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axi_lite_dw_converter.sv
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axi_lite_dw_converter.sv
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// Copyright 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 <[email protected]>
/// # AXI4-Lite data width downsize module.
///
/// ## Down Conversion
///
/// The module will be in this mode if `AxiSlvPortDataWidth > AxiMstPortDataWidth`.
/// The module does multiple transactions on the master port for each transaction of the salve port.
///
/// The address on the master port will be aligned to the bus width, regardless what the input
/// address was. The number of transactions generated on the master port is equal to the
/// `DownsizeFactor = AxiSlvPortDataWidth / AxiMstPortDataWidth`.
///
/// Eg: `AxiAddrWidth == 32'd16`, `AxiSlvPortDataWidth == 32'64`, `AxiMstPortDataWidth == 32'd32'
/// This is for write transactions. Reads are accessing the whole width of the slave port.
///
///
/// | EG NUM | SLV ADDR | SLV W DATA | SLV W STRB | MST ADDR | MST W DATA | MST W STRB |
/// |--------|----------|--------------------|------------|----------|------------|------------|
/// | 1 | 0x0000 | 0xBEEFBEEFAAAABBBB | 0xAB | 0x0000 | 0xAAAABBBB | 0xB |
/// | 1 | | | | 0x0004 | 0xBEEFBEEF | 0xA |
/// | | | | | | | |
/// | 2 | 0x0000 | 0xBEEFBEEFAAAABBBB | 0xF0 | 0x0000 | 0xAAAABBBB | 0x0 |
/// | 2 | | | | 0x0004 | 0xBEEFBEEF | 0xF |
/// | | | | | | | |
/// | 3 | 0x0004 | 0xBEEFBEEFAAAABBBB | 0xF0 | 0x0000 | 0xAAAABBBB | 0x0 |
/// | 3 | | | | 0x0004 | 0xBEEFBEEF | 0xF |
/// | | | | | | | |
/// | 4 | 0x0004 | 0xBEEFBEEFAAAABBBB | 0x0F | 0x0000 | 0xAAAABBBB | 0xF |
/// | 4 | | | | 0x0004 | 0xBEEFBEEF | 0x0 |
/// | | | | | | | |
/// | 5 | 0x0005 | 0xBEEFBE0000000000 | 0xE0 | 0x0000 | 0x00000000 | 0x0 |
/// | 5 | | | | 0x0004 | 0xBEEFBE00 | 0xE |
///
/// Response field is aggregated (OR'ed) between the multiple requests made on the master port.
/// If one of the requests on the master port errors, the error response of the request
/// on the slave port will also signal an error.
///
/// ## Up conversion
///
/// The module will be in this mode if `AxiSlvPortDataWidth < AxiMstPortDataWidth`.
/// This mode will generate the same amount of transactions on the master port as on the slave port.
/// Data is replicated to match the bus width. Write strobes are silenced for the byte lanes not
/// written.
///
/// ## Pass Through
///
/// The module will be in this mode if `AxiSlvPortDataWidth == AxiMstPortDataWidth`.
/// Here the module passes through the slave port to the master port.
`include "common_cells/registers.svh"
module axi_lite_dw_converter #(
/// AXI4-Lite address width of the ports.
parameter int unsigned AxiAddrWidth = 32'd0,
/// AXI4-Lite data width of the slave port.
parameter int unsigned AxiSlvPortDataWidth = 32'd0,
/// AXI4-Lite data width of the master port.
parameter int unsigned AxiMstPortDataWidth = 32'd0,
/// AXI4-Lite AW channel struct type. This is for both ports the same.
parameter type axi_lite_aw_t = logic,
/// AXI4-Lite W channel struct type of the slave port.
parameter type axi_lite_slv_w_t = logic,
/// AXI4-Lite W channel struct type of the master port.
parameter type axi_lite_mst_w_t = logic,
/// AXI4-Lite B channel struct type. This is for both ports.
parameter type axi_lite_b_t = logic,
/// AXI4-Lite AR channel struct type. This is for both ports.
parameter type axi_lite_ar_t = logic,
/// AXI4-Lite R channel struct type of the slave port.
parameter type axi_lite_slv_r_t = logic,
/// AXI4-Lite R channel struct type of the master port.
parameter type axi_lite_mst_r_t = logic,
/// AXI4-Lite request struct of the slave port.
parameter type axi_lite_slv_req_t = logic,
/// AXI4-Lite response struct of the slave port.
parameter type axi_lite_slv_res_t = logic,
/// AXI4-Lite request struct of the master port.
parameter type axi_lite_mst_req_t = logic,
/// AXI4-Lite response struct of the master port.
parameter type axi_lite_mst_res_t = logic
) (
/// Clock, positive edge triggered.
input logic clk_i,
/// Asynchrounous reset, active low.
input logic rst_ni,
/// Salve port, AXI4-Lite request.
input axi_lite_slv_req_t slv_req_i,
/// Salve port, AXI4-Lite response.
output axi_lite_slv_res_t slv_res_o,
/// Master port, AXI4-Lite request.
output axi_lite_mst_req_t mst_req_o,
/// Master port, AXI4-Lite response.
input axi_lite_mst_res_t mst_res_i
);
// Strobe parameter for the two AXI4-Lite ports.
localparam int unsigned AxiSlvPortStrbWidth = AxiSlvPortDataWidth / 32'd8;
localparam int unsigned AxiMstPortStrbWidth = AxiMstPortDataWidth / 32'd8;
typedef logic [AxiAddrWidth-1:0] addr_t;
// AXI4-Lite downsizer
if (AxiSlvPortDataWidth > AxiMstPortDataWidth) begin : gen_downsizer
// The Downsize factor determines how often the data channel has to be multiplexed.
localparam int unsigned DownsizeFactor = AxiSlvPortDataWidth / AxiMstPortDataWidth;
// Selection width for choosing the byte lanes.
localparam int unsigned SelWidth = $clog2(DownsizeFactor);
// Type for the selection signal.
typedef logic [SelWidth-1:0] sel_t;
// Offset determines, which part of the address corresponds to the `w_chan_sel` signal.
localparam int unsigned SelOffset = $clog2(AxiMstPortStrbWidth);
// Calculate the output address for the master port.
// `address`: The address as seen on the salve port.
// `sel`: T The current selection.
// `l_zero`: If set, the lowest bits are zero, for all generated addresses after the first.
function automatic addr_t out_address(input addr_t address, input sel_t sel);
out_address = address;
out_address[SelOffset+:SelWidth] = sel;
out_address[SelOffset-1:0] = SelOffset'(0);
endfunction : out_address
// Write channels.
// Input spill register of the AW channel.
axi_lite_aw_t aw_chan_spill;
logic aw_chan_spill_valid, aw_chan_spill_ready;
spill_register #(
.T ( axi_lite_aw_t ),
.Bypass ( 1'b0 )
) i_spill_register_aw (
.clk_i,
.rst_ni,
.valid_i ( slv_req_i.aw_valid ),
.ready_o ( slv_res_o.aw_ready ),
.data_i ( slv_req_i.aw ),
.valid_o ( aw_chan_spill_valid ),
.ready_i ( aw_chan_spill_ready ),
.data_o ( aw_chan_spill )
);
sel_t aw_sel_q, aw_sel_d;
logic aw_sel_load;
// AW channel output assignment
always_comb begin : proc_aw_chan_oup
mst_req_o.aw = aw_chan_spill;
mst_req_o.aw.addr = out_address(aw_chan_spill.addr, aw_sel_q);
end
// Slave port aw is valid, if there is something in the spill register.
assign mst_req_o.aw_valid = aw_chan_spill_valid;
assign aw_chan_spill_ready = mst_res_i.aw_ready & (&aw_sel_q);
assign aw_sel_load = mst_req_o.aw_valid & mst_res_i.aw_ready;
assign aw_sel_d = sel_t'(aw_sel_q + 1'b1);
`FFLARN(aw_sel_q, aw_sel_d, aw_sel_load, '0, clk_i, rst_ni)
// Input spill register of the W channel.
axi_lite_slv_w_t w_chan_spill;
logic w_chan_spill_valid, w_chan_spill_ready;
spill_register #(
.T ( axi_lite_slv_w_t ),
.Bypass ( 1'b0 )
) i_spill_register_w (
.clk_i,
.rst_ni,
.valid_i ( slv_req_i.w_valid ),
.ready_o ( slv_res_o.w_ready ),
.data_i ( slv_req_i.w ),
.valid_o ( w_chan_spill_valid ),
.ready_i ( w_chan_spill_ready ),
.data_o ( w_chan_spill )
);
// Data multiplexer on the W channel
sel_t w_sel_q, w_sel_d;
logic w_sel_load;
// W channel output assignment
assign mst_req_o.w = axi_lite_mst_w_t'{
data: w_chan_spill.data[w_sel_q*AxiMstPortDataWidth+:AxiMstPortDataWidth],
strb: w_chan_spill.strb[w_sel_q*AxiMstPortStrbWidth+:AxiMstPortStrbWidth],
default: '0
};
assign mst_req_o.w_valid = w_chan_spill_valid;
assign w_chan_spill_ready = mst_res_i.w_ready & (&w_sel_q);
assign w_sel_load = mst_req_o.w_valid & mst_res_i.w_ready;
assign w_sel_d = sel_t'(w_sel_q + 1'b1);
`FFLARN(w_sel_q, w_sel_d, w_sel_load, '0, clk_i, rst_ni)
// B response aggregation
// Slave port B output is the aggregated error of the last few B responses.
sel_t b_sel_q, b_sel_d;
axi_pkg::resp_t b_resp_q, b_resp_d;
logic b_resp_load;
assign slv_res_o.b = axi_lite_b_t'{
resp: b_resp_q | mst_res_i.b.resp,
default: '0
};
// Output is valid, if it is the last b response for the wide W, we have something
// in the B FIFO and the B response is valid from the master port.
assign slv_res_o.b_valid = mst_res_i.b_valid & (&b_sel_q);
// Assign the b_channel ready output. The master port is ready if something is in the
// B FIFO. Except, if it is the last one which should do a response on the slave port.
assign mst_req_o.b_ready = (&b_sel_q) ? slv_req_i.b_ready : 1'b1;
// B channel error response retention FF
assign b_sel_d = sel_t'(b_sel_q + 1'b1);
assign b_resp_d = (&b_sel_q) ? axi_pkg::RESP_OKAY : (b_resp_q | mst_res_i.b.resp);
assign b_resp_load = mst_res_i.b_valid & mst_req_o.b_ready;
`FFLARN(b_sel_q, b_sel_d, b_resp_load, '0, clk_i, rst_ni)
`FFLARN(b_resp_q, b_resp_d, b_resp_load, axi_pkg::RESP_OKAY, clk_i, rst_ni)
// Read channels.
// Input spill register of the AW channel.
axi_lite_ar_t ar_chan_spill;
logic ar_chan_spill_valid, ar_chan_spill_ready;
spill_register #(
.T ( axi_lite_ar_t ),
.Bypass ( 1'b0 )
) i_spill_register_ar (
.clk_i,
.rst_ni,
.valid_i ( slv_req_i.ar_valid ),
.ready_o ( slv_res_o.ar_ready ),
.data_i ( slv_req_i.ar ),
.valid_o ( ar_chan_spill_valid ),
.ready_i ( ar_chan_spill_ready ),
.data_o ( ar_chan_spill )
);
sel_t ar_sel_q, ar_sel_d;
logic ar_sel_load;
// AR channel output assignment
always_comb begin : proc_ar_chan_oup
mst_req_o.ar = ar_chan_spill;
mst_req_o.ar.addr = out_address(ar_chan_spill.addr, ar_sel_q);
end
// Slave port aw is valid, if there is something in the spill register.
assign mst_req_o.ar_valid = ar_chan_spill_valid;
assign ar_chan_spill_ready = mst_res_i.ar_ready & (&ar_sel_q);
assign ar_sel_load = mst_req_o.ar_valid & mst_res_i.ar_ready;
assign ar_sel_d = sel_t'(ar_sel_q + 1'b1);
`FFLARN(ar_sel_q, ar_sel_d, ar_sel_load, '0, clk_i, rst_ni)
// Responses have to be aggregated, one FF less, as the last data is feed directly through.
sel_t r_sel_q, r_sel_d;
logic r_sel_load;
axi_lite_mst_r_t [DownsizeFactor-2:0] r_chan_mst_q;
logic [DownsizeFactor-2:0] r_chan_mst_load;
for (genvar i = 0; unsigned'(i) < (DownsizeFactor-1); i++) begin : gen_r_chan_ff
assign r_chan_mst_load[i] = (sel_t'(i) == r_sel_q) & mst_res_i.r_valid & mst_req_o.r_ready;
`FFLARN(r_chan_mst_q[i], mst_res_i.r, r_chan_mst_load[i], axi_lite_mst_r_t'{default: '0}, clk_i, rst_ni)
end
assign r_sel_load = mst_res_i.r_valid & mst_req_o.r_ready;
assign r_sel_d = sel_t'(r_sel_q + 1'b1);
`FFLARN(r_sel_q, r_sel_d, r_sel_load, '0, clk_i, rst_ni)
always_comb begin : proc_r_chan_oup
slv_res_o.r = axi_lite_slv_r_t'{
resp: mst_res_i.r.resp,
default: '0
};
// Response is the OR of all responses
for (int unsigned i = 0; i < (DownsizeFactor-1); i++) begin
slv_res_o.r.resp = slv_res_o.r.resp | r_chan_mst_q[i].resp;
slv_res_o.r.data[i*AxiMstPortDataWidth+:AxiMstPortDataWidth] = r_chan_mst_q[i].data;
end
// The highest bits of the data can be directly the master port.
slv_res_o.r.data[(DownsizeFactor-1)*AxiMstPortDataWidth+:AxiMstPortDataWidth] =
mst_res_i.r.data;
end
assign slv_res_o.r_valid = (&r_sel_q) ? mst_res_i.r_valid : 1'b0;
assign mst_req_o.r_ready = (&r_sel_q) ? slv_req_i.r_ready : 1'b1;
end else if (AxiMstPortDataWidth > AxiSlvPortDataWidth) begin : gen_upsizer
// The upsize factor determines the amount of replication.
localparam int unsigned UpsizeFactor = AxiMstPortDataWidth / AxiSlvPortDataWidth;
// Selection type and offset for the address
localparam int unsigned SelOffset = $clog2(AxiSlvPortStrbWidth);
localparam int unsigned SelWidth = $clog2(UpsizeFactor);
typedef logic [SelWidth-1:0] sel_t;
// AW channel can be passed through, however block handshake if FIFO is full.
assign mst_req_o.aw = slv_req_i.aw;
// Lock the valid on the master port if it has been given.
logic lock_aw_q, lock_aw_d, load_aw_lock;
// W channel needs a FIFO to determine the silencing of the strobe signal.
logic w_full, w_empty, w_push, w_pop;
sel_t aw_sel, w_sel;
// AW channel handshake control
always_comb begin : proc_aw_handshake
// default assignment
load_aw_lock = 1'b0; // the FF is toggling back and forth when loaded.
mst_req_o.aw_valid = 1'b0;
slv_res_o.aw_ready = 1'b0;
w_push = 1'b0;
if (lock_aw_q) begin
mst_req_o.aw_valid = 1'b1;
slv_res_o.aw_ready = mst_res_i.aw_ready;
if (mst_res_i.aw_ready) begin
load_aw_lock = 1'b1;
end
end else begin
// Only connect handshake if there is space in the FIFO
if (!w_full) begin
mst_req_o.aw_valid = slv_req_i.aw_valid;
slv_res_o.aw_ready = mst_res_i.aw_ready;
// If there is a valid on the slave port, push the FIFO
if (slv_req_i.aw_valid) begin
w_push = 1'b1;
// When no transaction, lock AW
if (!mst_res_i.aw_ready) begin
load_aw_lock = 1'b1;
end
end
end
end
end
assign lock_aw_d = ~lock_aw_q;
`FFLARN(lock_aw_q, lock_aw_d, load_aw_lock, 1'b0, clk_i, rst_ni)
// The selection comes from part of the AW address.
assign aw_sel = sel_t'(slv_req_i.aw.addr >> SelOffset);
fifo_v3 #(
.FALL_THROUGH ( 1'b1 ),
.DEPTH ( UpsizeFactor ),
.dtype ( sel_t )
) i_fifo_w_sel (
.clk_i,
.rst_ni,
.flush_i ( 1'b0 ),
.testmode_i ( 1'b0 ),
.full_o ( w_full ),
.empty_o ( w_empty ),
.usage_o ( /*not used*/ ),
.data_i ( aw_sel ),
.push_i ( w_push ),
.data_o ( w_sel ),
.pop_i ( w_pop )
);
// Pop if there is a W transaction on the master port.
assign w_pop = mst_req_o.w_valid & mst_res_i.w_ready;
// Replicate Data but silence strobe signal.
assign mst_req_o.w = axi_lite_mst_w_t'{
data: {UpsizeFactor{slv_req_i.w.data}},
strb: {AxiMstPortStrbWidth{1'b0}} | (slv_req_i.w.strb << (w_sel * AxiSlvPortStrbWidth)),
default: '0
};
// Connect W handshake if the selection is in the FIFO
assign mst_req_o.w_valid = slv_req_i.w_valid & ~w_empty;
assign slv_res_o.w_ready = mst_res_i.w_ready & ~w_empty;
// B channel can be passed through
assign slv_res_o.b = mst_res_i.b;
assign slv_res_o.b_valid = mst_res_i.b_valid;
assign mst_req_o.b_ready = slv_req_i.b_ready;
// AR channel can be passed through, however block handshake if FIFO is full.
assign mst_req_o.ar = slv_req_i.ar;
// Lock the valid on the master port if it has been given.
logic lock_ar_q, lock_ar_d, load_ar_lock;
// W channel needs a FIFO to determine the silencing of the strobe signal.
logic r_full, r_empty, r_push, r_pop;
sel_t ar_sel, r_sel;
// AW channel handshake control
always_comb begin : proc_ar_handshake
// default assignment
load_ar_lock = 1'b0; // the FF is toggling back and forth when loaded.
mst_req_o.ar_valid = 1'b0;
slv_res_o.ar_ready = 1'b0;
r_push = 1'b0;
if (lock_ar_q) begin
mst_req_o.ar_valid = 1'b1;
slv_res_o.ar_ready = mst_res_i.ar_ready;
if (mst_res_i.ar_ready) begin
load_ar_lock = 1'b1;
end
end else begin
// Only connect handshake if there is space in the FIFO
if (!r_full) begin
mst_req_o.ar_valid = slv_req_i.ar_valid;
slv_res_o.ar_ready = mst_res_i.ar_ready;
// If there is a valid on the slave port, push the FIFO
if (slv_req_i.ar_valid) begin
r_push = 1'b1;
// When no transaction, lock AW
if (!mst_res_i.ar_ready) begin
load_ar_lock = 1'b1;
end
end
end
end
end
assign lock_ar_d = ~lock_ar_q;
`FFLARN(lock_ar_q, lock_ar_d, load_ar_lock, 1'b0, clk_i, rst_ni)
// The selection comes from part of the AW address.
assign ar_sel = sel_t'(slv_req_i.ar.addr >> SelOffset);
fifo_v3 #(
.FALL_THROUGH ( 1'b1 ),
.DEPTH ( UpsizeFactor ),
.dtype ( sel_t )
) i_fifo_r_sel (
.clk_i,
.rst_ni,
.flush_i ( 1'b0 ),
.testmode_i ( 1'b0 ),
.full_o ( r_full ),
.empty_o ( r_empty ),
.usage_o ( /*not used*/ ),
.data_i ( ar_sel ),
.push_i ( r_push ),
.data_o ( r_sel ),
.pop_i ( r_pop )
);
// Pop if there is a R transaction on the slave port.
assign r_pop = slv_res_o.r_valid & slv_req_i.r_ready;
// R channel has to be cut out
assign slv_res_o.r = axi_lite_slv_r_t'{
data: mst_res_i.r.data[(r_sel*AxiSlvPortDataWidth)+:AxiSlvPortDataWidth],
resp: mst_res_i.r.resp,
default: '0
};
// Connect R handshake if there is something in the FIFO.
assign slv_res_o.r_valid = mst_res_i.r_valid & ~r_empty;
assign mst_req_o.r_ready = slv_req_i.r_ready & ~r_empty;
end else begin : gen_passthrough
assign mst_req_o = slv_req_i;
assign slv_res_o = mst_res_i;
end
// Assertions, check params
// pragma translate_off
`ifndef VERILATOR
initial begin
assume (AxiAddrWidth > 0) else $fatal(1, "AXI address width has to be > 0");
assume (AxiSlvPortDataWidth > 8) else $fatal(1, "AxiSlvPortDataWidth has to be > 8");
assume (AxiMstPortDataWidth > 8) else $fatal(1, "AxiMstPortDataWidth has to be > 8");
assume ($onehot(AxiSlvPortDataWidth)) else $fatal(1, "AxiSlvPortDataWidth must be power of 2");
assume ($onehot(AxiMstPortDataWidth)) else $fatal(1, "AxiMstPortDataWidth must be power of 2");
end
default disable iff (~rst_ni);
stable_aw: assert property (@(posedge clk_i)
(mst_req_o.aw_valid && !mst_res_i.aw_ready) |=> $stable(mst_req_o.aw)) else
$fatal(1, "AW must remain stable until handshake happened.");
stable_w: assert property (@(posedge clk_i)
(mst_req_o.w_valid && !mst_res_i.w_ready) |=> $stable(mst_req_o.w)) else
$fatal(1, "W must remain stable until handshake happened.");
stable_b: assert property (@(posedge clk_i)
(slv_res_o.b_valid && !slv_req_i.b_ready) |=> $stable(slv_res_o.b)) else
$fatal(1, "B must remain stable until handshake happened.");
stable_ar: assert property (@(posedge clk_i)
(mst_req_o.ar_valid && !mst_res_i.ar_ready) |=> $stable(mst_req_o.ar)) else
$fatal(1, "AR must remain stable until handshake happened.");
stable_r: assert property (@(posedge clk_i)
(slv_res_o.r_valid && !slv_req_i.r_ready) |=> $stable(slv_res_o.r)) else
$fatal(1, "R must remain stable until handshake happened.");
`endif
// pragma translate_on
endmodule
/// Interface wrapper for `axi_lite_dw_converter`.
`include "axi/typedef.svh"
`include "axi/assign.svh"
module axi_lite_dw_converter_intf #(
/// AXI4-Lite address width of the ports.
parameter int unsigned AXI_ADDR_WIDTH = 32'd0,
/// AXI4-Lite data width of the slave port.
parameter int unsigned AXI_SLV_PORT_DATA_WIDTH = 32'd0,
/// AXI4-Lite data width of the master port.
parameter int unsigned AXI_MST_PORT_DATA_WIDTH = 32'd0
) (
/// Clock, positive edge triggered.
input logic clk_i,
/// Asynchrounous reset, active low.
input logic rst_ni,
/// Slave port interface.
AXI_LITE.Slave slv,
/// Master port interface.
AXI_LITE.Master mst
);
// AXI configuration
localparam int unsigned AxiStrbWidthSlv = AXI_SLV_PORT_DATA_WIDTH / 32'd8;
localparam int unsigned AxiStrbWidthMst = AXI_MST_PORT_DATA_WIDTH / 32'd8;
// Type definitions
typedef logic [AXI_ADDR_WIDTH-1:0] lite_addr_t;
typedef logic [AXI_SLV_PORT_DATA_WIDTH-1:0] lite_data_slv_t;
typedef logic [AxiStrbWidthSlv-1:0] lite_strb_slv_t;
typedef logic [AXI_MST_PORT_DATA_WIDTH-1:0] lite_data_mst_t;
typedef logic [AxiStrbWidthMst-1:0] lite_strb_mst_t;
`AXI_LITE_TYPEDEF_AW_CHAN_T(aw_chan_lite_t, lite_addr_t)
`AXI_LITE_TYPEDEF_W_CHAN_T(w_chan_lite_slv_t, lite_data_slv_t, lite_strb_slv_t)
`AXI_LITE_TYPEDEF_W_CHAN_T(w_chan_lite_mst_t, lite_data_mst_t, lite_strb_mst_t)
`AXI_LITE_TYPEDEF_B_CHAN_T(b_chan_lite_t)
`AXI_LITE_TYPEDEF_AR_CHAN_T(ar_chan_lite_t, lite_addr_t)
`AXI_LITE_TYPEDEF_R_CHAN_T(r_chan_lite_slv_t, lite_data_slv_t)
`AXI_LITE_TYPEDEF_R_CHAN_T(r_chan_lite_mst_t, lite_data_mst_t)
`AXI_LITE_TYPEDEF_REQ_T(req_lite_slv_t, aw_chan_lite_t, w_chan_lite_slv_t, ar_chan_lite_t)
`AXI_LITE_TYPEDEF_RESP_T(res_lite_slv_t, b_chan_lite_t, r_chan_lite_slv_t)
`AXI_LITE_TYPEDEF_REQ_T(req_lite_mst_t, aw_chan_lite_t, w_chan_lite_mst_t, ar_chan_lite_t)
`AXI_LITE_TYPEDEF_RESP_T(res_lite_mst_t, b_chan_lite_t, r_chan_lite_mst_t)
req_lite_slv_t slv_req;
res_lite_slv_t slv_res;
req_lite_mst_t mst_req;
res_lite_mst_t mst_res;
`AXI_LITE_ASSIGN_TO_REQ(slv_req, slv)
`AXI_LITE_ASSIGN_FROM_RESP(slv, slv_res)
`AXI_LITE_ASSIGN_FROM_REQ(mst, mst_req)
`AXI_LITE_ASSIGN_TO_RESP(mst_res, mst)
axi_lite_dw_converter #(
.AxiAddrWidth ( AXI_ADDR_WIDTH ),
.AxiSlvPortDataWidth ( AXI_SLV_PORT_DATA_WIDTH ),
.AxiMstPortDataWidth ( AXI_MST_PORT_DATA_WIDTH ),
.axi_lite_aw_t ( aw_chan_lite_t ),
.axi_lite_slv_w_t ( w_chan_lite_slv_t ),
.axi_lite_mst_w_t ( w_chan_lite_mst_t ),
.axi_lite_b_t ( b_chan_lite_t ),
.axi_lite_ar_t ( ar_chan_lite_t ),
.axi_lite_slv_r_t ( r_chan_lite_slv_t ),
.axi_lite_mst_r_t ( r_chan_lite_mst_t ),
.axi_lite_slv_req_t ( req_lite_slv_t ),
.axi_lite_slv_res_t ( res_lite_slv_t ),
.axi_lite_mst_req_t ( req_lite_mst_t ),
.axi_lite_mst_res_t ( res_lite_mst_t )
) i_axi_lite_dw_converter (
.clk_i,
.rst_ni,
.slv_req_i ( slv_req ),
.slv_res_o ( slv_res ),
.mst_req_o ( mst_req ),
.mst_res_i ( mst_res )
);
endmodule