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axi_atop_filter.sv
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axi_atop_filter.sv
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// Copyright 2018 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:
// - Andreas Kurth <[email protected]>
// - Wolfgang Roenninger <[email protected]>
/// Filter atomic operations (ATOPs) in a protocol-compliant manner.
///
/// This module filters atomic operations (ATOPs), i.e., write transactions that have a non-zero
/// `aw_atop` value, from its `slv` to its `mst` port. This module guarantees that:
///
/// 1) `aw_atop` is always zero on the `mst` port;
///
/// 2) write transactions with non-zero `aw_atop` on the `slv` port are handled in conformance with
/// the AXI standard by replying to such write transactions with the proper B and R responses.
/// The response code on atomic operations that reach this module is always SLVERR
/// (implementation-specific, not defined in the AXI standard).
///
/// ## Intended usage
/// This module is intended to be placed between masters that may issue ATOPs and slaves that do not
/// support ATOPs. That way, this module ensures that the AXI protocol remains in a defined state on
/// systems with mixed ATOP capabilities.
///
/// ## Specification reminder
/// The AXI standard specifies that there may be no ordering requirements between different atomic
/// bursts (i.e., a burst started by an AW with ATOP other than 0) and none between atomic bursts
/// and non-atomic bursts [E2.1.4]. That is, **an atomic burst may never have the same ID as any
/// other write or read burst that is in-flight at the same time**.
module axi_atop_filter #(
/// AXI ID width
parameter int unsigned AxiIdWidth = 0,
/// Maximum number of in-flight AXI write transactions
parameter int unsigned AxiMaxWriteTxns = 0,
/// AXI request type
parameter type req_t = logic,
/// AXI response type
parameter type resp_t = logic
) (
/// Rising-edge clock of both ports
input logic clk_i,
/// Asynchronous reset, active low
input logic rst_ni,
/// Slave port request
input req_t slv_req_i,
/// Slave port response
output resp_t slv_resp_o,
/// Master port request
output req_t mst_req_o,
/// Master port response
input resp_t mst_resp_i
);
// Minimum counter width is 2 to detect underflows.
localparam int unsigned COUNTER_WIDTH = (AxiMaxWriteTxns == 1) ? 2 : $clog2(AxiMaxWriteTxns+1);
typedef struct packed {
logic underflow;
logic [COUNTER_WIDTH-1:0] cnt;
} cnt_t;
cnt_t w_cnt_d, w_cnt_q;
typedef enum logic [2:0] {
W_FEEDTHROUGH, BLOCK_AW, ABSORB_W, HOLD_B, INJECT_B, WAIT_R
} w_state_e;
w_state_e w_state_d, w_state_q;
typedef enum logic [1:0] { R_FEEDTHROUGH, INJECT_R, R_HOLD } r_state_e;
r_state_e r_state_d, r_state_q;
typedef logic [AxiIdWidth-1:0] id_t;
id_t id_d, id_q;
typedef logic [7:0] len_t;
len_t r_beats_d, r_beats_q;
typedef struct packed {
len_t len;
} r_resp_cmd_t;
r_resp_cmd_t r_resp_cmd_push, r_resp_cmd_pop;
logic aw_without_complete_w_downstream,
complete_w_without_aw_downstream,
r_resp_cmd_push_valid, r_resp_cmd_push_ready,
r_resp_cmd_pop_valid, r_resp_cmd_pop_ready;
// An AW without a complete W burst is in-flight downstream if the W counter is > 0 and not
// underflowed.
assign aw_without_complete_w_downstream = !w_cnt_q.underflow && (w_cnt_q.cnt > 0);
// A complete W burst without AW is in-flight downstream if the W counter is -1.
assign complete_w_without_aw_downstream = w_cnt_q.underflow && &(w_cnt_q.cnt);
// Manage AW, W, and B channels.
always_comb begin
// Defaults:
// Disable AW and W handshakes.
mst_req_o.aw_valid = 1'b0;
slv_resp_o.aw_ready = 1'b0;
mst_req_o.w_valid = 1'b0;
slv_resp_o.w_ready = 1'b0;
// Feed write responses through.
mst_req_o.b_ready = slv_req_i.b_ready;
slv_resp_o.b_valid = mst_resp_i.b_valid;
slv_resp_o.b = mst_resp_i.b;
// Keep ID stored for B and R response.
id_d = id_q;
// Do not push R response commands.
r_resp_cmd_push_valid = 1'b0;
// Keep the current state.
w_state_d = w_state_q;
unique case (w_state_q)
W_FEEDTHROUGH: begin
// Feed AW channel through if the maximum number of outstanding bursts is not reached.
if (complete_w_without_aw_downstream || (w_cnt_q.cnt < AxiMaxWriteTxns)) begin
mst_req_o.aw_valid = slv_req_i.aw_valid;
slv_resp_o.aw_ready = mst_resp_i.aw_ready;
end
// Feed W channel through if ..
if (aw_without_complete_w_downstream // .. downstream is missing W bursts ..
// .. or a new non-ATOP AW is being applied and there is not already a complete W burst
// downstream (to prevent underflows of w_cnt).
|| ((slv_req_i.aw_valid && slv_req_i.aw.atop[5:4] == axi_pkg::ATOP_NONE)
&& !complete_w_without_aw_downstream)
) begin
mst_req_o.w_valid = slv_req_i.w_valid;
slv_resp_o.w_ready = mst_resp_i.w_ready;
end
// Filter out AWs that are atomic operations.
if (slv_req_i.aw_valid && slv_req_i.aw.atop[5:4] != axi_pkg::ATOP_NONE) begin
mst_req_o.aw_valid = 1'b0; // Do not let AW pass to master port.
slv_resp_o.aw_ready = 1'b1; // Absorb AW on slave port.
id_d = slv_req_i.aw.id; // Store ID for B response.
// All atomic operations except atomic stores require a response on the R channel.
if (slv_req_i.aw.atop[5:4] != axi_pkg::ATOP_ATOMICSTORE) begin
// Push R response command. We do not have to wait for the ready of the register
// because we know it is ready: we are its only master and will wait for the register to
// be emptied before going back to the `W_FEEDTHROUGH` state.
r_resp_cmd_push_valid = 1'b1;
end
// If downstream is missing W beats, block the AW channel and let the W bursts complete.
if (aw_without_complete_w_downstream) begin
w_state_d = BLOCK_AW;
// If downstream is not missing W beats, absorb the W beats for this atomic AW.
end else begin
mst_req_o.w_valid = 1'b0; // Do not let W beats pass to master port.
slv_resp_o.w_ready = 1'b1; // Absorb W beats on slave port.
if (slv_req_i.w_valid && slv_req_i.w.last) begin
// If the W beat is valid and the last, proceed by injecting the B response.
// However, if there is a non-handshaked B on our response port, we must let that
// complete first.
if (slv_resp_o.b_valid && !slv_req_i.b_ready) begin
w_state_d = HOLD_B;
end else begin
w_state_d = INJECT_B;
end
end else begin
// Otherwise continue with absorbing W beats.
w_state_d = ABSORB_W;
end
end
end
end
BLOCK_AW: begin
// Feed W channel through to let outstanding bursts complete.
if (aw_without_complete_w_downstream) begin
mst_req_o.w_valid = slv_req_i.w_valid;
slv_resp_o.w_ready = mst_resp_i.w_ready;
end else begin
// If there are no more outstanding W bursts, start absorbing the next W burst.
slv_resp_o.w_ready = 1'b1;
if (slv_req_i.w_valid && slv_req_i.w.last) begin
// If the W beat is valid and the last, proceed by injecting the B response.
if (slv_resp_o.b_valid && !slv_req_i.b_ready) begin
w_state_d = HOLD_B;
end else begin
w_state_d = INJECT_B;
end
end else begin
// Otherwise continue with absorbing W beats.
w_state_d = ABSORB_W;
end
end
end
ABSORB_W: begin
// Absorb all W beats of the current burst.
slv_resp_o.w_ready = 1'b1;
if (slv_req_i.w_valid && slv_req_i.w.last) begin
if (slv_resp_o.b_valid && !slv_req_i.b_ready) begin
w_state_d = HOLD_B;
end else begin
w_state_d = INJECT_B;
end
end
end
HOLD_B: begin
// Proceed with injection of B response upon handshake.
if (slv_resp_o.b_valid && slv_req_i.b_ready) begin
w_state_d = INJECT_B;
end
end
INJECT_B: begin
// Pause forwarding of B response.
mst_req_o.b_ready = 1'b0;
// Inject error response instead. Since the B channel has an ID and the atomic burst we are
// replying to is guaranteed to be the only burst with this ID in flight, we do not have to
// observe any ordering and can immediately inject on the B channel.
slv_resp_o.b = '0;
slv_resp_o.b.id = id_q;
slv_resp_o.b.resp = axi_pkg::RESP_SLVERR;
slv_resp_o.b_valid = 1'b1;
if (slv_req_i.b_ready) begin
// If not all beats of the R response have been injected, wait for them. Otherwise, return
// to `W_FEEDTHROUGH`.
if (r_resp_cmd_pop_valid && !r_resp_cmd_pop_ready) begin
w_state_d = WAIT_R;
end else begin
w_state_d = W_FEEDTHROUGH;
end
end
end
WAIT_R: begin
// Wait with returning to `W_FEEDTHROUGH` until all beats of the R response have been
// injected.
if (!r_resp_cmd_pop_valid) begin
w_state_d = W_FEEDTHROUGH;
end
end
default: w_state_d = W_FEEDTHROUGH;
endcase
end
// Connect signals on AW and W channel that are not managed by the control FSM from slave port to
// master port.
// Feed-through of the AW and W vectors, make sure that downstream aw.atop is always zero
always_comb begin
// overwrite the atop signal
mst_req_o.aw = slv_req_i.aw;
mst_req_o.aw.atop = '0;
end
assign mst_req_o.w = slv_req_i.w;
// Manage R channel.
always_comb begin
// Defaults:
// Feed read responses through.
slv_resp_o.r = mst_resp_i.r;
slv_resp_o.r_valid = mst_resp_i.r_valid;
mst_req_o.r_ready = slv_req_i.r_ready;
// Do not pop R response command.
r_resp_cmd_pop_ready = 1'b0;
// Keep the current value of the beats counter.
r_beats_d = r_beats_q;
// Keep the current state.
r_state_d = r_state_q;
unique case (r_state_q)
R_FEEDTHROUGH: begin
if (mst_resp_i.r_valid && !slv_req_i.r_ready) begin
r_state_d = R_HOLD;
end else if (r_resp_cmd_pop_valid) begin
// Upon a command to inject an R response, immediately proceed with doing so because there
// are no ordering requirements with other bursts that may be ongoing on the R channel at
// this moment.
r_beats_d = r_resp_cmd_pop.len;
r_state_d = INJECT_R;
end
end
INJECT_R: begin
mst_req_o.r_ready = 1'b0;
slv_resp_o.r = '0;
slv_resp_o.r.id = id_q;
slv_resp_o.r.resp = axi_pkg::RESP_SLVERR;
slv_resp_o.r.last = (r_beats_q == '0);
slv_resp_o.r_valid = 1'b1;
if (slv_req_i.r_ready) begin
if (slv_resp_o.r.last) begin
r_resp_cmd_pop_ready = 1'b1;
r_state_d = R_FEEDTHROUGH;
end else begin
r_beats_d -= 1;
end
end
end
R_HOLD: begin
if (mst_resp_i.r_valid && slv_req_i.r_ready) begin
r_state_d = R_FEEDTHROUGH;
end
end
default: r_state_d = R_FEEDTHROUGH;
endcase
end
// Feed all signals on AR through.
assign mst_req_o.ar = slv_req_i.ar;
assign mst_req_o.ar_valid = slv_req_i.ar_valid;
assign slv_resp_o.ar_ready = mst_resp_i.ar_ready;
// Keep track of outstanding downstream write bursts and responses.
always_comb begin
w_cnt_d = w_cnt_q;
if (mst_req_o.aw_valid && mst_resp_i.aw_ready) begin
w_cnt_d.cnt += 1;
end
if (mst_req_o.w_valid && mst_resp_i.w_ready && mst_req_o.w.last) begin
w_cnt_d.cnt -= 1;
end
if (w_cnt_q.underflow && (w_cnt_d.cnt == '0)) begin
w_cnt_d.underflow = 1'b0;
end else if (w_cnt_q.cnt == '0 && &(w_cnt_d.cnt)) begin
w_cnt_d.underflow = 1'b1;
end
end
always_ff @(posedge clk_i, negedge rst_ni) begin
if (!rst_ni) begin
id_q <= '0;
r_beats_q <= '0;
r_state_q <= R_FEEDTHROUGH;
w_cnt_q <= '{default: '0};
w_state_q <= W_FEEDTHROUGH;
end else begin
id_q <= id_d;
r_beats_q <= r_beats_d;
r_state_q <= r_state_d;
w_cnt_q <= w_cnt_d;
w_state_q <= w_state_d;
end
end
stream_register #(
.T(r_resp_cmd_t)
) r_resp_cmd (
.clk_i (clk_i),
.rst_ni (rst_ni),
.clr_i (1'b0),
.testmode_i (1'b0),
.valid_i (r_resp_cmd_push_valid),
.ready_o (r_resp_cmd_push_ready),
.data_i (r_resp_cmd_push),
.valid_o (r_resp_cmd_pop_valid),
.ready_i (r_resp_cmd_pop_ready),
.data_o (r_resp_cmd_pop)
);
assign r_resp_cmd_push.len = slv_req_i.aw.len;
// pragma translate_off
`ifndef VERILATOR
initial begin: p_assertions
assert (AxiIdWidth >= 1) else $fatal(1, "AXI ID width must be at least 1!");
assert (AxiMaxWriteTxns >= 1)
else $fatal(1, "Maximum number of outstanding write transactions must be at least 1!");
end
`endif
// pragma translate_on
endmodule
`include "axi/assign.svh"
`include "axi/typedef.svh"
/// Interface variant of [`axi_atop_filter`](module.axi_atop_filter).
module axi_atop_filter_intf #(
/// AXI ID width
parameter int unsigned AXI_ID_WIDTH = 0,
/// AXI address width
parameter int unsigned AXI_ADDR_WIDTH = 0,
/// AXI data width
parameter int unsigned AXI_DATA_WIDTH = 0,
/// AXI user signal width
parameter int unsigned AXI_USER_WIDTH = 0,
/// Maximum number of in-flight AXI write transactions
parameter int unsigned AXI_MAX_WRITE_TXNS = 0
) (
/// Rising-edge clock of both ports
input logic clk_i,
/// Asynchronous reset, active low
input logic rst_ni,
/// Slave interface port
AXI_BUS.Slave slv,
/// Master interface port
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(req_t, aw_chan_t, w_chan_t, ar_chan_t)
`AXI_TYPEDEF_RESP_T(resp_t, b_chan_t, r_chan_t)
req_t slv_req, mst_req;
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_atop_filter #(
.AxiIdWidth ( AXI_ID_WIDTH ),
// Maximum number of AXI write bursts outstanding at the same time
.AxiMaxWriteTxns ( AXI_MAX_WRITE_TXNS ),
// AXI request & response type
.req_t ( req_t ),
.resp_t ( resp_t )
) i_axi_atop_filter (
.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 ADDR width must be at least 1!");
assert (AXI_DATA_WIDTH >= 1) else $fatal(1, "AXI DATA width must be at least 1!");
assert (AXI_USER_WIDTH >= 1) else $fatal(1, "AXI USER width must be at least 1!");
end
`endif
// pragma translate_on
endmodule