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    /qspiflash/trunk/rtl
    from Rev 10 to Rev 11
    Reverse comparison

Rev 10 → Rev 11

/eqspiflash.v
725,6 → 725,7
 
reg [3:0] rd_state;
reg r_leave_xip, r_xip, r_quad, r_requested;
reg [3:0] invalid_ack_pipe;
initial rd_state = `RD_IDLE;
initial o_data_ack = 1'b0;
initial o_bus_ack = 1'b0;
736,6 → 737,7
o_spi_recycle <= 1'b0;
if (i_spi_valid)
o_data <= i_spi_data;
invalid_ack_pipe <= { invalid_ack_pipe[2:0], accepted };
case(rd_state)
`RD_IDLE: begin
r_requested <= 1'b0;
776,9 → 778,8
o_spi_spd <= 1'b0;
o_spi_len <= 2'b11;
o_spi_wr <= (~r_requested)||(i_piperd);
// if (accepted)
// o_spi_wr <= (i_piperd);
o_data_ack <= (r_requested)&&(i_spi_valid);
invalid_ack_pipe[0] <= (!r_requested);
o_data_ack <= (!invalid_ack_pipe[3])&&(i_spi_valid)&&(r_requested);
o_bus_ack <= (r_requested)&&(accepted)&&(i_piperd);
r_requested <= (r_requested)||(accepted);
if ((i_spi_valid)&&(~o_spi_wr))
790,13 → 791,14
o_spi_spd <= 1'b1;
o_spi_len <= 2'b11;
o_spi_recycle <= (r_leave_xip)? 1'b1: 1'b0;
invalid_ack_pipe[0] <= (!r_requested);
r_requested <= (r_requested)||(accepted);
o_data_ack <= (r_requested)&&(i_spi_valid)&&(~r_leave_xip);
o_data_ack <= (!invalid_ack_pipe[3])&&(i_spi_valid)&&(r_requested)&&(~r_leave_xip);
o_bus_ack <= (r_requested)&&(accepted)&&(i_piperd)&&(~r_leave_xip);
o_spi_wr <= (~r_requested)||(i_piperd);
// if (accepted)
// o_spi_wr <= (i_piperd);
if (accepted)
if (accepted) // only happens if (o_spi_wr)
o_data <= i_spi_data;
if ((i_spi_valid)&&(~o_spi_wr))
rd_state <= ((r_leave_xip)||(~r_xip))?`RD_GO_TO_IDLE:`RD_GO_TO_XIP;
839,12 → 841,17
o_bus_ack <= i_readreq;
end end
`RD_GO_TO_IDLE: begin
if ((!invalid_ack_pipe[3])&&(i_spi_valid)&&(~r_leave_xip))
o_data_ack <= 1'b1;
o_spi_wr <= 1'b0;
o_qspi_req <= 1'b0;
o_spi_wr <= 1'b0;
if ((i_spi_stopped)&&(~i_grant))
rd_state <= `RD_IDLE;
end
`RD_GO_TO_XIP: begin
r_requested <= 1'b0;
if ((i_spi_valid)&&(!invalid_ack_pipe[3]))
o_data_ack <= 1'b1;
o_qspi_req <= 1'b1;
o_spi_wr <= 1'b0;
if (i_spi_stopped)
925,7 → 932,7
accepted <= (~i_spi_busy)&&(i_qspi_grant)&&(o_spi_wr)&&(~accepted);
 
 
reg cyc, chk_wip;
reg cyc, chk_wip, valid_status;
reg [3:0] wr_state;
initial wr_state = `WR_IDLE;
initial cyc = 1'b0;
934,9 → 941,9
chk_wip <= 1'b0;
o_bus_ack <= 1'b0;
o_data_ack <= 1'b0;
cyc <= (cyc)&&(~i_endpipe);
case(wr_state)
`WR_IDLE: begin
valid_status <= 1'b0;
o_qspi_req <= 1'b0;
cyc <= 1'b0;
if (i_ereq)
1000,6 → 1007,7
o_spi_spd <= i_quad;
o_spi_hold <= 1'b1;
o_spi_word <= i_data;
cyc <= (cyc)&&(~i_endpipe);
if (~cyc)
wr_state <= `WR_WAIT_ON_STOP;
else if (i_pipewr)
1061,6 → 1069,7
o_spi_word <= 32'h00;
if (accepted)
wr_state <= `WR_READ_STATUS;
valid_status <= 1'b0;
end
`WR_READ_STATUS: begin
o_wip <= 1'b1;
1072,6 → 1081,8
o_spi_dir <= 1'b1; // Read
o_spi_word <= 32'h00;
if (i_spi_valid)
valid_status <= 1'b1;
if ((i_spi_valid)&&(valid_status))
chk_wip <= 1'b1;
if ((chk_wip)&&(~i_spi_data[0]))
wr_state <= `WR_WAIT_ON_FINAL_STOP;
1147,6 → 1158,7
 
reg [2:0] ctstate;
reg accepted;
reg [3:0] invalid_ack_pipe;
 
 
initial accepted = 1'b0;
1153,7 → 1165,7
always @(posedge i_clk)
accepted <= (~i_spi_busy)&&(i_grant)&&(o_spi_wr)&&(~accepted);
 
reg r_ctdat_len, ctbus_ack;
reg r_ctdat_len, ctbus_ack, first_valid;
assign ctdat_len = { 1'b0, r_ctdat_len };
 
// First step, calculate the values for our state machine
1265,6 → 1277,7
o_spi_wr <= 1'b1;
o_bus_ack <= 1'b0;
o_data_ack <= 1'b0;
invalid_ack_pipe <= { invalid_ack_pipe[2:0], accepted };
if (i_spi_valid)
o_data <= i_spi_data;
case(ctstate)
1304,11 → 1317,13
ctstate <= (ctdat_wr)?`CT_WAIT_FOR_IDLE:`CT_READ_DATA;
if ((accepted)&&(ctdat_wr))
o_data_ack <= 1'b1;
first_valid <= 1'b0;
end
`CT_READ_DATA: begin
o_spi_wr <= 1'b0; // No more words to go, just to wait
o_spi_req <= 1'b1;
if (i_spi_valid) // for a value to read
invalid_ack_pipe[0] <= 1'b0;
if ((i_spi_valid)&&(!invalid_ack_pipe[3])) // for a value to read
begin
o_data_ack <= 1'b1;
o_data <= i_spi_data;
1426,8 → 1441,9
reg nxt_data_ack, nxt_data_spi;
reg [31:0] nxt_data;
 
reg set_val, chk_wip;
reg set_val, chk_wip, first_valid;
reg [2:0] set_addr;
reg [3:0] invalid_ack_pipe;
 
always @(posedge i_clk)
begin // Depends upon state[4], otp_rd, otp_wr, otp_pipe, id_req, accepted, last_addr
1438,6 → 1454,7
nxt_data_spi <= 1'b0;
chk_wip <= 1'b0;
set_val <= 1'b0;
invalid_ack_pipe <= { invalid_ack_pipe[2:0], accepted };
if ((id_loaded)&&(id_read_request))
begin
nxt_data_ack <= 1'b1;
1454,6 → 1471,7
o_spi_word[6:0] <= { req_addr[4:0], 2'b00 };
r_data <= i_data;
o_wip <= 1'b0;
first_valid <= 1'b0;
if (otp_read_request)
begin
// o_spi_word <= { 8'h48, 8'h00, 8'h00, 8'h00 };
1498,11 → 1516,12
end
`ID_READ_DATA_COMMAND: begin
o_spi_len <= 2'b11; // 32-bits
o_spi_wr <= (~last_addr); // Still transmitting
o_spi_wr <= 1'b1; // Still transmitting
o_spi_dir <= 1'b1; // Read from SPI
o_qspi_req <= 1'b1;
if (accepted)
id_state <= `ID_GET_DATA;
first_valid <= 1'b0;
end
`ID_GET_DATA: begin
o_spi_len <= 2'b11; // 32-bits
1509,7 → 1528,8
o_spi_wr <= (~last_addr); // Still transmitting
o_spi_dir <= 1'b1; // Read from SPI
o_qspi_req <= 1'b1;
if (i_spi_valid) // same as accepted
invalid_ack_pipe[0] <= 1'b0;
if((i_spi_valid)&&(!invalid_ack_pipe[3]))
begin
set_val <= 1'b1;
set_addr <= lcl_id_addr[2:0];
1542,12 → 1562,13
`ID_OTP_CLEAR: begin
o_spi_wr <= 1'b1; // Still writing
o_spi_dir <= 1'b1; // Read from SPI
o_spi_len <= 2'b11; // Read from SPI
o_spi_len <= 2'b11; // Read 32 bits
if (accepted)
id_state <= `ID_OTP_GET_DATA;
end
`ID_OTP_GET_DATA: begin
if (i_spi_valid)
invalid_ack_pipe[0] <= 1'b0;
if ((i_spi_valid)&&(!invalid_ack_pipe[3]))
begin
id_state <= `ID_FINAL_STOP;
nxt_data_ack <= 1'b1;
1596,7 → 1617,8
o_spi_dir <= 1'b1; // Read
o_spi_len <= 2'b00; // 8 bits
// o_spi_word <= dont care
if (i_spi_valid)
invalid_ack_pipe[0] <= 1'b0;
if ((i_spi_valid)&&(~invalid_ack_pipe[3]))
chk_wip <= 1'b1;
if ((chk_wip)&&(~i_spi_data[0]))
begin
/lleqspi.v
1,6 → 1,6
///////////////////////////////////////////////////////////////////////////
//
// Filename: llqspi.v
// Filename: lleqspi.v
//
// Project: Wishbone Controlled Quad SPI Flash Controller
//
70,7 → 70,7
input i_dir; // 0 -> read, 1 -> write to SPI
input i_recycle; // 0 = 20ns, 1 = 50ns
output reg [31:0] o_word;
output wire o_valid;
output reg o_valid;
output reg o_busy;
// Interface with the QSPI lines
output reg o_sck;
83,100 → 83,6
// assign o_dbg = { state, spi_len,
// o_busy, o_valid, o_cs_n, o_sck, o_mod, o_dat, i_dat };
 
// Timing:
//
// Tick Clk BSY/WR CS_n BIT/MO STATE
// 0 1 0/0 1 -
// 1 1 0/1 1 -
// 2 1 1/0 0 - QSPI_START
// 3 0 1/0 0 - QSPI_START
// 4 0 1/0 0 0 QSPI_BITS
// 5 1 1/0 0 0 QSPI_BITS
// 6 0 1/0 0 1 QSPI_BITS
// 7 1 1/0 0 1 QSPI_BITS
// 8 0 1/0 0 2 QSPI_BITS
// 9 1 1/0 0 2 QSPI_BITS
// 10 0 1/0 0 3 QSPI_BITS
// 11 1 1/0 0 3 QSPI_BITS
// 12 0 1/0 0 4 QSPI_BITS
// 13 1 1/0 0 4 QSPI_BITS
// 14 0 1/0 0 5 QSPI_BITS
// 15 1 1/0 0 5 QSPI_BITS
// 16 0 1/0 0 6 QSPI_BITS
// 17 1 1/1 0 6 QSPI_BITS
// 18 0 1/1 0 7 QSPI_READY
// 19 1 0/1 0 7 QSPI_READY
// 20 0 1/0/V 0 8 QSPI_BITS
// 21 1 1/0 0 8 QSPI_BITS
// 22 0 1/0 0 9 QSPI_BITS
// 23 1 1/0 0 9 QSPI_BITS
// 24 0 1/0 0 10 QSPI_BITS
// 25 1 1/0 0 10 QSPI_BITS
// 26 0 1/0 0 11 QSPI_BITS
// 27 1 1/0 0 11 QSPI_BITS
// 28 0 1/0 0 12 QSPI_BITS
// 29 1 1/0 0 12 QSPI_BITS
// 30 0 1/0 0 13 QSPI_BITS
// 31 1 1/0 0 13 QSPI_BITS
// 32 0 1/0 0 14 QSPI_BITS
// 33 1 1/0 0 14 QSPI_BITS
// 34 0 1/0 0 15 QSPI_READY
// 35 1 1/0 0 15 QSPI_READY
// 36 1 1/0/V 0 - QSPI_STOP
// 37 1 1/0 0 - QSPI_STOPB
// 38 1 1/0 1 - QSPI_IDLE
// 39 1 0/0 1 -
// Now, let's switch from single bit to quad mode
// 40 1 0/0 1 - QSPI_IDLE
// 41 1 0/1 1 - QSPI_IDLE
// 42 1 1/0 0 - QSPI_START
// 43 0 1/0 0 - QSPI_START
// 44 0 1/0 0 0 QSPI_BITS
// 45 1 1/0 0 0 QSPI_BITS
// 46 0 1/0 0 1 QSPI_BITS
// 47 1 1/0 0 1 QSPI_BITS
// 48 0 1/0 0 2 QSPI_BITS
// 49 1 1/0 0 2 QSPI_BITS
// 50 0 1/0 0 3 QSPI_BITS
// 51 1 1/0 0 3 QSPI_BITS
// 52 0 1/0 0 4 QSPI_BITS
// 53 1 1/0 0 4 QSPI_BITS
// 54 0 1/0 0 5 QSPI_BITS
// 55 1 1/0 0 5 QSPI_BITS
// 56 0 1/0 0 6 QSPI_BITS
// 57 1 1/1/QR 0 6 QSPI_BITS
// 58 0 1/1/QR 0 7 QSPI_READY
// 59 1 0/1/QR 0 7 QSPI_READY
// 60 0 1/0/?/V 0 8-11 QSPI_BITS
// 61 1 1/0/? 0 8-11 QSPI_BITS
// 62 0 1/0/? 0 12-15 QSPI_BITS
// 63 1 1/0/? 0 12-15 QSPI_BITS
// 64 1 1/0/?/V 0 - QSPI_STOP
// 65 1 1/0/? 0 - QSPI_STOPB
// 66 1 1/0/? 1 - QSPI_IDLE
// 67 1 0/0 1 - QSPI_IDLE
// Now let's try something entirely in Quad read mode, from the
// beginning
// 68 1 0/1/QR 1 - QSPI_IDLE
// 69 1 1/0 0 - QSPI_START
// 70 0 1/0 0 - QSPI_START
// 71 0 1/0 0 0-3 QSPI_BITS
// 72 1 1/0 0 0-3 QSPI_BITS
// 73 0 1/1/QR 0 4-7 QSPI_BITS
// 74 1 0/1/QR 0 4-7 QSPI_BITS
// 75 0 1/?/?/V 0 8-11 QSPI_BITS
// 76 1 1/?/? 0 8-11 QSPI_BITS
// 77 0 1/1/QR 0 12-15 QSPI_BITS
// 78 1 0/1/QR 0 12-15 QSPI_BITS
// 79 0 1/?/?/V 0 16-19 QSPI_BITS
// 80 1 1/0 0 16-19 QSPI_BITS
// 81 0 1/0 0 20-23 QSPI_BITS
// 82 1 1/0 0 20-23 QSPI_BITS
// 83 1 1/0/V 0 - QSPI_STOP
// 84 1 1/0 0 - QSPI_STOPB
// 85 1 1/0 1 - QSPI_IDLE
// 86 1 0/0 1 - QSPI_IDLE
 
wire i_miso;
assign i_miso = i_dat[1];
 
391,22 → 297,43
*/
end
 
`define EXTRA_DELAY
wire rd_input_N, rd_valid_N, r_spd_N;
`ifdef EXTRA_DELAY
reg [2:0] rd_input_p, rd_valid_p, r_spd_p;
always @(posedge i_clk)
rd_input_p <= { rd_input_p[1:0], rd_input };
always @(posedge i_clk)
rd_valid_p <= { rd_valid_p[1:0], rd_valid };
always @(posedge i_clk)
r_spd_p <= { r_spd_p[1:0], r_spd };
 
assign rd_input_N = rd_input_p[2];
assign rd_valid_N = rd_valid_p[2];
assign r_spd_N = r_spd_p[2];
`else
assign rd_input_N = rd_input;
assign rd_valid_N = rd_valid;
assign r_spd_N = rd_spd;
`endif
 
 
always @(posedge i_clk)
begin
if ((state == `EQSPI_IDLE)||(rd_valid))
// if ((state == `EQSPI_IDLE)||(rd_valid_N))
if (o_valid)
r_input <= 31'h00;
else if ((rd_input)&&(r_spd))
if ((rd_input_N)&&(r_spd_N))
r_input <= { r_input[26:0], i_dat };
else if (rd_input)
else if (rd_input_N)
r_input <= { r_input[29:0], i_miso };
 
if ((rd_valid)&&(r_spd))
if ((rd_valid_N)&&(r_spd_N))
o_word <= { r_input[27:0], i_dat };
else if (rd_valid)
else if (rd_valid_N)
o_word <= { r_input[30:0], i_miso };
o_valid <= rd_valid_N;
end
 
assign o_valid = rd_valid;
 
endmodule
 
/Makefile
0,0 → 1,63
##########################################################################/
##
## Filename: Makefile
##
## Project: Wishbone Controlled Quad SPI Flash Controller
##
## Purpose: To direct the Verilator build of the SoC sources. The result
## is C++ code (built by Verilator), that is then built (herein)
## into a library that you can find in obj_dir.
##
##
## Creator: Dan Gisselquist, Ph.D.
## Gisselquist Technology, LLC
##
##########################################################################/
##
## Copyright (C) 2015, Gisselquist Technology, LLC
##
## This program is free software (firmware): you can redistribute it and/or
## modify it under the terms of the GNU General Public License as published
## by the Free Software Foundation, either version 3 of the License, or (at
## your option) any later version.
##
## This program is distributed in the hope that it will be useful, but WITHOUT
## ANY WARRANTY; without even the implied warranty of MERCHANTIBILITY or
## FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
## for more details.
##
## License: GPL, v3, as defined and found on www.gnu.org,
## http:##www.gnu.org/licenses/gpl.html
##
##
##########################################################################/
##
##
all: test
YYMMDD=`date +%Y%m%d`
CXX := g++
FBDIR := .
VDIRFB:= $(FBDIR)/obj_dir
 
.PHONY: test
test: $(VDIRFB)/Veqspiflash__ALL.a
# test: $(VDIRFB)/Vfastmaster__ALL.a
 
$(VDIRFB)/Veqspiflash.h $(VDIRFB)/Veqspiflash.cpp $(VDIRFB)/Veqspiflash.mk: eqspiflash.v lleqspi.v
$(VDIRFB)/V%.cpp $(VDIRFB)/V%.h $(VDIRFB)/V%.mk: $(FBDIR)/%.v
verilator -cc $*.v
 
$(VDIRFB)/V%__ALL.a: $(VDIRFB)/V%.mk
cd $(VDIRFB); make -f V$*.mk
 
.PHONY:
archive:
tar --transform s,^,$(YYMMDD)-rtl/, -chjf $(YYMMDD)-rtl.tjz Makefile *.v cpu/*.v
 
.PHONY: clean
clean:
rm -rf $(VDIRFB)/*.mk
rm -rf $(VDIRFB)/*.cpp
rm -rf $(VDIRFB)/*.h
rm -rf $(VDIRFB)/
 

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