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qflexpress.v
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qflexpress.v
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////////////////////////////////////////////////////////////////////////////////
//
// Filename: rtl/qflexpress.v
// {{{
// Project: KIMOS, a Mercury KX2 demonstration project
//
// Purpose: To provide wishbone controlled read access (and read access
// *only*) to the QSPI flash, using a flash clock equal to the
// system clock, and nothing more. Indeed, this is designed to be a
// *very* stripped down version of a flash driver, with the goal of
// providing 1) very fast access for 2) very low logic count.
//
// Three modes/states of operation:
// 1. Startup/maintenance, places the device in the Quad XIP mode
// 2. Normal operations, takes 33 clocks to read a value
// - 16 subsequent clocks will read a piped value
// 3. Configuration--useful to allow an external controller issue erase
// or program commands (or other) without requiring us to
// clutter up the logic with a giant state machine
//
// STARTUP
// 1. Waits for the flash to come on line
// Start out idle for 300 uS
// 2. Sends a signal to remove the flash from any QSPI read mode. In our
// case, we'll send several clocks of an empty command. In SPI
// mode, it'll get ignored. In QSPI mode, it'll remove us from
// QSPI mode.
// 3. Explicitly places and leaves the flash into QSPI mode
// 0xEB 3(0x00) 0xa0 6(0x00)
// 4. All done
//
// Creator: Dan Gisselquist, Ph.D.
// Gisselquist Technology, LLC
//
////////////////////////////////////////////////////////////////////////////////
// }}}
// Copyright (C) 2024, Gisselquist Technology, LLC
// {{{
// This file is part of the KIMOS project.
//
// The KIMOS project is free software and gateware: 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.
//
// You should have received a copy of the GNU General Public License along
// with this program. (It's in the $(ROOT)/doc directory. Run make with no
// target there if the PDF file isn't present.) If not, see
// <http://www.gnu.org/licenses/> for a copy.
// }}}
// License: GPL, v3, as defined and found on www.gnu.org,
// {{{
// http://www.gnu.org/licenses/gpl.html
//
////////////////////////////////////////////////////////////////////////////////
//
`default_nettype none
// }}}
// 290 raw, 372 w/ pipe, 410 cfg, 499 cfg w/pipe
module qflexpress #(
//
// LGFLASHSZ is the size of the flash memory. It defines the
// {{{
// number of bits in the address register and more. This
// controller will support flash sizes up to 2^LGFLASHSZ,
// where LGFLASHSZ goes up to 32.
parameter LGFLASHSZ=24,
// }}}
// OPT_PIPE makes it possible to string multiple requests
// {{{
// together, with no intervening need to shutdown the
// QSPI connection and send a new address
parameter [0:0] OPT_PIPE = 1'b1,
// }}}
// OPT_CFG enables the configuration logic port, and hence the
// {{{
// ability to erase and program the flash, as well as the
// ability to perform other commands such as read-manufacturer
// ID, adjust configuration registers, etc.
parameter [0:0] OPT_CFG = 1'b1,
// }}}
// OPT_STARTUP enables the startup logic
// {{{
parameter [0:0] OPT_STARTUP = 1'b1,
// }}}
parameter OPT_CLKDIV = 0,
//
// OPT_ENDIANSWAP. Normally, I place the first byte read from
// {{{
// the flash, and the lowest flash address, into bits [7:0],
// and then shift it up--to where upon return it is found in
// bits [31:24]. This is ideal for a big endian systems, not
// so much for little endian systems. The endian swap allows
// the bus to swap the return values in order to support little
// endian systems.
parameter [0:0] OPT_ENDIANSWAP = 1'b0,
// }}}
// RDDELAY is the number of clock cycles from when o_qspi_dat
// {{{
// is valid until i_qspi_dat is valid. Read delays from
// 0-4 have been verified. DDR Registered I/O on a
// Xilinx device can be done with a RDDELAY=3. On Intel/Altera
// devices, RDDELAY=2 works. I'm using RDDELAY=0 for my iCE40
// devices
parameter RDDELAY = 0,
// }}}
// NDUMMY is the number of "dummy" clock cycles between the
// {{{
// 24-bits (or 32-bits) of the Quad I/O address and the first
// data bits. This includes the two clocks of the Quad output
// mode byte, 0xa0. The default is 10 for a Micron device.
// Windbond seems to want 2. Note your flash device carefully
// when you choose this value.
parameter NDUMMY = 6,
// }}}
// OPT_STARTUP_FILE: For dealing with multiple flash devices,
// {{{
// the OPT_STARTUP_FILE allows a hex file to be provided
// containing the necessary script to place the design into
// the proper initial configuration.
parameter OPT_STARTUP_FILE="spansion.hex",
// }}}
//
localparam AW=LGFLASHSZ-2,
localparam DW=32
) (
// {{{
input wire i_clk, i_reset,
//
// Flash memory port
// {{{
input wire i_wb_cyc, i_wb_stb, i_wb_we,
input wire [(AW-1):0] i_wb_addr,
input wire [(DW-1):0] i_wb_data,
input wire [DW/8-1:0] i_wb_sel,
//
output wire o_wb_stall, o_wb_ack,
output reg [(DW-1):0] o_wb_data,
// }}}
// Configuration port
// {{{
input wire i_cfg_cyc, i_cfg_stb, i_cfg_we,
input wire [(DW-1):0] i_cfg_data,
input wire [DW/8-1:0] i_cfg_sel,
//
output wire o_cfg_stall, o_cfg_ack,
output wire [(DW-1):0] o_cfg_data,
// }}}
// Device
// {{{
output reg o_qspi_sck,
output reg o_qspi_cs_n,
output reg [1:0] o_qspi_mod,
output wire [3:0] o_qspi_dat,
input wire [3:0] i_qspi_dat,
// }}}
// Debugging port
// {{{
output wire o_dbg_trigger,
output wire [31:0] o_debug
// }}}
// }}}
);
// Local declarations
// {{{
// OPT_ADDR32 enables 32 bit addressing, rather than 24bit
// {{{
// Control this by controlling the LGFLASHSZ parameter above.
// Anything greater than 24 will use 32-bit addressing,
// otherwise the regular 24-bit addressing
localparam [0:0] OPT_ADDR32 = (LGFLASHSZ > 24);
// }}}
// OPT_ODDR will be true any time the clock has no clock division
// {{{
localparam [0:0] OPT_ODDR = (OPT_CLKDIV == 0);
// }}}
// CKDV_BITS is the number of bits necessary to represent a
// {{{
// counter that can do the CLKDIV division
localparam CKDV_BITS = (OPT_CLKDIV == 0) ? 0
: ((OPT_CLKDIV < 2) ? 1
: ((OPT_CLKDIV < 4) ? 2
: ((OPT_CLKDIV < 8) ? 3
: ((OPT_CLKDIV < 16) ? 4
: ((OPT_CLKDIV < 32) ? 5
: ((OPT_CLKDIV < 64) ? 6
: ((OPT_CLKDIV < 128) ? 7
: ((OPT_CLKDIV < 256) ? 8 : 9))))))));
// }}}
localparam [4:0] CFG_MODE = 12;
localparam [4:0] QSPEED_BIT = 11;
// localparam [4:0] DSPEED_BIT = 10; // Unused in QSPI controller
localparam [4:0] DIR_BIT = 9;
localparam [4:0] USER_CS_n = 8;
//
localparam [1:0] NORMAL_SPI = 2'b00;
localparam [1:0] QUAD_WRITE = 2'b10;
localparam [1:0] QUAD_READ = 2'b11;
// Read commands are unused in this driver, since its based around
// XiP access
// {{{
// localparam [7:0] DIO_READ_CMD = 8'hbb;
// localparam [7:0] QIO_READ_CMD = OPT_ADDR32 ? 8'hec : 8'heb;
// }}}
//
`ifdef FORMAL
localparam F_LGDEPTH=$clog2(3+RDDELAY+(OPT_ADDR32 ? 2:0));
reg f_past_valid;
`endif
//
//
// Arbitrated bus registers and inputs
//
wire bus_cyc, bus_stb, bus_we, ign_wb_err, ign_cfg_err;
wire [(AW-1):0] bus_addr;
wire [31:0] bus_data;
wire [3:0] bus_sel;
reg bus_stall, bus_ack;
wire cfg_bus_stb, mem_bus_stb;
reg dly_ack, read_sck;
wire xtra_stall;
// clk_ctr must have enough bits for ...
// 6 address clocks, 4-bits each
// NDUMMY dummy clocks, including two mode bytes
// 8 data clocks
// (RDDELAY clocks not counted here)
reg [4:0] clk_ctr;
//
// User override logic
//
reg cfg_mode, cfg_speed, cfg_dir, cfg_cs;
wire cfg_write, cfg_hs_write, cfg_ls_write, cfg_hs_read,
user_request, bus_request, pipe_req, cfg_noop, cfg_stb;
//
assign bus_request = (mem_bus_stb)&&(!bus_stall)
&&(!bus_we)&&(!cfg_mode);
assign cfg_stb = (OPT_CFG)&&(cfg_bus_stb)&&(!bus_stall);
assign cfg_noop = ((cfg_stb)&&((!bus_we)||(!i_cfg_data[CFG_MODE])
||(i_cfg_data[USER_CS_n])))
||((!OPT_CFG)&&(cfg_bus_stb)&&(!bus_stall));
assign user_request = (cfg_stb)&&(i_cfg_we)&&(i_cfg_data[CFG_MODE]);
assign cfg_write = (user_request)&&(!i_cfg_data[USER_CS_n]);
assign cfg_hs_write = (cfg_write)&&(i_cfg_data[QSPEED_BIT])
&&(i_cfg_data[DIR_BIT]);
assign cfg_hs_read = (cfg_write)&&(i_cfg_data[QSPEED_BIT])
&&(!i_cfg_data[DIR_BIT]);
assign cfg_ls_write = (cfg_write)&&(!i_cfg_data[QSPEED_BIT]);
reg ckstb, ckpos, ckneg, ckpre;
reg maintenance;
reg [1:0] m_mod;
reg m_cs_n;
reg m_clk;
reg [3:0] m_dat;
reg [32+(OPT_ADDR32 ? 8:0)+4*(OPT_ODDR ? 0:1)-1:0] data_pipe;
reg pre_ack = 1'b0;
wire actual_sck;
reg r_last_cfg;
// }}}
////////////////////////////////////////////////////////////////////////
//
// Incoming bus arbiter
// {{{
generate if (OPT_CFG)
begin : GEN_MEMCFG_ARBITER
// {{{
wire cfg_bus_grant;
//
// Memory vs Configuration bus arbiter
//
wbarbiter #(
// {{{
.DW(DW), .AW(AW+1), .SCHEME("PRIORITY")
`ifdef FORMAL
, .F_MAX_STALL(0), .F_MAX_ACK_DELAY(0)
`endif
// }}}
) arbiter(
// {{{
i_clk, i_reset,
i_wb_cyc, i_wb_stb, i_wb_we, { 1'b0, i_wb_addr },
i_wb_data, i_wb_sel,
o_wb_stall, o_wb_ack, ign_wb_err,
i_cfg_cyc, i_cfg_stb, i_cfg_we, { 1'b1, i_wb_addr },
i_cfg_data, i_cfg_sel,
o_cfg_stall, o_cfg_ack, ign_cfg_err,
bus_cyc, bus_stb, bus_we, { cfg_bus_grant, bus_addr }, bus_data, bus_sel,
bus_stall, bus_ack, 1'b0
// }}}
);
assign cfg_bus_stb = bus_stb && cfg_bus_grant;
assign mem_bus_stb = bus_stb && !cfg_bus_grant;
assign o_cfg_data = o_wb_data;
// verilator lint_off UNUSED
wire unused;
assign unused = &{ 1'b0, bus_data, bus_addr, ign_cfg_err,
ign_wb_err };
// verilator lint_on UNUSED
// }}}
end else begin : NO_CFG_ARBITER
// {{{
assign bus_cyc = i_wb_cyc;
assign bus_stb = i_wb_stb;
assign bus_we = i_wb_we;
assign bus_addr = i_wb_addr;
assign bus_data = i_wb_data;
assign bus_sel = i_wb_sel;
assign o_wb_ack = bus_ack;
assign o_wb_stall = bus_stall;
assign mem_bus_stb = bus_stb;
assign cfg_bus_stb = 0;
assign o_cfg_ack = i_cfg_stb;
assign o_cfg_stall = 0;
assign o_cfg_data = 0;
// }}}
end endgenerate
// }}}
////////////////////////////////////////////////////////////////////////
//
// (Sub)Clock generation
// {{{
////////////////////////////////////////////////////////////////////////
//
//
generate if (OPT_ODDR)
begin : CKSTB_ZERO // Flash clock == system clock speed
// {{{
always @(*)
begin
ckstb = 1'b1;
ckpos = 1'b1;
ckneg = 1'b1;
ckpre = 1'b1;
end
// }}}
end else if (OPT_CLKDIV == 1)
begin : CKSTB_ONE // Flash clock can be generated logically, == sysclk/2
// {{{
reg clk_counter;
initial clk_counter = 1'b1;
always @(posedge i_clk)
if (i_reset)
clk_counter <= 1'b1;
else if (clk_counter != 0)
clk_counter <= 1'b0;
else if (bus_request)
clk_counter <= (pipe_req);
else if ((maintenance)||(!o_qspi_cs_n && bus_stall))
clk_counter <= 1'b1;
always @(*)
begin
ckpre = (clk_counter == 1);
ckstb = (clk_counter == 0);
ckpos = (clk_counter == 1);
ckneg = (clk_counter == 0);
end
// }}}
end else begin : CKSTB_GEN
// {{{
reg [CKDV_BITS-1:0] clk_counter;
initial clk_counter = OPT_CLKDIV;
always @(posedge i_clk)
if (i_reset)
clk_counter <= OPT_CLKDIV;
else if (clk_counter != 0)
clk_counter <= clk_counter - 1;
else if (bus_request)
clk_counter <= (pipe_req ? OPT_CLKDIV : 0);
else if ((maintenance)||(!o_qspi_cs_n && bus_stall))
clk_counter <= OPT_CLKDIV;
initial ckpre = (OPT_CLKDIV == 1);
initial ckstb = 1'b0;
initial ckpos = (OPT_CLKDIV == 1);
always @(posedge i_clk)
if (i_reset)
begin
ckpre <= (OPT_CLKDIV == 1);
ckstb <= 1'b0;
ckpos <= (OPT_CLKDIV == 1);
end else // if (OPT_CLKDIV > 1)
begin
ckpre <= (clk_counter == 2);
ckstb <= (clk_counter == 1);
ckpos <= (clk_counter == (OPT_CLKDIV+1)/2+1);
end
always @(*)
ckneg = ckstb;
`ifdef FORMAL
always @(*)
assert(!ckpos || !ckneg);
always @(posedge i_clk)
if ((f_past_valid)&&(!$past(i_reset))&&($past(ckpre)))
assert(ckstb);
`endif
// }}}
end endgenerate
// }}}
////////////////////////////////////////////////////////////////////////
//
// Maintenance / startup portion
// {{{
////////////////////////////////////////////////////////////////////////
//
//
generate if (OPT_STARTUP)
begin : GEN_STARTUP
// {{{
// Signal declarations
// {{{
localparam M_WAITBIT=10;
localparam M_LGADDR=5;
`ifdef FORMAL
// For formal, jump into the middle of the startup
localparam M_FIRSTIDX=9;
`else
localparam M_FIRSTIDX=0;
`endif
reg [M_WAITBIT:0] m_this_word;
reg [M_WAITBIT:0] m_cmd_word [0:(1<<M_LGADDR)-1];
reg [M_LGADDR-1:0] m_cmd_index;
reg [M_WAITBIT-1:0] m_counter;
reg m_midcount;
reg [3:0] m_bitcount;
reg [7:0] m_byte;
// }}}
// Command ISA description:
// {{{
// Let's script our startup with a series of commands.
// These commands are specific to the Micron Serial NOR flash
// memory that was on the original Arty A7 board. Switching
// from one memory to another should only require adjustments
// to this startup sequence, and to the flashdrvr.cpp module
// found in sw/host.
//
// The format of the data words is ...
// 1'bit (MSB) to indicate this is a counter word.
// Counter words count a number of idle cycles,
// in which the port is unused (CSN is high)
//
// 2'bit mode. This is either ...
// NORMAL_SPI, for a normal SPI interaction:
// MOSI, MISO, WPn and HOLD
// QUAD_READ, all four pins set as inputs. In this
// startup, the input values will be
// ignored.
// or QUAD_WRITE, all four pins are outputs. This is
// important for getting the flash into
// an XIP mode that we can then use for
// all reads following.
//
// 8'bit data To be sent 1-bit at a time in NORMAL_SPI
// mode, or 4-bits at a time in QUAD_WRITE
// mode. Ignored otherwis
// }}}
integer k;
initial if (OPT_STARTUP_FILE != 0)
$readmemh(OPT_STARTUP_FILE, m_cmd_word);
else begin
// {{{
for(k=0; k<(1<<M_LGADDR); k=k+1)
m_cmd_word[k] = -1;
// cmd_word= m_ctr_flag, m_mod[1:0],
// m_cs_n, m_clk, m_data[3:0]
// Start off idle
// This is really redundant since all of our commands are
// idle's.
m_cmd_word[5'h07] = -1;
//
// Since we don't know what mode we started in, whether the
// device was left in XIP mode or some other mode, we'll start
// by exiting any mode we might have been in.
//
// The key to doing this is to issue a non-command, that can
// also be interpreted as an XIP address with an incorrect
// mode bit. That will get us out of any XIP mode, and back
// into a SPI mode we might use. The command is issued in
// NORMAL_SPI mode, however, since we don't know if the device
// is initially in XIP or not.
//
// Exit any QSPI mode we might've been in
m_cmd_word[5'h08] = { 1'b0, NORMAL_SPI, 8'hff }; // Addr 1
m_cmd_word[5'h09] = { 1'b0, NORMAL_SPI, 8'hff }; // Addr 2
m_cmd_word[5'h0a] = { 1'b0, NORMAL_SPI, 8'hff }; // Addr 2
// Idle
m_cmd_word[5'h0b] = { 1'b1, 10'h3f };
//
// Write configuration register
//
// The write enable must come first: 06
m_cmd_word[5'h0c] = { 1'b0, NORMAL_SPI, 8'h06 };
//
// Idle
m_cmd_word[5'h0d] = { 1'b1, 10'h3ff };
//
// Write configuration register, follows a write-register
m_cmd_word[5'h0e] = { 1'b0, NORMAL_SPI, 8'h01 }; // WRR
m_cmd_word[5'h0f] = { 1'b0, NORMAL_SPI, 8'h00 }; // status register
m_cmd_word[5'h10] = { 1'b0, NORMAL_SPI, 8'h02 }; // Config register
//
// Idle
m_cmd_word[5'h11] = { 1'b1, 10'h3ff };
m_cmd_word[5'h12] = { 1'b1, 10'h3ff };
//
//
// WRDI: write disable: 04
m_cmd_word[5'h13] = { 1'b0, NORMAL_SPI, 8'h04 };
//
// Idle
m_cmd_word[5'h14] = { 1'b1, 10'h3ff };
//
// Enter into QSPI mode, 0xeb, 0,0,0
// 0xeb
m_cmd_word[5'h15] = { 1'b0, NORMAL_SPI, 8'heb };
// Addr #1
m_cmd_word[5'h16] = { 1'b0, QUAD_WRITE, 8'h00 };
// Addr #2
m_cmd_word[5'h17] = { 1'b0, QUAD_WRITE, 8'h00 };
// Addr #3
m_cmd_word[5'h18] = { 1'b0, QUAD_WRITE, 8'h00 };
// Mode byte
m_cmd_word[5'h19] = { 1'b0, QUAD_WRITE, 8'ha0 };
// Dummy clocks, x6 for this flash
m_cmd_word[5'h1a] = { 1'b0, QUAD_WRITE, 8'h00 };
m_cmd_word[5'h1b] = { 1'b0, QUAD_WRITE, 8'h00 };
m_cmd_word[5'h1c] = { 1'b0, QUAD_WRITE, 8'h00 };
// Now read a byte for form
m_cmd_word[5'h1d] = { 1'b0, QUAD_READ, 8'h00 };
//
// Idle -- These last two idles are *REQUIRED* and not optional
// (although they might be able to be trimmed back a bit...)
m_cmd_word[5'h1e] = -1;
m_cmd_word[5'h1f] = -1;
// Then we are in business!
// }}}
end
reg m_final;
wire m_ce, new_word;
assign m_ce = (!m_midcount)&&(ckstb);
assign new_word = (m_ce && m_bitcount == 0);
// m_cmd_index, maintenance (on/off)
// {{{
initial maintenance = 1'b1;
initial m_cmd_index = M_FIRSTIDX;
always @(posedge i_clk)
if (i_reset)
begin
m_cmd_index <= M_FIRSTIDX;
maintenance <= 1'b1;
end else if (new_word)
begin
maintenance <= (maintenance)&&(!m_final);
if (!(&m_cmd_index))
m_cmd_index <= m_cmd_index + 1'b1;
end
// }}}
// m_this_word -- current command
// {{{
initial m_this_word = -1;
always @(posedge i_clk)
if (new_word)
m_this_word <= m_cmd_word[m_cmd_index];
// }}}
// m_final
// {{{
initial m_final = 1'b0;
always @(posedge i_clk)
if (i_reset)
m_final <= 1'b0;
else if (new_word)
m_final <= (m_final || (&m_cmd_index));
// }}}
// m_midcount .. are we in the middle of a counter/pause?
// {{{
initial m_midcount = 1;
initial m_counter = -1;
always @(posedge i_clk)
if (i_reset)
begin
// {{{
m_midcount <= 1'b1;
`ifdef FORMAL
m_counter <= 3;
`else
m_counter <= -1;
`endif
// }}}
end else if (new_word)
begin
// {{{
m_midcount <= m_this_word[M_WAITBIT]
&& (|m_this_word[M_WAITBIT-1:0]);
if (m_this_word[M_WAITBIT])
begin
m_counter <= m_this_word[M_WAITBIT-1:0];
`ifdef FORMAL
if (m_this_word[M_WAITBIT-1:0] > 3)
m_counter <= 3;
`endif
end
// }}}
end else begin
// {{{
m_midcount <= (m_counter > 1);
if (m_counter > 0)
m_counter <= m_counter - 1'b1;
// }}}
end
// }}}
// m_cs_n, m_mod, m_bitcount
// {{{
initial m_cs_n = 1'b1;
initial m_mod = NORMAL_SPI;
always @(posedge i_clk)
if (i_reset)
begin
m_cs_n <= 1'b1;
m_mod <= NORMAL_SPI;
m_bitcount <= 0;
end else if (ckstb)
begin
if (m_bitcount != 0)
m_bitcount <= m_bitcount - 1;
else if ((m_ce)&&(m_final))
begin
m_cs_n <= 1'b1;
m_mod <= NORMAL_SPI;
m_bitcount <= 0;
end else if ((m_midcount)||(m_this_word[M_WAITBIT]))
begin
m_cs_n <= 1'b1;
m_mod <= NORMAL_SPI;
m_bitcount <= 0;
end else begin
m_cs_n <= 1'b0;
m_mod <= m_this_word[M_WAITBIT-1:M_WAITBIT-2];
m_bitcount <= (!OPT_ODDR && m_cs_n) ? 4'h2 : 4'h1;
if (!m_this_word[M_WAITBIT-1])
m_bitcount <= (!OPT_ODDR && m_cs_n) ? 4'h8 : 4'h7;//i.e.7
end
end
// }}}
// m_dat, m_byte
// {{{
always @(posedge i_clk)
if (m_ce)
begin
if (m_bitcount == 0)
begin
// {{{
if (!OPT_ODDR && m_cs_n)
begin
m_dat <= {(4){m_this_word[7]}};
m_byte <= m_this_word[7:0];
end else begin
m_dat <= m_this_word[7:4];
m_byte <= { m_this_word[3:0], 4'h0};
if (!m_this_word[M_WAITBIT-1])
begin
// Slow speed
m_dat[0] <= m_this_word[7];
m_byte <= { m_this_word[6:0], 1'b0 };
end
end
// }}}
end else begin
// {{{
m_dat <= m_byte[7:4];
m_byte <= { m_byte[3:0], 4'h0 };
if (!m_mod[1])
begin
// Slow speed
m_dat[0] <= m_byte[7];
m_byte <= { m_byte[6:0], 1'b0 };
end else begin
m_byte <= { m_byte[3:0], 4'b00 };
end
// }}}
end
end
// }}}
if (OPT_ODDR)
begin : M_CLK_DDR
always @(*)
m_clk = !m_cs_n;
end else begin : GEN_M_CLK_LOGIC
// {{{
always @(posedge i_clk)
if (i_reset)
m_clk <= 1'b1;
else if (m_cs_n)
m_clk <= 1'b1;
else if ((!m_clk)&&(ckpos))
m_clk <= 1'b1;
else if (m_midcount)
m_clk <= 1'b1;
else if (new_word && m_this_word[M_WAITBIT])
m_clk <= 1'b1;
else if (ckneg)
m_clk <= 1'b0;
// }}}
end
// }}}
`ifdef FORMAL
// {{{
(* anyconst *) reg [M_LGADDR:0] f_const_addr;
always @(*)
begin
assert((m_cmd_word[f_const_addr][M_WAITBIT])
||(m_cmd_word[f_const_addr][M_WAITBIT-1:M_WAITBIT-2] != 2'b01));
if (m_cmd_word[f_const_addr][M_WAITBIT])
assert(m_cmd_word[f_const_addr][M_WAITBIT-3:0] > 0);
end
always @(*)
begin
if (m_cmd_index != f_const_addr)
assume((m_cmd_word[m_cmd_index][M_WAITBIT])||(m_cmd_word[m_cmd_index][M_WAITBIT-1:M_WAITBIT-2] != 2'b01));
if (m_cmd_word[m_cmd_index][M_WAITBIT])
assume(m_cmd_word[m_cmd_index][M_WAITBIT-3:0]>0);
end
always @(*)
begin
assert((m_this_word[M_WAITBIT])
||(m_this_word[M_WAITBIT-1:M_WAITBIT-2] != 2'b01));
if (m_this_word[M_WAITBIT])
assert(m_this_word[M_WAITBIT-3:0] > 0);
end
// Setting the last two command words to IDLE with maximum
// counts is required by our implementation
always @(*)
assert(m_cmd_word[5'h1e] == 11'h7ff);
always @(*)
assert(m_cmd_word[5'h1f] == 11'h7ff);
wire [M_LGADDR-1:0] last_index;
assign last_index = m_cmd_index - 1;
always @(posedge i_clk)
if ((f_past_valid)&&(m_cmd_index != M_FIRSTIDX))
assert(m_this_word == m_cmd_word[last_index]);
always @(posedge i_clk)
assert(m_midcount == (m_counter != 0));
reg [20:0] f_mpipe;
initial f_mpipe = 0;
always @(posedge i_clk)
if (i_reset)
f_mpipe <= 0;
else
f_mpipe <= { f_mpipe[19:0], (m_cmd_index == 5'h15) };
always @(posedge i_clk)
begin
cover(!maintenance);
cover(f_mpipe[3]);
cover(f_mpipe[4]);
cover(f_mpipe[5]);
cover(f_mpipe[6]);
cover(f_mpipe[7]);
cover(f_mpipe[8]);
cover(f_mpipe[9]);
cover(f_mpipe[10]);
cover(f_mpipe[11]);
cover(m_cmd_index == 5'h0a);
cover(m_cmd_index == 5'h0b);
cover(m_cmd_index == 5'h0c);
cover(m_cmd_index == 5'h0d);
cover(m_cmd_index == 5'h0e);
cover(m_cmd_index == 5'h0f);
cover(m_cmd_index == 5'h10);
cover(m_cmd_index == 5'h11);
cover(m_cmd_index == 5'h12);
cover(m_cmd_index == 5'h13);
cover(m_cmd_index == 5'h14);
cover(m_cmd_index == 5'h15);
cover(m_cmd_index == 5'h16); // @ 470
cover(m_cmd_index == 5'h17); // @482
cover(m_cmd_index == 5'h18); // @ 494
cover(m_cmd_index == 5'h19); // @ 506
cover(m_cmd_index == 5'h1a); // @ 518
cover(m_cmd_index == 5'h1b); // @ 530
cover(m_cmd_index == 5'h1c); // @ 542
cover(m_cmd_index == 5'h1d); // @ 554
cover(m_cmd_index == 5'h1e); // @ 572
cover(m_cmd_index == 5'h1f); // @ 590
// 602
end
`endif
// }}}
end else begin : NO_STARTUP_OPT
// {{{
always @(*)
begin
maintenance = 0;
m_mod = 2'b00;
m_cs_n = 1'b1;
m_clk = 1'b0;
m_dat = 4'h0;
end
// verilator lint_off UNUSED
wire unused_maintenance;
assign unused_maintenance = &{ 1'b0, maintenance,
m_mod, m_cs_n, m_clk, m_dat };
// verilator lint_on UNUSED
// }}}
end endgenerate
// }}}
////////////////////////////////////////////////////////////////////////
//
// Data / access portion
// {{{
////////////////////////////////////////////////////////////////////////
//
//
// data_pipe
// {{{
initial data_pipe = 0;
always @(posedge i_clk)
begin
if (!bus_stall)
begin
// Set the high bits to zero initially
data_pipe <= 0;
data_pipe[8+LGFLASHSZ-1:0] <= {
i_wb_addr, 2'b00, 4'ha, 4'h0 };
if (cfg_bus_stb)
// High speed configuration I/O
data_pipe[24+(OPT_ADDR32 ? 8:0) +: 8] <= i_cfg_data[7:0];
if ((i_cfg_stb)&&(!i_cfg_data[QSPEED_BIT]))
begin // Low speed configuration I/O
data_pipe[28+(OPT_ADDR32 ? 8:0)] <= i_cfg_data[7];
data_pipe[24+(OPT_ADDR32 ? 8:0)] <= i_cfg_data[6];
end
if (i_cfg_stb)
begin // These can be set independent of speed
data_pipe[20+(OPT_ADDR32 ? 8:0)] <= i_cfg_data[5];
data_pipe[16+(OPT_ADDR32 ? 8:0)] <= i_cfg_data[4];
data_pipe[12+(OPT_ADDR32 ? 8:0)] <= i_cfg_data[3];
data_pipe[ 8+(OPT_ADDR32 ? 8:0)] <= i_cfg_data[2];
data_pipe[ 4+(OPT_ADDR32 ? 8:0)] <= i_cfg_data[1];
data_pipe[ 0+(OPT_ADDR32 ? 8:0)] <= i_cfg_data[0];
end
end else if (ckstb)
data_pipe <= { data_pipe[(32+(OPT_ADDR32 ? 8:0)+4*((OPT_ODDR ? 0:1)-1))-1:0], 4'h0 };
if (maintenance)
data_pipe[28+(OPT_ADDR32 ? 8:0)+4*(OPT_ODDR ? 0:1) +: 4] <= m_dat;
end
// }}}
assign o_qspi_dat = data_pipe[28+(OPT_ADDR32 ? 8:0)+4*(OPT_ODDR ? 0:1) +: 4];
// pre_ack
// {{{
// Since we can't abort any transaction once started, without
// risking losing XIP mode or any other mode we might be in, we'll
// keep track of whether this operation should be ack'd upon
// completion
always @(posedge i_clk)
if ((i_reset)||(!bus_cyc))
pre_ack <= 1'b0;
else if ((bus_request)||(cfg_write))
pre_ack <= 1'b1;
// }}}
// pipe_req
// {{{
generate if (OPT_PIPE)
begin : OPT_PIPE_BLOCK
// {{{
reg r_pipe_req;
wire w_pipe_condition;
reg [(AW-1):0] next_addr;
always @(posedge i_clk)
if (!bus_stall)
next_addr <= i_wb_addr + 1'b1;
assign w_pipe_condition = (mem_bus_stb)
&&(!i_wb_we)&&(pre_ack)
&&(!maintenance)
&&(!cfg_mode)
&&(!o_qspi_cs_n)
&&(|clk_ctr[2:0])
&&(next_addr == i_wb_addr);
initial r_pipe_req = 1'b0;
always @(posedge i_clk)
if ((clk_ctr == 1)&&(ckstb))
r_pipe_req <= 1'b0;
else
r_pipe_req <= w_pipe_condition;
assign pipe_req = r_pipe_req;
// }}}
end else begin : NO_PIPE
assign pipe_req = 1'b0;
end endgenerate
// }}}
// clk_ctr
// {{{
initial clk_ctr = 0;
always @(posedge i_clk)
if ((i_reset)||(maintenance))
clk_ctr <= 0;
else if ((bus_request)&&(!pipe_req))
// Notice that this is only for
// regular bus reads, and so the check for
// !pipe_req
clk_ctr <= 5'd14 + NDUMMY[3:0] + (OPT_ADDR32 ? 2:0)+(OPT_ODDR ? 0:1);
else if (bus_request) // && pipe_req
// Otherwise, if this is a piped read, we'll
// reset the counter back to eight.
clk_ctr <= 5'd8;
else if (cfg_ls_write)
clk_ctr <= 5'd8 + ((OPT_ODDR) ? 0:1);
else if (cfg_write)
clk_ctr <= 5'd2 + ((OPT_ODDR) ? 0:1);
else if ((ckstb)&&(|clk_ctr))
clk_ctr <= clk_ctr - 1'b1;
// }}}
// o_qspi_sck
// {{{
initial o_qspi_sck = (!OPT_ODDR);
always @(posedge i_clk)
if (i_reset)
o_qspi_sck <= (!OPT_ODDR);
else if (maintenance)
o_qspi_sck <= m_clk;
else if ((!OPT_ODDR)&&(bus_request)&&(pipe_req))
o_qspi_sck <= 1'b0;
else if ((bus_request)||(cfg_write))
o_qspi_sck <= 1'b1;
else if (OPT_ODDR)
begin
if ((cfg_mode)&&(clk_ctr <= 1))
// Config mode has no pipe instructions
o_qspi_sck <= 1'b0;
else if (clk_ctr[4:0] > 5'd1)
o_qspi_sck <= 1'b1;
else
o_qspi_sck <= 1'b0;
end else if (((ckpos)&&(!o_qspi_sck))||(o_qspi_cs_n))
begin
o_qspi_sck <= 1'b1;
end else if ((ckneg)&&(o_qspi_sck)) begin
if ((cfg_mode)&&(clk_ctr <= 1))
// Config mode has no pipe instructions
o_qspi_sck <= 1'b1;
else if (clk_ctr[4:0] > 5'd1)
o_qspi_sck <= 1'b0;
else