contains |
| // the original copyright notice and the associated disclaimer. |
| // |
| // This source file is free software; you can redistribute it |
| // and/or modify it under the terms of the GNU Lesser General |
| // Public License as published by the Free Software Foundation; |
| // either version 2.1 of the License, or (at your option) any |
| // later version. |
| // |
| // This source is distributed in the hope that it will be |
| // useful, but WITHOUT ANY WARRANTY; without even the implied |
| // warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR |
| // PURPOSE. See the GNU Lesser General Public License for more |
| // details. |
| // |
| //-------------------------------------------------------------------- |
| // |
| // resetn: active low async reset |
| // clk: master clock (before prescaler) |
| // stream: |
| // 0 = apply/release CSB separately for each byte |
| // 1 = apply CSB until stream bit is cleared |
| // mlb: |
| // 0 = msb 1st |
| // 1 = lsb 1st |
| // invsck: |
| // 0 = normal SCK |
| // 1 = inverted SCK |
| // invcsb: |
| // 0 = normal CSB (active low) |
| // 1 = inverted CSB (active high) |
| // mode: |
| // 0 = read and change data on opposite SCK edges |
| // 1 = read and change data on the same SCK edge |
| // enable: |
| // 0 = disable the SPI master |
| // 1 = enable the SPI master |
| // irqena: |
| // 0 = disable interrupt |
| // 1 = enable interrupt |
| // hkconn: |
| // 0 = housekeeping SPI disconnected |
| // 1 = housekeeping SPI connected (when SPI master enabled) |
| // prescaler: count (in master clock cycles) of 1/2 SCK cycle. |
| // |
| // reg_dat_we: |
| // 1 = data write enable |
| // reg_dat_re: |
| // 1 = data read enable |
| // reg_cfg_*: Signaling for read/write of configuration register |
| // reg_dat_*: Signaling for read/write of data register |
| // |
| // err_out: Indicates attempt to read/write before data ready |
| // (failure to wait for reg_dat_wait to clear) |
| // |
| // Between "mode" and "invsck", all four standard SPI modes are supported |
| // |
| //-------------------------------------------------------------------- |
| |
| module simple_spi_master_wb #( |
| parameter BASE_ADR = 32'h2100_0000, |
| parameter CONFIG = 8'h00, |
| parameter DATA = 8'h04 |
| ) ( |
| input wb_clk_i, |
| input wb_rst_i, |
| input [31:0] wb_adr_i, |
| input [31:0] wb_dat_i, |
| input [3:0] wb_sel_i, |
| input wb_we_i, |
| input wb_cyc_i, |
| input wb_stb_i, |
| output wb_ack_o, |
| output [31:0] wb_dat_o, |
| |
| output hk_connect, // Connect to housekeeping SPI |
| input sdi, // SPI input |
| output csb, // SPI chip select |
| output sck, // SPI clock |
| output sdo, // SPI output |
| output sdoenb, // SPI output enable |
| output irq // interrupt output |
| ); |
| |
| wire [31:0] simple_spi_master_reg_cfg_do; |
| wire [31:0] simple_spi_master_reg_dat_do; |
| |
| wire resetn = ~wb_rst_i; |
| wire valid = wb_stb_i && wb_cyc_i; |
| wire simple_spi_master_reg_cfg_sel = valid && (wb_adr_i == (BASE_ADR | CONFIG)); |
| wire simple_spi_master_reg_dat_sel = valid && (wb_adr_i == (BASE_ADR | DATA)); |
| |
| wire [1:0] reg_cfg_we = (simple_spi_master_reg_cfg_sel) ? |
| (wb_sel_i[1:0] & {2{wb_we_i}}): 2'b00; |
| wire reg_dat_we = (simple_spi_master_reg_dat_sel) ? (wb_sel_i[0] & wb_we_i): 1'b0; |
| |
| wire [31:0] mem_wdata = wb_dat_i; |
| wire reg_dat_re = simple_spi_master_reg_dat_sel && !wb_sel_i && ~wb_we_i; |
| |
| assign wb_dat_o = (simple_spi_master_reg_cfg_sel) ? simple_spi_master_reg_cfg_do : |
| simple_spi_master_reg_dat_do; |
| assign wb_ack_o = (simple_spi_master_reg_cfg_sel || simple_spi_master_reg_dat_sel) |
| && (!reg_dat_wait); |
| |
| simple_spi_master spi_master ( |
| .resetn(resetn), |
| .clk(wb_clk_i), |
| .reg_cfg_we(reg_cfg_we), |
| .reg_cfg_di(mem_wdata), |
| .reg_cfg_do(simple_spi_master_reg_cfg_do), |
| .reg_dat_we(reg_dat_we), |
| .reg_dat_re(reg_dat_re), |
| .reg_dat_di(mem_wdata), |
| .reg_dat_do(simple_spi_master_reg_dat_do), |
| .reg_dat_wait(reg_dat_wait), |
| |
| .hk_connect(hk_connect), // Attach to housekeeping SPI slave |
| .sdi(sdi), // SPI input |
| .csb(csb), // SPI chip select |
| .sck(sck), // SPI clock |
| .sdo(sdo), // SPI output |
| .irq_out(irq) // interrupt |
| ); |
| endmodule |
| |
| module simple_spi_master ( |
| input resetn, |
| input clk, // master clock (assume 100MHz) |
| |
| input [1:0] reg_cfg_we, |
| input [31:0] reg_cfg_di, |
| output [31:0] reg_cfg_do, |
| |
| input reg_dat_we, |
| input reg_dat_re, |
| input [31:0] reg_dat_di, |
| output [31:0] reg_dat_do, |
| output reg_dat_wait, |
| output irq_out, |
| output err_out, |
| |
| output hk_connect, // Connect to housekeeping SPI |
| input sdi, // SPI input |
| output csb, // SPI chip select |
| output sck, // SPI clock |
| output sdo // SPI output |
| ); |
| |
| parameter IDLE = 2'b00; |
| parameter SENDL = 2'b01; |
| parameter SENDH = 2'b10; |
| parameter FINISH = 2'b11; |
| |
| reg done; |
| reg isdo, hsck, icsb; |
| reg [1:0] state; |
| reg isck; |
| reg err_out; |
| |
| reg [7:0] treg, rreg, d_latched; |
| reg [2:0] nbit; |
| |
| reg [7:0] prescaler; |
| reg [7:0] count; |
| reg invsck; |
| reg invcsb; |
| reg mlb; |
| reg irqena; |
| reg stream; |
| reg mode; |
| reg enable; |
| reg hkconn; |
| |
| wire csb; |
| wire irq_out; |
| wire sck; |
| wire sdo; |
| wire sdoenb; |
| wire hk_connect; |
| |
| // Define behavior for inverted SCK and inverted CSB |
| assign csb = (enable == 1'b0) ? 1'bz : (invcsb) ? ~icsb : icsb; |
| assign sck = (enable == 1'b0) ? 1'bz : (invsck) ? ~isck : isck; |
| |
| // No bidirectional 3-pin mode defined, so SDO is enabled whenever CSB is low. |
| assign sdoenb = icsb; |
| // assign sdo = (enable == 1'b0) ? 1'bz : icsb ? 1'bz : isdo; |
| assign sdo = (enable == 1'b0) ? 1'bz : isdo; |
| |
| assign irq_out = irqena & done; |
| assign hk_connect = (enable == 1'b1) ? hkconn : 1'b0; |
| |
| // Read configuration and data registers |
| assign reg_cfg_do = {16'd0, hkconn, irqena, enable, stream, mode, |
| invsck, invcsb, mlb, prescaler}; |
| assign reg_dat_wait = ~done; |
| assign reg_dat_do = done ? rreg : ~0; |
| |
| // Write configuration register |
| always @(posedge clk or negedge resetn) begin |
| if (resetn == 1'b0) begin |
| prescaler <= 8'd2; |
| invcsb <= 1'b0; |
| invsck <= 1'b0; |
| mlb <= 1'b0; |
| enable <= 1'b0; |
| irqena <= 1'b0; |
| stream <= 1'b0; |
| mode <= 1'b0; |
| hkconn <= 1'b0; |
| end else begin |
| if (reg_cfg_we[0]) prescaler <= reg_cfg_di[7:0]; |
| if (reg_cfg_we[1]) begin |
| mlb <= reg_cfg_di[8]; |
| invcsb <= reg_cfg_di[9]; |
| invsck <= reg_cfg_di[10]; |
| mode <= reg_cfg_di[11]; |
| stream <= reg_cfg_di[12]; |
| enable <= reg_cfg_di[13]; |
| irqena <= reg_cfg_di[14]; |
| hkconn <= reg_cfg_di[15]; |
| end //reg_cfg_we[1] |
| end //resetn |
| end //always |
| |
| // Watch for read and write enables on clk, not hsck, so as not to |
| // miss them. |
| |
| reg w_latched, r_latched; |
| |
| always @(posedge clk or negedge resetn) begin |
| if (resetn == 1'b0) begin |
| err_out <= 1'b0; |
| w_latched <= 1'b0; |
| r_latched <= 1'b0; |
| d_latched <= 8'd0; |
| end else begin |
| // Clear latches on SEND, otherwise latch when seen |
| if (state == SENDL || state == SENDH) begin |
| if (reg_dat_we == 1'b0) begin |
| w_latched <= 1'b0; |
| end |
| end else begin |
| if (reg_dat_we == 1'b1) begin |
| if (done == 1'b0 && w_latched == 1'b1) begin |
| err_out <= 1'b1; |
| end else begin |
| w_latched <= 1'b1; |
| d_latched <= reg_dat_di[7:0]; |
| err_out <= 1'b0; |
| end |
| end |
| end |
| |
| if (reg_dat_re == 1'b1) begin |
| if (r_latched == 1'b1) begin |
| r_latched <= 1'b0; |
| end else begin |
| err_out <= 1'b1; // byte not available |
| end |
| end else if (state == FINISH) begin |
| r_latched <= 1'b1; |
| end if (state == SENDL || state == SENDH) begin |
| if (r_latched == 1'b1) begin |
| err_out <= 1'b1; // last byte was never read |
| end else begin |
| r_latched <= 1'b0; |
| end |
| end |
| end |
| end |
| |
| // State transition. |
| |
| always @(posedge hsck or negedge resetn) begin |
| if (resetn == 1'b0) begin |
| state <= IDLE; |
| nbit <= 3'd0; |
| icsb <= 1'b1; |
| done <= 1'b1; |
| end else begin |
| if (state == IDLE) begin |
| if (w_latched == 1'b1) begin |
| state <= SENDL; |
| nbit <= 3'd0; |
| icsb <= 1'b0; |
| done <= 1'b0; |
| end else begin |
| icsb <= ~stream; |
| end |
| end else if (state == SENDL) begin |
| state <= SENDH; |
| end else if (state == SENDH) begin |
| nbit <= nbit + 1; |
| if (nbit == 3'd7) begin |
| state <= FINISH; |
| end else begin |
| state <= SENDL; |
| end |
| end else if (state == FINISH) begin |
| icsb <= ~stream; |
| done <= 1'b1; |
| state <= IDLE; |
| end |
| end |
| end |
| |
| // Set up internal clock. The enable bit gates the internal clock |
| // to shut down the master SPI when disabled. |
| |
| always @(posedge clk or negedge resetn) begin |
| if (resetn == 1'b0) begin |
| count <= 8'd0; |
| hsck <= 1'b0; |
| end else begin |
| if (enable == 1'b0) begin |
| count <= 8'd0; |
| end else begin |
| count <= count + 1; |
| if (count == prescaler) begin |
| hsck <= ~hsck; |
| count <= 8'd0; |
| end // count |
| end // enable |
| end // resetn |
| end // always |
| |
| // sck is half the rate of hsck |
| |
| always @(posedge hsck or negedge resetn) begin |
| if (resetn == 1'b0) begin |
| isck <= 1'b0; |
| end else begin |
| if (state == IDLE || state == FINISH) |
| isck <= 1'b0; |
| else |
| isck <= ~isck; |
| end // resetn |
| end // always |
| |
| // Main procedure: read, write, shift data |
| |
| always @(posedge hsck or negedge resetn) begin |
| if (resetn == 1'b0) begin |
| rreg <= 8'hff; |
| treg <= 8'hff; |
| isdo <= 1'b0; |
| end else begin |
| if (isck == 1'b0 && (state == SENDL || state == SENDH)) begin |
| if (mlb == 1'b1) begin |
| // LSB first, sdi@msb -> right shift |
| rreg <= {sdi, rreg[7:1]}; |
| end else begin |
| // MSB first, sdi@lsb -> left shift |
| rreg <= {rreg[6:0], sdi}; |
| end |
| end // read on ~isck |
| |
| if (w_latched == 1'b1) begin |
| if (mlb == 1'b1) begin |
| treg <= {1'b1, d_latched[7:1]}; |
| isdo <= d_latched[0]; |
| end else begin |
| treg <= {d_latched[6:0], 1'b1}; |
| isdo <= d_latched[7]; |
| end // mlb |
| end else if ((mode ^ isck) == 1'b1) begin |
| if (mlb == 1'b1) begin |
| // LSB first, shift right |
| treg <= {1'b1, treg[7:1]}; |
| isdo <= treg[0]; |
| end else begin |
| // MSB first shift LEFT |
| treg <= {treg[6:0], 1'b1}; |
| isdo <= treg[7]; |
| end // mlb |
| end // write on mode ^ isck |
| end // resetn |
| end // always |
| |
| endmodule |