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axildouble.v
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axildouble.v
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////////////////////////////////////////////////////////////////////////////////
//
// Filename: axildouble.v
// {{{
// Project: WB2AXIPSP: bus bridges and other odds and ends
//
// Purpose: Create a special slave which can be used to reduce crossbar
// logic for multiple simplified slaves. This is a companion
// core to the similar axilsingle core, but allowing the slave to
// decode the clock between multiple possible addresses.
//
// To use this, the slave must follow specific (simplified AXI) rules:
//
// Write interface
// 1. The slave must guarantee that AWREADY == WREADY = 1
// (This core doesn't have AWREADY or WREADY inputs)
// 2. The slave must also guarantee that BVALID == $past(AWVALID)
// (This core internally generates BVALID)
// 3. The controller will guarantee that AWVALID == WVALID
// (You can connect AWVALID to WVALID when connecting to your core)
// 4. The controller will also guarantee that BREADY = 1
// (This core doesn't have a BVALID input)
//
// Read interface
// 1. The slave must guarantee that ARREADY == 1
// (This core doesn't have an ARREADY input)
// 2. The slave must also guarantee that RVALID == $past(ARVALID)
// (This core doesn't have an RVALID input, trusting the slave
// instead)
// 3. The controller will guarantee that RREADY = 1
// (This core doesn't have an RREADY output)
//
//
// Why? This simplifies slave logic. Slaves may interact with the bus
// using only the logic below:
//
// always @(posedge S_AXI_ACLK)
// if (AWVALID) case(AWADDR)
// R1: slvreg_1 <= WDATA;
// R2: slvreg_2 <= WDATA;
// R3: slvreg_3 <= WDATA;
// R4: slvreg_4 <= WDATA;
// endcase
//
// always @(*)
// BRESP = 2'b00;
//
// always @(posedge S_AXI_ACLK)
// if (ARVALID)
// case(ARADDR)
// R1: RDATA <= slvreg_1;
// R2: RDATA <= slvreg_2;
// R3: RDATA <= slvreg_3;
// R4: RDATA <= slvreg_4;
// endcase
//
// always @(*)
// RRESP = 2'b00;
//
// This core will then keep track of the more complex bus logic,
// simplifying both slaves and connection logic. Slaves with the more
// complicated (and proper/accurate) logic, that follow the rules above,
// should have no problems with this additional logic.
//
// Performance:
//
// This core can sustain one read/write per clock as long as the upstream
// AXI master keeps S_AXI_[BR]READY high. If S_AXI_[BR]READY ever drops,
// there's some flexibility provided by the return FIFO, so the master
// might not notice a drop in throughput until the FIFO fills.
//
// The more practical performance measure is the latency of this core.
// That I've measured at four clocks.
//
// 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
// `ifdef VERILATOR
// `define FORMAL
// `endif
// }}}
module axildouble #(
// {{{
parameter integer C_AXI_DATA_WIDTH = 32,
parameter integer C_AXI_ADDR_WIDTH = 32,
//
// NS is the number of slave interfaces
parameter NS = 8,
//
//
parameter [NS*C_AXI_ADDR_WIDTH-1:0] SLAVE_ADDR = {
{ 3'b111, {(C_AXI_ADDR_WIDTH-3){1'b0}} },
{ 3'b110, {(C_AXI_ADDR_WIDTH-3){1'b0}} },
{ 3'b101, {(C_AXI_ADDR_WIDTH-3){1'b0}} },
{ 3'b100, {(C_AXI_ADDR_WIDTH-3){1'b0}} },
{ 3'b011, {(C_AXI_ADDR_WIDTH-3){1'b0}} },
{ 3'b010, {(C_AXI_ADDR_WIDTH-3){1'b0}} },
{ 4'b0001,{(C_AXI_ADDR_WIDTH-4){1'b0}} },
{ 4'b0000,{(C_AXI_ADDR_WIDTH-4){1'b0}} } },
//
//
parameter [NS*C_AXI_ADDR_WIDTH-1:0] SLAVE_MASK =
(NS <= 1) ? 0
: { {(NS-2){ 3'b111,{(C_AXI_ADDR_WIDTH-3){1'b0}} }},
{(2){ 4'b1111,{(C_AXI_ADDR_WIDTH-4){1'b0}} }}
},
//
//
// LGFLEN specifies the log (based two) of the number of
// transactions that may need to be held outstanding internally.
// If you really want high throughput, and if you expect any
// back pressure at all, then increase LGFLEN. Otherwise the
// default value of 3 (FIFO size = 8) should be sufficient
// to maintain full loading
parameter LGFLEN=3,
//
// If set, OPT_LOWPOWER will set all unused registers, both
// internal and external, to zero anytime their corresponding
// *VALID bit is clear
parameter [0:0] OPT_LOWPOWER = 0
// }}}
) (
// {{{
input wire S_AXI_ACLK,
input wire S_AXI_ARESETN,
//
input wire S_AXI_AWVALID,
output wire S_AXI_AWREADY,
input wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_AWADDR,
input wire [3-1:0] S_AXI_AWPROT,
//
input wire S_AXI_WVALID,
output wire S_AXI_WREADY,
input wire [C_AXI_DATA_WIDTH-1:0] S_AXI_WDATA,
input wire [C_AXI_DATA_WIDTH/8-1:0] S_AXI_WSTRB,
//
output wire [2-1:0] S_AXI_BRESP,
output wire S_AXI_BVALID,
input wire S_AXI_BREADY,
//
input wire [C_AXI_ADDR_WIDTH-1:0] S_AXI_ARADDR,
input wire [3-1:0] S_AXI_ARPROT,
input wire S_AXI_ARVALID,
output wire S_AXI_ARREADY,
//
output wire [C_AXI_DATA_WIDTH-1:0] S_AXI_RDATA,
output wire [2-1:0] S_AXI_RRESP,
output wire S_AXI_RVALID,
input wire S_AXI_RREADY,
//
//
//
output wire [NS-1:0] M_AXI_AWVALID,
output wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_AWADDR,
output wire [3-1:0] M_AXI_AWPROT,
//
output wire [C_AXI_DATA_WIDTH-1:0] M_AXI_WDATA,
output wire [C_AXI_DATA_WIDTH/8-1:0] M_AXI_WSTRB,
//
input wire [NS*2-1:0] M_AXI_BRESP,
//
output wire [NS-1:0] M_AXI_ARVALID,
output wire [C_AXI_ADDR_WIDTH-1:0] M_AXI_ARADDR,
output wire [3-1:0] M_AXI_ARPROT,
//
input wire [NS*C_AXI_DATA_WIDTH-1:0] M_AXI_RDATA,
input wire [NS*2-1:0] M_AXI_RRESP
// }}}
);
//
// AW, and DW, are short-hand abbreviations used locally.
localparam AW = C_AXI_ADDR_WIDTH;
localparam DW = C_AXI_DATA_WIDTH;
localparam LGNS = $clog2(NS);
//
localparam INTERCONNECT_ERROR = 2'b11;
////////////////////////////////////////////////////////////////////////
//
// Write logic:
//
////////////////////////////////////////////////////////////////////////
//
//
wire awskid_valid, bffull, bempty, write_awskidready,
dcd_awvalid;
reg write_bvalid, write_response;
reg bfull, write_wready, write_no_index;
wire [NS:0] wdecode;
wire [AW-1:0] awskid_addr;
wire [AW-1:0] m_awaddr;
reg [LGNS-1:0] write_windex, write_bindex;
wire [3-1:0] awskid_prot, m_axi_awprot;
wire [LGFLEN:0] bfill;
reg [LGFLEN:0] write_count;
reg [1:0] write_resp;
integer k;
skidbuffer #(.OPT_LOWPOWER(OPT_LOWPOWER), .OPT_OUTREG(0),
.DW(AW+3))
awskid( .i_clk(S_AXI_ACLK),
.i_reset(!S_AXI_ARESETN),
.i_valid(S_AXI_AWVALID),
.o_ready(S_AXI_AWREADY),
.i_data({ S_AXI_AWPROT, S_AXI_AWADDR }),
.o_valid(awskid_valid), .i_ready(write_awskidready),
.o_data({ awskid_prot, awskid_addr }));
wire awskd_stall;
addrdecode #(.AW(AW), .DW(3), .NS(NS),
.SLAVE_ADDR(SLAVE_ADDR),
.SLAVE_MASK(SLAVE_MASK),
.OPT_REGISTERED(1'b1))
wraddr(.i_clk(S_AXI_ACLK), .i_reset(!S_AXI_ARESETN),
.i_valid(awskid_valid && write_awskidready), .o_stall(awskd_stall),
.i_addr(awskid_addr),
.i_data(awskid_prot),
.o_valid(dcd_awvalid), .i_stall(!S_AXI_WVALID),
.o_decode(wdecode), .o_addr(m_awaddr),
.o_data(m_axi_awprot));
always @(*)
write_wready = dcd_awvalid;
assign S_AXI_WREADY = write_wready;
assign M_AXI_AWVALID = (S_AXI_WVALID) ? wdecode[NS-1:0] : 0;
assign M_AXI_AWADDR = m_awaddr;
assign M_AXI_AWPROT = m_axi_awprot;
assign M_AXI_WDATA = S_AXI_WDATA;
assign M_AXI_WSTRB = S_AXI_WSTRB;
assign write_awskidready = (S_AXI_WVALID || !S_AXI_WREADY) && !bfull;
always @(*)
begin
write_windex = 0;
for(k=0; k<NS; k=k+1)
if (wdecode[k])
write_windex = write_windex | k[LGNS-1:0];
end
always @(posedge S_AXI_ACLK)
begin
write_bindex <= write_windex;
write_no_index <= wdecode[NS];
end
initial { write_response, write_bvalid } = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
{ write_response, write_bvalid } <= 0;
else
{ write_response, write_bvalid }
<= { write_bvalid, (S_AXI_WVALID && S_AXI_WREADY) };
always @(posedge S_AXI_ACLK)
if (write_no_index)
write_resp <= INTERCONNECT_ERROR;
else
write_resp <= M_AXI_BRESP[2*write_bindex +: 2];
initial write_count = 0;
initial bfull = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
begin
write_count <= 0;
bfull <= 0;
end else case({ (awskid_valid && write_awskidready),
(S_AXI_BVALID & S_AXI_BREADY) })
2'b01: begin
write_count <= write_count - 1;
bfull <= 1'b0;
end
2'b10: begin
write_count <= write_count + 1;
bfull <= (&write_count[LGFLEN-1:0]);
end
default: begin end
endcase
`ifdef FORMAL
always @(*)
assert(write_count <= { 1'b1, {(LGFLEN){1'b0}} });
always @(*)
assert(bfull == (write_count == { 1'b1, {(LGFLEN){1'b0}} }));
`endif
sfifo #(.BW(2), .OPT_ASYNC_READ(0), .LGFLEN(LGFLEN))
bfifo ( .i_clk(S_AXI_ACLK), .i_reset(!S_AXI_ARESETN),
.i_wr(write_response), .i_data(write_resp), .o_full(bffull),
.o_fill(bfill),
.i_rd(S_AXI_BVALID && S_AXI_BREADY), .o_data(S_AXI_BRESP),
.o_empty(bempty));
`ifdef FORMAL
always @(*)
assert(write_count == bfill
+ (write_response ? 1:0)
+ (write_bvalid ? 1:0)
+ (write_wready ? 1:0));
`ifdef VERIFIC
always @(*)
if (bfifo.f_first_in_fifo)
assert(bfifo.f_first_data != 2'b01);
always @(*)
if (bfifo.f_second_in_fifo)
assert(bfifo.f_second_data != 2'b01);
always @(*)
if (!bempty && (!bfifo.f_first_in_fifo
|| bfifo.rd_addr != bfifo.f_first_addr)
&&(!bfifo.f_second_in_fifo
|| bfifo.rd_addr != bfifo.f_second_addr))
assume(S_AXI_BRESP != 2'b01);
`else
always @(*)
if (!bempty)
assume(S_AXI_BRESP != 2'b01);
`endif
`endif
assign S_AXI_BVALID = !bempty;
`ifdef FORMAL
always @(*)
assert(!bffull || !write_bvalid);
`endif
////////////////////////////////////////////////////////////////////////
//
// Read logic
//
////////////////////////////////////////////////////////////////////////
//
//
wire rempty, rdfull;
wire [LGFLEN:0] rfill;
reg [LGNS-1:0] read_index, last_read_index;
reg [1:0] read_resp;
reg [DW-1:0] read_rdata;
wire read_rwait, arskd_stall;
reg read_rvalid, read_result, read_no_index;
wire [AW-1:0] m_araddr;
wire [3-1:0] m_axi_arprot;
wire [NS:0] rdecode;
addrdecode #(.AW(AW), .DW(3), .NS(NS),
.SLAVE_ADDR(SLAVE_ADDR),
.SLAVE_MASK(SLAVE_MASK),
.OPT_REGISTERED(1'b1))
rdaddr(.i_clk(S_AXI_ACLK), .i_reset(!S_AXI_ARESETN),
.i_valid(S_AXI_ARVALID && S_AXI_ARREADY), .o_stall(arskd_stall),
.i_addr(S_AXI_ARADDR), .i_data(S_AXI_ARPROT),
.o_valid(read_rwait), .i_stall(1'b0),
.o_decode(rdecode), .o_addr(m_araddr),
.o_data(m_axi_arprot));
assign M_AXI_ARVALID = rdecode[NS-1:0];
assign M_AXI_ARADDR = m_araddr;
assign M_AXI_ARPROT = m_axi_arprot;
initial { read_result, read_rvalid } = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
{ read_result, read_rvalid } <= 2'b00;
else
{ read_result, read_rvalid } <= { read_rvalid, read_rwait };
always @(*)
begin
read_index = 0;
for(k=0; k<NS; k=k+1)
if (rdecode[k])
read_index = read_index | k[LGNS-1:0];
end
always @(posedge S_AXI_ACLK)
last_read_index <= read_index;
always @(posedge S_AXI_ACLK)
read_no_index <= rdecode[NS];
always @(posedge S_AXI_ACLK)
read_rdata <= M_AXI_RDATA[DW*last_read_index +: DW];
always @(posedge S_AXI_ACLK)
if (read_no_index)
read_resp <= INTERCONNECT_ERROR;
else
read_resp <= M_AXI_RRESP[2*last_read_index +: 2];
reg read_full;
reg [LGFLEN:0] read_count;
initial { read_count, read_full } = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
{ read_count, read_full } <= 0;
else case({ S_AXI_ARVALID & S_AXI_ARREADY, S_AXI_RVALID & S_AXI_RREADY})
2'b10: begin
read_count <= read_count + 1;
read_full <= &read_count[LGFLEN-1:0];
end
2'b01: begin
read_count <= read_count - 1;
read_full <= 1'b0;
end
default: begin end
endcase
`ifdef FORMAL
always @(*)
assert(read_count <= { 1'b1, {(LGFLEN){1'b0}} });
always @(*)
assert(read_full == (read_count == { 1'b1, {(LGFLEN){1'b0}} }));
`endif
assign S_AXI_ARREADY = !read_full;
sfifo #(.BW(DW+2), .OPT_ASYNC_READ(0), .LGFLEN(LGFLEN))
rfifo ( .i_clk(S_AXI_ACLK), .i_reset(!S_AXI_ARESETN),
.i_wr(read_result), .i_data({ read_rdata, read_resp }),
.o_full(rdfull), .o_fill(rfill),
.i_rd(S_AXI_RVALID && S_AXI_RREADY),
.o_data({ S_AXI_RDATA, S_AXI_RRESP }),.o_empty(rempty));
`ifdef FORMAL
always @(*)
assert(read_count == rfill + read_result + read_rvalid + read_rwait);
`ifdef VERIFIC
always @(*)
if (rfifo.f_first_in_fifo)
assert(rfifo.f_first_data[1:0] != 2'b01);
always @(*)
if (rfifo.f_second_in_fifo)
assert(rfifo.f_second_data[1:0] != 2'b01);
always @(*)
if (!rempty && (!rfifo.f_first_in_fifo
|| rfifo.rd_addr != rfifo.f_first_addr)
&&(!rfifo.f_second_in_fifo
|| rfifo.rd_addr != rfifo.f_second_addr))
assume(S_AXI_RRESP != 2'b01);
`else
always @(*)
if (!rempty)
assume(S_AXI_RRESP != 2'b01);
`endif
`endif
assign S_AXI_RVALID = !rempty;
// verilator lint_off UNUSED
wire unused;
assign unused = &{ 1'b0,
bffull, rdfull, bfill, rfill,
awskd_stall, arskd_stall };
// verilator lint_on UNUSED
`ifdef FORMAL
localparam F_LGDEPTH = LGFLEN+1;
reg f_past_valid;
reg [F_LGDEPTH-1:0] count_awr_outstanding, count_wr_outstanding,
count_rd_outstanding;
wire [(F_LGDEPTH-1):0] f_axi_awr_outstanding,
f_axi_wr_outstanding,
f_axi_rd_outstanding;
wire [1:0] fm_axi_awr_outstanding [0:NS-1];
wire [1:0] fm_axi_wr_outstanding [0:NS-1];
wire [1:0] fm_axi_rd_outstanding [0:NS-1];
reg [NS-1:0] m_axi_rvalid, m_axi_bvalid;
faxil_slave #(// .C_AXI_DATA_WIDTH(C_AXI_DATA_WIDTH),
.C_AXI_ADDR_WIDTH(C_AXI_ADDR_WIDTH),
// .F_OPT_NO_READS(1'b0),
// .F_OPT_NO_WRITES(1'b0),
.F_OPT_XILINX(1),
.F_LGDEPTH(F_LGDEPTH))
properties (
.i_clk(S_AXI_ACLK),
.i_axi_reset_n(S_AXI_ARESETN),
//
.i_axi_awvalid(S_AXI_AWVALID),
.i_axi_awready(S_AXI_AWREADY),
.i_axi_awaddr(S_AXI_AWADDR),
.i_axi_awprot(S_AXI_AWPROT),
//
.i_axi_wvalid(S_AXI_WVALID),
.i_axi_wready(S_AXI_WREADY),
.i_axi_wdata(S_AXI_WDATA),
.i_axi_wstrb(S_AXI_WSTRB),
//
.i_axi_bvalid(S_AXI_BVALID),
.i_axi_bready(S_AXI_BREADY),
.i_axi_bresp(S_AXI_BRESP),
//
.i_axi_arvalid(S_AXI_ARVALID),
.i_axi_arready(S_AXI_ARREADY),
.i_axi_araddr(S_AXI_ARADDR),
.i_axi_arprot(S_AXI_ARPROT),
//
.i_axi_rvalid(S_AXI_RVALID),
.i_axi_rready(S_AXI_RREADY),
.i_axi_rdata(S_AXI_RDATA),
.i_axi_rresp(S_AXI_RRESP),
//
.f_axi_rd_outstanding(f_axi_rd_outstanding),
.f_axi_wr_outstanding(f_axi_wr_outstanding),
.f_axi_awr_outstanding(f_axi_awr_outstanding));
initial f_past_valid = 1'b0;
always @(posedge S_AXI_ACLK)
f_past_valid <= 1'b1;
genvar M;
generate for(M=0; M<NS; M=M+1)
begin : CONSTRAIN_SLAVE_INTERACTIONS
faxil_master #(// .C_AXI_DATA_WIDTH(C_AXI_DATA_WIDTH),
.C_AXI_ADDR_WIDTH(C_AXI_ADDR_WIDTH),
.C_AXI_DATA_WIDTH(C_AXI_DATA_WIDTH),
// .F_OPT_NO_READS(1'b0),
// .F_OPT_NO_WRITES(1'b0),
.F_OPT_NO_RESET(1'b1),
.F_LGDEPTH(2))
properties (
.i_clk(S_AXI_ACLK),
.i_axi_reset_n(S_AXI_ARESETN),
//
.i_axi_awvalid(M_AXI_AWVALID[M]),
.i_axi_awready(1'b1),
.i_axi_awaddr(M_AXI_AWADDR),
.i_axi_awprot(M_AXI_AWPROT),
//
.i_axi_wvalid(M_AXI_AWVALID[M]),
.i_axi_wready(1'b1),
.i_axi_wdata(M_AXI_WDATA[C_AXI_DATA_WIDTH-1:0]),
.i_axi_wstrb(M_AXI_WSTRB[C_AXI_DATA_WIDTH/8-1:0]),
//
.i_axi_bvalid(m_axi_bvalid[M]),
.i_axi_bready(1'b1),
.i_axi_bresp(M_AXI_BRESP[2*M +: 2]),
//
.i_axi_arvalid(M_AXI_ARVALID[M]),
.i_axi_arready(1'b1),
.i_axi_araddr(M_AXI_ARADDR),
.i_axi_arprot(M_AXI_ARPROT),
//
.i_axi_rdata(M_AXI_RDATA[M*C_AXI_DATA_WIDTH +: C_AXI_DATA_WIDTH]),
.i_axi_rresp(M_AXI_RRESP[2*M +: 2]),
.i_axi_rvalid(m_axi_rvalid[M]),
.i_axi_rready(1'b1),
//
.f_axi_rd_outstanding(fm_axi_rd_outstanding[M]),
.f_axi_wr_outstanding(fm_axi_wr_outstanding[M]),
.f_axi_awr_outstanding(fm_axi_awr_outstanding[M]));
initial m_axi_bvalid <= 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
m_axi_bvalid[M] <= 1'b0;
else
m_axi_bvalid[M] <= M_AXI_AWVALID[M];
initial m_axi_rvalid[M] <= 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
m_axi_rvalid[M] <= 1'b0;
else
m_axi_rvalid[M] <= M_AXI_ARVALID[M];
always @(*)
assert(fm_axi_awr_outstanding[M] == fm_axi_wr_outstanding[M]);
always @(*)
assert(fm_axi_wr_outstanding[M]== (m_axi_bvalid[M] ? 1:0));
always @(*)
assert(fm_axi_rd_outstanding[M]== (m_axi_rvalid[M] ? 1:0));
end endgenerate
////////////////////////////////////////////////////////////////////////
//
// Properties necessary to pass induction
//
////////////////////////////////////////////////////////////////////////
//
//
always @(*)
assert(S_AXI_WREADY == (wdecode != 0));
`ifdef VERIFIC
always @(*)
assert($onehot0(M_AXI_AWVALID));
always @(*)
assert($onehot0(m_axi_bvalid));
always @(*)
assert($onehot0(m_axi_rvalid));
`endif
always @(*)
begin
count_awr_outstanding = 0;
if (!S_AXI_AWREADY)
count_awr_outstanding = count_awr_outstanding + 1;
if (write_wready)
count_awr_outstanding = count_awr_outstanding + 1;
if (write_bvalid)
count_awr_outstanding = count_awr_outstanding + 1;
if (write_response)
count_awr_outstanding = count_awr_outstanding + 1;
count_awr_outstanding = count_awr_outstanding + bfill;
end
always @(*)
if (S_AXI_ARESETN)
assert(f_axi_awr_outstanding == count_awr_outstanding);
always @(*)
begin
count_wr_outstanding = 0;
if (write_bvalid)
count_wr_outstanding = count_wr_outstanding + 1;
if (write_response)
count_wr_outstanding = count_wr_outstanding + 1;
count_wr_outstanding = count_wr_outstanding + bfill;
end
always @(*)
if (S_AXI_ARESETN)
assert(f_axi_wr_outstanding == count_wr_outstanding);
//
//
//
always @(*)
begin
count_rd_outstanding = 0;
if (read_rwait)
count_rd_outstanding = count_rd_outstanding + 1;
if (read_rvalid)
count_rd_outstanding = count_rd_outstanding + 1;
if (read_result)
count_rd_outstanding = count_rd_outstanding + 1;
count_rd_outstanding = count_rd_outstanding + rfill;
end
always @(*)
if (S_AXI_ARESETN)
assert(f_axi_rd_outstanding == count_rd_outstanding);
////////////////////////////////////////////////////////////////////////
//
// Cover properties
//
////////////////////////////////////////////////////////////////////////
//
//
reg [3:0] cvr_arvalids, cvr_awvalids, cvr_reads, cvr_writes;
initial cvr_awvalids = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
cvr_awvalids <= 0;
else if (S_AXI_AWVALID && S_AXI_AWREADY && !(&cvr_awvalids))
cvr_awvalids <= cvr_awvalids + 1;
initial cvr_arvalids = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
cvr_arvalids <= 0;
else if (S_AXI_ARVALID && S_AXI_ARREADY && !(&cvr_arvalids))
cvr_arvalids <= cvr_arvalids + 1;
initial cvr_writes = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
cvr_writes <= 0;
else if (S_AXI_BVALID && S_AXI_BREADY && !(&cvr_writes))
cvr_writes <= cvr_writes + 1;
initial cvr_reads = 0;
always @(posedge S_AXI_ACLK)
if (!S_AXI_ARESETN)
cvr_reads <= 0;
else if (S_AXI_RVALID && S_AXI_RREADY && !(&cvr_arvalids))
cvr_reads <= cvr_reads + 1;
always @(*)
cover(cvr_awvalids > 4);
always @(*)
cover(cvr_arvalids > 4);
always @(*)
cover(cvr_reads > 4);
always @(*)
cover(cvr_writes > 4);
always @(*)
cover((cvr_writes > 4) && (cvr_reads > 4));
`endif
endmodule
// `ifndef YOSYS
// `default_nettype wire
// `endif