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axi_lite_mailbox.sv
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axi_lite_mailbox.sv
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// Copyright (c) 2020 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 <wroennin@iis.ee.ethz.ch>
// - Andreas Kurth <akurth@iis.ee.ethz.ch>
// Description: A mailbox with two AXI4-Lite slave ports and associated interrupt requests.
// See `doc/axi_lite_mailbox.md` for the documentation, including the definition
// of parameters and ports.
`include "common_cells/registers.svh"
module axi_lite_mailbox #(
parameter int unsigned MailboxDepth = 32'd0,
parameter bit unsigned IrqEdgeTrig = 1'b0,
parameter bit unsigned IrqActHigh = 1'b1,
parameter int unsigned AxiAddrWidth = 32'd0,
parameter int unsigned AxiDataWidth = 32'd0,
parameter type req_lite_t = logic,
parameter type resp_lite_t = logic,
// DEPENDENT PARAMETERS, DO NOT OVERRIDE!
parameter type addr_t = logic [AxiAddrWidth-1:0]
) (
input logic clk_i, // Clock
input logic rst_ni, // Asynchronous reset active low
input logic test_i, // Testmode enable
// slave ports [1:0]
input req_lite_t [1:0] slv_reqs_i,
output resp_lite_t [1:0] slv_resps_o,
output logic [1:0] irq_o, // interrupt output for each port
input addr_t [1:0] base_addr_i // base address for each port
);
localparam int unsigned FifoUsageWidth = $clog2(MailboxDepth);
typedef logic [AxiDataWidth-1:0] data_t;
// usage type of the mailbox FIFO, also the type of the threshold comparison
// is one bit wider, MSB is the fifo_full flag of the respective fifo
typedef logic [FifoUsageWidth:0] usage_t;
// signal declaration for the mailbox FIFO's, signal index is the port
logic [1:0] mbox_full, mbox_empty; // index is the instantiated mailbox FIFO
logic [1:0] mbox_push, mbox_pop; // index is port
logic [1:0] w_mbox_flush, r_mbox_flush; // index is port
data_t [1:0] mbox_w_data, mbox_r_data; // index is port
usage_t [1:0] mbox_usage; // index is the instantiated mailbox FIFO
// interrupt request from this slave port, level triggered, active high --> convert
logic [1:0] slv_irq;
logic [1:0] clear_irq;
axi_lite_mailbox_slave #(
.MailboxDepth ( MailboxDepth ),
.AxiAddrWidth ( AxiAddrWidth ),
.AxiDataWidth ( AxiDataWidth ),
.req_lite_t ( req_lite_t ),
.resp_lite_t ( resp_lite_t ),
.addr_t ( addr_t ),
.data_t ( data_t ),
.usage_t ( usage_t ) // fill pointer from MBOX FIFO
) i_slv_port_0 (
.clk_i, // Clock
.rst_ni, // Asynchronous reset active low
// slave port
.slv_req_i ( slv_reqs_i[0] ),
.slv_resp_o ( slv_resps_o[0] ),
.base_addr_i ( base_addr_i[0] ), // base address for the slave port
// write FIFO port
.mbox_w_data_o ( mbox_w_data[0] ),
.mbox_w_full_i ( mbox_full[0] ),
.mbox_w_push_o ( mbox_push[0] ),
.mbox_w_flush_o ( w_mbox_flush[0] ),
.mbox_w_usage_i ( mbox_usage[0] ),
// read FIFO port
.mbox_r_data_i ( mbox_r_data[0] ),
.mbox_r_empty_i ( mbox_empty[1] ),
.mbox_r_pop_o ( mbox_pop[0] ),
.mbox_r_flush_o ( r_mbox_flush[0] ),
.mbox_r_usage_i ( mbox_usage[1] ),
// interrupt output, level triggered, active high, conversion in top
.irq_o ( slv_irq[0] ),
.clear_irq_o ( clear_irq[0] )
);
axi_lite_mailbox_slave #(
.MailboxDepth ( MailboxDepth ),
.AxiAddrWidth ( AxiAddrWidth ),
.AxiDataWidth ( AxiDataWidth ),
.req_lite_t ( req_lite_t ),
.resp_lite_t ( resp_lite_t ),
.addr_t ( addr_t ),
.data_t ( data_t ),
.usage_t ( usage_t ) // fill pointer from MBOX FIFO
) i_slv_port_1 (
.clk_i, // Clock
.rst_ni, // Asynchronous reset active low
// slave port
.slv_req_i ( slv_reqs_i[1] ),
.slv_resp_o ( slv_resps_o[1] ),
.base_addr_i ( base_addr_i[1] ), // base address for the slave port
// write FIFO port
.mbox_w_data_o ( mbox_w_data[1] ),
.mbox_w_full_i ( mbox_full[1] ),
.mbox_w_push_o ( mbox_push[1] ),
.mbox_w_flush_o ( w_mbox_flush[1] ),
.mbox_w_usage_i ( mbox_usage[1] ),
// read FIFO port
.mbox_r_data_i ( mbox_r_data[1] ),
.mbox_r_empty_i ( mbox_empty[0] ),
.mbox_r_pop_o ( mbox_pop[1] ),
.mbox_r_flush_o ( r_mbox_flush[1] ),
.mbox_r_usage_i ( mbox_usage[0] ),
// interrupt output, level triggered, active high, conversion in top
.irq_o ( slv_irq[1] ),
.clear_irq_o ( clear_irq[1] )
);
// the usage gets concatinated with the full flag to have consistent threshold detection
logic [FifoUsageWidth-1:0] mbox_0_to_1_usage, mbox_1_to_0_usage;
fifo_v3 #(
.FALL_THROUGH ( 1'b0 ),
.DEPTH ( MailboxDepth ),
.dtype ( data_t )
) i_mbox_0_to_1 (
.clk_i,
.rst_ni,
.testmode_i( test_i ),
.flush_i ( w_mbox_flush[0] | r_mbox_flush[1] ),
.full_o ( mbox_full[0] ),
.empty_o ( mbox_empty[0] ),
.usage_o ( mbox_0_to_1_usage ),
.data_i ( mbox_w_data[0] ),
.push_i ( mbox_push[0] ),
.data_o ( mbox_r_data[1] ),
.pop_i ( mbox_pop[1] )
);
// assign the MSB of the FIFO to the correct usage signal
assign mbox_usage[0] = {mbox_full[0], mbox_0_to_1_usage};
fifo_v3 #(
.FALL_THROUGH ( 1'b0 ),
.DEPTH ( MailboxDepth ),
.dtype ( data_t )
) i_mbox_1_to_0 (
.clk_i,
.rst_ni,
.testmode_i( test_i ),
.flush_i ( w_mbox_flush[1] | r_mbox_flush[0] ),
.full_o ( mbox_full[1] ),
.empty_o ( mbox_empty[1] ),
.usage_o ( mbox_1_to_0_usage ),
.data_i ( mbox_w_data[1] ),
.push_i ( mbox_push[1] ),
.data_o ( mbox_r_data[0] ),
.pop_i ( mbox_pop[0] )
);
assign mbox_usage[1] = {mbox_full[1], mbox_1_to_0_usage};
for (genvar i = 0; i < 2; i++) begin : gen_irq_conversion
if (IrqEdgeTrig) begin : gen_irq_edge
logic irq_q, irq_d, update_irq;
always_comb begin
// default assignments
irq_d = irq_q;
update_irq = 1'b0;
// init the irq and pulse only on update
irq_o[i] = ~IrqActHigh;
if (clear_irq[i]) begin
irq_d = 1'b0;
update_irq = 1'b1;
end else if (!irq_q && slv_irq[i]) begin
irq_d = 1'b1;
update_irq = 1'b1;
irq_o[i] = IrqActHigh; // on update of the register pulse the irq signal
end
end
`FFLARN(irq_q, irq_d, update_irq, '0, clk_i, rst_ni)
end else begin : gen_irq_level
assign irq_o[i] = (IrqActHigh) ? slv_irq[i] : ~slv_irq[i];
end
end
// pragma translate_off
`ifndef VERILATOR
initial begin : proc_check_params
mailbox_depth: assert (MailboxDepth > 1) else $fatal(1, "MailboxDepth has to be at least 2");
axi_addr_width: assert (AxiAddrWidth > 0) else $fatal(1, "AxiAddrWidth has to be > 0");
axi_data_width: assert (AxiDataWidth > 0) else $fatal(1, "AxiDataWidth has to be > 0");
end
`endif
// pragma translate_on
endmodule
`include "axi/typedef.svh"
// slave port module
module axi_lite_mailbox_slave #(
parameter int unsigned MailboxDepth = 32'd16,
parameter int unsigned AxiAddrWidth = 32'd32,
parameter int unsigned AxiDataWidth = 32'd32,
parameter type req_lite_t = logic,
parameter type resp_lite_t = logic,
parameter type addr_t = logic [AxiAddrWidth-1:0],
parameter type data_t = logic [AxiDataWidth-1:0],
parameter type usage_t = logic // fill pointer from MBOX FIFO
) (
input logic clk_i, // Clock
input logic rst_ni, // Asynchronous reset active low
// slave port
input req_lite_t slv_req_i,
output resp_lite_t slv_resp_o,
input addr_t base_addr_i, // base address for the slave port
// write FIFO port
output data_t mbox_w_data_o,
input logic mbox_w_full_i,
output logic mbox_w_push_o,
output logic mbox_w_flush_o,
input usage_t mbox_w_usage_i,
// read FIFO port
input data_t mbox_r_data_i,
input logic mbox_r_empty_i,
output logic mbox_r_pop_o,
output logic mbox_r_flush_o,
input usage_t mbox_r_usage_i,
// interrupt output, level triggered, active high, conversion in top
output logic irq_o,
output logic clear_irq_o // clear the edge trigger irq register in `axi_lite_mailbox`
);
`AXI_LITE_TYPEDEF_B_CHAN_T(b_chan_lite_t)
`AXI_LITE_TYPEDEF_R_CHAN_T(r_chan_lite_t, data_t)
localparam int unsigned NoRegs = 32'd10;
typedef enum logic [3:0] {
MBOXW = 4'd0, // Mailbox write register
MBOXR = 4'd1, // Mailbox read register
STATUS = 4'd2, // Mailbox status register
ERROR = 4'd3, // Mailbox error register
WIRQT = 4'd4, // Write interrupt request threshold register
RIRQT = 4'd5, // Read interrupt request threshold register
IRQS = 4'd6, // Interrupt request status register
IRQEN = 4'd7, // Interrupt request enable register
IRQP = 4'd8, // Interrupt request pending register
CTRL = 4'd9 // Mailbox control register
} reg_e;
// address map rule struct, as required from `addr_decode` from `common_cells`
typedef struct packed {
int unsigned idx;
addr_t start_addr;
addr_t end_addr;
} rule_t;
// output type of the address decoders, to be casted onto the enum type `reg_e`
typedef logic [$clog2(NoRegs)-1:0] idx_t;
// LITE response signals, go into the output spill registers to prevent combinational response
logic b_valid, b_ready;
b_chan_lite_t b_chan;
logic r_valid, r_ready;
r_chan_lite_t r_chan;
// address map generation
rule_t [NoRegs-1:0] addr_map;
for (genvar i = 0; i < NoRegs; i++) begin : gen_addr_map
assign addr_map[i] = '{
idx: i,
start_addr: base_addr_i + i * (AxiDataWidth / 8),
end_addr: base_addr_i + (i + 1) * (AxiDataWidth / 8),
default: '0
};
end
// address decode flags
idx_t w_reg_idx, r_reg_idx;
logic dec_w_valid, dec_r_valid;
// mailbox register signal declarations, get extended when read, some of these regs
// are build combinationally, indicated by the absence of the `*_d` signal
logic [3:0] status_q; // mailbox status register (read only)
logic [1:0] error_q, error_d; // mailbox error register
data_t wirqt_q, wirqt_d; // write interrupt request threshold register
data_t rirqt_q, rirqt_d; // read interrupt request threshold register
logic [2:0] irqs_q, irqs_d; // interrupt request status register
logic [2:0] irqen_q, irqen_d; // interrupt request enable register
logic [2:0] irqp_q; // interrupt request pending register (read only)
logic [1:0] ctrl_q; // mailbox control register
logic update_regs; // register enable signal
// register instantiation
`FFLARN(error_q, error_d, update_regs, '0, clk_i, rst_ni)
`FFLARN(wirqt_q, wirqt_d, update_regs, '0, clk_i, rst_ni)
`FFLARN(rirqt_q, rirqt_d, update_regs, '0, clk_i, rst_ni)
`FFLARN(irqs_q, irqs_d, update_regs, '0, clk_i, rst_ni)
`FFLARN(irqen_q, irqen_d, update_regs, '0, clk_i, rst_ni)
// Mailbox FIFO data assignments
for (genvar i = 0; i < (AxiDataWidth/8); i++) begin : gen_w_mbox_data
assign mbox_w_data_o[i*8+:8] = slv_req_i.w.strb[i] ? slv_req_i.w.data[i*8+:8] : '0;
end
// combinational mailbox register assignments, for the read only registers
assign status_q = { mbox_r_usage_i > usage_t'(rirqt_q),
mbox_w_usage_i > usage_t'(wirqt_q),
mbox_w_full_i,
mbox_r_empty_i };
assign irqp_q = irqs_q & irqen_q; // interrupt request pending is bit wise and
assign ctrl_q = {mbox_r_flush_o, mbox_w_flush_o}; // read ctrl_q is flush signals
assign irq_o = |irqp_q; // generate an active-high level irq
always_comb begin
// slave port channel outputs for the AW, W and R channel, other driven from spill register
slv_resp_o.aw_ready = 1'b0;
slv_resp_o.w_ready = 1'b0;
b_chan = '{resp: axi_pkg::RESP_SLVERR};
b_valid = 1'b0;
slv_resp_o.ar_ready = 1'b0;
r_chan = '{data: '0, resp: axi_pkg::RESP_SLVERR};
r_valid = 1'b0;
// Default assignments for the internal registers
error_d = error_q; // mailbox error register
wirqt_d = wirqt_q; // write interrupt request threshold register
rirqt_d = rirqt_q; // read interrupt request threshold register
irqs_d = irqs_q; // interrupt request status register
irqen_d = irqen_q; // interrupt request enable register
update_regs = 1'b0; // register update enable signal
// MBOX FIFO control signals
mbox_w_push_o = 1'b0;
mbox_w_flush_o = 1'b0;
mbox_r_pop_o = 1'b0;
mbox_r_flush_o = 1'b0;
// clear the edge triggered irq register if it is instantiated
clear_irq_o = 1'b0;
// -------------------------------------------
// Set the read and write interrupt FF (irqs), when the threshold triggers
// -------------------------------------------
// strict threshold interrupt these fields get cleared by acknowledge on write onto the register
// read trigger, see status_q above
if (!irqs_q[1] && status_q[3]) begin
irqs_d[1] = 1'b1;
update_regs = 1'b1;
end
// write trigger, see status_q above
if (!irqs_q[0] && status_q[2]) begin
irqs_d[0] = 1'b1;
update_regs = 1'b1;
end
// -------------------------------------------
// Read registers
// -------------------------------------------
// The logic of the read and write channels have to be in the same `always_comb` block.
// The reason is that the error register could be cleared in the same cycle as a read from
// the mailbox FIFO generates a new error. In this case the error is NOT cleared. Instead
// it will generate a new irq when it is edge triggered, or the level will stay at its
// active state.
// Check if there is a pending read request on the slave port.
if (slv_req_i.ar_valid) begin
// set the right read channel output depending on the address decoding
if (dec_r_valid) begin
// when decode not valid, send the default slaveerror
// read the right register when the transfer happens and decode is valid
unique case (reg_e'(r_reg_idx))
MBOXW: r_chan = '{data: data_t'( 32'hFEEDC0DE ), resp: axi_pkg::RESP_OKAY};
MBOXR: begin
if (!mbox_r_empty_i) begin
r_chan = '{data: data_t'( mbox_r_data_i ), resp: axi_pkg::RESP_OKAY};
mbox_r_pop_o = 1'b1;
end else begin
// read mailbox is empty, set the read error Flip flop and respond with error
r_chan = '{data: data_t'( 32'hFEEDDEAD ), resp: axi_pkg::RESP_SLVERR};
error_d[0] = 1'b1;
irqs_d[2] = 1'b1;
update_regs = 1'b1;
end
end
STATUS: r_chan = '{data: data_t'( status_q ), resp: axi_pkg::RESP_OKAY};
ERROR: begin // clear the error register
r_chan = '{data: data_t'( error_q ), resp: axi_pkg::RESP_OKAY};
error_d = '0;
update_regs = 1'b1;
end
WIRQT: r_chan = '{data: data_t'( wirqt_q ), resp: axi_pkg::RESP_OKAY};
RIRQT: r_chan = '{data: data_t'( rirqt_q ), resp: axi_pkg::RESP_OKAY};
IRQS: r_chan = '{data: data_t'( irqs_q ), resp: axi_pkg::RESP_OKAY};
IRQEN: r_chan = '{data: data_t'( irqen_q ), resp: axi_pkg::RESP_OKAY};
IRQP: r_chan = '{data: data_t'( irqp_q ), resp: axi_pkg::RESP_OKAY};
CTRL: r_chan = '{data: data_t'( ctrl_q ), resp: axi_pkg::RESP_OKAY};
default: /*do nothing*/;
endcase
end
r_valid = 1'b1;
if (r_ready) begin
slv_resp_o.ar_ready = 1'b1;
end
end // read register
// -------------------------------------------
// Write registers
// -------------------------------------------
// Wait for control and write data to be valid.
if (slv_req_i.aw_valid && slv_req_i.w_valid) begin
// Can do the handshake here as the b response goes into a spill register with latency one.
// Without the B spill register, the B channel would violate the AXI stable requirement.
b_valid = 1'b1;
if (b_ready) begin
// write to the register if required
if (dec_w_valid) begin
unique case (reg_e'(w_reg_idx))
MBOXW: begin
if (!mbox_w_full_i) begin
mbox_w_push_o = 1'b1;
b_chan = '{resp: axi_pkg::RESP_OKAY};
end else begin
// response with default error and set the error FF
error_d[1] = 1'b1;
irqs_d[2] = 1'b1;
update_regs = 1'b1;
end
end
// MBOXR: read only
// STATUS: read only
// ERROR: read only
WIRQT: begin
for (int unsigned i = 0; i < AxiDataWidth/8; i++) begin
wirqt_d[i*8+:8] = slv_req_i.w.strb[i] ? slv_req_i.w.data[i*8+:8] : 8'b0000_0000;
end
if (wirqt_d >= data_t'(MailboxDepth)) begin
// the `-1` is to have the interrupt fireing when the FIFO is comletely full
wirqt_d = data_t'(MailboxDepth) - data_t'(32'd1); // Threshold to maximal value
end
update_regs = 1'b1;
b_chan = '{resp: axi_pkg::RESP_OKAY};
end
RIRQT: begin
for (int unsigned i = 0; i < AxiDataWidth/8; i++) begin
rirqt_d[i*8+:8] = slv_req_i.w.strb[i] ? slv_req_i.w.data[i*8+:8] : 8'b0000_0000;
end
if (rirqt_d >= data_t'(MailboxDepth)) begin
// Threshold to maximal value, minus two to prevent overflow in usage
rirqt_d = data_t'(MailboxDepth) - data_t'(32'd1);
end
update_regs = 1'b1;
b_chan = '{resp: axi_pkg::RESP_OKAY};
end
IRQS: begin
// Acknowledge and clear the register by asserting the respective one
if (slv_req_i.w.strb[0]) begin
// *_d signal is set in the beginning of this process, prevent accidental
// overwrite of not acknowledged irq
irqs_d[2] = slv_req_i.w.data[2] ? 1'b0 : irqs_d[2]; // Error irq status
irqs_d[1] = slv_req_i.w.data[1] ? 1'b0 : irqs_d[1]; // Read irq status
irqs_d[0] = slv_req_i.w.data[0] ? 1'b0 : irqs_d[0]; // Write irq status
clear_irq_o = 1'b1;
update_regs = 1'b1;
end
b_chan = '{resp: axi_pkg::RESP_OKAY};
end
IRQEN: begin
if (slv_req_i.w.strb[0]) begin
irqen_d[2:0] = slv_req_i.w.data[2:0]; // set the irq enable bits
update_regs = 1'b1;
end
b_chan = '{resp: axi_pkg::RESP_OKAY};
end
// IRQP: read only
CTRL: begin
if (slv_req_i.w.strb[0]) begin
mbox_r_flush_o = slv_req_i.w.data[1]; // Flush read FIFO
mbox_w_flush_o = slv_req_i.w.data[0]; // Flush write FIFO
end
b_chan = '{resp: axi_pkg::RESP_OKAY};
end
default : /* use default b_chan */;
endcase
end
slv_resp_o.aw_ready = 1'b1;
slv_resp_o.w_ready = 1'b1;
end // if (b_ready): Does not violate AXI spec, because the ready comes from an internal
// spill register and does not propagate the ready from the b channel.
end // write register
end
// address decoder and response FIFOs for the LITE channel, the port can take a new transaction if
// these FIFOs are not full, not fall through to prevent combinational paths to the return path
addr_decode #(
.NoIndices( NoRegs ),
.NoRules ( NoRegs ),
.addr_t ( addr_t ),
.rule_t ( rule_t )
) i_waddr_decode (
.addr_i ( slv_req_i.aw.addr ),
.addr_map_i ( addr_map ),
.idx_o ( w_reg_idx ),
.dec_valid_o ( dec_w_valid ),
.dec_error_o ( /*not used*/ ),
.en_default_idx_i ( 1'b0 ),
.default_idx_i ( '0 )
);
spill_register #(
.T ( b_chan_lite_t )
) i_b_chan_outp (
.clk_i,
.rst_ni,
.valid_i ( b_valid ),
.ready_o ( b_ready ),
.data_i ( b_chan ),
.valid_o ( slv_resp_o.b_valid ),
.ready_i ( slv_req_i.b_ready ),
.data_o ( slv_resp_o.b )
);
addr_decode #(
.NoIndices( NoRegs ),
.NoRules ( NoRegs ),
.addr_t ( addr_t ),
.rule_t ( rule_t )
) i_raddr_decode (
.addr_i ( slv_req_i.ar.addr ),
.addr_map_i ( addr_map ),
.idx_o ( r_reg_idx ),
.dec_valid_o ( dec_r_valid ),
.dec_error_o ( /*not used*/ ),
.en_default_idx_i ( 1'b0 ),
.default_idx_i ( '0 )
);
spill_register #(
.T ( r_chan_lite_t )
) i_r_chan_outp (
.clk_i,
.rst_ni,
.valid_i ( r_valid ),
.ready_o ( r_ready ),
.data_i ( r_chan ),
.valid_o ( slv_resp_o.r_valid ),
.ready_i ( slv_req_i.r_ready ),
.data_o ( slv_resp_o.r )
);
// pragma translate_off
`ifndef VERILATOR
initial begin : proc_check_params
assert (AxiAddrWidth == $bits(slv_req_i.aw.addr)) else $fatal(1, "AW AxiAddrWidth mismatch");
assert (AxiDataWidth == $bits(slv_req_i.w.data)) else $fatal(1, " W AxiDataWidth mismatch");
assert (AxiAddrWidth == $bits(slv_req_i.ar.addr)) else $fatal(1, "AR AxiAddrWidth mismatch");
assert (AxiDataWidth == $bits(slv_resp_o.r.data)) else $fatal(1, " R AxiDataWidth mismatch");
end
`endif
// pragma translate_on
endmodule
`include "axi/assign.svh"
module axi_lite_mailbox_intf #(
parameter int unsigned MAILBOX_DEPTH = 32'd0,
parameter bit unsigned IRQ_EDGE_TRIG = 1'b0,
parameter bit unsigned IRQ_ACT_HIGH = 1'b1,
parameter int unsigned AXI_ADDR_WIDTH = 32'd0,
parameter int unsigned AXI_DATA_WIDTH = 32'd0,
// DEPENDENT PARAMETERS, DO NOT OVERRIDE!
parameter type addr_t = logic [AXI_ADDR_WIDTH-1:0]
) (
input logic clk_i, // Clock
input logic rst_ni, // Asynchronous reset active low
input logic test_i, // Testmode enable
AXI_LITE.Slave slv [1:0], // slave ports [1:0]
output logic [1:0] irq_o, // interrupt output for each port
input addr_t [1:0] base_addr_i // base address for each port
);
typedef logic [AXI_DATA_WIDTH-1:0] data_t;
typedef logic [AXI_DATA_WIDTH/8-1:0] strb_t;
`AXI_LITE_TYPEDEF_AW_CHAN_T(aw_chan_lite_t, addr_t)
`AXI_LITE_TYPEDEF_W_CHAN_T(w_chan_lite_t, data_t, strb_t)
`AXI_LITE_TYPEDEF_B_CHAN_T(b_chan_lite_t)
`AXI_LITE_TYPEDEF_AR_CHAN_T(ar_chan_lite_t, addr_t)
`AXI_LITE_TYPEDEF_R_CHAN_T(r_chan_lite_t, data_t)
`AXI_LITE_TYPEDEF_REQ_T(req_lite_t, aw_chan_lite_t, w_chan_lite_t, ar_chan_lite_t)
`AXI_LITE_TYPEDEF_RESP_T(resp_lite_t, b_chan_lite_t, r_chan_lite_t)
req_lite_t [1:0] slv_reqs;
resp_lite_t [1:0] slv_resps;
for (genvar i = 0; i < 2; i++) begin : gen_port_assign
`AXI_LITE_ASSIGN_TO_REQ(slv_reqs[i], slv[i])
`AXI_LITE_ASSIGN_FROM_RESP(slv[i], slv_resps[i])
end
axi_lite_mailbox #(
.MailboxDepth ( MAILBOX_DEPTH ),
.IrqEdgeTrig ( IRQ_EDGE_TRIG ),
.IrqActHigh ( IRQ_ACT_HIGH ),
.AxiAddrWidth ( AXI_ADDR_WIDTH ),
.AxiDataWidth ( AXI_DATA_WIDTH ),
.req_lite_t ( req_lite_t ),
.resp_lite_t ( resp_lite_t )
) i_axi_lite_mailbox (
.clk_i, // Clock
.rst_ni, // Asynchronous reset active low
.test_i, // Testmode enable
// slave ports [1:0]
.slv_reqs_i ( slv_reqs ),
.slv_resps_o ( slv_resps ),
.irq_o, // interrupt output for each port
.base_addr_i // base address for each port
);
// pragma translate_off
`ifndef VERILATOR
initial begin
assert (slv[0].AXI_ADDR_WIDTH == AXI_ADDR_WIDTH)
else $fatal(1, "LITE Interface [0] AXI_ADDR_WIDTH missmatch!");
assert (slv[1].AXI_ADDR_WIDTH == AXI_ADDR_WIDTH)
else $fatal(1, "LITE Interface [1] AXI_ADDR_WIDTH missmatch!");
assert (slv[0].AXI_DATA_WIDTH == AXI_DATA_WIDTH)
else $fatal(1, "LITE Interface [0] AXI_DATA_WIDTH missmatch!");
assert (slv[1].AXI_DATA_WIDTH == AXI_DATA_WIDTH)
else $fatal(1, "LITE Interface [1] AXI_DATA_WIDTH missmatch!");
end
`endif
// pragma translate_on
endmodule