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axi_serializer.sv
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axi_serializer.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 <[email protected]>
// - Andreas Kurth <[email protected]>
`include "common_cells/registers.svh"
/// Serialize all AXI transactions to a single ID (zero).
///
/// This module contains one queue with slave port IDs for the read direction and one for the write
/// direction. These queues are used to reconstruct the ID of responses at the slave port. The
/// depth of each queue is defined by `MaxReadTxns` and `MaxWriteTxns`, respectively.
module axi_serializer #(
/// Maximum number of in flight read transactions.
parameter int unsigned MaxReadTxns = 32'd0,
/// Maximum number of in flight write transactions.
parameter int unsigned MaxWriteTxns = 32'd0,
/// AXI4+ATOP ID width.
parameter int unsigned AxiIdWidth = 32'd0,
/// AXI4+ATOP request struct definition.
parameter type axi_req_t = logic,
/// AXI4+ATOP response struct definition.
parameter type axi_resp_t = logic
) (
/// Clock
input logic clk_i,
/// Asynchronous reset, active low
input logic rst_ni,
/// Slave port request
input axi_req_t slv_req_i,
/// Slave port response
output axi_resp_t slv_resp_o,
/// Master port request
output axi_req_t mst_req_o,
/// Master port response
input axi_resp_t mst_resp_i
);
typedef logic [AxiIdWidth-1:0] id_t;
typedef enum logic [1:0] {
AtopIdle = 2'b00,
AtopDrain = 2'b01,
AtopExecute = 2'b10
} state_e;
logic rd_fifo_full, rd_fifo_empty, rd_fifo_push, rd_fifo_pop,
wr_fifo_full, wr_fifo_empty, wr_fifo_push, wr_fifo_pop;
id_t b_id,
r_id, ar_id;
state_e state_q, state_d;
always_comb begin
// Default assignments
state_d = state_q;
rd_fifo_push = 1'b0;
wr_fifo_push = 1'b0;
// Default, connect the channels
mst_req_o = slv_req_i;
slv_resp_o = mst_resp_i;
// Serialize transactions -> tie downstream IDs to zero.
mst_req_o.aw.id = '0;
mst_req_o.ar.id = '0;
// Reflect upstream ID in response.
ar_id = slv_req_i.ar.id;
slv_resp_o.b.id = b_id;
slv_resp_o.r.id = r_id;
// Default, cut the AW/AR handshaking
mst_req_o.ar_valid = 1'b0;
slv_resp_o.ar_ready = 1'b0;
mst_req_o.aw_valid = 1'b0;
slv_resp_o.aw_ready = 1'b0;
unique case (state_q)
AtopIdle, AtopExecute: begin
// Wait until the ATOP response(s) have been sent back upstream.
if (state_q == AtopExecute) begin
if ((wr_fifo_empty && rd_fifo_empty) || (wr_fifo_pop && rd_fifo_pop) ||
(wr_fifo_empty && rd_fifo_pop) || (wr_fifo_pop && rd_fifo_empty)) begin
state_d = AtopIdle;
end
end
// This part lets new Transactions through, if no ATOP is underway or the last ATOP
// response has been transmitted.
if ((state_q == AtopIdle) || (state_d == AtopIdle)) begin
// Gate AR handshake with ready output of Read FIFO.
mst_req_o.ar_valid = slv_req_i.ar_valid & ~rd_fifo_full;
slv_resp_o.ar_ready = mst_resp_i.ar_ready & ~rd_fifo_full;
rd_fifo_push = mst_req_o.ar_valid & mst_resp_i.ar_ready;
if (slv_req_i.aw_valid) begin
if (slv_req_i.aw.atop[5:4] == axi_pkg::ATOP_NONE) begin
// Normal operation
// Gate AW handshake with ready output of Write FIFO.
mst_req_o.aw_valid = ~wr_fifo_full;
slv_resp_o.aw_ready = mst_resp_i.aw_ready & ~wr_fifo_full;
wr_fifo_push = mst_req_o.aw_valid & mst_resp_i.aw_ready;
end else begin
// Atomic Operation received, go to drain state, when both channels are ready
// Wait for finished or no AR beat
if (!mst_req_o.ar_valid || (mst_req_o.ar_valid && mst_resp_i.ar_ready)) begin
state_d = AtopDrain;
end
end
end
end
end
AtopDrain: begin
// Send the ATOP AW when the last open transaction terminates
if (wr_fifo_empty && rd_fifo_empty) begin
mst_req_o.aw_valid = 1'b1;
slv_resp_o.aw_ready = mst_resp_i.aw_ready;
wr_fifo_push = mst_resp_i.aw_ready;
if (slv_req_i.aw.atop[axi_pkg::ATOP_R_RESP]) begin
// Overwrite the read ID with the one from AW
ar_id = slv_req_i.aw.id;
rd_fifo_push = mst_resp_i.aw_ready;
end
if (mst_resp_i.aw_ready) begin
state_d = AtopExecute;
end
end
end
default : /* do nothing */;
endcase
// Gate B handshake with empty flag output of Write FIFO.
slv_resp_o.b_valid = mst_resp_i.b_valid & ~wr_fifo_empty;
mst_req_o.b_ready = slv_req_i.b_ready & ~wr_fifo_empty;
// Gate R handshake with empty flag output of Read FIFO.
slv_resp_o.r_valid = mst_resp_i.r_valid & ~rd_fifo_empty;
mst_req_o.r_ready = slv_req_i.r_ready & ~rd_fifo_empty;
end
fifo_v3 #(
.FALL_THROUGH ( 1'b0 ), // No fall-through as response has to come a cycle later anyway
.DEPTH ( MaxReadTxns ),
.dtype ( id_t )
) i_rd_id_fifo (
.clk_i,
.rst_ni,
.flush_i ( 1'b0 ),
.testmode_i ( 1'b0 ),
.data_i ( ar_id ),
.push_i ( rd_fifo_push ),
.full_o ( rd_fifo_full ),
.data_o ( r_id ),
.empty_o ( rd_fifo_empty ),
.pop_i ( rd_fifo_pop ),
.usage_o ( /*not used*/ )
);
// Assign as this condition is needed in FSM
assign rd_fifo_pop = slv_resp_o.r_valid & slv_req_i.r_ready & slv_resp_o.r.last;
fifo_v3 #(
.FALL_THROUGH ( 1'b0 ),
.DEPTH ( MaxWriteTxns ),
.dtype ( id_t )
) i_wr_id_fifo (
.clk_i,
.rst_ni,
.flush_i ( 1'b0 ),
.testmode_i ( 1'b0 ),
.data_i ( slv_req_i.aw.id ),
.push_i ( wr_fifo_push ),
.full_o ( wr_fifo_full ),
.data_o ( b_id ),
.empty_o ( wr_fifo_empty ),
.pop_i ( wr_fifo_pop ),
.usage_o ( /*not used*/ )
);
// Assign as this condition is needed in FSM
assign wr_fifo_pop = slv_resp_o.b_valid & slv_req_i.b_ready;
`FFARN(state_q, state_d, AtopIdle, clk_i, rst_ni)
// pragma translate_off
`ifndef VERILATOR
initial begin: p_assertions
assert (AxiIdWidth >= 1) else $fatal(1, "AXI ID width must be at least 1!");
assert (MaxReadTxns >= 1)
else $fatal(1, "Maximum number of read transactions must be >= 1!");
assert (MaxWriteTxns >= 1)
else $fatal(1, "Maximum number of write transactions must be >= 1!");
end
default disable iff (~rst_ni);
aw_lost : assert property( @(posedge clk_i)
(slv_req_i.aw_valid & slv_resp_o.aw_ready |-> mst_req_o.aw_valid & mst_resp_i.aw_ready))
else $error("AW beat lost.");
w_lost : assert property( @(posedge clk_i)
(slv_req_i.w_valid & slv_resp_o.w_ready |-> mst_req_o.w_valid & mst_resp_i.w_ready))
else $error("W beat lost.");
b_lost : assert property( @(posedge clk_i)
(mst_resp_i.b_valid & mst_req_o.b_ready |-> slv_resp_o.b_valid & slv_req_i.b_ready))
else $error("B beat lost.");
ar_lost : assert property( @(posedge clk_i)
(slv_req_i.ar_valid & slv_resp_o.ar_ready |-> mst_req_o.ar_valid & mst_resp_i.ar_ready))
else $error("AR beat lost.");
r_lost : assert property( @(posedge clk_i)
(mst_resp_i.r_valid & mst_req_o.r_ready |-> slv_resp_o.r_valid & slv_req_i.r_ready))
else $error("R beat lost.");
`endif
// pragma translate_on
endmodule
`include "axi/typedef.svh"
`include "axi/assign.svh"
/// Serialize all AXI transactions to a single ID (zero), interface version.
module axi_serializer_intf #(
/// AXI4+ATOP ID width.
parameter int unsigned AXI_ID_WIDTH = 32'd0,
/// AXI4+ATOP address width.
parameter int unsigned AXI_ADDR_WIDTH = 32'd0,
/// AXI4+ATOP data width.
parameter int unsigned AXI_DATA_WIDTH = 32'd0,
/// AXI4+ATOP user width.
parameter int unsigned AXI_USER_WIDTH = 32'd0,
/// Maximum number of in flight read transactions.
parameter int unsigned MAX_READ_TXNS = 32'd0,
/// Maximum number of in flight write transactions.
parameter int unsigned MAX_WRITE_TXNS = 32'd0
) (
/// Clock
input logic clk_i,
/// Asynchronous reset, active low
input logic rst_ni,
/// AXI4+ATOP Slave modport
AXI_BUS.Slave slv,
/// AXI4+ATOP Master modport
AXI_BUS.Master mst
);
typedef logic [AXI_ID_WIDTH -1:0] id_t;
typedef logic [AXI_ADDR_WIDTH -1:0] addr_t;
typedef logic [AXI_DATA_WIDTH -1:0] data_t;
typedef logic [AXI_DATA_WIDTH/8-1:0] strb_t;
typedef logic [AXI_USER_WIDTH -1:0] user_t;
`AXI_TYPEDEF_AW_CHAN_T(aw_chan_t, addr_t, id_t, user_t)
`AXI_TYPEDEF_W_CHAN_T(w_chan_t, data_t, strb_t, user_t)
`AXI_TYPEDEF_B_CHAN_T(b_chan_t, id_t, user_t)
`AXI_TYPEDEF_AR_CHAN_T(ar_chan_t, addr_t, id_t, user_t)
`AXI_TYPEDEF_R_CHAN_T(r_chan_t, data_t, id_t, user_t)
`AXI_TYPEDEF_REQ_T(axi_req_t, aw_chan_t, w_chan_t, ar_chan_t)
`AXI_TYPEDEF_RESP_T(axi_resp_t, b_chan_t, r_chan_t)
axi_req_t slv_req, mst_req;
axi_resp_t slv_resp, mst_resp;
`AXI_ASSIGN_TO_REQ(slv_req, slv)
`AXI_ASSIGN_FROM_RESP(slv, slv_resp)
`AXI_ASSIGN_FROM_REQ(mst, mst_req)
`AXI_ASSIGN_TO_RESP(mst_resp, mst)
axi_serializer #(
.MaxReadTxns ( MAX_READ_TXNS ),
.MaxWriteTxns ( MAX_WRITE_TXNS ),
.AxiIdWidth ( AXI_ID_WIDTH ),
.axi_req_t ( axi_req_t ),
.axi_resp_t ( axi_resp_t )
) i_axi_serializer (
.clk_i,
.rst_ni,
.slv_req_i ( slv_req ),
.slv_resp_o ( slv_resp ),
.mst_req_o ( mst_req ),
.mst_resp_i ( mst_resp )
);
// pragma translate_off
`ifndef VERILATOR
initial begin: p_assertions
assert (AXI_ADDR_WIDTH >= 1) else $fatal(1, "AXI address width must be at least 1!");
assert (AXI_DATA_WIDTH >= 1) else $fatal(1, "AXI data width must be at least 1!");
assert (AXI_ID_WIDTH >= 1) else $fatal(1, "AXI ID width must be at least 1!");
assert (AXI_USER_WIDTH >= 1) else $fatal(1, "AXI user width must be at least 1!");
assert (MAX_READ_TXNS >= 1)
else $fatal(1, "Maximum number of read transactions must be >= 1!");
assert (MAX_WRITE_TXNS >= 1)
else $fatal(1, "Maximum number of write transactions must be >= 1!");
end
`endif
// pragma translate_on
endmodule