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[/] [yifive/] [trunk/] [caravel_yifive/] [verilog/] [rtl/] [spi_master/] [src/] [spim_ctrl.sv] - Rev 19
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//////////////////////////////////////////////////////////////////////
//// ////
//// SPI CTRL I/F Module ////
//// ////
//// This file is part of the YIFive cores project ////
//// http://www.opencores.org/cores/yifive/ ////
//// ////
//// Description ////
//// ////
//// To Do: ////
//// nothing ////
//// ////
//// Author(s): ////
//// - Dinesh Annayya, dinesha@opencores.org ////
//// ////
//// Revision : ////
//// V.0 - June 8, 2021 ////
//// ////
//////////////////////////////////////////////////////////////////////
//// ////
//// Copyright (C) 2000 Authors and OPENCORES.ORG ////
//// ////
//// 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. ////
//// ////
//// You should have received a copy of the GNU Lesser General ////
//// Public License along with this source; if not, download it ////
//// from http://www.opencores.org/lgpl.shtml ////
//// ////
//////////////////////////////////////////////////////////////////////
module spim_ctrl
(
input logic clk,
input logic rstn,
output logic eot,
input logic [7:0] spi_clk_div,
input logic spi_clk_div_valid,
output logic [7:0] spi_status,
input logic spi_req,
input logic [31:0] spi_addr,
input logic [5:0] spi_addr_len,
input logic [7:0] spi_cmd,
input logic [5:0] spi_cmd_len,
input logic [7:0] spi_mode_cmd,
input logic spi_mode_cmd_enb,
input logic [3:0] spi_csreg,
input logic [15:0] spi_data_len,
input logic [15:0] spi_dummy_rd_len,
input logic [15:0] spi_dummy_wr_len,
input logic spi_swrst, //FIXME Not used at all
input logic spi_rd,
input logic spi_wr,
input logic spi_qrd,
input logic spi_qwr,
input logic [31:0] spi_wdata,
output logic [31:0] spi_rdata,
output logic spi_ack,
output logic spi_clk,
output logic spi_csn0,
output logic spi_csn1,
output logic spi_csn2,
output logic spi_csn3,
output logic [1:0] spi_mode,
output logic spi_sdo0,
output logic spi_sdo1,
output logic spi_sdo2,
output logic spi_sdo3,
input logic spi_sdi0,
input logic spi_sdi1,
input logic spi_sdi2,
input logic spi_sdi3,
output logic spi_en_tx // Spi Direction control
);
parameter SPI_STD = 2'b00;
parameter SPI_QUAD_TX = 2'b01;
parameter SPI_QUAD_RX = 2'b10;
logic spi_rise;
logic spi_fall;
logic spi_clock_en;
logic spi_en_rx;
logic [15:0] counter_tx;
logic counter_tx_valid;
logic [15:0] counter_rx;
logic counter_rx_valid;
logic [31:0] data_to_tx;
logic data_to_tx_valid;
logic data_to_tx_ready;
logic en_quad;
logic en_quad_int;
logic do_tx; //FIXME NOT USED at all!!
logic do_rx;
logic tx_done;
logic rx_done;
logic [1:0] s_spi_mode;
logic ctrl_data_valid;
logic spi_cs;
logic tx_clk_en;
logic rx_clk_en;
logic en_quad_in;
enum logic [2:0] {DATA_NULL,DATA_EMPTY,DATA_CMD,DATA_ADDR,DATA_MODE,DATA_FIFO} ctrl_data_mux;
enum logic [4:0] {IDLE,CMD,ADDR,MODE,DUMMY,DATA_TX,DATA_RX,WAIT_EDGE} state,state_next;
assign en_quad = spi_qrd | spi_qwr | en_quad_int;
assign en_quad_in = (s_spi_mode == SPI_STD) ? 1'b0 : 1'b1;
spim_clkgen u_clkgen
(
.clk ( clk ),
.rstn ( rstn ),
.en ( spi_clock_en ),
.cfg_sck_period( spi_clk_div ),
.spi_clk ( spi_clk ),
.spi_fall ( spi_fall ),
.spi_rise ( spi_rise )
);
spim_tx u_txreg
(
.clk ( clk ),
.rstn ( rstn ),
.en ( spi_en_tx ),
.tx_edge ( spi_fall ),
.tx_done ( tx_done ),
.sdo0 ( spi_sdo0 ),
.sdo1 ( spi_sdo1 ),
.sdo2 ( spi_sdo2 ),
.sdo3 ( spi_sdo3 ),
.en_quad_in ( en_quad_in ),
.counter_in ( counter_tx ),
.txdata ( data_to_tx ),
.data_valid ( data_to_tx_valid ),
.data_ready ( ),
.clk_en_o ( tx_clk_en )
);
spim_rx u_rxreg
(
.clk ( clk ),
.rstn ( rstn ),
.en ( spi_en_rx ),
.rx_edge ( spi_rise ),
.rx_done ( rx_done ),
.sdi0 ( spi_sdi0 ),
.sdi1 ( spi_sdi1 ),
.sdi2 ( spi_sdi2 ),
.sdi3 ( spi_sdi3 ),
.en_quad_in ( en_quad_in ),
.counter_in ( counter_rx ),
.counter_in_upd ( counter_rx_valid ),
.data ( spi_rdata ),
.data_valid ( ),
.data_ready ( 1'b1 ),
.clk_en_o ( rx_clk_en )
);
always_comb
begin
data_to_tx = 'h0;
data_to_tx_valid = 1'b0;
case(ctrl_data_mux)
DATA_NULL:
begin
data_to_tx = '0;
data_to_tx_valid = 1'b0;
end
DATA_EMPTY:
begin
data_to_tx = '0;
data_to_tx_valid = 1'b1;
end
DATA_CMD:
begin
data_to_tx = {spi_cmd,24'h0};
data_to_tx_valid = ctrl_data_valid;
end
DATA_MODE:
begin
data_to_tx = {spi_mode_cmd,24'h0};
data_to_tx_valid = ctrl_data_valid;
end
DATA_ADDR:
begin
data_to_tx = spi_addr;
data_to_tx_valid = ctrl_data_valid;
end
DATA_FIFO:
begin
data_to_tx = spi_wdata;
data_to_tx_valid = ctrl_data_valid;
end
endcase
end
always_comb
begin
spi_cs = 1'b1;
spi_clock_en = 1'b0;
counter_tx = '0;
counter_tx_valid = 1'b0;
counter_rx = '0;
counter_rx_valid = 1'b0;
state_next = state;
ctrl_data_mux = DATA_NULL;
ctrl_data_valid = 1'b0;
spi_en_rx = 1'b0;
spi_en_tx = 1'b0;
spi_status = '0;
s_spi_mode = SPI_QUAD_RX;
eot = 1'b0;
case(state)
IDLE:
begin
spi_status[0] = 1'b1;
s_spi_mode = SPI_QUAD_RX;
if (spi_req)
begin
spi_cs = 1'b0;
spi_clock_en = 1'b1;
if (spi_cmd_len != 0)
begin
// s_spi_mode = (spi_qrd | spi_qwr) ? `SPI_QUAD_TX : `SPI_STD;
s_spi_mode = SPI_STD; // COMMAND is always Standard Mode ?
counter_tx = {8'h0,spi_cmd_len};
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_CMD;
ctrl_data_valid = 1'b1;
spi_en_tx = 1'b1;
state_next = CMD;
end
else if (spi_addr_len != 0)
begin
s_spi_mode = (spi_qrd | spi_qwr) ? SPI_QUAD_TX : SPI_STD;
counter_tx = {8'h0,spi_addr_len};
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_ADDR;
ctrl_data_valid = 1'b1;
spi_en_tx = 1'b1;
state_next = ADDR;
end
else if (spi_mode_cmd_enb != 0)
begin
s_spi_mode = (spi_qrd | spi_qwr) ? SPI_QUAD_TX : SPI_STD;
counter_tx = {8'h0,8'h8};
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_MODE;
ctrl_data_valid = 1'b1;
spi_en_tx = 1'b1;
state_next = MODE;
end
else if (spi_data_len != 0)
begin
if (spi_rd || spi_qrd)
begin
s_spi_mode = (spi_qrd) ? SPI_QUAD_RX : SPI_STD;
if(spi_dummy_rd_len != 0)
begin
counter_tx = en_quad ? {2'b00,spi_dummy_rd_len[13:0]} : spi_dummy_rd_len;
counter_tx_valid = 1'b1;
spi_en_tx = 1'b1;
ctrl_data_mux = DATA_EMPTY;
state_next = DUMMY;
end
else
begin
counter_rx = spi_data_len;
counter_rx_valid = 1'b1;
spi_en_rx = 1'b1;
state_next = DATA_RX;
end
end
else
begin
s_spi_mode = (spi_qwr) ? SPI_QUAD_TX : SPI_STD;
if(spi_dummy_wr_len != 0)
begin
counter_tx = en_quad ? {2'b00,spi_dummy_wr_len[13:0]} : spi_dummy_wr_len;
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_EMPTY;
spi_en_tx = 1'b1;
state_next = DUMMY;
end
else
begin
counter_tx = spi_data_len;
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_FIFO;
ctrl_data_valid = 1'b0;
spi_en_tx = 1'b1;
state_next = DATA_TX;
end
end
end
end
else
begin
spi_cs = 1'b1;
state_next = IDLE;
end
end
CMD:
begin
spi_status[1] = 1'b1;
spi_cs = 1'b0;
spi_clock_en = 1'b1;
// s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
s_spi_mode = SPI_STD; // Command is always Standard Mode ?
if (tx_done)
begin
if (spi_addr_len != 0)
begin
s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
counter_tx = {8'h0,spi_addr_len};
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_ADDR;
ctrl_data_valid = 1'b1;
spi_en_tx = 1'b1;
state_next = ADDR;
end
else if (spi_mode_cmd_enb != 0)
begin
s_spi_mode = (spi_qrd | spi_qwr) ? SPI_QUAD_TX : SPI_STD;
counter_tx = {8'h0,8'h8};
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_MODE;
ctrl_data_valid = 1'b1;
spi_en_tx = 1'b1;
state_next = MODE;
end
else if (spi_data_len != 0)
begin
if (do_rx)
begin
s_spi_mode = (en_quad) ? SPI_QUAD_RX : SPI_STD;
if(spi_dummy_rd_len != 0)
begin
counter_tx = en_quad ? {2'b00,spi_dummy_rd_len[13:0]} : spi_dummy_rd_len;
counter_tx_valid = 1'b1;
spi_en_tx = 1'b1;
ctrl_data_mux = DATA_EMPTY;
state_next = DUMMY;
end
else
begin
counter_rx = spi_data_len;
counter_rx_valid = 1'b1;
spi_en_rx = 1'b1;
state_next = DATA_RX;
end
end
else
begin
s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
if(spi_dummy_wr_len != 0)
begin
counter_tx = en_quad ? {2'b00,spi_dummy_wr_len[13:0]} : spi_dummy_wr_len;
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_EMPTY;
spi_en_tx = 1'b1;
state_next = DUMMY;
end
else
begin
counter_tx = spi_data_len;
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_FIFO;
ctrl_data_valid = 1'b1;
spi_en_tx = 1'b1;
state_next = DATA_TX;
end
end
end
else
begin
spi_en_tx = 1'b1;
state_next = WAIT_EDGE;
end
end
else
begin
spi_en_tx = 1'b1;
state_next = CMD;
end
end
ADDR:
begin
spi_en_tx = 1'b1;
spi_status[2] = 1'b1;
spi_cs = 1'b0;
spi_clock_en = 1'b1;
s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
if (tx_done)
begin
if (spi_mode_cmd_enb != 0)
begin
s_spi_mode = (spi_qrd | spi_qwr) ? SPI_QUAD_TX : SPI_STD;
counter_tx = {8'h0,8'h8};
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_MODE;
ctrl_data_valid = 1'b1;
spi_en_tx = 1'b1;
state_next = MODE;
end
else if (spi_data_len != 0)
begin
if (do_rx)
begin
s_spi_mode = (en_quad) ? SPI_QUAD_RX : SPI_STD;
if(spi_dummy_rd_len != 0)
begin
counter_tx = en_quad ? {2'b00,spi_dummy_rd_len[13:0]} : spi_dummy_rd_len;
counter_tx_valid = 1'b1;
spi_en_tx = 1'b1;
ctrl_data_mux = DATA_EMPTY;
state_next = DUMMY;
end
else
begin
counter_rx = spi_data_len;
counter_rx_valid = 1'b1;
spi_en_rx = 1'b1;
state_next = DATA_RX;
end
end
else
begin
s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
spi_en_tx = 1'b1;
if(spi_dummy_wr_len != 0) begin
counter_tx = en_quad ? {2'b00,spi_dummy_wr_len[13:0]} : spi_dummy_wr_len;
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_EMPTY;
state_next = DUMMY;
end else begin
counter_tx = spi_data_len;
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_FIFO;
ctrl_data_valid = 1'b1;
state_next = DATA_TX;
end
end
end
else
begin
state_next = WAIT_EDGE;
end
end
end
MODE:
begin
spi_en_tx = 1'b1;
spi_status[3] = 1'b1;
spi_cs = 1'b0;
spi_clock_en = 1'b1;
s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
if (tx_done)
begin
if (spi_data_len != 0)
begin
if (do_rx)
begin
s_spi_mode = (en_quad) ? SPI_QUAD_RX : SPI_STD;
if(spi_dummy_rd_len != 0)
begin
counter_tx = en_quad ? {2'b00,spi_dummy_rd_len[13:0]} : spi_dummy_rd_len;
counter_tx_valid = 1'b1;
spi_en_tx = 1'b1;
ctrl_data_mux = DATA_EMPTY;
state_next = DUMMY;
end
else
begin
counter_rx = spi_data_len;
counter_rx_valid = 1'b1;
spi_en_rx = 1'b1;
state_next = DATA_RX;
end
end
else
begin
s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
spi_en_tx = 1'b1;
if(spi_dummy_wr_len != 0) begin
counter_tx = en_quad ? {2'b00,spi_dummy_wr_len[13:0]} : spi_dummy_wr_len;
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_EMPTY;
state_next = DUMMY;
end else begin
counter_tx = spi_data_len;
counter_tx_valid = 1'b1;
ctrl_data_mux = DATA_FIFO;
ctrl_data_valid = 1'b1;
state_next = DATA_TX;
end
end
end
else
begin
state_next = WAIT_EDGE;
end
end
end
DUMMY:
begin
spi_en_tx = 1'b1;
spi_status[4] = 1'b1;
spi_cs = 1'b0;
spi_clock_en = 1'b1;
s_spi_mode = (en_quad) ? SPI_QUAD_RX : SPI_STD;
if (tx_done) begin
if (spi_data_len != 0) begin
if (do_rx) begin
counter_rx = spi_data_len;
counter_rx_valid = 1'b1;
spi_en_rx = 1'b1;
state_next = DATA_RX;
end else begin
counter_tx = spi_data_len;
counter_tx_valid = 1'b1;
s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
spi_clock_en = tx_clk_en;
spi_en_tx = 1'b1;
state_next = DATA_TX;
end
end
else
begin
eot = 1'b1;
state_next = WAIT_EDGE;
end
end
else
begin
ctrl_data_mux = DATA_EMPTY;
spi_en_tx = 1'b1;
state_next = DUMMY;
end
end
DATA_TX:
begin
spi_status[5] = 1'b1;
spi_cs = 1'b0;
spi_clock_en = tx_clk_en;
ctrl_data_mux = DATA_FIFO;
ctrl_data_valid = 1'b1;
spi_en_tx = 1'b1;
s_spi_mode = (en_quad) ? SPI_QUAD_TX : SPI_STD;
if (tx_done) begin
eot = 1'b1;
state_next = WAIT_EDGE;
spi_clock_en = 1'b0;
end else begin
state_next = DATA_TX;
end
end
DATA_RX:
begin
spi_status[6] = 1'b1;
spi_cs = 1'b0;
spi_clock_en = rx_clk_en;
s_spi_mode = (en_quad) ? SPI_QUAD_RX : SPI_STD;
if (rx_done) begin
state_next = WAIT_EDGE;
end else begin
spi_en_rx = 1'b1;
state_next = DATA_RX;
end
end
WAIT_EDGE:
begin
spi_status[7] = 1'b1;
spi_cs = 1'b0;
spi_clock_en = 1'b0;
s_spi_mode = (en_quad) ? SPI_QUAD_RX : SPI_STD;
eot = 1'b1;
state_next = IDLE;
end
endcase
end
assign spi_ack = ((spi_req ==1) && (state_next == WAIT_EDGE)) ? 1'b1 : 1'b0;
always_ff @(posedge clk, negedge rstn)
begin
if (rstn == 1'b0)
begin
state <= IDLE;
en_quad_int <= 1'b0;
do_rx <= 1'b0;
do_tx <= 1'b0;
spi_mode <= SPI_QUAD_RX;
end
else
begin
state <= state_next;
spi_mode <= s_spi_mode;
if (spi_qrd || spi_qwr)
en_quad_int <= 1'b1;
else if (state_next == IDLE)
en_quad_int <= 1'b0;
if (spi_rd || spi_qrd)
begin
do_rx <= 1'b1;
do_tx <= 1'b0;
end
else if (spi_wr || spi_qwr)
begin
do_rx <= 1'b0;
do_tx <= 1'b1;
end
else if (state_next == IDLE)
begin
do_rx <= 1'b0;
do_tx <= 1'b0;
end
end
end
assign spi_csn0 = ~spi_csreg[0] | spi_cs;
assign spi_csn1 = ~spi_csreg[1] | spi_cs;
assign spi_csn2 = ~spi_csreg[2] | spi_cs;
assign spi_csn3 = ~spi_csreg[3] | spi_cs;
endmodule
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