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axi_lite_mux.sv
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axi_lite_mux.sv
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// Copyright (c) 2020 ETH Zurich, 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]>
// - Andreas Kurth <[email protected]>
// AXI4-Lite Multiplexer: This module multiplexes the AXI4-Lite slave ports down to one master port.
// The multiplexing happens in a round robin fashion, responses get
// sent back in order.
// register macros
`include "common_cells/registers.svh"
module axi_lite_mux #(
// AXI4-Lite parameter and channel types
parameter type aw_chan_t = logic, // AW LITE Channel Type
parameter type w_chan_t = logic, // W LITE Channel Type
parameter type b_chan_t = logic, // B LITE Channel Type
parameter type ar_chan_t = logic, // AR LITE Channel Type
parameter type r_chan_t = logic, // R LITE Channel Type
parameter type axi_req_t = logic, // AXI4-Lite request type
parameter type axi_resp_t = logic, // AXI4-Lite response type
parameter int unsigned NoSlvPorts = 32'd0, // Number of slave ports
// Maximum number of outstanding transactions per write or read
parameter int unsigned MaxTrans = 32'd0,
// If enabled, this multiplexer is purely combinatorial
parameter bit FallThrough = 1'b0,
// add spill register on write master port, adds a cycle latency on write channels
parameter bit SpillAw = 1'b1,
parameter bit SpillW = 1'b0,
parameter bit SpillB = 1'b0,
// add spill register on read master port, adds a cycle latency on read channels
parameter bit SpillAr = 1'b1,
parameter bit SpillR = 1'b0
) (
input logic clk_i, // Clock
input logic rst_ni, // Asynchronous reset active low
input logic test_i, // Test Mode enable
// slave ports (AXI4-Lite inputs), connect master modules here
input axi_req_t [NoSlvPorts-1:0] slv_reqs_i,
output axi_resp_t [NoSlvPorts-1:0] slv_resps_o,
// master port (AXI4-Lite output), connect slave module here
output axi_req_t mst_req_o,
input axi_resp_t mst_resp_i
);
// pass through if only one slave port
if (NoSlvPorts == 32'h1) begin : gen_no_mux
spill_register #(
.T ( aw_chan_t ),
.Bypass ( ~SpillAw )
) i_aw_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( slv_reqs_i[0].aw_valid ),
.ready_o ( slv_resps_o[0].aw_ready ),
.data_i ( slv_reqs_i[0].aw ),
.valid_o ( mst_req_o.aw_valid ),
.ready_i ( mst_resp_i.aw_ready ),
.data_o ( mst_req_o.aw )
);
spill_register #(
.T ( w_chan_t ),
.Bypass ( ~SpillW )
) i_w_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( slv_reqs_i[0].w_valid ),
.ready_o ( slv_resps_o[0].w_ready ),
.data_i ( slv_reqs_i[0].w ),
.valid_o ( mst_req_o.w_valid ),
.ready_i ( mst_resp_i.w_ready ),
.data_o ( mst_req_o.w )
);
spill_register #(
.T ( b_chan_t ),
.Bypass ( ~SpillB )
) i_b_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( mst_resp_i.b_valid ),
.ready_o ( mst_req_o.b_ready ),
.data_i ( mst_resp_i.b ),
.valid_o ( slv_resps_o[0].b_valid ),
.ready_i ( slv_reqs_i[0].b_ready ),
.data_o ( slv_resps_o[0].b )
);
spill_register #(
.T ( ar_chan_t ),
.Bypass ( ~SpillAr )
) i_ar_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( slv_reqs_i[0].ar_valid ),
.ready_o ( slv_resps_o[0].ar_ready ),
.data_i ( slv_reqs_i[0].ar ),
.valid_o ( mst_req_o.ar_valid ),
.ready_i ( mst_resp_i.ar_ready ),
.data_o ( mst_req_o.ar )
);
spill_register #(
.T ( r_chan_t ),
.Bypass ( ~SpillR )
) i_r_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( mst_resp_i.r_valid ),
.ready_o ( mst_req_o.r_ready ),
.data_i ( mst_resp_i.r ),
.valid_o ( slv_resps_o[0].r_valid ),
.ready_i ( slv_reqs_i[0].r_ready ),
.data_o ( slv_resps_o[0].r )
);
// other non degenerate cases
end else begin : gen_mux
// typedef for the FIFO types
typedef logic [$clog2(NoSlvPorts)-1:0] select_t;
// input to the AW arbitration tree, unpacked from request struct
aw_chan_t [NoSlvPorts-1:0] slv_aw_chans;
logic [NoSlvPorts-1:0] slv_aw_valids, slv_aw_readies;
// AW channel arb tree decision
select_t aw_select;
aw_chan_t mst_aw_chan;
logic mst_aw_valid, mst_aw_ready;
// AW master handshake internal, so that we are able to stall, if w_fifo is full
logic aw_valid, aw_ready;
// FF to lock the AW valid signal, when a new arbitration decision is made the decision
// gets pushed into the W FIFO, when it now stalls prevent subsequent pushing
// This FF removes AW to W dependency
logic lock_aw_valid_d, lock_aw_valid_q;
logic load_aw_lock;
// signals for the FIFO that holds the last switching decision of the AW channel
logic w_fifo_full, w_fifo_empty;
logic w_fifo_push, w_fifo_pop;
// W channel spill reg
select_t w_select;
w_chan_t mst_w_chan;
logic mst_w_valid, mst_w_ready;
// switching decision for the B response back routing
select_t b_select;
// signals for the FIFO that holds the last switching decision of the AW channel
logic b_fifo_full, b_fifo_empty;
logic /*w_fifo_pop*/b_fifo_pop;
// B channel spill reg
b_chan_t mst_b_chan;
logic mst_b_valid, mst_b_ready;
// input to the AR arbitration tree, unpacked from request struct
ar_chan_t [NoSlvPorts-1:0] slv_ar_chans;
logic [NoSlvPorts-1:0] slv_ar_valids, slv_ar_readies;
// AR channel for when spill is enabled
select_t ar_select;
ar_chan_t mst_ar_chan;
logic mst_ar_valid, mst_ar_ready;
// AR master handshake internal, so that we are able to stall, if R_fifo is full
logic ar_valid, ar_ready;
// master ID in the r_id
select_t r_select;
// signals for the FIFO that holds the last switching decision of the AR channel
logic r_fifo_full, r_fifo_empty;
logic r_fifo_push, r_fifo_pop;
// R channel spill reg
r_chan_t mst_r_chan;
logic mst_r_valid, mst_r_ready;
//--------------------------------------
// AW Channel
//--------------------------------------
// unpach AW channel from request/response array
for (genvar i = 0; i < NoSlvPorts; i++) begin : gen_aw_arb_input
assign slv_aw_chans[i] = slv_reqs_i[i].aw;
assign slv_aw_valids[i] = slv_reqs_i[i].aw_valid;
assign slv_resps_o[i].aw_ready = slv_aw_readies[i];
end
rr_arb_tree #(
.NumIn ( NoSlvPorts ),
.DataType ( aw_chan_t ),
.AxiVldRdy( 1'b1 ),
.LockIn ( 1'b1 )
) i_aw_arbiter (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.flush_i( 1'b0 ),
.rr_i ( '0 ),
.req_i ( slv_aw_valids ),
.gnt_o ( slv_aw_readies ),
.data_i ( slv_aw_chans ),
.gnt_i ( aw_ready ),
.req_o ( aw_valid ),
.data_o ( mst_aw_chan ),
.idx_o ( aw_select )
);
// control of the AW channel
always_comb begin
// default assignments
lock_aw_valid_d = lock_aw_valid_q;
load_aw_lock = 1'b0;
w_fifo_push = 1'b0;
mst_aw_valid = 1'b0;
aw_ready = 1'b0;
// had a downstream stall, be valid and send the AW along
if (lock_aw_valid_q) begin
mst_aw_valid = 1'b1;
// transaction
if (mst_aw_ready) begin
aw_ready = 1'b1;
lock_aw_valid_d = 1'b0;
load_aw_lock = 1'b1;
end
end else begin
if (!w_fifo_full && aw_valid) begin
mst_aw_valid = 1'b1;
w_fifo_push = 1'b1;
if (mst_aw_ready) begin
aw_ready = 1'b1;
end else begin
// go to lock if transaction not in this cycle
lock_aw_valid_d = 1'b1;
load_aw_lock = 1'b1;
end
end
end
end
`FFLARN(lock_aw_valid_q, lock_aw_valid_d, load_aw_lock, '0, clk_i, rst_ni)
fifo_v3 #(
.FALL_THROUGH ( FallThrough ),
.DEPTH ( MaxTrans ),
.dtype ( select_t )
) i_w_fifo (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.flush_i ( 1'b0 ),
.testmode_i( test_i ),
.full_o ( w_fifo_full ),
.empty_o ( w_fifo_empty ),
.usage_o ( ),
.data_i ( aw_select ),
.push_i ( w_fifo_push ),
.data_o ( w_select ),
.pop_i ( w_fifo_pop )
);
spill_register #(
.T ( aw_chan_t ),
.Bypass ( ~SpillAw ) // Param indicated that we want a spill reg
) i_aw_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( mst_aw_valid ),
.ready_o ( mst_aw_ready ),
.data_i ( mst_aw_chan ),
.valid_o ( mst_req_o.aw_valid ),
.ready_i ( mst_resp_i.aw_ready ),
.data_o ( mst_req_o.aw )
);
//--------------------------------------
// W Channel
//--------------------------------------
// multiplexer
assign mst_w_chan = slv_reqs_i[w_select].w;
assign mst_w_valid = (!w_fifo_empty && !b_fifo_full) ? slv_reqs_i[w_select].w_valid : 1'b0;
for (genvar i = 0; i < NoSlvPorts; i++) begin : gen_slv_w_ready
assign slv_resps_o[i].w_ready = mst_w_ready & ~w_fifo_empty &
~b_fifo_full & (w_select == select_t'(i));
end
assign w_fifo_pop = mst_w_valid & mst_w_ready;
fifo_v3 #(
.FALL_THROUGH ( FallThrough ),
.DEPTH ( MaxTrans ),
.dtype ( select_t )
) i_b_fifo (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.flush_i ( 1'b0 ),
.testmode_i( test_i ),
.full_o ( b_fifo_full ),
.empty_o ( b_fifo_empty ),
.usage_o ( ),
.data_i ( w_select ),
.push_i ( w_fifo_pop ), // push the selection for the B channel on W transaction
.data_o ( b_select ),
.pop_i ( b_fifo_pop )
);
spill_register #(
.T ( w_chan_t ),
.Bypass ( ~SpillW )
) i_w_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( mst_w_valid ),
.ready_o ( mst_w_ready ),
.data_i ( mst_w_chan ),
.valid_o ( mst_req_o.w_valid ),
.ready_i ( mst_resp_i.w_ready ),
.data_o ( mst_req_o.w )
);
//--------------------------------------
// B Channel
//--------------------------------------
// replicate B channels
for (genvar i = 0; i < NoSlvPorts; i++) begin : gen_slv_resps_b
assign slv_resps_o[i].b = mst_b_chan;
assign slv_resps_o[i].b_valid = mst_b_valid & ~b_fifo_empty & (b_select == select_t'(i));
end
assign mst_b_ready = ~b_fifo_empty & slv_reqs_i[b_select].b_ready;
assign b_fifo_pop = mst_b_valid & mst_b_ready;
spill_register #(
.T ( b_chan_t ),
.Bypass ( ~SpillB )
) i_b_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( mst_resp_i.b_valid ),
.ready_o ( mst_req_o.b_ready ),
.data_i ( mst_resp_i.b ),
.valid_o ( mst_b_valid ),
.ready_i ( mst_b_ready ),
.data_o ( mst_b_chan )
);
//--------------------------------------
// AR Channel
//--------------------------------------
// unpack AR channel from request/response struct
for (genvar i = 0; i < NoSlvPorts; i++) begin : gen_ar_arb_input
assign slv_ar_chans[i] = slv_reqs_i[i].ar;
assign slv_ar_valids[i] = slv_reqs_i[i].ar_valid;
assign slv_resps_o[i].ar_ready = slv_ar_readies[i];
end
rr_arb_tree #(
.NumIn ( NoSlvPorts ),
.DataType ( ar_chan_t ),
.AxiVldRdy( 1'b1 ),
.LockIn ( 1'b1 )
) i_ar_arbiter (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.flush_i( 1'b0 ),
.rr_i ( '0 ),
.req_i ( slv_ar_valids ),
.gnt_o ( slv_ar_readies ),
.data_i ( slv_ar_chans ),
.gnt_i ( ar_ready ),
.req_o ( ar_valid ),
.data_o ( mst_ar_chan ),
.idx_o ( ar_select )
);
// connect the handshake if there is space in the FIFO, no need for valid locking
// as the R response is only allowed, when AR is transferred
assign mst_ar_valid = (!r_fifo_full) ? ar_valid : 1'b0;
assign ar_ready = (!r_fifo_full) ? mst_ar_ready : 1'b0;
assign r_fifo_push = mst_ar_valid & mst_ar_ready;
fifo_v3 #(
.FALL_THROUGH ( FallThrough ),
.DEPTH ( MaxTrans ),
.dtype ( select_t )
) i_r_fifo (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.flush_i ( 1'b0 ),
.testmode_i( test_i ),
.full_o ( r_fifo_full ),
.empty_o ( r_fifo_empty ),
.usage_o ( ),
.data_i ( ar_select ),
.push_i ( r_fifo_push ), // push the selection when w transaction happens
.data_o ( r_select ),
.pop_i ( r_fifo_pop )
);
spill_register #(
.T ( ar_chan_t ),
.Bypass ( ~SpillAr )
) i_ar_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( mst_ar_valid ),
.ready_o ( mst_ar_ready ),
.data_i ( mst_ar_chan ),
.valid_o ( mst_req_o.ar_valid ),
.ready_i ( mst_resp_i.ar_ready ),
.data_o ( mst_req_o.ar )
);
//--------------------------------------
// R Channel
//--------------------------------------
// replicate R channels
for (genvar i = 0; i < NoSlvPorts; i++) begin : gen_slv_resps_r
assign slv_resps_o[i].r = mst_r_chan;
assign slv_resps_o[i].r_valid = mst_r_valid & ~r_fifo_empty & (r_select == select_t'(i));
end
assign mst_r_ready = ~r_fifo_empty & slv_reqs_i[r_select].r_ready;
assign r_fifo_pop = mst_r_valid & mst_r_ready;
spill_register #(
.T ( r_chan_t ),
.Bypass ( ~SpillR )
) i_r_spill_reg (
.clk_i ( clk_i ),
.rst_ni ( rst_ni ),
.valid_i ( mst_resp_i.r_valid ),
.ready_o ( mst_req_o.r_ready ),
.data_i ( mst_resp_i.r ),
.valid_o ( mst_r_valid ),
.ready_i ( mst_r_ready ),
.data_o ( mst_r_chan )
);
end
// pragma translate_off
`ifndef VERILATOR
initial begin: p_assertions
NoPorts: assert (NoSlvPorts > 0) else $fatal("Number of slave ports must be at least 1!");
MaxTnx: assert (MaxTrans > 0) else $fatal("Number of transactions must be at least 1!");
end
`endif
// pragma translate_on
endmodule
// interface wrap
`include "axi/assign.svh"
`include "axi/typedef.svh"
module axi_lite_mux_intf #(
parameter int unsigned AxiAddrWidth = 32'd0,
parameter int unsigned AxiDataWidth = 32'd0,
parameter int unsigned NoSlvPorts = 32'd0, // Number of slave ports
// Maximum number of outstanding transactions per write
parameter int unsigned MaxTrans = 32'd0,
// if enabled, this multiplexer is purely combinatorial
parameter bit FallThrough = 1'b0,
// add spill register on write master ports, adds a cycle latency on write channels
parameter bit SpillAw = 1'b1,
parameter bit SpillW = 1'b0,
parameter bit SpillB = 1'b0,
// add spill register on read master ports, adds a cycle latency on read channels
parameter bit SpillAr = 1'b1,
parameter bit SpillR = 1'b0
) (
input logic clk_i, // Clock
input logic rst_ni, // Asynchronous reset active low
input logic test_i, // Testmode enable
AXI_LITE.Slave slv [NoSlvPorts-1:0], // slave ports
AXI_LITE.Master mst // master port
);
typedef logic [AxiAddrWidth-1:0] addr_t;
typedef logic [AxiDataWidth-1:0] data_t;
typedef logic [AxiDataWidth/8-1:0] strb_t;
// channels typedef
`AXI_LITE_TYPEDEF_AW_CHAN_T(aw_chan_t, addr_t)
`AXI_LITE_TYPEDEF_W_CHAN_T(w_chan_t, data_t, strb_t)
`AXI_LITE_TYPEDEF_B_CHAN_T(b_chan_t)
`AXI_LITE_TYPEDEF_AR_CHAN_T(ar_chan_t, addr_t)
`AXI_LITE_TYPEDEF_R_CHAN_T(r_chan_t, data_t)
`AXI_LITE_TYPEDEF_REQ_T(axi_req_t, aw_chan_t, w_chan_t, ar_chan_t)
`AXI_LITE_TYPEDEF_RESP_T(axi_resp_t, b_chan_t, r_chan_t)
axi_req_t [NoSlvPorts-1:0] slv_reqs;
axi_resp_t [NoSlvPorts-1:0] slv_resps;
axi_req_t mst_req;
axi_resp_t mst_resp;
for (genvar i = 0; i < NoSlvPorts; i++) begin : gen_assign_slv_ports
`AXI_LITE_ASSIGN_TO_REQ(slv_reqs[i], slv[i])
`AXI_LITE_ASSIGN_FROM_RESP(slv[i], slv_resps[i])
end
`AXI_LITE_ASSIGN_FROM_REQ(mst, mst_req)
`AXI_LITE_ASSIGN_TO_RESP(mst_resp, mst)
axi_lite_mux #(
.aw_chan_t ( aw_chan_t ), // AW Channel Type
.w_chan_t ( w_chan_t ), // W Channel Type
.b_chan_t ( b_chan_t ), // B Channel Type
.ar_chan_t ( ar_chan_t ), // AR Channel Type
.r_chan_t ( r_chan_t ), // R Channel Type
.axi_req_t ( axi_req_t ),
.axi_resp_t ( axi_resp_t ),
.NoSlvPorts ( NoSlvPorts ), // Number of slave ports
.MaxTrans ( MaxTrans ),
.FallThrough ( FallThrough ),
.SpillAw ( SpillAw ),
.SpillW ( SpillW ),
.SpillB ( SpillB ),
.SpillAr ( SpillAr ),
.SpillR ( SpillR )
) i_axi_mux (
.clk_i, // Clock
.rst_ni, // Asynchronous reset active low
.test_i, // Test Mode enable
.slv_reqs_i ( slv_reqs ),
.slv_resps_o ( slv_resps ),
.mst_req_o ( mst_req ),
.mst_resp_i ( mst_resp )
);
// pragma translate_off
`ifndef VERILATOR
initial begin: p_assertions
AddrWidth: assert (AxiAddrWidth > 0) else $fatal("Axi Parameter has to be > 0!");
DataWidth: assert (AxiDataWidth > 0) else $fatal("Axi Parameter has to be > 0!");
end
`endif
// pragma translate_on
endmodule