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axi_demux_simple.sv
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axi_demux_simple.sv
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// Copyright (c) 2019 ETH Zurich and University of Bologna.
// Copyright and related rights are licensed under the Solderpad Hardware
// License, Version 0.51 (the "License"); you may not use this file except in
// compliance with the License. You may obtain a copy of the License at
// http://solderpad.org/licenses/SHL-0.51. Unless required by applicable law
// or agreed to in writing, software, hardware and materials distributed under
// this 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.
//
// Authors:
// - Wolfgang Roenninger <[email protected]>
// - Michael Rogenmoser <[email protected]>
// - Thomas Benz <[email protected]>
// - Andreas Kurth <[email protected]>
`include "common_cells/assertions.svh"
`include "common_cells/registers.svh"
`include "axi/assign.svh"
`ifdef QUESTA
// Derive `TARGET_VSIM`, which is used for tool-specific workarounds in this file, from `QUESTA`,
// which is automatically set in Questa.
`define TARGET_VSIM
`endif
/// Demultiplex one AXI4+ATOP slave port to multiple AXI4+ATOP master ports.
///
/// The AW and AR slave channels each have a `select` input to determine to which master port the
/// current request is sent. The `select` can, for example, be driven by an address decoding module
/// to map address ranges to different AXI slaves.
///
/// ## Design overview
///
/// ![Block diagram](module.axi_demux.png "Block diagram")
///
/// Beats on the W channel are routed by demultiplexer according to the selection for the
/// corresponding AW beat. This relies on the AXI property that W bursts must be sent in the same
/// order as AW beats and beats from different W bursts may not be interleaved.
///
/// Beats on the B and R channel are multiplexed from the master ports to the slave port with
/// a round-robin arbitration tree.
module axi_demux_simple #(
parameter int unsigned AxiIdWidth = 32'd0,
parameter bit AtopSupport = 1'b1,
parameter type axi_req_t = logic,
parameter type axi_resp_t = logic,
parameter int unsigned NoMstPorts = 32'd0,
parameter int unsigned MaxTrans = 32'd8,
parameter int unsigned AxiLookBits = 32'd3,
parameter bit UniqueIds = 1'b0,
// Dependent parameters, DO NOT OVERRIDE!
parameter int unsigned SelectWidth = (NoMstPorts > 32'd1) ? $clog2(NoMstPorts) : 32'd1,
parameter type select_t = logic [SelectWidth-1:0]
) (
input logic clk_i,
input logic rst_ni,
input logic test_i,
// Slave Port
input axi_req_t slv_req_i,
input select_t slv_aw_select_i,
input select_t slv_ar_select_i,
output axi_resp_t slv_resp_o,
// Master Ports
output axi_req_t [NoMstPorts-1:0] mst_reqs_o,
input axi_resp_t [NoMstPorts-1:0] mst_resps_i
);
localparam int unsigned IdCounterWidth = cf_math_pkg::idx_width(MaxTrans);
typedef logic [IdCounterWidth-1:0] id_cnt_t;
// pass through if only one master port
if (NoMstPorts == 32'h1) begin : gen_no_demux
`AXI_ASSIGN_REQ_STRUCT(mst_reqs_o[0], slv_req_i)
`AXI_ASSIGN_RESP_STRUCT(slv_resp_o, mst_resps_i[0])
end else begin
//--------------------------------------
//--------------------------------------
// Signal Declarations
//--------------------------------------
//--------------------------------------
//--------------------------------------
// Write Transaction
//--------------------------------------
// Register which locks the AW valid signal
logic lock_aw_valid_d, lock_aw_valid_q, load_aw_lock;
logic aw_valid, aw_ready;
// AW ID counter
select_t lookup_aw_select;
logic aw_select_occupied, aw_id_cnt_full;
// Upon an ATOP load, inject IDs from the AW into the AR channel
logic atop_inject;
// W select counter: stores the decision to which master W beats should go
select_t w_select, w_select_q;
logic w_select_valid;
id_cnt_t w_open;
logic w_cnt_up, w_cnt_down;
// B channles input into the arbitration
logic [NoMstPorts-1:0] mst_b_valids, mst_b_readies;
//--------------------------------------
// Read Transaction
//--------------------------------------
// AR ID counter
select_t lookup_ar_select;
logic ar_select_occupied, ar_id_cnt_full;
logic ar_push;
// Register which locks the AR valid signel
logic lock_ar_valid_d, lock_ar_valid_q, load_ar_lock;
logic ar_valid, ar_ready;
logic [NoMstPorts-1:0] mst_r_valids, mst_r_readies;
//--------------------------------------
// Channel Control
//--------------------------------------
//--------------------------------------
//--------------------------------------
// AW Channel
//--------------------------------------
// Control of the AW handshake
always_comb begin
// AXI Handshakes
slv_resp_o.aw_ready = 1'b0;
aw_valid = 1'b0;
// `lock_aw_valid`, used to be protocol conform as it is not allowed to deassert
// a valid if there was no corresponding ready. As this process has to be able to inject
// an AXI ID into the counter of the AR channel on an ATOP, there could be a case where
// this process waits on `aw_ready` but in the mean time on the AR channel the counter gets
// full.
lock_aw_valid_d = lock_aw_valid_q;
load_aw_lock = 1'b0;
// AW ID counter and W FIFO
w_cnt_up = 1'b0;
// ATOP injection into ar counter
atop_inject = 1'b0;
// we had an arbitration decision, the valid is locked, wait for the transaction
if (lock_aw_valid_q) begin
aw_valid = 1'b1;
// transaction
if (aw_ready) begin
slv_resp_o.aw_ready = 1'b1;
lock_aw_valid_d = 1'b0;
load_aw_lock = 1'b1;
// inject the ATOP if necessary
atop_inject = slv_req_i.aw.atop[axi_pkg::ATOP_R_RESP] & AtopSupport;
end
end else begin
// An AW can be handled if `i_aw_id_counter` and `i_counter_open_w` are not full. An ATOP that
// requires an R response can be handled if additionally `i_ar_id_counter` is not full (this
// only applies if ATOPs are supported at all).
if (!aw_id_cnt_full && (w_open != {IdCounterWidth{1'b1}}) &&
(!(ar_id_cnt_full && slv_req_i.aw.atop[axi_pkg::ATOP_R_RESP]) ||
!AtopSupport)) begin
// There is a valid AW vector make the id lookup and go further, if it passes.
// Also stall if previous transmitted AWs still have active W's in flight.
// This prevents deadlocking of the W channel. The counters are there for the
// Handling of the B responses.
if (slv_req_i.aw_valid &&
((w_open == '0) || (w_select == slv_aw_select_i)) &&
(!aw_select_occupied || (slv_aw_select_i == lookup_aw_select))) begin
// connect the handshake
aw_valid = 1'b1;
// push arbitration to the W FIFO regardless, do not wait for the AW transaction
w_cnt_up = 1'b1;
// on AW transaction
if (aw_ready) begin
slv_resp_o.aw_ready = 1'b1;
atop_inject = slv_req_i.aw.atop[axi_pkg::ATOP_R_RESP] & AtopSupport;
// no AW transaction this cycle, lock the decision
end else begin
lock_aw_valid_d = 1'b1;
load_aw_lock = 1'b1;
end
end
end
end
end
// lock the valid signal, as the selection gets pushed into the W FIFO on first assertion,
// prevent further pushing
`FFLARN(lock_aw_valid_q, lock_aw_valid_d, load_aw_lock, '0, clk_i, rst_ni)
if (UniqueIds) begin : gen_unique_ids_aw
// If the `UniqueIds` parameter is set, each write transaction has an ID that is unique among
// all in-flight write transactions, or all write transactions with a given ID target the same
// master port as all write transactions with the same ID, or both. This means that the
// signals that are driven by the ID counters if this parameter is not set can instead be
// derived from existing signals. The ID counters can therefore be omitted.
assign lookup_aw_select = slv_aw_select_i;
assign aw_select_occupied = 1'b0;
assign aw_id_cnt_full = 1'b0;
end else begin : gen_aw_id_counter
axi_demux_id_counters #(
.AxiIdBits ( AxiLookBits ),
.CounterWidth ( IdCounterWidth ),
.mst_port_select_t ( select_t )
) i_aw_id_counter (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.lookup_axi_id_i ( slv_req_i.aw.id[0+:AxiLookBits] ),
.lookup_mst_select_o ( lookup_aw_select ),
.lookup_mst_select_occupied_o ( aw_select_occupied ),
.full_o ( aw_id_cnt_full ),
.inject_axi_id_i ( '0 ),
.inject_i ( 1'b0 ),
.push_axi_id_i ( slv_req_i.aw.id[0+:AxiLookBits] ),
.push_mst_select_i ( slv_aw_select_i ),
.push_i ( w_cnt_up ),
.pop_axi_id_i ( slv_resp_o.b.id[0+:AxiLookBits] ),
.pop_i ( slv_resp_o.b_valid & slv_req_i.b_ready )
);
// pop from ID counter on outward transaction
end
// This counter steers the demultiplexer of the W channel.
// `w_select` determines, which handshaking is connected.
// AWs are only forwarded, if the counter is empty, or `w_select_q` is the same as
// `slv_aw_select_i`.
counter #(
.WIDTH ( IdCounterWidth ),
.STICKY_OVERFLOW ( 1'b0 )
) i_counter_open_w (
.clk_i,
.rst_ni,
.clear_i ( 1'b0 ),
.en_i ( w_cnt_up ^ w_cnt_down ),
.load_i ( 1'b0 ),
.down_i ( w_cnt_down ),
.d_i ( '0 ),
.q_o ( w_open ),
.overflow_o ( /*not used*/ )
);
`FFLARN(w_select_q, slv_aw_select_i, w_cnt_up, select_t'(0), clk_i, rst_ni)
assign w_select = (|w_open) ? w_select_q : slv_aw_select_i;
assign w_select_valid = w_cnt_up | (|w_open);
//--------------------------------------
// W Channel
//--------------------------------------
//--------------------------------------
// B Channel
//--------------------------------------
logic [cf_math_pkg::idx_width(NoMstPorts)-1:0] b_idx;
// Arbitration of the different B responses
rr_arb_tree #(
.NumIn ( NoMstPorts ),
.DataType ( logic ),
.AxiVldRdy( 1'b1 ),
.LockIn ( 1'b1 )
) i_b_mux (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.flush_i( 1'b0 ),
.rr_i ( '0 ),
.req_i ( mst_b_valids ),
.gnt_o ( mst_b_readies ),
.data_i ( '0 ),
.gnt_i ( slv_req_i.b_ready ),
.req_o ( slv_resp_o.b_valid ),
.data_o ( ),
.idx_o ( b_idx )
);
always_comb begin
if (slv_resp_o.b_valid) begin
`AXI_SET_B_STRUCT(slv_resp_o.b, mst_resps_i[b_idx].b)
end else begin
slv_resp_o.b = '0;
end
end
//--------------------------------------
// AR Channel
//--------------------------------------
// control of the AR handshake
always_comb begin
// AXI Handshakes
slv_resp_o.ar_ready = 1'b0;
ar_valid = 1'b0;
// `lock_ar_valid`: Used to be protocol conform as it is not allowed to deassert `ar_valid`
// if there was no corresponding `ar_ready`. There is the possibility that an injection
// of a R response from an `atop` from the AW channel can change the occupied flag of the
// `i_ar_id_counter`, even if it was previously empty. This FF prevents the deassertion.
lock_ar_valid_d = lock_ar_valid_q;
load_ar_lock = 1'b0;
// AR id counter
ar_push = 1'b0;
// The process had an arbitration decision in a previous cycle, the valid is locked,
// wait for the AR transaction.
if (lock_ar_valid_q) begin
ar_valid = 1'b1;
// transaction
if (ar_ready) begin
slv_resp_o.ar_ready = 1'b1;
ar_push = 1'b1;
lock_ar_valid_d = 1'b0;
load_ar_lock = 1'b1;
end
end else begin
// The process can start handling AR transaction if `i_ar_id_counter` has space.
if (!ar_id_cnt_full) begin
// There is a valid AR, so look the ID up.
if (slv_req_i.ar_valid && (!ar_select_occupied ||
(slv_ar_select_i == lookup_ar_select))) begin
// connect the AR handshake
ar_valid = 1'b1;
// on transaction
if (ar_ready) begin
slv_resp_o.ar_ready = 1'b1;
ar_push = 1'b1;
// no transaction this cycle, lock the valid decision!
end else begin
lock_ar_valid_d = 1'b1;
load_ar_lock = 1'b1;
end
end
end
end
end
// this ff is needed so that ar does not get de-asserted if an atop gets injected
`FFLARN(lock_ar_valid_q, lock_ar_valid_d, load_ar_lock, '0, clk_i, rst_ni)
if (UniqueIds) begin : gen_unique_ids_ar
// If the `UniqueIds` parameter is set, each read transaction has an ID that is unique among
// all in-flight read transactions, or all read transactions with a given ID target the same
// master port as all read transactions with the same ID, or both. This means that the
// signals that are driven by the ID counters if this parameter is not set can instead be
// derived from existing signals. The ID counters can therefore be omitted.
assign lookup_ar_select = slv_ar_select_i;
assign ar_select_occupied = 1'b0;
assign ar_id_cnt_full = 1'b0;
end else begin : gen_ar_id_counter
axi_demux_id_counters #(
.AxiIdBits ( AxiLookBits ),
.CounterWidth ( IdCounterWidth ),
.mst_port_select_t ( select_t )
) i_ar_id_counter (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.lookup_axi_id_i ( slv_req_i.ar.id[0+:AxiLookBits] ),
.lookup_mst_select_o ( lookup_ar_select ),
.lookup_mst_select_occupied_o ( ar_select_occupied ),
.full_o ( ar_id_cnt_full ),
.inject_axi_id_i ( slv_req_i.aw.id[0+:AxiLookBits] ),
.inject_i ( atop_inject ),
.push_axi_id_i ( slv_req_i.ar.id[0+:AxiLookBits] ),
.push_mst_select_i ( slv_ar_select_i ),
.push_i ( ar_push ),
.pop_axi_id_i ( slv_resp_o.r.id[0+:AxiLookBits] ),
.pop_i ( slv_resp_o.r_valid & slv_req_i.r_ready & slv_resp_o.r.last )
);
end
//--------------------------------------
// R Channel
//--------------------------------------
logic [cf_math_pkg::idx_width(NoMstPorts)-1:0] r_idx;
// Arbitration of the different r responses
rr_arb_tree #(
.NumIn ( NoMstPorts ),
.DataType ( logic ),
.AxiVldRdy( 1'b1 ),
.LockIn ( 1'b1 )
) i_r_mux (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.flush_i( 1'b0 ),
.rr_i ( '0 ),
.req_i ( mst_r_valids ),
.gnt_o ( mst_r_readies ),
.data_i ( '0 ),
.gnt_i ( slv_req_i.r_ready ),
.req_o ( slv_resp_o.r_valid ),
.data_o (),
.idx_o ( r_idx )
);
always_comb begin
if (slv_resp_o.r_valid) begin
`AXI_SET_R_STRUCT(slv_resp_o.r, mst_resps_i[r_idx].r)
end else begin
slv_resp_o.r = '0;
end
end
assign ar_ready = ar_valid & mst_resps_i[slv_ar_select_i].ar_ready;
assign aw_ready = aw_valid & mst_resps_i[slv_aw_select_i].aw_ready;
// process that defines the individual demuxes and assignments for the arbitration
// as mst_reqs_o has to be drivem from the same always comb block!
always_comb begin
// default assignments
mst_reqs_o = '0;
slv_resp_o.w_ready = 1'b0;
w_cnt_down = 1'b0;
for (int unsigned i = 0; i < NoMstPorts; i++) begin
// AW channel
mst_reqs_o[i].aw = slv_req_i.aw;
mst_reqs_o[i].aw_valid = 1'b0;
if (aw_valid && (slv_aw_select_i == i)) begin
mst_reqs_o[i].aw_valid = 1'b1;
end
// W channel
mst_reqs_o[i].w = slv_req_i.w;
mst_reqs_o[i].w_valid = 1'b0;
if (w_select_valid && (w_select == i)) begin
mst_reqs_o[i].w_valid = slv_req_i.w_valid;
slv_resp_o.w_ready = mst_resps_i[i].w_ready;
w_cnt_down = slv_req_i.w_valid & mst_resps_i[i].w_ready & slv_req_i.w.last;
end
// B channel
mst_reqs_o[i].b_ready = mst_b_readies[i];
// AR channel
mst_reqs_o[i].ar = slv_req_i.ar;
mst_reqs_o[i].ar_valid = 1'b0;
if (ar_valid && (slv_ar_select_i == i)) begin
mst_reqs_o[i].ar_valid = 1'b1;
end
// R channel
mst_reqs_o[i].r_ready = mst_r_readies[i];
end
end
// unpack the response B and R channels for the arbitration
for (genvar i = 0; i < NoMstPorts; i++) begin : gen_b_channels
// assign mst_b_chans[i] = mst_resps_i[i].b;
assign mst_b_valids[i] = mst_resps_i[i].b_valid;
// assign mst_r_chans[i] = mst_resps_i[i].r;
assign mst_r_valids[i] = mst_resps_i[i].r_valid;
end
// Validate parameters.
// pragma translate_off
`ifndef VERILATOR
`ifndef XSIM
initial begin: validate_params
no_mst_ports: assume (NoMstPorts > 0) else
$fatal(1, "The Number of slaves (NoMstPorts) has to be at least 1");
AXI_ID_BITS: assume (AxiIdWidth >= AxiLookBits) else
$fatal(1, "AxiIdBits has to be equal or smaller than AxiIdWidth.");
end
default disable iff (!rst_ni);
aw_select: assume property( @(posedge clk_i) (slv_req_i.aw_valid |->
(slv_aw_select_i < NoMstPorts))) else
$fatal(1, "slv_aw_select_i is %d: AW has selected a slave that is not defined.\
NoMstPorts: %d", slv_aw_select_i, NoMstPorts);
ar_select: assume property( @(posedge clk_i) (slv_req_i.ar_valid |->
(slv_ar_select_i < NoMstPorts))) else
$fatal(1, "slv_ar_select_i is %d: AR has selected a slave that is not defined.\
NoMstPorts: %d", slv_ar_select_i, NoMstPorts);
aw_valid_stable: assert property( @(posedge clk_i) (aw_valid && !aw_ready) |=> aw_valid) else
$fatal(1, "aw_valid was deasserted, when aw_ready = 0 in last cycle.");
ar_valid_stable: assert property( @(posedge clk_i)
(ar_valid && !ar_ready) |=> ar_valid) else
$fatal(1, "ar_valid was deasserted, when ar_ready = 0 in last cycle.");
slv_aw_chan_stable: assert property( @(posedge clk_i) (aw_valid && !aw_ready)
|=> $stable(slv_req_i.aw)) else
$fatal(1, "slv_aw_chan unstable with valid set.");
slv_aw_select_stable: assert property( @(posedge clk_i) (aw_valid && !aw_ready)
|=> $stable(slv_aw_select_i)) else
$fatal(1, "slv_aw_select_i unstable with valid set.");
slv_ar_chan_stable: assert property( @(posedge clk_i) (ar_valid && !ar_ready)
|=> $stable(slv_req_i.ar)) else
$fatal(1, "slv_ar_chan unstable with valid set.");
slv_ar_select_stable: assert property( @(posedge clk_i) (ar_valid && !ar_ready)
|=> $stable(slv_ar_select_i)) else
$fatal(1, "slv_ar_select_i unstable with valid set.");
internal_ar_select: assert property( @(posedge clk_i)
(ar_valid |-> slv_ar_select_i < NoMstPorts))
else $fatal(1, "slv_ar_select_i illegal while ar_valid.");
internal_aw_select: assert property( @(posedge clk_i)
(aw_valid |-> slv_aw_select_i < NoMstPorts))
else $fatal(1, "slv_aw_select_i illegal while aw_valid.");
w_underflow: assert property( @(posedge clk_i)
((w_open == '0) && (w_cnt_up ^ w_cnt_down) |-> !w_cnt_down)) else
$fatal(1, "W counter underflowed!");
`ASSUME(NoAtopAllowed, !AtopSupport && slv_req_i.aw_valid |-> slv_req_i.aw.atop == '0)
`endif
`endif
// pragma translate_on
end
endmodule
module axi_demux_id_counters #(
// the lower bits of the AXI ID that should be considered, results in 2**AXI_ID_BITS counters
parameter int unsigned AxiIdBits = 2,
parameter int unsigned CounterWidth = 4,
parameter type mst_port_select_t = logic
) (
input clk_i, // Clock
input rst_ni, // Asynchronous reset active low
// lookup
input logic [AxiIdBits-1:0] lookup_axi_id_i,
output mst_port_select_t lookup_mst_select_o,
output logic lookup_mst_select_occupied_o,
// push
output logic full_o,
input logic [AxiIdBits-1:0] push_axi_id_i,
input mst_port_select_t push_mst_select_i,
input logic push_i,
// inject ATOPs in AR channel
input logic [AxiIdBits-1:0] inject_axi_id_i,
input logic inject_i,
// pop
input logic [AxiIdBits-1:0] pop_axi_id_i,
input logic pop_i
);
localparam int unsigned NoCounters = 2**AxiIdBits;
typedef logic [CounterWidth-1:0] cnt_t;
// registers, each gets loaded when push_en[i]
mst_port_select_t [NoCounters-1:0] mst_select_q;
// counter signals
logic [NoCounters-1:0] push_en, inject_en, pop_en, occupied, cnt_full;
//-----------------------------------
// Lookup
//-----------------------------------
assign lookup_mst_select_o = mst_select_q[lookup_axi_id_i];
assign lookup_mst_select_occupied_o = occupied[lookup_axi_id_i];
//-----------------------------------
// Push and Pop
//-----------------------------------
assign push_en = (push_i) ? (1 << push_axi_id_i) : '0;
assign inject_en = (inject_i) ? (1 << inject_axi_id_i) : '0;
assign pop_en = (pop_i) ? (1 << pop_axi_id_i) : '0;
assign full_o = |cnt_full;
// counters
for (genvar i = 0; i < NoCounters; i++) begin : gen_counters
logic cnt_en, cnt_down, overflow;
cnt_t cnt_delta, in_flight;
always_comb begin
unique case ({push_en[i], inject_en[i], pop_en[i]})
3'b001 : begin // pop_i = -1
cnt_en = 1'b1;
cnt_down = 1'b1;
cnt_delta = cnt_t'(1);
end
3'b010 : begin // inject_i = +1
cnt_en = 1'b1;
cnt_down = 1'b0;
cnt_delta = cnt_t'(1);
end
// 3'b011, inject_i & pop_i = 0 --> use default
3'b100 : begin // push_i = +1
cnt_en = 1'b1;
cnt_down = 1'b0;
cnt_delta = cnt_t'(1);
end
// 3'b101, push_i & pop_i = 0 --> use default
3'b110 : begin // push_i & inject_i = +2
cnt_en = 1'b1;
cnt_down = 1'b0;
cnt_delta = cnt_t'(2);
end
3'b111 : begin // push_i & inject_i & pop_i = +1
cnt_en = 1'b1;
cnt_down = 1'b0;
cnt_delta = cnt_t'(1);
end
default : begin // do nothing to the counters
cnt_en = 1'b0;
cnt_down = 1'b0;
cnt_delta = cnt_t'(0);
end
endcase
end
delta_counter #(
.WIDTH ( CounterWidth ),
.STICKY_OVERFLOW ( 1'b0 )
) i_in_flight_cnt (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.clear_i ( 1'b0 ),
.en_i ( cnt_en ),
.load_i ( 1'b0 ),
.down_i ( cnt_down ),
.delta_i ( cnt_delta ),
.d_i ( '0 ),
.q_o ( in_flight ),
.overflow_o ( overflow )
);
assign occupied[i] = |in_flight;
assign cnt_full[i] = overflow | (&in_flight);
// holds the selection signal for this id
`FFLARN(mst_select_q[i], push_mst_select_i, push_en[i], '0, clk_i, rst_ni)
// pragma translate_off
`ifndef VERILATOR
`ifndef XSIM
// Validate parameters.
cnt_underflow: assert property(
@(posedge clk_i) disable iff (~rst_ni) (pop_en[i] |=> !overflow)) else
$fatal(1, "axi_demux_id_counters > Counter: %0d underflowed.\
The reason is probably a faulty AXI response.", i);
`endif
`endif
// pragma translate_on
end
endmodule