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axi_sim_mem.sv
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axi_sim_mem.sv
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// Copyright (c) 2020 ETH Zurich and University of Bologna
// SPDX-License-Identifier: SHL-0.51
//
// Authors:
// - Andreas Kurth <[email protected]>
// - Samuel Riedel <[email protected]>
// - Michael Rogenmoser <[email protected]>
// - Thomas Benz <[email protected]>
`include "axi/typedef.svh"
/// Infinite (Simulation-Only) Memory with AXI Slave Port
///
/// The memory array is named `mem`, and it is *not* initialized or reset. This makes it possible to
/// load the memory of this module in simulation with an external `$readmem*` command, e.g.,
/// ```sv
/// axi_sim_mem #( ... ) i_sim_mem ( ... );
/// initial begin
/// $readmemh("file_with_memory_addrs_and_data.mem", i_sim_mem.mem);
/// $readmemh("file_with_memory_addrs_and_read_errors.mem", i_sim_mem.rerr);
/// $readmemh("file_with_memory_addrs_and_write_errors.mem", i_sim_mem.werr);
/// end
/// ```
/// `mem` is addressed (or indexed) byte-wise with `AddrWidth`-wide addresses.
///
/// This module does not support atomic operations (ATOPs).
module axi_sim_mem #(
/// AXI Address Width
parameter int unsigned AddrWidth = 32'd0,
/// AXI Data Width
parameter int unsigned DataWidth = 32'd0,
/// AXI ID Width
parameter int unsigned IdWidth = 32'd0,
/// AXI User Width.
parameter int unsigned UserWidth = 32'd0,
/// Number of request ports
parameter int unsigned NumPorts = 32'd1,
/// AXI4 request struct definition
parameter type axi_req_t = logic,
/// AXI4 response struct definition
parameter type axi_rsp_t = logic,
/// Warn on accesses to uninitialized bytes
parameter bit WarnUninitialized = 1'b0,
/// Default value for uninitialized memory (undefined, zeros, ones, random)
parameter UninitializedData = "undefined",
/// Clear error on access
parameter bit ClearErrOnAccess = 1'b0,
/// Application delay (measured after rising clock edge)
parameter time ApplDelay = 0ps,
/// Acquisition delay (measured after rising clock edge)
parameter time AcqDelay = 0ps
) (
/// Rising-edge clock
input logic clk_i,
/// Active-low reset
input logic rst_ni,
/// AXI4 request struct
input axi_req_t [NumPorts-1:0] axi_req_i,
/// AXI4 response struct
output axi_rsp_t [NumPorts-1:0] axi_rsp_o,
/// Memory monitor write valid. All `mon_w_*` outputs are only valid if this signal is high.
/// A write to the memory is visible on the `mon_w_*` outputs in the clock cycle after it has
/// happened.
output logic [NumPorts-1:0] mon_w_valid_o,
/// Memory monitor write address
output logic [NumPorts-1:0][AddrWidth-1:0] mon_w_addr_o,
/// Memory monitor write data
output logic [NumPorts-1:0][DataWidth-1:0] mon_w_data_o,
/// Memory monitor write ID
output logic [NumPorts-1:0][IdWidth-1:0] mon_w_id_o,
/// Memory monitor write user
output logic [NumPorts-1:0][UserWidth-1:0] mon_w_user_o,
/// Memory monitor write beat count
output axi_pkg::len_t [NumPorts-1:0] mon_w_beat_count_o,
/// Memory monitor write last
output logic [NumPorts-1:0] mon_w_last_o,
/// Memory monitor read valid. All `mon_r_*` outputs are only valid if this signal is high.
/// A read from the memory is visible on the `mon_w_*` outputs in the clock cycle after it has
/// happened.
output logic [NumPorts-1:0] mon_r_valid_o,
/// Memory monitor read address
output logic [NumPorts-1:0][AddrWidth-1:0] mon_r_addr_o,
/// Memory monitor read data
output logic [NumPorts-1:0][DataWidth-1:0] mon_r_data_o,
/// Memory monitor read ID
output logic [NumPorts-1:0][IdWidth-1:0] mon_r_id_o,
/// Memory monitor read user
output logic [NumPorts-1:0][UserWidth-1:0] mon_r_user_o,
/// Memory monitor read beat count
output axi_pkg::len_t [NumPorts-1:0] mon_r_beat_count_o,
/// Memory monitor read last
output logic [NumPorts-1:0] mon_r_last_o
);
localparam int unsigned StrbWidth = DataWidth / 8;
typedef logic [AddrWidth-1:0] addr_t;
typedef logic [DataWidth-1:0] data_t;
typedef logic [IdWidth-1:0] id_t;
typedef logic [StrbWidth-1:0] strb_t;
typedef logic [UserWidth-1:0] user_t;
`AXI_TYPEDEF_AW_CHAN_T(aw_t, addr_t, id_t, user_t)
`AXI_TYPEDEF_W_CHAN_T(w_t, data_t, strb_t, user_t)
`AXI_TYPEDEF_B_CHAN_T(b_t, id_t, user_t)
`AXI_TYPEDEF_AR_CHAN_T(ar_t, addr_t, id_t, user_t)
`AXI_TYPEDEF_R_CHAN_T(r_t, data_t, id_t, user_t)
typedef struct packed {
logic valid;
logic [AddrWidth-1:0] addr;
logic [DataWidth-1:0] data;
logic [IdWidth-1:0] id;
logic [UserWidth-1:0] user;
axi_pkg::len_t beat_count;
logic last;
} monitor_t;
monitor_t [NumPorts-1:0] mon_w, mon_r;
logic [7:0] mem[addr_t];
axi_pkg::resp_t rerr[addr_t] = '{default: axi_pkg::RESP_OKAY};
axi_pkg::resp_t werr[addr_t] = '{default: axi_pkg::RESP_OKAY};
// error happened in write burst
axi_pkg::resp_t [NumPorts-1:0] error_happened = axi_pkg::RESP_OKAY;
for (genvar i = 0; i < NumPorts; i++) begin
initial begin
automatic ar_t ar_queue[$];
automatic aw_t aw_queue[$];
automatic b_t b_queue[$];
automatic shortint unsigned r_cnt = 0, w_cnt = 0;
axi_rsp_o[i] = '0;
// Monitor interface
mon_w[i] = '0;
mon_r[i] = '0;
wait (rst_ni);
fork
// AW
forever begin
@(posedge clk_i);
#(ApplDelay);
axi_rsp_o[i].aw_ready = 1'b1;
#(AcqDelay - ApplDelay);
if (axi_req_i[i].aw_valid) begin
automatic aw_t aw = axi_req_i[i].aw;
aw_queue.push_back(aw);
end
end
// W
forever begin
@(posedge clk_i);
#(ApplDelay);
axi_rsp_o[i].w_ready = 1'b0;
mon_w[i] = '0;
if (aw_queue.size() != 0) begin
axi_rsp_o[i].w_ready = 1'b1;
#(AcqDelay - ApplDelay);
if (axi_req_i[i].w_valid) begin
automatic axi_pkg::burst_t burst = aw_queue[0].burst;
automatic axi_pkg::len_t len = aw_queue[0].len;
automatic axi_pkg::size_t size = aw_queue[0].size;
automatic addr_t addr = axi_pkg::beat_addr(aw_queue[0].addr, size, len, burst,
w_cnt);
mon_w[i].valid = 1'b1;
mon_w[i].addr = addr;
mon_w[i].data = axi_req_i[i].w.data;
mon_w[i].id = aw_queue[0].id;
mon_w[i].user = aw_queue[0].user;
mon_w[i].beat_count = w_cnt;
for (shortint unsigned
i_byte = axi_pkg::beat_lower_byte(aw_queue[0].addr, size, len, burst, StrbWidth, w_cnt);
i_byte <= axi_pkg::beat_upper_byte(aw_queue[0].addr, size, len, burst, StrbWidth, w_cnt);
i_byte++) begin
if (axi_req_i[i].w.strb[i_byte]) begin
automatic addr_t byte_addr = (addr / StrbWidth) * StrbWidth + i_byte;
mem[byte_addr] = axi_req_i[i].w.data[i_byte*8+:8];
error_happened[i] = axi_pkg::resp_precedence(werr[byte_addr], error_happened[i]);
if (ClearErrOnAccess)
werr[byte_addr] = axi_pkg::RESP_OKAY;
end
end
if (w_cnt == aw_queue[0].len) begin
automatic b_t b_beat = '0;
assert (axi_req_i[i].w.last) else $error("Expected last beat of W burst!");
b_beat.id = aw_queue[0].id;
b_beat.resp = error_happened[i];
b_queue.push_back(b_beat);
w_cnt = 0;
mon_w[i].last = 1'b1;
error_happened[i] = axi_pkg::RESP_OKAY;
void'(aw_queue.pop_front());
end else begin
assert (!axi_req_i[i].w.last) else $error("Did not expect last beat of W burst!");
w_cnt++;
end
end
end
end
// B
forever begin
@(posedge clk_i);
#(ApplDelay);
axi_rsp_o[i].b_valid = 1'b0;
if (b_queue.size() != 0) begin
axi_rsp_o[i].b = b_queue[0];
axi_rsp_o[i].b_valid = 1'b1;
#(AcqDelay - ApplDelay);
if (axi_req_i[i].b_ready) begin
void'(b_queue.pop_front());
end
end
end
// AR
forever begin
@(posedge clk_i);
#(ApplDelay);
axi_rsp_o[i].ar_ready = 1'b1;
#(AcqDelay - ApplDelay);
if (axi_req_i[i].ar_valid) begin
automatic ar_t ar = axi_req_i[i].ar;
ar_queue.push_back(ar);
end
end
// R
forever begin
@(posedge clk_i);
#(ApplDelay);
axi_rsp_o[i].r_valid = 1'b0;
mon_r[i] = '0;
if (ar_queue.size() != 0) begin
automatic axi_pkg::burst_t burst = ar_queue[0].burst;
automatic axi_pkg::len_t len = ar_queue[0].len;
automatic axi_pkg::size_t size = ar_queue[0].size;
automatic addr_t addr = axi_pkg::beat_addr(ar_queue[0].addr, size, len, burst, r_cnt);
automatic r_t r_beat = '0;
automatic data_t r_data = 'x; // compatibility reasons
r_beat.data = 'x;
r_beat.id = ar_queue[0].id;
r_beat.resp = axi_pkg::RESP_OKAY;
for (shortint unsigned
i_byte = axi_pkg::beat_lower_byte(ar_queue[0].addr, size, len, burst, StrbWidth, r_cnt);
i_byte <= axi_pkg::beat_upper_byte(ar_queue[0].addr, size, len, burst, StrbWidth, r_cnt);
i_byte++) begin
automatic addr_t byte_addr = (addr / StrbWidth) * StrbWidth + i_byte;
if (!mem.exists(byte_addr)) begin
if (WarnUninitialized) begin
$warning("Access to non-initialized byte at address 0x%016x by ID 0x%x.", byte_addr,
r_beat.id);
end
case (UninitializedData)
"random":
r_data[i_byte*8+:8] = $urandom;
"ones":
r_data[i_byte*8+:8] = '1;
"zeros":
r_data[i_byte*8+:8] = '0;
default:
r_data[i_byte*8+:8] = 'x;
endcase
end else begin
r_data[i_byte*8+:8] = mem[byte_addr];
end
r_beat.resp = axi_pkg::resp_precedence(rerr[byte_addr], r_beat.resp);
if (ClearErrOnAccess & axi_req_i[i].r_ready) begin
rerr[byte_addr] = axi_pkg::RESP_OKAY;
end
end
r_beat.data = r_data;
if (r_cnt == ar_queue[0].len) begin
r_beat.last = 1'b1;
mon_r[i].last = 1'b1;
end
axi_rsp_o[i].r = r_beat;
axi_rsp_o[i].r_valid = 1'b1;
mon_r[i].valid = 1'b1;
mon_r[i].addr = addr;
mon_r[i].data = r_beat.data;
mon_r[i].id = r_beat.id;
mon_r[i].user = ar_queue[0].user;
mon_r[i].beat_count = r_cnt;
#(AcqDelay - ApplDelay);
while (!axi_req_i[i].r_ready) begin
@(posedge clk_i);
#(AcqDelay);
mon_r[i] = '0;
end
if (r_beat.last) begin
r_cnt = 0;
void'(ar_queue.pop_front());
end else begin
r_cnt++;
end
end
end
join
end
// Assign the monitor output in the next clock cycle. Rationale: We only know whether we are
// writing until after `AcqDelay`. This means we could only provide the monitoring output for
// writes after `AcqDelay` in the same cycle, which is incompatible with ATI timing. Thus, we
// provide the monitoring output for writes (and for uniformity also for reads) in the next clock
// cycle.
initial begin
mon_w_valid_o[i] = '0;
mon_w_addr_o[i] = '0;
mon_w_data_o[i] = '0;
mon_w_id_o[i] = '0;
mon_w_user_o[i] = '0;
mon_w_beat_count_o[i] = '0;
mon_w_last_o[i] = '0;
mon_r_valid_o[i] = '0;
mon_r_addr_o[i] = '0;
mon_r_data_o[i] = '0;
mon_r_id_o[i] = '0;
mon_r_user_o[i] = '0;
mon_r_beat_count_o[i] = '0;
mon_r_last_o[i] = '0;
wait (rst_ni);
forever begin
@(posedge clk_i);
mon_w_valid_o[i] <= #(ApplDelay) mon_w[i].valid;
mon_w_addr_o[i] <= #(ApplDelay) mon_w[i].addr;
mon_w_data_o[i] <= #(ApplDelay) mon_w[i].data;
mon_w_id_o[i] <= #(ApplDelay) mon_w[i].id;
mon_w_user_o[i] <= #(ApplDelay) mon_w[i].user;
mon_w_beat_count_o[i] <= #(ApplDelay) mon_w[i].beat_count;
mon_w_last_o[i] <= #(ApplDelay) mon_w[i].last;
mon_r_valid_o[i] <= #(ApplDelay) mon_r[i].valid;
mon_r_addr_o[i] <= #(ApplDelay) mon_r[i].addr;
mon_r_data_o[i] <= #(ApplDelay) mon_r[i].data;
mon_r_id_o[i] <= #(ApplDelay) mon_r[i].id;
mon_r_user_o[i] <= #(ApplDelay) mon_r[i].user;
mon_r_beat_count_o[i] <= #(ApplDelay) mon_r[i].beat_count;
mon_r_last_o[i] <= #(ApplDelay) mon_r[i].last;
end
end
end
// Parameter Assertions
initial begin
assert (AddrWidth != 0) else $fatal("AddrWidth must be non-zero!", 1);
assert (DataWidth != 0) else $fatal("DataWidth must be non-zero!", 1);
assert (IdWidth != 0) else $fatal("IdWidth must be non-zero!", 1);
assert (UserWidth != 0) else $fatal("UserWidth must be non-zero!", 1);
end
endmodule
`include "axi/assign.svh"
/// Interface variant of [`axi_sim_mem`](module.axi_sim_mem).
///
/// See the documentation of the main module for the definition of ports and parameters.
module axi_sim_mem_intf #(
parameter int unsigned AXI_ADDR_WIDTH = 32'd0,
parameter int unsigned AXI_DATA_WIDTH = 32'd0,
parameter int unsigned AXI_ID_WIDTH = 32'd0,
parameter int unsigned AXI_USER_WIDTH = 32'd0,
parameter bit WARN_UNINITIALIZED = 1'b0,
parameter UNINITIALIZED_DATA = "undefined",
parameter bit ClearErrOnAccess = 1'b0,
parameter time APPL_DELAY = 0ps,
parameter time ACQ_DELAY = 0ps
) (
input logic clk_i,
input logic rst_ni,
AXI_BUS.Slave axi_slv,
output logic mon_w_valid_o,
output logic [AXI_ADDR_WIDTH-1:0] mon_w_addr_o,
output logic [AXI_DATA_WIDTH-1:0] mon_w_data_o,
output logic [AXI_ID_WIDTH-1:0] mon_w_id_o,
output logic [AXI_USER_WIDTH-1:0] mon_w_user_o,
output axi_pkg::len_t mon_w_beat_count_o,
output logic mon_w_last_o,
output logic mon_r_valid_o,
output logic [AXI_ADDR_WIDTH-1:0] mon_r_addr_o,
output logic [AXI_DATA_WIDTH-1:0] mon_r_data_o,
output logic [AXI_ID_WIDTH-1:0] mon_r_id_o,
output logic [AXI_USER_WIDTH-1:0] mon_r_user_o,
output axi_pkg::len_t mon_r_beat_count_o,
output logic mon_r_last_o
);
typedef logic [AXI_ADDR_WIDTH-1:0] axi_addr_t;
typedef logic [AXI_DATA_WIDTH-1:0] axi_data_t;
typedef logic [AXI_ID_WIDTH-1:0] axi_id_t;
typedef logic [AXI_DATA_WIDTH/8-1:0] axi_strb_t;
typedef logic [AXI_USER_WIDTH-1:0] axi_user_t;
`AXI_TYPEDEF_ALL(axi, axi_addr_t, axi_id_t, axi_data_t, axi_strb_t, axi_user_t)
axi_req_t axi_req;
axi_resp_t axi_rsp;
`AXI_ASSIGN_TO_REQ(axi_req, axi_slv)
`AXI_ASSIGN_FROM_RESP(axi_slv, axi_rsp)
axi_sim_mem #(
.AddrWidth (AXI_ADDR_WIDTH),
.DataWidth (AXI_DATA_WIDTH),
.IdWidth (AXI_ID_WIDTH),
.UserWidth (AXI_USER_WIDTH),
.axi_req_t (axi_req_t),
.axi_rsp_t (axi_resp_t),
.WarnUninitialized (WARN_UNINITIALIZED),
.UninitializedData (UNINITIALIZED_DATA),
.ClearErrOnAccess (ClearErrOnAccess),
.ApplDelay (APPL_DELAY),
.AcqDelay (ACQ_DELAY)
) i_sim_mem (
.clk_i,
.rst_ni,
.axi_req_i (axi_req),
.axi_rsp_o (axi_rsp),
.mon_w_valid_o,
.mon_w_addr_o,
.mon_w_data_o,
.mon_w_id_o,
.mon_w_user_o,
.mon_w_beat_count_o,
.mon_w_last_o,
.mon_r_valid_o,
.mon_r_addr_o,
.mon_r_data_o,
.mon_r_id_o,
.mon_r_user_o,
.mon_r_beat_count_o,
.mon_r_last_o
);
endmodule
/// Mutliport interface variant of [`axi_sim_mem`](module.axi_sim_mem).
///
/// See the documentation of the main module for the definition of ports and parameters.
module axi_sim_mem_multiport_intf #(
parameter int unsigned AXI_ADDR_WIDTH = 32'd0,
parameter int unsigned AXI_DATA_WIDTH = 32'd0,
parameter int unsigned AXI_ID_WIDTH = 32'd0,
parameter int unsigned AXI_USER_WIDTH = 32'd0,
parameter int unsigned NUM_PORTS = 32'd1,
parameter bit WARN_UNINITIALIZED = 1'b0,
parameter UNINITIALIZED_DATA = "undefined",
parameter bit ClearErrOnAccess = 1'b0,
parameter time APPL_DELAY = 0ps,
parameter time ACQ_DELAY = 0ps
) (
input logic clk_i,
input logic rst_ni,
AXI_BUS.Slave axi_slv[NUM_PORTS],
output logic [NUM_PORTS-1:0] mon_w_valid_o,
output logic [NUM_PORTS-1:0][AXI_ADDR_WIDTH-1:0] mon_w_addr_o,
output logic [NUM_PORTS-1:0][AXI_DATA_WIDTH-1:0] mon_w_data_o,
output logic [NUM_PORTS-1:0][AXI_ID_WIDTH-1:0] mon_w_id_o,
output logic [NUM_PORTS-1:0][AXI_USER_WIDTH-1:0] mon_w_user_o,
output axi_pkg::len_t [NUM_PORTS-1:0] mon_w_beat_count_o,
output logic [NUM_PORTS-1:0] mon_w_last_o,
output logic [NUM_PORTS-1:0] mon_r_valid_o,
output logic [NUM_PORTS-1:0][AXI_ADDR_WIDTH-1:0] mon_r_addr_o,
output logic [NUM_PORTS-1:0][AXI_DATA_WIDTH-1:0] mon_r_data_o,
output logic [NUM_PORTS-1:0][AXI_ID_WIDTH-1:0] mon_r_id_o,
output logic [NUM_PORTS-1:0][AXI_USER_WIDTH-1:0] mon_r_user_o,
output axi_pkg::len_t [NUM_PORTS-1:0] mon_r_beat_count_o,
output logic [NUM_PORTS-1:0] mon_r_last_o
);
typedef logic [AXI_ADDR_WIDTH-1:0] axi_addr_t;
typedef logic [AXI_DATA_WIDTH-1:0] axi_data_t;
typedef logic [AXI_ID_WIDTH-1:0] axi_id_t;
typedef logic [AXI_DATA_WIDTH/8-1:0] axi_strb_t;
typedef logic [AXI_USER_WIDTH-1:0] axi_user_t;
`AXI_TYPEDEF_ALL(axi, axi_addr_t, axi_id_t, axi_data_t, axi_strb_t, axi_user_t)
axi_req_t [NUM_PORTS-1:0] axi_req;
axi_resp_t [NUM_PORTS-1:0] axi_rsp;
for (genvar i = 0; i < NUM_PORTS; i++) begin
`AXI_ASSIGN_TO_REQ(axi_req[i], axi_slv[i])
`AXI_ASSIGN_FROM_RESP(axi_slv[i], axi_rsp[i])
end
axi_sim_mem #(
.AddrWidth (AXI_ADDR_WIDTH),
.DataWidth (AXI_DATA_WIDTH),
.IdWidth (AXI_ID_WIDTH),
.UserWidth (AXI_USER_WIDTH),
.NumPorts (NUM_PORTS),
.axi_req_t (axi_req_t),
.axi_rsp_t (axi_resp_t),
.WarnUninitialized (WARN_UNINITIALIZED),
.UninitializedData (UNINITIALIZED_DATA),
.ClearErrOnAccess (ClearErrOnAccess),
.ApplDelay (APPL_DELAY),
.AcqDelay (ACQ_DELAY)
) i_sim_mem (
.clk_i,
.rst_ni,
.axi_req_i (axi_req),
.axi_rsp_o (axi_rsp),
.mon_w_valid_o,
.mon_w_addr_o,
.mon_w_data_o,
.mon_w_id_o,
.mon_w_user_o,
.mon_w_beat_count_o,
.mon_w_last_o,
.mon_r_valid_o,
.mon_r_addr_o,
.mon_r_data_o,
.mon_r_id_o,
.mon_r_user_o,
.mon_r_beat_count_o,
.mon_r_last_o
);
endmodule