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axi_lite_to_apb.sv
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axi_lite_to_apb.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]>
// - Samuel Riedel <[email protected]>
// Description: AXI4-Lite to APB4 bridge
//
// This module has one AXI4-Lite slave port and is capable of generating
// APB4 requests for multiple APB4 slave modules. The address and data widths
// of AXI4-Lite and APB4 have to be the same for both ports and are enforced over assertions.
// The selection of the APB4 slave is handled by the `addr_decode` module from `common_cells`.
// This module will answer with a `axi_pkg::RESP_DECERR` when a AXI4-Lite AW or AR request
// is not in the address map of the module and `no` APB4 request is made.
//
// The type of the APB4 request is required to look like:
// typedef struct packed {
// addr_t paddr; // same as AXI4-Lite
// prot_t pprot; // same as AXI4-Lite, specification is the same
// logic psel; // each APB4 slave has its own single-bit psel
// logic penable; // enable signal shows second APB4 cycle
// logic pwrite; // write enable
// data_t pwdata; // write data, comes from W channel
// strb_t pstrb; // write strb, comes from W channel
// } apb_req_t;
// For every APB4 slave, the `psel` field is only asserted when the decoded address matches that
// slave. If `psel` is deasserted, the value of the other fields may be undefined.
//
// The type of the APB4 response is required to look like:
// typedef struct packed {
// logic pready; // slave signals that it is ready
// data_t prdata; // read data, connects to R channel
// logic pslverr; // gets translated into either `axi_pkg::RESP_OK` or `axi_pkg::RESP_SLVERR`
// } apb_resp_t;
// Each connected `apb_resp`, has to be connected to the corresponding port index. The module
// routes the response depending on the `apb_req.psel` bit and `apb_req.pwrite` either to the
// AXI4Lite B channel for writes and to the R channel for reads.
`include "common_cells/registers.svh"
module axi_lite_to_apb #(
parameter int unsigned NoApbSlaves = 32'd1, // Number of connected APB slaves
parameter int unsigned NoRules = 32'd1, // Number of APB address rules
parameter int unsigned AddrWidth = 32'd32, // Address width
parameter int unsigned DataWidth = 32'd32, // Data width
parameter bit PipelineRequest = 1'b0, // Pipeline request path
parameter bit PipelineResponse = 1'b0, // Pipeline response path
parameter type axi_lite_req_t = logic, // AXI4-Lite request struct
parameter type axi_lite_resp_t = logic, // AXI4-Lite response sruct
parameter type apb_req_t = logic, // APB4 request struct
parameter type apb_resp_t = logic, // APB4 response struct
parameter type rule_t = logic // Address Decoder rule from `common_cells`
) (
input logic clk_i, // Clock
input logic rst_ni, // Asynchronous reset active low
// AXI LITE slave port
input axi_lite_req_t axi_lite_req_i,
output axi_lite_resp_t axi_lite_resp_o,
// APB master port
output apb_req_t [NoApbSlaves-1:0] apb_req_o,
input apb_resp_t [NoApbSlaves-1:0] apb_resp_i,
// APB Slave Address Map
input rule_t [NoRules-1:0] addr_map_i
);
localparam logic RD = 1'b0; // Encode index of a read request
localparam logic WR = 1'b1; // Encode index of a write request
localparam int unsigned SelIdxWidth = (NoApbSlaves > 32'd1) ? $clog2(NoApbSlaves) : 32'd1;
typedef logic [AddrWidth-1:0] addr_t; // AXI4-Lite, APB4 and rule_t addr width
typedef logic [DataWidth-1:0] data_t; // AXI4-Lite and APB4 data width
typedef logic [DataWidth/8-1:0] strb_t; // AXI4-Lite and APB4 strb width
typedef logic [SelIdxWidth-1:0] sel_idx_t; // Selection index from addr_decode
typedef struct packed {
addr_t addr;
axi_pkg::prot_t prot; // prot has the exact same bit mapping in AXI4-Lite as In APB v2.0
data_t data;
strb_t strb;
logic write;
} int_req_t; // request type generated by the read and write channel, internal
typedef struct packed {
data_t data; // read data from APB
axi_pkg::resp_t resp; // response bit from APB
} int_resp_t; // internal
typedef enum logic {
Setup = 1'b0, // APB in Idle or Setup
Access = 1'b1 // APB in Access
} apb_state_e;
// Signals from AXI4-Lite slave to arbitration tree
int_req_t [1:0] axi_req;
logic [1:0] axi_req_valid, axi_req_ready;
// Signals from response spill registers
axi_pkg::resp_t axi_bresp;
logic axi_bresp_valid, axi_bresp_ready;
int_resp_t axi_rresp;
logic axi_rresp_valid, axi_rresp_ready;
// -----------------------------------------------------------------------------------------------
// AXI4-Lite slave
// -----------------------------------------------------------------------------------------------
// read request
assign axi_req[RD] = '{
addr: axi_lite_req_i.ar.addr,
prot: axi_lite_req_i.ar.prot,
data: '0,
strb: '0,
write: RD
};
assign axi_req_valid[RD] = axi_lite_req_i.ar_valid;
// write request
assign axi_req[WR] = '{
addr: axi_lite_req_i.aw.addr,
prot: axi_lite_req_i.aw.prot,
data: axi_lite_req_i.w.data,
strb: axi_lite_req_i.w.strb,
write: WR
};
assign axi_req_valid[WR] = axi_lite_req_i.aw_valid & axi_lite_req_i.w_valid;
assign axi_lite_resp_o = '{
aw_ready: axi_req_valid[WR] & axi_req_ready[WR], // if AXI AW & W valid & tree gnt_o[WR]
w_ready: axi_req_valid[WR] & axi_req_ready[WR], // if AXI AW & W valid & tree gnt_o[WR]
b: '{resp: axi_bresp}, // from spill reg
b_valid: axi_bresp_valid, // from spill reg
ar_ready: axi_req_valid[RD] & axi_req_ready[RD], // if AXI AR valid and tree gnt[RD]
r: '{data: axi_rresp.data, resp: axi_rresp.resp}, // from spill reg
r_valid: axi_rresp_valid // from spill reg
};
// -----------------------------------------------------------------------------------------------
// Arbitration between write and read plus spill register for request and response
// -----------------------------------------------------------------------------------------------
int_req_t arb_req, apb_req;
logic arb_req_valid, arb_req_ready, apb_req_valid, apb_req_ready;
axi_pkg::resp_t apb_wresp;
logic apb_wresp_valid, apb_wresp_ready;
int_resp_t apb_rresp;
logic apb_rresp_valid, apb_rresp_ready;
rr_arb_tree #(
.NumIn ( 32'd2 ),
.DataType ( int_req_t ),
.ExtPrio ( 1'b0 ),
.AxiVldRdy( 1'b1 ),
.LockIn ( 1'b1 )
) i_req_arb (
.clk_i,
.rst_ni,
.flush_i ( '0 ),
.rr_i ( '0 ),
.req_i ( axi_req_valid ),
.gnt_o ( axi_req_ready ),
.data_i ( axi_req ),
.gnt_i ( arb_req_ready ),
.req_o ( arb_req_valid ),
.data_o ( arb_req ),
.idx_o ( /*not used*/ )
);
if (PipelineRequest) begin : gen_req_spill
spill_register #(
.T ( int_req_t ),
.Bypass ( 1'b0 )
) i_req_spill (
.clk_i,
.rst_ni,
.valid_i ( arb_req_valid ),
.ready_o ( arb_req_ready ),
.data_i ( arb_req ),
.valid_o ( apb_req_valid ),
.ready_i ( apb_req_ready ),
.data_o ( apb_req )
);
end else begin : gen_req_ft_reg
fall_through_register #(
.T ( int_req_t )
) i_req_ft_reg (
.clk_i,
.rst_ni,
.clr_i ( 1'b0 ),
.testmode_i ( 1'b0 ),
.valid_i ( arb_req_valid ),
.ready_o ( arb_req_ready ),
.data_i ( arb_req ),
.valid_o ( apb_req_valid ),
.ready_i ( apb_req_ready ),
.data_o ( apb_req )
);
end
if (PipelineResponse) begin : gen_resp_spill
spill_register #(
.T ( axi_pkg::resp_t ),
.Bypass ( 1'b0 )
) i_write_resp_spill (
.clk_i,
.rst_ni,
.valid_i ( apb_wresp_valid ),
.ready_o ( apb_wresp_ready ),
.data_i ( apb_wresp ),
.valid_o ( axi_bresp_valid ),
.ready_i ( axi_lite_req_i.b_ready ),
.data_o ( axi_bresp )
);
spill_register #(
.T ( int_resp_t ),
.Bypass ( 1'b0 )
) i_read_resp_spill (
.clk_i,
.rst_ni,
.valid_i ( apb_rresp_valid ),
.ready_o ( apb_rresp_ready ),
.data_i ( apb_rresp ),
.valid_o ( axi_rresp_valid ),
.ready_i ( axi_lite_req_i.r_ready ),
.data_o ( axi_rresp )
);
end else begin : gen_resp_ft_reg
fall_through_register #(
.T ( axi_pkg::resp_t )
) i_write_resp_ft_reg (
.clk_i,
.rst_ni,
.clr_i ( 1'b0 ),
.testmode_i ( 1'b0 ),
.valid_i ( apb_wresp_valid ),
.ready_o ( apb_wresp_ready ),
.data_i ( apb_wresp ),
.valid_o ( axi_bresp_valid ),
.ready_i ( axi_lite_req_i.b_ready ),
.data_o ( axi_bresp )
);
fall_through_register #(
.T ( int_resp_t )
) i_read_resp_ft_reg (
.clk_i,
.rst_ni,
.clr_i ( 1'b0 ),
.testmode_i ( 1'b0 ),
.valid_i ( apb_rresp_valid ),
.ready_o ( apb_rresp_ready ),
.data_i ( apb_rresp ),
.valid_o ( axi_rresp_valid ),
.ready_i ( axi_lite_req_i.r_ready ),
.data_o ( axi_rresp )
);
end
// -----------------------------------------------------------------------------------------------
// APB master FSM
// -----------------------------------------------------------------------------------------------
// APB access state machine
apb_state_e apb_state_q, apb_state_d;
logic apb_update;
// output of address decoder to determine PSELx signal
logic apb_dec_valid;
sel_idx_t apb_sel_idx;
addr_decode #(
.NoIndices( NoApbSlaves ),
.NoRules ( NoRules ),
.addr_t ( addr_t ),
.rule_t ( rule_t )
) i_apb_decode (
.addr_i ( apb_req.addr ),
.addr_map_i ( addr_map_i ),
.idx_o ( apb_sel_idx ),
.dec_valid_o ( apb_dec_valid ), // when not valid -> decode error
.dec_error_o ( /*not used*/ ),
.en_default_idx_i ( '0 ),
.default_idx_i ( '0 )
);
always_comb begin
// default assignments
apb_state_d = apb_state_q;
apb_update = 1'b0;
apb_req_o = '0;
apb_req_ready = 1'b0;
// response defaults to the two response spill registers
apb_wresp = axi_pkg::RESP_SLVERR;
apb_wresp_valid = 1'b0;
apb_rresp = '{data: data_t'(32'hDEA110C8), resp: axi_pkg::RESP_SLVERR};
apb_rresp_valid = 1'b0;
unique case (apb_state_q)
Setup: begin
// `Idle` and `Setup` steps
// can check here for readiness, because the response goes into spill_registers
if (apb_req_valid && apb_wresp_ready && apb_rresp_ready) begin
if (apb_dec_valid) begin
// `Setup` step
// set the request output
apb_req_o[apb_sel_idx] = '{
paddr: apb_req.addr,
pprot: apb_req.prot,
psel: 1'b1,
penable: 1'b0,
pwrite: apb_req.write,
pwdata: apb_req.data,
pstrb: apb_req.strb
};
apb_state_d = Access;
apb_update = 1'b1;
end else begin
// decode error, generate error and do not generate APB request, pop it
apb_req_ready = 1'b1;
if (apb_req.write) begin
apb_wresp = axi_pkg::RESP_DECERR;
apb_wresp_valid = 1'b1;
end else begin
apb_rresp.resp = axi_pkg::RESP_DECERR;
apb_rresp_valid = 1'b1;
end
end
end
end
Access: begin
// `Access` step
apb_req_o[apb_sel_idx] = '{
paddr: apb_req.addr,
pprot: apb_req.prot,
psel: 1'b1,
penable: 1'b1,
pwrite: apb_req.write,
pwdata: apb_req.data,
pstrb: apb_req.strb
};
if (apb_resp_i[apb_sel_idx].pready) begin
// transfer, pop the request, generate response and update state
apb_req_ready = 1'b1;
// we are only in this state if the response spill registers are ready anyway
if (apb_req.write) begin
apb_wresp = apb_resp_i[apb_sel_idx].pslverr ?
axi_pkg::RESP_SLVERR : axi_pkg::RESP_OKAY;
apb_wresp_valid = 1'b1;
end else begin
apb_rresp.data = apb_resp_i[apb_sel_idx].prdata;
apb_rresp.resp = apb_resp_i[apb_sel_idx].pslverr ?
axi_pkg::RESP_SLVERR : axi_pkg::RESP_OKAY;
apb_rresp_valid = 1'b1;
end
apb_state_d = Setup;
apb_update = 1'b1;
end
end
default: /* do nothing */ ;
endcase
end
`FFLARN(apb_state_q, apb_state_d, apb_update, Setup, clk_i, rst_ni)
// parameter check
// pragma translate_off
`ifndef VERILATOR
initial begin : check_params
addr_width: assert ($bits(axi_lite_req_i.aw.addr ) == $bits(apb_req_o[0].paddr)) else
$fatal(1, $sformatf("AXI4-Lite and APB address width not equal"));
wdata_width: assert ($bits(axi_lite_req_i.w.data ) == $bits(apb_req_o[0].pwdata)) else
$fatal(1, $sformatf("AXI4-Lite and APB write data width not equal"));
strb_width: assert ($bits(axi_lite_req_i.w.strb ) == $bits(apb_req_o[0].pstrb)) else
$fatal(1, $sformatf("AXI4-Lite and APB strobe width not equal"));
rdata_width: assert ($bits(axi_lite_resp_o.r.data ) == $bits(apb_resp_i[0].prdata)) else
$fatal(1, $sformatf("AXI4-Lite and APB read data width not equal"));
sel_width: assert ($bits(apb_req_o[0].psel) == 32'd1) else
$fatal(1, $sformatf("APB psel signal has to have a width of 1'b1"));
end
`endif
// pragma translate_on
endmodule
`include "axi/typedef.svh"
`include "axi/assign.svh"
module axi_lite_to_apb_intf #(
parameter int unsigned NoApbSlaves = 32'd1, // Number of connected APB slaves
parameter int unsigned NoRules = 32'd1, // Number of APB address rules
parameter int unsigned AddrWidth = 32'd32, // Address width
parameter int unsigned DataWidth = 32'd32, // Data width
parameter bit PipelineRequest = 1'b0, // Pipeline request path
parameter bit PipelineResponse = 1'b0, // Pipeline response path
parameter type rule_t = logic, // Address Decoder rule from `common_cells`
// DEPENDENT PARAMERETS, DO NOT OVERWRITE!
parameter type addr_t = logic [AddrWidth-1:0],
parameter type data_t = logic [DataWidth-1:0],
parameter type strb_t = logic [DataWidth/8-1:0],
parameter type sel_t = logic [NoApbSlaves-1:0]
) (
input logic clk_i, // Clock
input logic rst_ni, // Asynchronous reset active low
// AXI LITE slave port
AXI_LITE.Slave slv,
// APB master port
output addr_t paddr_o,
output logic [2:0] pprot_o,
output sel_t pselx_o,
output logic penable_o,
output logic pwrite_o,
output data_t pwdata_o,
output strb_t pstrb_o,
input logic [NoApbSlaves-1:0] pready_i,
input data_t [NoApbSlaves-1:0] prdata_i,
input [NoApbSlaves-1:0] pslverr_i,
// APB Slave Address Map
input rule_t [NoRules-1:0] addr_map_i
);
localparam int unsigned SelIdxWidth = NoApbSlaves > 1 ? $clog2(NoApbSlaves) : 1;
typedef struct packed {
addr_t paddr; // same as AXI4-Lite
axi_pkg::prot_t pprot; // same as AXI4-Lite, specification is the same
logic psel; // onehot, one psel line per connected APB4 slave
logic penable; // enable signal shows second APB4 cycle
logic pwrite; // write enable
data_t pwdata; // write data, comes from W channel
strb_t pstrb; // write strb, comes from W channel
} apb_req_t;
typedef struct packed {
logic pready; // slave signals that it is ready
data_t prdata; // read data, connects to R channel
logic pslverr; // gets translated into either `axi_pkg::RESP_OK` or `axi_pkg::RESP_SLVERR`
} apb_resp_t;
`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 axi_req;
axi_resp_t axi_resp;
apb_req_t [NoApbSlaves-1:0] apb_req;
apb_resp_t [NoApbSlaves-1:0] apb_resp;
logic [SelIdxWidth-1:0] apb_sel;
`AXI_LITE_ASSIGN_TO_REQ(axi_req, slv)
`AXI_LITE_ASSIGN_FROM_RESP(slv, axi_resp)
onehot_to_bin #(
.ONEHOT_WIDTH ( NoApbSlaves )
) i_onehot_to_bin (
.onehot ( pselx_o ),
.bin ( apb_sel )
);
assign paddr_o = apb_req[apb_sel].paddr;
assign pprot_o = apb_req[apb_sel].pprot;
assign penable_o = apb_req[apb_sel].penable;
assign pwrite_o = apb_req[apb_sel].pwrite;
assign pwdata_o = apb_req[apb_sel].pwdata;
assign pstrb_o = apb_req[apb_sel].pstrb;
for (genvar i = 0; i < NoApbSlaves; i++) begin : gen_apb_resp_assign
assign pselx_o[i] = apb_req[i].psel;
assign apb_resp[i].pready = pready_i[i];
assign apb_resp[i].prdata = prdata_i[i];
assign apb_resp[i].pslverr = pslverr_i[i];
end
axi_lite_to_apb #(
.NoApbSlaves ( NoApbSlaves ),
.NoRules ( NoRules ),
.AddrWidth ( AddrWidth ),
.DataWidth ( DataWidth ),
.PipelineRequest ( PipelineRequest ),
.PipelineResponse ( PipelineResponse ),
.axi_lite_req_t ( axi_req_t ),
.axi_lite_resp_t ( axi_resp_t ),
.apb_req_t ( apb_req_t ),
.apb_resp_t ( apb_resp_t ),
.rule_t ( rule_t )
) i_axi_lite_to_apb (
.clk_i, // Clock
.rst_ni, // Asynchronous reset active low
// AXI LITE slave port
.axi_lite_req_i ( axi_req ),
.axi_lite_resp_o ( axi_resp ),
// APB master port
.apb_req_o ( apb_req ),
.apb_resp_i ( apb_resp ),
// APB Slave Address Map
.addr_map_i
);
endmodule