demofull.v

////////////////////////////////////////////////////////////////////////////////
//
// Filename: 	demofull.v
// {{{
// Project:	WB2AXIPSP: bus bridges and other odds and ends
//
// Purpose:	Demonstrate a formally verified AXI4 core with a (basic)
//		interface.  This interface is explained below.
//
// Performance: This core has been designed for a total throughput of one beat
//		per clock cycle.  Both read and write channels can achieve
//	this.  The write channel will also introduce two clocks of latency,
//	assuming no other latency from the master.  This means it will take
//	a minimum of 3+AWLEN clock cycles per transaction of (1+AWLEN) beats,
//	including both address and acknowledgment cycles.  The read channel
//	will introduce a single clock of latency, requiring 2+ARLEN cycles
//	per transaction of 1+ARLEN beats.
//
// Creator:	Dan Gisselquist, Ph.D.
//		Gisselquist Technology, LLC
//
////////////////////////////////////////////////////////////////////////////////
// }}}
// Copyright (C) 2019-2024, Gisselquist Technology, LLC
// {{{
// This file is part of the WB2AXIP project.
//
// The WB2AXIP project contains free software and gateware, licensed under the
// Apache License, Version 2.0 (the "License").  You may not use this project,
// or 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.
//
////////////////////////////////////////////////////////////////////////////////
//
`default_nettype	none
// }}}
module demofull #(
		// {{{
		parameter integer C_S_AXI_ID_WIDTH	= 2,
		parameter integer C_S_AXI_DATA_WIDTH	= 32,
		parameter integer C_S_AXI_ADDR_WIDTH	= 6,
		parameter	[0:0]	OPT_LOCK     = 1'b0,
		parameter	[0:0]	OPT_LOCKID   = 1'b1,
		parameter	[0:0]	OPT_LOWPOWER = 1'b0,
		// Some useful short-hand definitions
		localparam	LSB = $clog2(C_S_AXI_DATA_WIDTH)-3
		// }}}
	) (
		// {{{
		// User ports
		// {{{
		// A very basic protocol-independent peripheral interface
		// 1. A value will be written any time o_we is true
		// 2. A value will be read any time o_rd is true
		// 3. Such a slave might just as easily be written as:
		//
		//	always @(posedge S_AXI_ACLK)
		//	if (o_we)
		//	begin
		//	    for(k=0; k<C_S_AXI_DATA_WIDTH/8; k=k+1)
		//	    begin
		//		if (o_wstrb[k])
		//		mem[o_waddr[AW-1:LSB]][k*8+:8] <= o_wdata[k*8+:8]
		//	    end
		//	end
		//
		//	always @(posedge S_AXI_ACLK)
		//	if (o_rd)
		//		i_rdata <= mem[o_raddr[AW-1:LSB]];
		//
		// 4. The rule on the input is that i_rdata must be registered,
		//    and that it must only change if o_rd is true.  Violating
		//    this rule will cause this core to violate the AXI
		//    protocol standard, as this value is not registered within
		//    this core
		output	reg					o_we,
		output	reg	[C_S_AXI_ADDR_WIDTH-LSB-1:0]	o_waddr,
		output	reg	[C_S_AXI_DATA_WIDTH-1:0]	o_wdata,
		output	reg	[C_S_AXI_DATA_WIDTH/8-1:0]	o_wstrb,
		//
		output	reg					o_rd,
		output	reg	[C_S_AXI_ADDR_WIDTH-LSB-1:0]	o_raddr,
		input	wire	[C_S_AXI_DATA_WIDTH-1:0]	i_rdata,
		//
		// User ports ends
		// }}}
		// Do not modify the ports beyond this line
		// AXI signals
		// {{{
		// Global Clock Signal
		input wire  S_AXI_ACLK,
		// Global Reset Signal. This Signal is Active LOW
		input wire  S_AXI_ARESETN,

		// Write address channel
		// {{{
		// Write Address ID
		input wire [C_S_AXI_ID_WIDTH-1 : 0] S_AXI_AWID,
		// Write address
		input wire [C_S_AXI_ADDR_WIDTH-1 : 0] S_AXI_AWADDR,
		// Burst length. The burst length gives the exact number of
		// transfers in a burst
		input wire [7 : 0] S_AXI_AWLEN,
		// Burst size. This signal indicates the size of each transfer
		// in the burst
		input wire [2 : 0] S_AXI_AWSIZE,
		// Burst type. The burst type and the size information,
		// determine how the address for each transfer within the burst
		// is calculated.
		input wire [1 : 0] S_AXI_AWBURST,
		// Lock type. Provides additional information about the
		// atomic characteristics of the transfer.
		input wire  S_AXI_AWLOCK,
		// Memory type. This signal indicates how transactions
		// are required to progress through a system.
		input wire [3 : 0] S_AXI_AWCACHE,
		// Protection type. This signal indicates the privilege
		// and security level of the transaction, and whether
		// the transaction is a data access or an instruction access.
		input wire [2 : 0] S_AXI_AWPROT,
		// Quality of Service, QoS identifier sent for each
		// write transaction.
		input wire [3 : 0] S_AXI_AWQOS,
		// Region identifier. Permits a single physical interface
		// on a slave to be used for multiple logical interfaces.
		// Write address valid. This signal indicates that
		// the channel is signaling valid write address and
		// control information.
		input wire  S_AXI_AWVALID,
		// Write address ready. This signal indicates that
		// the slave is ready to accept an address and associated
		// control signals.
		output wire  S_AXI_AWREADY,
		// }}}
		// Write data channel
		// {{{
		// Write Data
		input wire [C_S_AXI_DATA_WIDTH-1 : 0] S_AXI_WDATA,
		// Write strobes. This signal indicates which byte
		// lanes hold valid data. There is one write strobe
		// bit for each eight bits of the write data bus.
		input wire [(C_S_AXI_DATA_WIDTH/8)-1 : 0] S_AXI_WSTRB,
		// Write last. This signal indicates the last transfer
		// in a write burst.
		input wire  S_AXI_WLAST,
		// Optional User-defined signal in the write data channel.
		// Write valid. This signal indicates that valid write
		// data and strobes are available.
		input wire  S_AXI_WVALID,
		// Write ready. This signal indicates that the slave
		// can accept the write data.
		output wire  S_AXI_WREADY,
		// }}}
		// Write response channel
		// {{{
		// Response ID tag. This signal is the ID tag of the
		// write response.
		output wire [C_S_AXI_ID_WIDTH-1 : 0] S_AXI_BID,
		// Write response. This signal indicates the status
		// of the write transaction.
		output wire [1 : 0] S_AXI_BRESP,
		// Optional User-defined signal in the write response channel.
		// Write response valid. This signal indicates that the
		// channel is signaling a valid write response.
		output wire  S_AXI_BVALID,
		// Response ready. This signal indicates that the master
		// can accept a write response.
		input wire  S_AXI_BREADY,
		// }}}
		// Read address channel
		// {{{
		// Read address ID. This signal is the identification
		// tag for the read address group of signals.
		input wire [C_S_AXI_ID_WIDTH-1 : 0] S_AXI_ARID,
		// Read address. This signal indicates the initial
		// address of a read burst transaction.
		input wire [C_S_AXI_ADDR_WIDTH-1 : 0] S_AXI_ARADDR,
		// Burst length. The burst length gives the exact number of
		// transfers in a burst
		input wire [7 : 0] S_AXI_ARLEN,
		// Burst size. This signal indicates the size of each transfer
		// in the burst
		input wire [2 : 0] S_AXI_ARSIZE,
		// Burst type. The burst type and the size information,
		// determine how the address for each transfer within the
		// burst is calculated.
		input wire [1 : 0] S_AXI_ARBURST,
		// Lock type. Provides additional information about the
		// atomic characteristics of the transfer.
		input wire  S_AXI_ARLOCK,
		// Memory type. This signal indicates how transactions
		// are required to progress through a system.
		input wire [3 : 0] S_AXI_ARCACHE,
		// Protection type. This signal indicates the privilege
		// and security level of the transaction, and whether
		// the transaction is a data access or an instruction access.
		input wire [2 : 0] S_AXI_ARPROT,
		// Quality of Service, QoS identifier sent for each
		// read transaction.
		input wire [3 : 0] S_AXI_ARQOS,
		// Region identifier. Permits a single physical interface
		// on a slave to be used for multiple logical interfaces.
		// Optional User-defined signal in the read address channel.
		// Write address valid. This signal indicates that
		// the channel is signaling valid read address and
		// control information.
		input wire  S_AXI_ARVALID,
		// Read address ready. This signal indicates that
		// the slave is ready to accept an address and associated
		// control signals.
		output wire  S_AXI_ARREADY,
		// }}}
		// Read data (return) channel
		// {{{
		// Read ID tag. This signal is the identification tag
		// for the read data group of signals generated by the slave.
		output wire [C_S_AXI_ID_WIDTH-1 : 0] S_AXI_RID,
		// Read Data
		output wire [C_S_AXI_DATA_WIDTH-1 : 0] S_AXI_RDATA,
		// Read response. This signal indicates the status of
		// the read transfer.
		output wire [1 : 0] S_AXI_RRESP,
		// Read last. This signal indicates the last transfer
		// in a read burst.
		output wire  S_AXI_RLAST,
		// Optional User-defined signal in the read address channel.
		// Read valid. This signal indicates that the channel
		// is signaling the required read data.
		output wire  S_AXI_RVALID,
		// Read ready. This signal indicates that the master can
		// accept the read data and response information.
		input wire  S_AXI_RREADY
		// }}}
		// }}}
		// }}}
	);

	// Local declarations
	// {{{
	// More useful shorthand definitions
	localparam	AW = C_S_AXI_ADDR_WIDTH;
	localparam	DW = C_S_AXI_DATA_WIDTH;
	localparam	IW = C_S_AXI_ID_WIDTH;
	// Double buffer the write response channel only
	reg	[IW-1 : 0]	r_bid;
	reg			r_bvalid;
	reg	[IW-1 : 0]	axi_bid;
	reg			axi_bvalid;

	reg			axi_awready, axi_wready;
	reg	[AW-1:0]	waddr;
	wire	[AW-1:0]	next_wr_addr;

	// Vivado will warn about wlen only using 4-bits.  This is
	// to be expected, since the axi_addr module only needs to use
	// the bottom four bits of wlen to determine address increments
	reg	[7:0]		wlen;
	// Vivado will also warn about the top bit of wsize being unused.
	// This is also to be expected for a DATA_WIDTH of 32-bits.
	reg	[2:0]		wsize;
	reg	[1:0]		wburst;

	wire			m_awvalid, m_awlock;
	reg			m_awready;
	wire	[AW-1:0]	m_awaddr;
	wire	[1:0]		m_awburst;
	wire	[2:0]		m_awsize;
	wire	[7:0]		m_awlen;
	wire	[IW-1:0]	m_awid;

	wire	[AW-1:0]	next_rd_addr;

	// Vivado will warn about rlen only using 4-bits.  This is
	// to be expected, since for a DATA_WIDTH of 32-bits, the axi_addr
	// module only uses the bottom four bits of rlen to determine
	// address increments
	reg	[7:0]		rlen;
	// Vivado will also warn about the top bit of wsize being unused.
	// This is also to be expected for a DATA_WIDTH of 32-bits.
	reg	[2:0]		rsize;
	reg	[1:0]		rburst;
	reg	[IW-1:0]	rid;
	reg			rlock;
	reg			axi_arready;
	reg	[8:0]		axi_rlen;
	reg	[AW-1:0]	raddr;

	// Read skid buffer
	reg			rskd_valid, rskd_last, rskd_lock;
	wire			rskd_ready;
	reg	[IW-1:0]	rskd_id;

	// Exclusive address register checking
	reg			exclusive_write, block_write;
	wire			write_lock_valid;
	reg			axi_exclusive_write;


	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// AW Skid buffer
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//
	skidbuffer #(
		// {{{
		.DW(AW+2+3+1+8+IW),
		.OPT_LOWPOWER(OPT_LOWPOWER),
		.OPT_OUTREG(1'b0)
		// }}}
	) awbuf(
		// {{{
		.i_clk(S_AXI_ACLK), .i_reset(!S_AXI_ARESETN),
		.i_valid(S_AXI_AWVALID), .o_ready(S_AXI_AWREADY),
			.i_data({ S_AXI_AWADDR, S_AXI_AWBURST, S_AXI_AWSIZE,
				S_AXI_AWLOCK, S_AXI_AWLEN, S_AXI_AWID }),
		.o_valid(m_awvalid), .i_ready(m_awready),
			.o_data({ m_awaddr, m_awburst, m_awsize,
				m_awlock, m_awlen, m_awid })
		// }}}
	);
	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// Write processing
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//

	// axi_awready, axi_wready
	// {{{
	initial	axi_awready = 1;
	initial	axi_wready  = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
	begin
		axi_awready  <= 1;
		axi_wready   <= 0;
	end else if (m_awvalid && m_awready)
	begin
		axi_awready <= 0;
		axi_wready  <= 1;
	end else if (S_AXI_WVALID && S_AXI_WREADY)
	begin
		axi_awready <= (S_AXI_WLAST)&&(!S_AXI_BVALID || S_AXI_BREADY);
		axi_wready  <= (!S_AXI_WLAST);
	end else if (!axi_awready)
	begin
		if (S_AXI_WREADY)
			axi_awready <= 1'b0;
		else if (r_bvalid && !S_AXI_BREADY)
			axi_awready <= 1'b0;
		else
			axi_awready <= 1'b1;
	end
	// }}}

	// Exclusive write calculation
	// {{{
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN || !OPT_LOCK)
	begin
		exclusive_write <= 0;
		block_write <= 0;
	end else if (m_awvalid && m_awready)
	begin
		exclusive_write <= 1'b0;
		block_write     <= 1'b0;
		if (write_lock_valid)
			exclusive_write <= 1'b1;
		else if (m_awlock)
			block_write <= 1'b1;
	end else if (m_awready)
	begin
		exclusive_write <= 1'b0;
		block_write     <= 1'b0;
	end

	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN || !OPT_LOCK)
		axi_exclusive_write <= 0;
	else if (!S_AXI_BVALID || S_AXI_BREADY)
	begin
		axi_exclusive_write <= exclusive_write;
		if (OPT_LOWPOWER && (!S_AXI_WVALID || !S_AXI_WREADY || !S_AXI_WLAST)
				&& !r_bvalid)
			axi_exclusive_write <= 0;
	end
	// }}}

	// Next write address calculation
	// {{{
	always @(posedge S_AXI_ACLK)
	if (m_awready)
	begin
		waddr    <= m_awaddr;
		wburst   <= m_awburst;
		wsize    <= m_awsize;
		wlen     <= m_awlen;
	end else if (S_AXI_WVALID)
		waddr <= next_wr_addr;

	axi_addr #(
		// {{{
		.AW(AW), .DW(DW)
		// }}}
	) get_next_wr_addr(
		// {{{
		waddr, wsize, wburst, wlen,
			next_wr_addr
		// }}}
	);
	// }}}

	// o_w*
	// {{{
	always @(posedge S_AXI_ACLK)
	begin
		o_we    <= (S_AXI_WVALID && S_AXI_WREADY);
		o_waddr <= waddr[AW-1:LSB];
		o_wdata <= S_AXI_WDATA;
		if (block_write)
			o_wstrb <= 0;
		else
			o_wstrb <= S_AXI_WSTRB;

		if (!S_AXI_ARESETN)
			o_we <= 0;
		if (OPT_LOWPOWER && (!S_AXI_ARESETN || !S_AXI_WVALID
					|| !S_AXI_WREADY))
		begin
			o_waddr <= 0;
			o_wdata <= 0;
			o_wstrb <= 0;
		end
	end
	// }}}

	//
	// Write return path
	// {{{
	// r_bvalid
	// {{{
	initial	r_bvalid = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		r_bvalid <= 1'b0;
	else if (S_AXI_WVALID && S_AXI_WREADY && S_AXI_WLAST
			&&(S_AXI_BVALID && !S_AXI_BREADY))
		r_bvalid <= 1'b1;
	else if (S_AXI_BREADY)
		r_bvalid <= 1'b0;
	// }}}

	// r_bid, axi_bid
	// {{{
	initial	r_bid = 0;
	initial	axi_bid = 0;
	always @(posedge S_AXI_ACLK)
	begin
		if (m_awready && (!OPT_LOWPOWER || m_awvalid))
			r_bid    <= m_awid;

		if (!S_AXI_BVALID || S_AXI_BREADY)
			axi_bid <= r_bid;

		if (OPT_LOWPOWER && !S_AXI_ARESETN)
		begin
			r_bid <= 0;
			axi_bid <= 0;
		end
	end
	// }}}

	// axi_bvalid
	// {{{
	initial	axi_bvalid = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		axi_bvalid <= 0;
	else if (S_AXI_WVALID && S_AXI_WREADY && S_AXI_WLAST)
		axi_bvalid <= 1;
	else if (S_AXI_BREADY)
		axi_bvalid <= r_bvalid;
	// }}}

	// m_awready
	// {{{
	always @(*)
	begin
		m_awready = axi_awready;
		if (S_AXI_WVALID && S_AXI_WREADY && S_AXI_WLAST
			&& (!S_AXI_BVALID || S_AXI_BREADY))
			m_awready = 1;
	end
	// }}}

	// At one time, axi_awready was the same as S_AXI_AWREADY.  Now, though,
	// with the extra write address skid buffer, this is no longer the case.
	// S_AXI_AWREADY is handled/created/managed by the skid buffer.
	//
	// assign S_AXI_AWREADY = axi_awready;
	//
	// The rest of these signals can be set according to their registered
	// values above.
	assign	S_AXI_WREADY  = axi_wready;
	assign	S_AXI_BVALID  = axi_bvalid;
	assign	S_AXI_BID     = axi_bid;
	//
	// This core does not produce any bus errors, nor does it support
	// exclusive access, so 2'b00 will always be the correct response.
	assign	S_AXI_BRESP = { 1'b0, axi_exclusive_write };
	// }}}

	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// Read processing
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//

	// axi_arready
	// {{{
	initial axi_arready = 1;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		axi_arready <= 1;
	else if (S_AXI_ARVALID && S_AXI_ARREADY)
		axi_arready <= (S_AXI_ARLEN==0)&&(o_rd);
	else if (o_rd)
		axi_arready <= (axi_rlen <= 1);
	// }}}

	// axi_rlen
	// {{{
	initial	axi_rlen = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		axi_rlen <= 0;
	else if (S_AXI_ARVALID && S_AXI_ARREADY)
		axi_rlen <= S_AXI_ARLEN + (o_rd ? 0:1);
	else if (o_rd)
		axi_rlen <= axi_rlen - 1;
	// }}}

	// Next read address calculation
	// {{{
	always @(posedge S_AXI_ACLK)
	if (o_rd)
		raddr <= next_rd_addr;
	else if (S_AXI_ARREADY)
	begin
		raddr <= S_AXI_ARADDR;
		if (OPT_LOWPOWER && !S_AXI_ARVALID)
			raddr <= 0;
	end

	// r*
	// {{{
	always @(posedge S_AXI_ACLK)
	if (S_AXI_ARREADY)
	begin
		rburst   <= S_AXI_ARBURST;
		rsize    <= S_AXI_ARSIZE;
		rlen     <= S_AXI_ARLEN;
		rid      <= S_AXI_ARID;
		rlock    <= S_AXI_ARLOCK && S_AXI_ARVALID && OPT_LOCK;

		if (OPT_LOWPOWER && !S_AXI_ARVALID)
		begin
			rburst   <= 0;
			rsize    <= 0;
			rlen     <= 0;
			rid      <= 0;
			rlock    <= 0;
		end
	end
	// }}}

	axi_addr #(
		// {{{
		.AW(AW), .DW(DW)
		// }}}
	) get_next_rd_addr(
		// {{{
		(S_AXI_ARREADY ? S_AXI_ARADDR : raddr),
		(S_AXI_ARREADY  ? S_AXI_ARSIZE : rsize),
		(S_AXI_ARREADY  ? S_AXI_ARBURST: rburst),
		(S_AXI_ARREADY  ? S_AXI_ARLEN  : rlen),
		next_rd_addr
		// }}}
	);
	// }}}

	// o_rd, o_raddr
	// {{{
	always @(*)
	begin
		o_rd = (S_AXI_ARVALID || !S_AXI_ARREADY);
		if (S_AXI_RVALID && !S_AXI_RREADY)
			o_rd = 0;
		if (rskd_valid && !rskd_ready)
			o_rd = 0;
		o_raddr = (S_AXI_ARREADY ? S_AXI_ARADDR[AW-1:LSB] : raddr[AW-1:LSB]);
	end
	// }}}

	// rskd_valid
	// {{{
	initial	rskd_valid = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		rskd_valid <= 0;
	else if (o_rd)
		rskd_valid <= 1;
	else if (rskd_ready)
		rskd_valid <= 0;
	// }}}

	// rskd_id
	// {{{
	always @(posedge S_AXI_ACLK)
	if (!rskd_valid || rskd_ready)
	begin
		if (S_AXI_ARVALID && S_AXI_ARREADY)
			rskd_id <= S_AXI_ARID;
		else
			rskd_id <= rid;
	end
	// }}}

	// rskd_last
	// {{{
	initial rskd_last   = 0;
	always @(posedge S_AXI_ACLK)
	if (!rskd_valid || rskd_ready)
	begin
		rskd_last <= 0;
		if (o_rd && axi_rlen == 1)
			rskd_last <= 1;
		if (S_AXI_ARVALID && S_AXI_ARREADY && S_AXI_ARLEN == 0)
			rskd_last <= 1;
	end
	// }}}

	// rskd_lock
	// {{{
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN || !OPT_LOCK)
		rskd_lock <= 1'b0;
	else if (!rskd_valid || rskd_ready)
	begin
		rskd_lock <= 0;
		if (!OPT_LOWPOWER || o_rd)
		begin
			if (S_AXI_ARVALID && S_AXI_ARREADY)
				rskd_lock <= S_AXI_ARLOCK;
			else
				rskd_lock <= rlock;
		end
	end
	// }}}


	// Outgoing read skidbuffer
	// {{{
	skidbuffer #(
		// {{{
		.OPT_LOWPOWER(OPT_LOWPOWER),
		.OPT_OUTREG(1),
		.DW(IW+2+DW)
		// }}}
	) rskid (
		// {{{
		.i_clk(S_AXI_ACLK), .i_reset(!S_AXI_ARESETN),
		.i_valid(rskd_valid), .o_ready(rskd_ready),
		.i_data({ rskd_id, rskd_lock, rskd_last, i_rdata }),
		.o_valid(S_AXI_RVALID), .i_ready(S_AXI_RREADY),
			.o_data({ S_AXI_RID, S_AXI_RRESP[0], S_AXI_RLAST,
					S_AXI_RDATA })
		// }}}
	);
	// }}}

	assign	S_AXI_RRESP[1] = 1'b0;
	assign	S_AXI_ARREADY = axi_arready;

	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// Exclusive address caching
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//

	generate if (OPT_LOCK && !OPT_LOCKID)
	begin : EXCLUSIVE_ACCESS_BLOCK
		// {{{
		// The AXI4 specification requires that we check one address
		// per ID.  This isn't that.  This algorithm checks one ID,
		// whichever the last ID was.  It's designed to be lighter on
		// the logic requirements, and (unnoticably) not (fully) spec
		// compliant.  (The difference, if noticed at all, will be in
		// performance when multiple masters try to perform an exclusive
		// transaction at once.)

		// Local declarations
		// {{{
		reg			w_valid_lock_request, w_cancel_lock,
					w_lock_request,
					lock_valid, returned_lock_valid;
		reg	[AW-LSB-1:0]	lock_start, lock_end;
		reg	[3:0]		lock_len;
		reg	[1:0]		lock_burst;
		reg	[2:0]		lock_size;
		reg	[IW-1:0]	lock_id;
		reg			w_write_lock_valid;
		// }}}

		// w_lock_request
		// {{{
		always @(*)
		begin
			w_lock_request = 0;
			if (S_AXI_ARVALID && S_AXI_ARREADY && S_AXI_ARLOCK)
				w_lock_request = 1;
		end
		// }}}

		// w_valid_lock_request
		// {{{
		always @(*)
		begin
			w_valid_lock_request = 0;
			if (w_lock_request)
				w_valid_lock_request = 1;
			if (o_we && o_waddr == S_AXI_ARADDR[AW-1:LSB])
				w_valid_lock_request = 0;
		end
		// }}}

		// returned_lock_valid
		// {{{
		initial	returned_lock_valid = 0;
		always @(posedge S_AXI_ACLK)
		if (!S_AXI_ARESETN)
			returned_lock_valid <= 0;
		else if (S_AXI_ARVALID && S_AXI_ARREADY
					&& S_AXI_ARLOCK && S_AXI_ARID== lock_id)
			returned_lock_valid <= 0;
		else if (w_cancel_lock)
			returned_lock_valid <= 0;
		else if (rskd_valid && rskd_lock && rskd_ready)
			returned_lock_valid <= lock_valid;
		// }}}

		// w_cancel_lock
		// {{{
		always @(*)
			w_cancel_lock = (lock_valid && w_lock_request)
				|| (lock_valid && o_we
					&& o_waddr >= lock_start
					&& o_waddr <= lock_end
					&& o_wstrb != 0);
		// }}}

		// lock_valid
		// {{{
		initial	lock_valid = 0;
		always @(posedge S_AXI_ACLK)
		if (!S_AXI_ARESETN || !OPT_LOCK)
			lock_valid <= 0;
		else begin
			if (S_AXI_ARVALID && S_AXI_ARREADY
					&& S_AXI_ARLOCK && S_AXI_ARID== lock_id)
				lock_valid <= 0;
			if (w_cancel_lock)
				lock_valid <= 0;
			if (w_valid_lock_request)
				lock_valid <= 1;
		end
		// }}}

		// lock_start, lock_end, lock_len, lock_size, lock_id
		// {{{
		always @(posedge S_AXI_ACLK)
		if (w_valid_lock_request)
		begin
			lock_start <= S_AXI_ARADDR[C_S_AXI_ADDR_WIDTH-1:LSB];
			lock_end <= S_AXI_ARADDR[C_S_AXI_ADDR_WIDTH-1:LSB]
					+ ((S_AXI_ARBURST == 2'b00) ? 0 : S_AXI_ARLEN[3:0]);
			lock_len   <= S_AXI_ARLEN[3:0];
			lock_burst <= S_AXI_ARBURST;
			lock_size  <= S_AXI_ARSIZE;
			lock_id    <= S_AXI_ARID;
		end
		// }}}

		// w_write_lock_valid
		// {{{
		always @(*)
		begin
			w_write_lock_valid = returned_lock_valid;
			if (!m_awvalid || !m_awready || !m_awlock || !lock_valid)
				w_write_lock_valid = 0;
			if (m_awaddr[C_S_AXI_ADDR_WIDTH-1:LSB] != lock_start)
				w_write_lock_valid = 0;
			if (m_awid != lock_id)
				w_write_lock_valid = 0;
			if (m_awlen[3:0] != lock_len)	// MAX transfer size is 16 beats
				w_write_lock_valid = 0;
			if (m_awburst != 2'b01 && lock_len != 0)
				w_write_lock_valid = 0;
			if (m_awsize != lock_size)
				w_write_lock_valid = 0;
		end
		// }}}

		assign	write_lock_valid = w_write_lock_valid;
		// }}}
	end else if (OPT_LOCK) // && OPT_LOCKID
	begin : EXCLUSIVE_ACCESS_PER_ID
		// {{{

		genvar	gk;
		wire	[(1<<IW)-1:0]	write_lock_valid_per_id;

		for(gk=0; gk<(1<<IW); gk=gk+1)
		begin : PER_ID_LOGIC
		// {{{
			// Local declarations
			// {{{
			reg			w_valid_lock_request,
						w_cancel_lock,
						lock_valid, returned_lock_valid;
			reg	[1:0]		lock_burst;
			reg	[2:0]		lock_size;
			reg	[3:0]		lock_len;
			reg	[AW-LSB-1:0]	lock_start, lock_end;
			reg			w_write_lock_valid;
			// }}}

			// valid_lock_request
			// {{{
			always @(*)
			begin
				w_valid_lock_request = 0;
				if (S_AXI_ARVALID && S_AXI_ARREADY
						&& S_AXI_ARID == gk[IW-1:0]
						&& S_AXI_ARLOCK)
					w_valid_lock_request = 1;
				if (o_we && o_waddr == S_AXI_ARADDR[AW-1:LSB])
					w_valid_lock_request = 0;
			end
			// }}}

			// returned_lock_valid
			// {{{
			initial	returned_lock_valid = 0;
			always @(posedge S_AXI_ACLK)
			if (!S_AXI_ARESETN)
				returned_lock_valid <= 0;
			else if (S_AXI_ARVALID && S_AXI_ARREADY
					&&S_AXI_ARLOCK&&S_AXI_ARID== gk[IW-1:0])
				returned_lock_valid <= 0;
			else if (w_cancel_lock)
				returned_lock_valid <= 0;
			else if (rskd_valid && rskd_lock && rskd_ready
					&& rskd_id == gk[IW-1:0])
				returned_lock_valid <= lock_valid;
			// }}}

			// w_cancel_lock
			// {{{
			always @(*)
				w_cancel_lock=(lock_valid&&w_valid_lock_request)
					|| (lock_valid && o_we
						&& o_waddr >= lock_start
						&& o_waddr <= lock_end
						&& o_wstrb != 0);
			// }}}

			// lock_valid
			// {{{
			initial	lock_valid = 0;
			always @(posedge S_AXI_ACLK)
			if (!S_AXI_ARESETN || !OPT_LOCK)
				lock_valid <= 0;
			else begin
				if (S_AXI_ARVALID && S_AXI_ARREADY
						&& S_AXI_ARLOCK
						&& S_AXI_ARID == gk[IW-1:0])
					lock_valid <= 0;
				if (w_cancel_lock)
					lock_valid <= 0;
				if (w_valid_lock_request)
					lock_valid <= 1;
			end
			// }}}

			// lock_start, lock_end, lock_len, lock_size
			// {{{
			always @(posedge S_AXI_ACLK)
			if (w_valid_lock_request)
			begin
				lock_start <= S_AXI_ARADDR[C_S_AXI_ADDR_WIDTH-1:LSB];
				// Verilator lint_off WIDTH
				lock_end <= S_AXI_ARADDR[C_S_AXI_ADDR_WIDTH-1:LSB]
					+ ((S_AXI_ARBURST == 2'b00) ? 4'h0 : S_AXI_ARLEN[3:0]);
				// Verilator lint_on  WIDTH
				lock_len   <= S_AXI_ARLEN[3:0];
				lock_size  <= S_AXI_ARSIZE;
				lock_burst <= S_AXI_ARBURST;
			end
			// }}}

			// w_write_lock_valid
			// {{{
			always @(*)
			begin
				w_write_lock_valid = returned_lock_valid;
				if (!m_awvalid || !m_awready || !m_awlock || !lock_valid)
					w_write_lock_valid = 0;
				if (m_awaddr[C_S_AXI_ADDR_WIDTH-1:LSB] != lock_start)
					w_write_lock_valid = 0;
				if (m_awid[IW-1:0] != gk[IW-1:0])
					w_write_lock_valid = 0;
				if (m_awlen[3:0] != lock_len)	// MAX transfer size is 16 beats
					w_write_lock_valid = 0;
				if (m_awburst != 2'b01 && lock_len != 0)
					w_write_lock_valid = 0;
				if (m_awsize != lock_size)
					w_write_lock_valid = 0;
			end
			// }}}

			assign	write_lock_valid_per_id[gk]= w_write_lock_valid;
		// }}}
		end

		assign	write_lock_valid = |write_lock_valid_per_id;
		// }}}
	end else begin : NO_LOCKING
		// {{{

		assign	write_lock_valid = 1'b0;
		// Verilator lint_off UNUSED
		wire	unused_lock;
		assign	unused_lock = &{ 1'b0, S_AXI_ARLOCK, S_AXI_AWLOCK };
		// Verilator lint_on  UNUSED
		// }}}
	end endgenerate
	// }}}

	// Make Verilator happy
	// {{{
	// Verilator lint_off UNUSED
	wire	unused;
	assign	unused = &{ 1'b0, S_AXI_AWCACHE, S_AXI_AWPROT, S_AXI_AWQOS,
		S_AXI_ARCACHE, S_AXI_ARPROT, S_AXI_ARQOS };
	// Verilator lint_on  UNUSED
	// }}}
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
//
// Formal properties
// {{{
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////
`ifdef	FORMAL
	//
	// The following properties are only some of the properties used
	// to verify this core
	//	
	// Local (formal) register declarations
	// {{{
	reg	f_past_valid;
	initial	f_past_valid = 0;
	always @(posedge S_AXI_ACLK)
		f_past_valid <= 1;

	always @(*)
	if (!f_past_valid)
		assume(!S_AXI_ARESETN);

	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// AXI slave properties
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//
	faxi_slave	#(
		// {{{
		.C_AXI_ID_WIDTH(C_S_AXI_ID_WIDTH),
		.C_AXI_DATA_WIDTH(C_S_AXI_DATA_WIDTH),
		.C_AXI_ADDR_WIDTH(C_S_AXI_ADDR_WIDTH))
		// ...
		// }}}
	f_slave(
		// {{{
		.i_clk(S_AXI_ACLK),
		.i_axi_reset_n(S_AXI_ARESETN),
		//
		// Address write channel
		// {{{
		.i_axi_awvalid(m_awvalid),
		.i_axi_awready(m_awready),
		.i_axi_awid(   m_awid),
		.i_axi_awaddr( m_awaddr),
		.i_axi_awlen(  m_awlen),
		.i_axi_awsize( m_awsize),
		.i_axi_awburst(m_awburst),
		.i_axi_awlock( m_awlock),
		.i_axi_awcache(4'h0),
		.i_axi_awprot( 3'h0),
		.i_axi_awqos(  4'h0),
		// }}}
		// Write Data Channel
		// {{{
		// Write Data
		.i_axi_wdata(S_AXI_WDATA),
		.i_axi_wstrb(S_AXI_WSTRB),
		.i_axi_wlast(S_AXI_WLAST),
		.i_axi_wvalid(S_AXI_WVALID),
		.i_axi_wready(S_AXI_WREADY),
		// }}}
		// Write response
		// {{{
		.i_axi_bvalid(S_AXI_BVALID),
		.i_axi_bready(S_AXI_BREADY),
		.i_axi_bid(   S_AXI_BID),
		.i_axi_bresp( S_AXI_BRESP),
		// }}}
		// Read address channel
		// {{{
		.i_axi_arvalid(S_AXI_ARVALID),
		.i_axi_arready(S_AXI_ARREADY),
		.i_axi_arid(   S_AXI_ARID),
		.i_axi_araddr( S_AXI_ARADDR),
		.i_axi_arlen(  S_AXI_ARLEN),
		.i_axi_arsize( S_AXI_ARSIZE),
		.i_axi_arburst(S_AXI_ARBURST),
		.i_axi_arlock( S_AXI_ARLOCK),
		.i_axi_arcache(S_AXI_ARCACHE),
		.i_axi_arprot( S_AXI_ARPROT),
		.i_axi_arqos(  S_AXI_ARQOS),
		// }}}
		// Read data return channel
		// {{{
		.i_axi_rvalid(S_AXI_RVALID),
		.i_axi_rready(S_AXI_RREADY),
		.i_axi_rid(S_AXI_RID),
		.i_axi_rdata(S_AXI_RDATA),
		.i_axi_rresp(S_AXI_RRESP),
		.i_axi_rlast(S_AXI_RLAST),
		// }}}
		//
		// ...
		// }}}
	);

	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// Write induction properties
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//


	//
	// ...
	//

	always @(*)
	if (r_bvalid)
		assert(S_AXI_BVALID);

	always @(*)
		assert(axi_awready == (!S_AXI_WREADY&& !r_bvalid));

	always @(*)
	if (axi_awready)
		assert(!S_AXI_WREADY);


	//
	// ...
	//

	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// Read induction properties
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//


	//
	// ...
	//


	always @(posedge S_AXI_ACLK)
	if (f_past_valid && axi_rlen == 0)
		assert(S_AXI_ARREADY);

	always @(posedge S_AXI_ACLK)
		assert(axi_rlen <= 256);

	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// Lowpower checking
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//

	always @(*)
	if (OPT_LOWPOWER && S_AXI_ARESETN)
	begin
		if (!rskd_valid)
			assert(!rskd_lock);
		if (faxi_awr_nbursts == 0)
		begin
			assert(S_AXI_BRESP == 2'b00);
			// assert(S_AXI_BID == 0);
		end

		if (!S_AXI_RVALID)
		begin
			assert(S_AXI_RID   == 0);
			assert(S_AXI_RDATA == 0);
			assert(S_AXI_RRESP == 2'b00);
		end

		if (!o_we)
		begin
			assert(o_waddr == 0);
			assert(o_wdata == 0);
			assert(o_wstrb == 0);
		end
	end
	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// Contract checking
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	// ...
	//

	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// Cover properties
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//
	reg	f_wr_cvr_valid, f_rd_cvr_valid;
	reg	[4:0]	f_dbl_rd_count, f_dbl_wr_count;

	initial	f_wr_cvr_valid = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		f_wr_cvr_valid <= 0;
	else if (S_AXI_AWVALID && S_AXI_AWREADY && S_AXI_AWLEN > 4)
		f_wr_cvr_valid <= 1;

	always @(*)
		cover(!S_AXI_BVALID && axi_awready && !m_awvalid
			&& f_wr_cvr_valid /* && ... */));

	initial	f_rd_cvr_valid = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		f_rd_cvr_valid <= 0;
	else if (S_AXI_ARVALID && S_AXI_ARREADY && S_AXI_ARLEN > 4)
		f_rd_cvr_valid <= 1;

	always @(*)
		cover(S_AXI_ARREADY && f_rd_cvr_valid /* && ... */);

	//
	// Generate cover statements associated with multiple successive bursts
	//
	// These will be useful for demonstrating the throughput of the core.
	//

	initial	f_dbl_wr_count = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		f_dbl_wr_count = 0;
	else if (S_AXI_AWVALID && S_AXI_AWREADY && S_AXI_AWLEN == 3)
	begin
		if (!(&f_dbl_wr_count))
			f_dbl_wr_count <= f_dbl_wr_count + 1;
	end

	always @(*)
		cover(S_AXI_ARESETN && (f_dbl_wr_count > 1));	//!

	always @(*)
		cover(S_AXI_ARESETN && (f_dbl_wr_count > 3));	//!

	always @(*)
		cover(S_AXI_ARESETN && (f_dbl_wr_count > 3) && !m_awvalid
			&&(!S_AXI_AWVALID && !S_AXI_WVALID && !S_AXI_BVALID)
			&& (faxi_awr_nbursts == 0)
			&& (faxi_wr_pending == 0));

	initial	f_dbl_rd_count = 0;
	always @(posedge S_AXI_ACLK)
	if (!S_AXI_ARESETN)
		f_dbl_rd_count = 0;
	else if (S_AXI_ARVALID && S_AXI_ARREADY && S_AXI_ARLEN == 3)
	begin
		if (!(&f_dbl_rd_count))
			f_dbl_rd_count <= f_dbl_rd_count + 1;
	end

	always @(*)
		cover(!S_AXI_ARESETN && (f_dbl_rd_count > 3)
			/* && ... */
			&& !S_AXI_ARVALID && !S_AXI_RVALID);

	generate if (OPT_LOCK)
	begin
		always @(*)
			cover(S_AXI_ARESETN && S_AXI_BVALID && S_AXI_BREADY
				&& S_AXI_BRESP == 2'b01);
	end endgenerate

`ifdef	VERIFIC
	cover property (@(posedge S_AXI_ACLK)
		disable iff (!S_AXI_ARESETN)
		// Accept a burst request for 4 beats
		(S_AXI_ARVALID && S_AXI_ARREADY && (S_AXI_ARLEN == 3)
			##1 S_AXI_ARVALID [*3]) [*3]
		##1 1 [*0:12]
		// The return to idle
		##1 (!S_AXI_ARVALID && !o_rd && !rskd_valid && !S_AXI_RVALID)
		);
`endif

	// }}}
	////////////////////////////////////////////////////////////////////////
	//
	// "Careless" assumptions
	// {{{
	////////////////////////////////////////////////////////////////////////
	//
	//

	// }}}
`endif
// }}}
endmodule
`ifndef	YOSYS
`default_nettype wire
`endif