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faxi_slave.v
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faxi_slave.v
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////////////////////////////////////////////////////////////////////////////////
//
// Filename: faxi_slave.v (Formal properties of an AXI4 (full) slave)
// {{{
// Project: WB2AXIPSP: bus bridges and other odds and ends
//
// Purpose: This file contains a subset of the formal properties which I've
// used to formally verify that a core truly follows the full
// AXI4 specification.
//
// Creator: Dan Gisselquist, Ph.D.
// Gisselquist Technology, LLC
//
////////////////////////////////////////////////////////////////////////////////
// }}}
// Copyright (C) 2017-2024, 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 faxi_slave #(
// {{{
parameter C_AXI_ID_WIDTH = 3, // The AXI id width used for R&W
// This is an int between 1-16
parameter C_AXI_DATA_WIDTH = 128,// Width of the AXI R&W data
parameter C_AXI_ADDR_WIDTH = 28, // AXI Address width (log wordsize)
parameter [7:0] OPT_MAXBURST = 8'hff,// Maximum burst length, minus 1
parameter [0:0] OPT_EXCLUSIVE = 1,// Exclusive access allowed
parameter [0:0] OPT_NARROW_BURST = 1,// Narrow bursts allowed by default
parameter [0:0] OPT_ASYNC_RESET = 0,
// F_OPT_ASSUME_RESET, if set, will cause the design to *assume* the
// existence of a correct reset, rather than asserting it. It is
// appropriate anytime the reset logic is outside of the circuit being
// examined
parameter [0:0] F_OPT_ASSUME_RESET = 1'b1,
parameter [0:0] F_OPT_NO_RESET = 1'b1,
// F_LGDEPTH is the number of bits necessary to count the maximum
// number of items in flight.
parameter F_LGDEPTH = 10,
parameter [(F_LGDEPTH-1):0] F_AXI_MAXSTALL = 3,
parameter [(F_LGDEPTH-1):0] F_AXI_MAXRSTALL= 3,
parameter [(F_LGDEPTH-1):0] F_AXI_MAXDELAY = 3,
localparam F_OPT_BURSTS = (OPT_MAXBURST != 0),
//
localparam IW = C_AXI_ID_WIDTH,
localparam DW = C_AXI_DATA_WIDTH,
localparam AW = C_AXI_ADDR_WIDTH
// }}}
) (
// {{{
input wire i_clk, // System clock
input wire i_axi_reset_n,
// AW* : AXI write address channel signals
// {{{
input wire i_axi_awvalid, // Write address valid
input wire i_axi_awready,//Slave is ready to accept
input wire [IW-1:0] i_axi_awid, // Write ID
input wire [AW-1:0] i_axi_awaddr, // Write address
input wire [7:0] i_axi_awlen, // Write Burst Length
input wire [2:0] i_axi_awsize, // Write Burst size
input wire [1:0] i_axi_awburst, // Write Burst type
input wire [0:0] i_axi_awlock, // Write lock type
input wire [3:0] i_axi_awcache, // Write Cache type
input wire [2:0] i_axi_awprot, // Write Protection type
input wire [3:0] i_axi_awqos, // Write Quality of Svc
// }}}
// W* : AXI write data channel signals
// {{{
input wire i_axi_wvalid, // Write valid
input wire i_axi_wready, // Write data ready
input wire [DW-1:0] i_axi_wdata, // Write data
input wire [DW/8-1:0] i_axi_wstrb, // Write strobes
input wire i_axi_wlast, // Last write transaction
// }}}
// B* : AXI write response channel signals
// {{{
input wire i_axi_bvalid, // Write reponse valid
input wire i_axi_bready, // Response ready
input wire [IW-1:0] i_axi_bid, // Response ID
input wire [1:0] i_axi_bresp, // Write response
// }}}
// AR* : AXI read address channel signals
// {{{
input wire i_axi_arvalid, // Read address valid
input wire i_axi_arready, // Read address ready
input wire [IW-1:0] i_axi_arid, // Read ID
input wire [AW-1:0] i_axi_araddr, // Read address
input wire [7:0] i_axi_arlen, // Read Burst Length
input wire [2:0] i_axi_arsize, // Read Burst size
input wire [1:0] i_axi_arburst, // Read Burst type
input wire [0:0] i_axi_arlock, // Read lock type
input wire [3:0] i_axi_arcache, // Read Cache type
input wire [2:0] i_axi_arprot, // Read Protection type
input wire [3:0] i_axi_arqos, // Read Protection type
// }}}
// R* : AXI read data channel signals
// {{{
input wire [IW-1:0] i_axi_rid, // Response ID
input wire [1:0] i_axi_rresp, // Read response
input wire i_axi_rvalid, // Read reponse valid
input wire [DW-1:0] i_axi_rdata, // Read data
input wire i_axi_rlast, // Read last
input wire i_axi_rready, // Read Response ready
// }}}
// Induction information
// {{{
output reg [F_LGDEPTH-1:0] f_axi_awr_nbursts,
output reg [9-1:0] f_axi_wr_pending,
output reg [F_LGDEPTH-1:0] f_axi_rd_nbursts,
output reg [F_LGDEPTH-1:0] f_axi_rd_outstanding,
// ...
// }}}
// }}}
// }}}
);
// Parameter declarations
// {{{
localparam [1:0] OKAY = 2'b00;
localparam [1:0] EXOKAY = 2'b01;
localparam F_AXI_MAXWAIT = F_AXI_MAXSTALL;
// Because of the nature and size of bursts, which can be up to
// 256 in length (AxLEN), the F_LGDEPTH parameter necessary to capture
// this *must* be at least 8 bits wide
initial begin
assert(F_LGDEPTH > 8);
// Only power of two data sizes are supported from 8-bits on up to
// 1024
assert((DW == 8)
||(DW == 16)
||(DW == 32)
||(DW == 64)
||(DW == 128)
||(DW == 256)
||(DW == 512)
||(DW == 1024));
end
// }}}
// Internal register and wire declarations
// {{{
wire axi_rd_ack, axi_wr_ack, axi_ard_req, axi_awr_req, axi_wr_req;
// axi_rd_err, axi_wr_err;
//
assign axi_ard_req = (i_axi_arvalid)&&(i_axi_arready);
assign axi_awr_req = (i_axi_awvalid)&&(i_axi_awready);
assign axi_wr_req = (i_axi_wvalid )&&(i_axi_wready);
//
assign axi_rd_ack = (i_axi_rvalid)&&(i_axi_rready);
assign axi_wr_ack = (i_axi_bvalid)&&(i_axi_bready);
// assign axi_rd_err = (axi_rd_ack)&&(i_axi_rresp[1]);
// assign axi_wr_err = (axi_wr_ack)&&(i_axi_bresp[1]);
//
// ...
//
// Within the slave core, we will *assume* properties from the master,
// and *assert* properties of signals coming from the slave and
// returning to the master. This order will be reversed within the
// master, and the following two definitions help us do that.
//
// Similarly, we will always *assert* local values of our own necessary
// for checks below. Those will use the assert() keyword, rather than
// either of these two macros.
`define SLAVE_ASSUME assume
`define SLAVE_ASSERT assert
//
// Setup
//
// integer k;
initial f_past_valid = 1'b0;
always @(posedge i_clk)
f_past_valid <= 1'b1;
always @(*)
if (!f_past_valid)
assume(!i_axi_reset_n);
// }}}
////////////////////////////////////////////////////////////////////////
//
// Reset properties
// {{{
////////////////////////////////////////////////////////////////////////
//
// Insist that the reset signal start out asserted (negative), and
// remain so for 16 clocks.
//
generate if (F_OPT_ASSUME_RESET)
begin : ASSUME_INITIAL_RESET
always @(*)
if (!f_past_valid)
assume(!i_axi_reset_n);
end else begin : ASSERT_INITIAL_RESET
always @(*)
if (!f_past_valid)
assert(!i_axi_reset_n);
end endgenerate
//
//
// If asserted, the reset must be asserted for a minimum of 16 clocks
initial f_reset_length = 0;
always @(posedge i_clk)
if (F_OPT_NO_RESET || i_axi_reset_n)
f_reset_length <= 0;
else if (!(&f_reset_length))
f_reset_length <= f_reset_length + 1'b1;
always @(posedge i_clk)
if ((f_past_valid)&& !F_OPT_NO_RESET
&& (!$past(i_axi_reset_n))&&(!$past(&f_reset_length)))
`SLAVE_ASSUME(!i_axi_reset_n);
//
// If the reset is not generated within this particular core, then it
// can be assumed if F_OPT_ASSUME_RESET is set
generate if (F_OPT_ASSUME_RESET && !F_OPT_NO_RESET)
begin : ASSUME_RESET
always @(posedge i_clk)
if ((f_past_valid)&&(!$past(i_axi_reset_n))&&(!$past(&f_reset_length)))
assume(!i_axi_reset_n);
always @(*)
if ((f_reset_length > 0)&&(f_reset_length < 4'hf))
assume(!i_axi_reset_n);
end else if (!F_OPT_NO_RESET)
begin : ASSERT_RESET
always @(posedge i_clk)
if ((f_past_valid)&&(!$past(i_axi_reset_n))&&(!$past(&f_reset_length)))
assert(!i_axi_reset_n);
always @(*)
if ((f_reset_length > 0)&&(f_reset_length < 4'hf))
assert(!i_axi_reset_n);
end endgenerate
//
// All of the xVALID signals *MUST* be set low on the clock following
// a reset. (See Fig A3-1) Not in the spec, but also checked here is
// that they must also be set low initially.
always @(posedge i_clk)
if ((!f_past_valid && F_OPT_INITIAL)||(f_past_valid && !$past(i_axi_reset_n)))
begin
`SLAVE_ASSUME(!i_axi_arvalid);
`SLAVE_ASSUME(!i_axi_awvalid);
`SLAVE_ASSUME(!i_axi_wvalid);
//
`SLAVE_ASSERT(!i_axi_bvalid);
`SLAVE_ASSERT(!i_axi_rvalid);
end
generate if (OPT_ASYNC_RESET)
begin
always @(*)
if (!i_axi_reset_n)
begin
`SLAVE_ASSUME(!i_axi_arvalid);
`SLAVE_ASSUME(!i_axi_awvalid);
`SLAVE_ASSUME(!i_axi_wvalid);
//
`SLAVE_ASSERT(!i_axi_bvalid);
`SLAVE_ASSERT(!i_axi_rvalid);
end
end endgenerate
// }}}
////////////////////////////////////////////////////////////////////////
//
// Stability properties--what happens if valid and not ready
// {{{
////////////////////////////////////////////////////////////////////////
//
//
// Assume any response from the bus will not change prior to that
// response being accepted
always @(posedge i_clk)
if ((f_past_valid)&& $past(i_axi_reset_n)
&& (!OPT_ASYNC_RESET || i_axi_reset_n))
begin
// Write address channel
if ((f_past_valid)&&($past(i_axi_awvalid && !i_axi_awready)))
begin
`SLAVE_ASSUME(i_axi_awvalid);
`SLAVE_ASSUME($stable(i_axi_awaddr));
`SLAVE_ASSUME($stable(i_axi_awid));
`SLAVE_ASSUME($stable(i_axi_awlen));
`SLAVE_ASSUME($stable(i_axi_awsize));
`SLAVE_ASSUME($stable(i_axi_awburst));
`SLAVE_ASSUME($stable(i_axi_awlock));
`SLAVE_ASSUME($stable(i_axi_awcache));
`SLAVE_ASSUME($stable(i_axi_awprot));
`SLAVE_ASSUME($stable(i_axi_awqos));
end
// Write data channel
if ((f_past_valid)&&($past(i_axi_wvalid && !i_axi_wready)))
begin
`SLAVE_ASSUME(i_axi_wvalid);
`SLAVE_ASSUME($stable(i_axi_wstrb));
`SLAVE_ASSUME($stable(i_axi_wdata));
`SLAVE_ASSUME($stable(i_axi_wlast));
end
// Incoming Read address channel
if ((f_past_valid)&&($past(i_axi_arvalid && !i_axi_arready)))
begin
`SLAVE_ASSUME(i_axi_arvalid);
`SLAVE_ASSUME($stable(i_axi_arid));
`SLAVE_ASSUME($stable(i_axi_araddr));
`SLAVE_ASSUME($stable(i_axi_arlen));
`SLAVE_ASSUME($stable(i_axi_arsize));
`SLAVE_ASSUME($stable(i_axi_arburst));
`SLAVE_ASSUME($stable(i_axi_arlock));
`SLAVE_ASSUME($stable(i_axi_arcache));
`SLAVE_ASSUME($stable(i_axi_arprot));
`SLAVE_ASSUME($stable(i_axi_arqos));
end
// Assume any response from the bus will not change prior to
// that response being accepted
if ((f_past_valid)&&($past(i_axi_rvalid && !i_axi_rready)))
begin
`SLAVE_ASSERT(i_axi_rvalid);
`SLAVE_ASSERT($stable(i_axi_rid));
`SLAVE_ASSERT($stable(i_axi_rresp));
`SLAVE_ASSERT($stable(i_axi_rdata));
`SLAVE_ASSERT($stable(i_axi_rlast));
end
if ((f_past_valid)&&($past(i_axi_bvalid && !i_axi_bready)))
begin
`SLAVE_ASSERT(i_axi_bvalid);
`SLAVE_ASSERT($stable(i_axi_bid));
`SLAVE_ASSERT($stable(i_axi_bresp));
end
end
// }}}
////////////////////////////////////////////////////////////////////////
//
// Insist upon a maximum delay before a request is accepted
// {{{
////////////////////////////////////////////////////////////////////////
//
//
generate if (F_AXI_MAXWAIT > 0)
begin : CHECK_STALL_COUNT
reg [(F_LGDEPTH-1):0] f_axi_awstall,
f_axi_wstall,
f_axi_arstall;
//
// AXI write address channel
//
// Count the number of times AWVALID is true while AWREADY
// is false. These are stalls, and we want to insist on a
// minimum number of them. However, if BVALID && !BREADY,
// then there's a reason for not accepting anything more.
// Similarly, many cores will only ever accept one request
// at a time, hence we won't count things as stalls if
// WR-PENDING > 0.
initial f_axi_awstall = 0;
always @(posedge i_clk)
if ((!i_axi_reset_n)||(!i_axi_awvalid)||(i_axi_awready)
||(f_axi_wr_pending > 0))
f_axi_awstall <= 0;
else if ((!i_axi_bvalid)||(i_axi_bready))
f_axi_awstall <= f_axi_awstall + 1'b1;
always @(*)
`SLAVE_ASSERT(f_axi_awstall < F_AXI_MAXWAIT);
//
// AXI write data channel
//
// Count the number of clock cycles that the write data
// channel is stalled, that is while WVALID && !WREADY.
// Since things can back up if BVALID & !BREADY, we avoid
// counting clock cycles in that circumstance
initial f_axi_wstall = 0;
always @(posedge i_clk)
if ((!i_axi_reset_n)||(!i_axi_wvalid)||(i_axi_wready)
||(f_axi_wr_pending == 0 && i_axi_wvalid))
f_axi_wstall <= 0;
else if ((!i_axi_bvalid)||(i_axi_bready))
f_axi_wstall <= f_axi_wstall + 1'b1;
always @(*)
`SLAVE_ASSERT(f_axi_wstall < F_AXI_MAXWAIT);
//
// AXI read address channel
//
// Similar to the first two above, once the master raises
// ARVALID, insist that the slave respond within a minimum
// number of clock cycles. Exceptions include any time
// RVALID is true, since that can back up the whole system,
// and any time the number of bursts is greater than zero,
// since many slaves can only accept one request at a time.
initial f_axi_arstall = 0;
always @(posedge i_clk)
if ((!i_axi_reset_n)||(!i_axi_arvalid)||(i_axi_arready)
||(i_axi_rvalid)||(f_axi_rd_nbursts > 0))
f_axi_arstall <= 0;
else
f_axi_arstall <= f_axi_arstall + 1'b1;
always @(*)
`SLAVE_ASSERT(f_axi_arstall < F_AXI_MAXWAIT);
end endgenerate
// }}}
////////////////////////////////////////////////////////////////////////
//
// Insist upon a maximum delay before any response is accepted
// {{{
////////////////////////////////////////////////////////////////////////
//
// These are separate from the earlier ones, in case you wish to
// control them separately. For example, an interconnect might be
// forced to let a channel wait indefinitely for access, but it might
// not be appropriate to require the response to be able to wait
// indefinitely as well
//
generate if (F_AXI_MAXRSTALL > 0)
begin : CHECK_RESPONSE_STALLS
// {{{
reg [(F_LGDEPTH-1):0] f_axi_wvstall,
f_axi_bstall,
f_axi_rstall;
// }}}
// f_axi_wvstall : AXI write channel valid
// {{{
// The first master stall check: guarantee that the master
// provides the required write data in fairly short order,
// and without much delay. That is, once AWVALID && AWREADY
// are true, the slave needs to provide the W* values
initial f_axi_wvstall = 0;
always @(posedge i_clk)
if ((!i_axi_reset_n)||(i_axi_wvalid)
||(i_axi_bvalid && !i_axi_bready)
||(f_axi_wr_pending == 0))
f_axi_wvstall <= 0;
else
f_axi_wvstall <= f_axi_wvstall + 1'b1;
always @(*)
`SLAVE_ASSUME(f_axi_wvstall < F_AXI_MAXRSTALL);
// }}}
// f_axi_bstall: AXI write response channel
// {{{
// Insist on a maximum number of clocks that BVALID can be
// high while BREADY is low
initial f_axi_bstall = 0;
always @(posedge i_clk)
if ((!i_axi_reset_n)||(!i_axi_bvalid)||(i_axi_bready))
f_axi_bstall <= 0;
else
f_axi_bstall <= f_axi_bstall + 1'b1;
always @(*)
`SLAVE_ASSUME(f_axi_bstall < F_AXI_MAXRSTALL);
// }}}
// f_axi_rstall: AXI read response channel
// {{{
// Insist on a maximum number of clocks that RVALID can be
// high while RREADY is low
initial f_axi_rstall = 0;
always @(posedge i_clk)
if ((!i_axi_reset_n)||(!i_axi_rvalid)||(i_axi_rready))
f_axi_rstall <= 0;
else
f_axi_rstall <= f_axi_rstall + 1'b1;
always @(*)
`SLAVE_ASSUME(f_axi_rstall < F_AXI_MAXRSTALL);
// }}}
end endgenerate
// }}}
////////////////////////////////////////////////////////////////////////
//
// Count outstanding transactions.
// {{{
////////////////////////////////////////////////////////////////////////
//
// With these measures, we count once per any burst.
//
// ...
initial f_axi_wr_pending = 0;
// ...
always @(posedge i_clk)
if (!i_axi_reset_n)
begin
f_axi_wr_pending <= 0;
// ...
end else case({ axi_awr_req, axi_wr_req })
2'b10: begin
// {{{
f_axi_wr_pending <= i_axi_awlen+1;
// ...
end
// }}}
2'b01: begin
// {{{
`SLAVE_ASSUME(f_axi_wr_pending > 0);
f_axi_wr_pending <= f_axi_wr_pending - 1'b1;
`SLAVE_ASSUME(!i_axi_wlast || (f_axi_wr_pending == 1));
// ...
end
// }}}
2'b11: begin
// {{{
// ...
if (f_axi_wr_pending > 0)
f_axi_wr_pending <= i_axi_awlen+1;
else begin
f_axi_wr_pending <= i_axi_awlen;
// ...
end end
// }}}
default: begin end
endcase
// }}}
// ...
//
// Insist that no WVALID value show up prior to a AWVALID value. The
// address *MUST* come first. Further, while waiting for the write
// data, NO OTHER WRITE ADDRESS may be permitted. This is not strictly
// required by the specification, but it is required in order to make
// these properties work (currently--I might revisit this later)
//
// ...
// f_axi_awr_nbursts
// {{{
// Count the number of outstanding BVALID's to expect
initial f_axi_awr_nbursts = 0;
always @(posedge i_clk)
if (!i_axi_reset_n)
f_axi_awr_nbursts <= 0;
else case({ (axi_awr_req), (axi_wr_ack) })
2'b10: f_axi_awr_nbursts <= f_axi_awr_nbursts + 1'b1;
2'b01: f_axi_awr_nbursts <= f_axi_awr_nbursts - 1'b1;
default: begin end
endcase
// }}}
//
// Count the number of reads bursts outstanding. This defines the
// number of RDVALID && RLAST's we expect to see before becoming idle
//
initial f_axi_rd_nbursts = 0;
always @(posedge i_clk)
if (!i_axi_reset_n)
f_axi_rd_nbursts <= 0;
else case({ (axi_ard_req), (axi_rd_ack)&&(i_axi_rlast) })
2'b01: f_axi_rd_nbursts <= f_axi_rd_nbursts - 1'b1;
2'b10: f_axi_rd_nbursts <= f_axi_rd_nbursts + 1'b1;
default: begin end
endcase
// }}}
// f_axi_rd_outstanding
// {{{
// f_axi_rd_outstanding counts the number of RDVALID's we expect to
// see before becoming idle. This must always be greater than or
// equal to the number of RVALID & RLAST's counted above
//
initial f_axi_rd_outstanding = 0;
always @(posedge i_clk)
if (!i_axi_reset_n)
f_axi_rd_outstanding <= 0;
else case({ (axi_ard_req), (axi_rd_ack) })
// Verilator lint_off WIDTH
2'b01: f_axi_rd_outstanding <= f_axi_rd_outstanding - 1'b1;
2'b10: f_axi_rd_outstanding <= f_axi_rd_outstanding + i_axi_arlen+1;
2'b11: f_axi_rd_outstanding <= f_axi_rd_outstanding + i_axi_arlen;
// Verilator lint_on WIDTH
default: begin end
endcase
// }}}
// Overflow checking
// {{{
// Do not let the number of outstanding requests overflow. This is
// a responsibility of the master to never allow 2^F_LGDEPTH-1
// requests to be outstanding.
//
always @(*)
`SLAVE_ASSERT(f_axi_rd_outstanding < {(F_LGDEPTH){1'b1}});
always @(*)
`SLAVE_ASSERT(f_axi_awr_nbursts < {(F_LGDEPTH){1'b1}});
always @(*)
`SLAVE_ASSERT(f_axi_wr_pending <= 256);
always @(*)
`SLAVE_ASSERT(f_axi_rd_nbursts < {(F_LGDEPTH){1'b1}});
// }}}
////////////////////////////////////////////////////////////////////////
//
// Read Burst counting
//
always @(*)
assert(f_axi_rd_nbursts <= f_axi_rd_outstanding);
always @(*)
assert((f_axi_rd_nbursts == 0)==(f_axi_rd_outstanding==0));
//
//
// ...
//
// AXI read data channel signals
// {{{
always @(*)
if (i_axi_rvalid && (F_OPT_INITIAL || f_past_valid))
begin
`SLAVE_ASSERT(f_axi_rd_outstanding > 0);
`SLAVE_ASSERT(f_axi_rd_nbursts > 0);
// ...
end
always @(*)
if (!F_OPT_INITIAL && !f_past_valid)
next_rd_nbursts = 0;
else
next_rd_nbursts = f_axi_rd_nbursts
- (i_axi_rvalid && i_axi_rlast ? 1:0);
always @(*)
if (!F_OPT_INITIAL && !f_past_valid)
next_rd_outstanding = 0;
else
next_rd_outstanding = f_axi_rd_outstanding
- (i_axi_rvalid ? 1:00);
// ...
always @(*)
`SLAVE_ASSERT(next_rd_nbursts <= next_rd_outstanding);
// ...
always @(*)
`SLAVE_ASSERT({ 8'h00, next_rd_outstanding }
<= { next_rd_nbursts, 8'h00 });
//
// ...
//
always @(*)
assert({ 8'h00, f_axi_rd_outstanding } <= { f_axi_rd_nbursts, 8'h0 });
//
// ...
//
always @(*)
assert({ 8'h00, f_axi_rd_outstanding } <= { f_axi_rd_nbursts, 8'h0 });
//
// ...
//
// }}}
////////////////////////////////////////////////////////////////////////
//
// Minimum delay to acknowledgment
// {{{
////////////////////////////////////////////////////////////////////////
//
// Insist that all responses are returned in less than a maximum delay
// In this case, we count responses within a burst, rather than entire
// bursts.
//
//
// A unique feature to the backpressure mechanism within AXI is that
// we have to reset our delay counters in the case of any push back,
// since the response can't move forward if the master isn't (yet)
// ready for it.
//
generate if (F_AXI_MAXDELAY > 0)
begin : CHECK_MAX_DELAY
reg [(F_LGDEPTH-1):0] f_axi_awr_ack_delay,
f_axi_rd_ack_delay;
// awr_ack_delay
// {{{
initial f_axi_awr_ack_delay = 0;
always @(posedge i_clk)
if ((!i_axi_reset_n)||(i_axi_bvalid)||(i_axi_wvalid)
||((f_axi_awr_nbursts == 1)
&&(f_axi_wr_pending>0))
||(f_axi_awr_nbursts == 0))
f_axi_awr_ack_delay <= 0;
else
f_axi_awr_ack_delay <= f_axi_awr_ack_delay + 1'b1;
// }}}
// rd_ack_delay
// {{{
initial f_axi_rd_ack_delay = 0;
always @(posedge i_clk)
if ((!i_axi_reset_n)||(i_axi_rvalid)||(f_axi_rd_outstanding==0))
f_axi_rd_ack_delay <= 0;
else
f_axi_rd_ack_delay <= f_axi_rd_ack_delay + 1'b1;
// }}}
always @(*)
`SLAVE_ASSERT(f_axi_awr_ack_delay < F_AXI_MAXDELAY);
always @(*)
`SLAVE_ASSERT(f_axi_rd_ack_delay < F_AXI_MAXDELAY);
end endgenerate
// }}}
////////////////////////////////////////////////////////////////////////
//
// Acknowledgements must follow requests
// {{{
////////////////////////////////////////////////////////////////////////
//
// The outstanding count is a count of bursts, but the acknowledgements
// we are looking for are individual. Hence, there should be no
// individual acknowledgements coming back if there's no outstanding
// burst.
//
//
// AXI write response channel
//
//
// ...
//
//
// Cannot have outstanding values if there aren't any outstanding
// bursts
//
// ...
//
always @(posedge i_clk)
if (f_axi_awr_nbursts == 0)
`SLAVE_ASSERT(f_axi_wr_pending == 0);
//
// ...
//
//
// Because we can't accept multiple AW* requests prior to the
// last WVALID && WLAST, the AWREADY signal *MUST* be high while
// waiting
//
always @(*)
if (f_axi_wr_pending > 1)
`SLAVE_ASSERT(!i_axi_awready);
// }}}
////////////////////////////////////////////////////////////////////////
//
// Write address checking
// {{{
////////////////////////////////////////////////////////////////////////
//
//
initial f_axi_wr_len = 0;
always @(posedge i_clk)
begin
//
// ...
//
// f_axi_wr_size maximums
// {{{
if (!OPT_NARROW_BURST)
begin
// In this case, all size parameters are fixed.
// Let's remove them from the solvers logic choices
// for optimization purposes
//
if (DW == 8)
f_axi_wr_size <= 0;
else if (DW == 16)
f_axi_wr_size <= 1;
else if (DW == 32)
f_axi_wr_size <= 2;
else if (DW == 64)
f_axi_wr_size <= 3;
else if (DW == 128)
f_axi_wr_size <= 4;
else if (DW == 256)
f_axi_wr_size <= 5;
else if (DW == 512)
f_axi_wr_size <= 6;
else // if (DW == 1024)
f_axi_wr_size <= 7;
end
// }}}
end
//
// ...
//
// }}}
// Write strobe validity checking
// {{{
always @(*)
// Verilator lint_off WIDTH
wstb_addr = f_axi_wr_addr;
// Verilator lint_on WIDTH
faxi_wstrb #(.C_AXI_DATA_WIDTH(DW))
f_wstrbck (wstb_addr, this_awsize, i_axi_wstrb, wstb_valid);
// Insist the only the appropriate bits be valid
// For example, if the lower address bit is one, then the
// strobe LSB cannot be 1, but must be zero. This is just
// enforcing the rules of the sub-address which must match
// the write strobe. An STRB of 0 is always allowed.
//
always @(*)
if (i_axi_wvalid && (f_past_valid || F_OPT_INITIAL))
`SLAVE_ASSUME(wstb_valid);
// }}}
//
// Write induction properties
// {{{
// These are actual assert()s and not `SLAVE_ASSERT or `SLAVE_ASSUMEs
// because they are testing the functionality of this core and its local
// logical registers, not so much the functionality of the core we are
// testing
//
always @(*)
val_wr_len = f_axi_wr_pending[7:0]-1;
always @(*)
if (f_axi_wr_pending > 0)
assert(f_axi_wr_pending <= f_axi_wr_len + 1);
always @(*)
assert(f_axi_wr_pending <= 9'h100);
always @(*)
if ((f_axi_wr_pending > 0)&&(f_axi_wr_burst == 2'b10))
assert((f_axi_wr_len == 1)
||(f_axi_wr_len == 3)
||(f_axi_wr_len == 7)
||(f_axi_wr_len == 15));
// }}}
////////////////////////////////////////////////////////////////////////
//
// Read address checking
// {{{
////////////////////////////////////////////////////////////////////////
//
//
always @(posedge i_clk)
begin
//
// ...
//
// f_axi_rd_cksize limiting
// {{{
if (!OPT_NARROW_BURST)
begin
// In this case, all size parameters are fixed.
// Let's remove them from the solvers logic choices
// for optimization purposes
//
if (DW == 8)
f_axi_rd_cksize <= 0;
else if (DW == 16)
f_axi_rd_cksize <= 1;
else if (DW == 32)
f_axi_rd_cksize <= 2;
else if (DW == 64)
f_axi_rd_cksize <= 3;
else if (DW == 128)
f_axi_rd_cksize <= 4;
else if (DW == 256)
f_axi_rd_cksize <= 5;
else if (DW == 512)
f_axi_rd_cksize <= 6;
else // if (DW == 1024)
f_axi_rd_cksize <= 7;
end
// }}}
end
// }}}
////////////////////////////////////////////////////////////////////////
//
// Read induction properties
// {{{
////////////////////////////////////////////////////////////////////////
//
// These are actual assert()s and not `SLAVE_ASSERT or `SLAVE_ASSUMEs
// because they are testing the functionality of this core and its local
// logical registers, not so much the functionality of the core we are
// testing
//
// ...
//
////////////////////////////////////////////////////////////////////////
//
// Exclusive access properties
// {{{
////////////////////////////////////////////////////////////////////////
generate if (!OPT_EXCLUSIVE)
begin : EXCLUSIVE_DISALLOWED
// {{{
//
// Without exclusive access support, the master shall not issue
// exclusive access requests
always @(*)
if (F_OPT_INITIAL || f_past_valid)
begin
`SLAVE_ASSUME(!i_axi_awvalid || !i_axi_awlock);
`SLAVE_ASSUME(!i_axi_arvalid || !i_axi_arlock);
end
// Similarly, without exclusive access support, the slave
// shall not respond with an okay indicating that exclusive
// access was supported.
always @(*)
if (F_OPT_INITIAL || f_past_valid)
begin
`SLAVE_ASSERT(!i_axi_bvalid || i_axi_bresp != EXOKAY);
`SLAVE_ASSERT(!i_axi_rvalid || i_axi_rresp != EXOKAY);
end
// }}}
end else begin : EXCLUSIVE_ACCESS_CHECKER
// {{{
//
// 1. Exclusive access burst lengths max out at 16
// 2. Exclusive access bursts must be aligned
// 3. Write must take place when the read channel is idle (on
// this ID)
// 4. Read returns may not switch between EXOKAY and OKAY. Once
// committed, can only switch to SLVERR or DECERR.
// 5. An address that can handle exclusive access will always
// return EXOKAY on a read attempt.
//
reg [1:0] exfsm_state;
reg [AW-1:0] exreq_addr;
reg [7:0] exreq_len;
reg [1:0] exreq_burst;
reg [2:0] exreq_size;
reg [F_LGDEPTH-1:0] rdid_bursts_to_lock;
reg [F_LGDEPTH-1:0] wrid_bursts_to_exwrite;
reg exreq_return;
// awcache check
// {{{
always @(*)
if (i_axi_awvalid && i_axi_awlock && (F_OPT_INITIAL || f_past_valid))
begin
// ...
end
// }}}
// arcache check
// {{{
always @(*)
if (i_axi_arvalid && i_axi_arlock && (F_OPT_INITIAL || f_past_valid))
begin
`SLAVE_ASSUME(!i_axi_arcache[0]);
end
// }}}
//
// ...
//
// Exclusive access state machine
// {{{