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/// Copyright by Syntacore LLC © 2016-2021. See LICENSE for details
/// @file <scr1_dmem_ahb.sv>
/// @brief Data memory AHB bridge
///
`include "scr1_ahb.svh"
`include "scr1_memif.svh"
module scr1_dmem_ahb (
// Control Signals
input logic rst_n,
input logic clk,
// Core Interface
output logic dmem_req_ack,
input logic dmem_req,
input logic dmem_cmd,
input logic [1:0] dmem_width,
input logic [SCR1_AHB_WIDTH-1:0] dmem_addr,
input logic [SCR1_AHB_WIDTH-1:0] dmem_wdata,
output logic [SCR1_AHB_WIDTH-1:0] dmem_rdata,
output logic [1:0] dmem_resp,
// AHB Interface
output logic [3:0] hprot,
output logic [2:0] hburst,
output logic [2:0] hsize,
output logic [1:0] htrans,
output logic hmastlock,
output logic [SCR1_AHB_WIDTH-1:0] haddr,
output logic hwrite,
output logic [SCR1_AHB_WIDTH-1:0] hwdata,
input logic hready,
input logic [SCR1_AHB_WIDTH-1:0] hrdata,
input logic hresp
);
//-------------------------------------------------------------------------------
// Local Parameters
//-------------------------------------------------------------------------------
`ifndef SCR1_DMEM_AHB_OUT_BP
localparam SCR1_FIFO_WIDTH = 2;
localparam SCR1_FIFO_CNT_WIDTH = $clog2(SCR1_FIFO_WIDTH+1);
`endif // SCR1_DMEM_AHB_OUT_BP
//-------------------------------------------------------------------------------
// Local type declaration
//-------------------------------------------------------------------------------
typedef enum logic {
SCR1_FSM_ADDR = 1'b0,
SCR1_FSM_DATA = 1'b1,
SCR1_FSM_ERR = 1'bx
} type_scr1_fsm_e;
typedef struct packed {
logic hwrite;
logic [2:0] hwidth;
logic [SCR1_AHB_WIDTH-1:0] haddr;
logic [SCR1_AHB_WIDTH-1:0] hwdata;
} type_scr1_req_fifo_s;
typedef struct packed {
logic hwrite;
logic [2:0] hwidth;
logic [1:0] haddr;
logic [SCR1_AHB_WIDTH-1:0] hwdata;
} type_scr1_data_fifo_s;
typedef struct packed {
logic hresp;
logic [2:0] hwidth;
logic [1:0] haddr;
logic [SCR1_AHB_WIDTH-1:0] hrdata;
} type_scr1_resp_fifo_s;
//-------------------------------------------------------------------------------
// Local functions
//-------------------------------------------------------------------------------
function automatic logic [2:0] scr1_conv_mem2ahb_width (
input logic [1:0] dmem_width
);
logic [2:0] tmp;
begin
case (dmem_width)
SCR1_MEM_WIDTH_BYTE : begin
tmp = SCR1_HSIZE_8B;
end
SCR1_MEM_WIDTH_HWORD : begin
tmp = SCR1_HSIZE_16B;
end
SCR1_MEM_WIDTH_WORD : begin
tmp = SCR1_HSIZE_32B;
end
default : begin
tmp = SCR1_HSIZE_ERR;
end
endcase
scr1_conv_mem2ahb_width = tmp; // cp.11
end
endfunction
function automatic logic[SCR1_AHB_WIDTH-1:0] scr1_conv_mem2ahb_wdata (
input logic [1:0] dmem_addr,
input logic [1:0] dmem_width,
input logic [SCR1_AHB_WIDTH-1:0] dmem_wdata
);
logic [SCR1_AHB_WIDTH-1:0] tmp;
begin
tmp = 'x;
case (dmem_width)
SCR1_MEM_WIDTH_BYTE : begin
case (dmem_addr)
2'b00 : begin
tmp[7:0] = dmem_wdata[7:0];
end
2'b01 : begin
tmp[15:8] = dmem_wdata[7:0];
end
2'b10 : begin
tmp[23:16] = dmem_wdata[7:0];
end
2'b11 : begin
tmp[31:24] = dmem_wdata[7:0];
end
default : begin
end
endcase
end
SCR1_MEM_WIDTH_HWORD : begin
case (dmem_addr[1])
1'b0 : begin
tmp[15:0] = dmem_wdata[15:0];
end
1'b1 : begin
tmp[31:16] = dmem_wdata[15:0];
end
default : begin
end
endcase
end
SCR1_MEM_WIDTH_WORD : begin
tmp = dmem_wdata;
end
default : begin
end
endcase
scr1_conv_mem2ahb_wdata = tmp;
end
endfunction
function automatic logic[SCR1_AHB_WIDTH-1:0] scr1_conv_ahb2mem_rdata (
input logic [2:0] hwidth,
input logic [1:0] haddr,
input logic [SCR1_AHB_WIDTH-1:0] hrdata
);
logic [SCR1_AHB_WIDTH-1:0] tmp;
begin
tmp = 'x;
case (hwidth)
SCR1_HSIZE_8B : begin
case (haddr)
2'b00 : tmp[7:0] = hrdata[7:0];
2'b01 : tmp[7:0] = hrdata[15:8];
2'b10 : tmp[7:0] = hrdata[23:16];
2'b11 : tmp[7:0] = hrdata[31:24];
default : begin
end
endcase
end
SCR1_HSIZE_16B : begin
case (haddr[1])
1'b0 : tmp[15:0] = hrdata[15:0];
1'b1 : tmp[15:0] = hrdata[31:16];
default : begin
end
endcase
end
SCR1_HSIZE_32B : begin
tmp = hrdata;
end
default : begin
end
endcase
scr1_conv_ahb2mem_rdata = tmp;
end
endfunction
//-------------------------------------------------------------------------------
// Local signal declaration
//-------------------------------------------------------------------------------
type_scr1_fsm_e fsm;
logic req_fifo_rd;
logic req_fifo_wr;
logic req_fifo_up;
`ifdef SCR1_DMEM_AHB_OUT_BP
type_scr1_req_fifo_s req_fifo_new;
type_scr1_req_fifo_s req_fifo_r;
type_scr1_req_fifo_s [0:0] req_fifo;
`else // SCR1_DMEM_AHB_OUT_BP
type_scr1_req_fifo_s [0:SCR1_FIFO_WIDTH-1] req_fifo;
type_scr1_req_fifo_s [0:SCR1_FIFO_WIDTH-1] req_fifo_new;
logic [SCR1_FIFO_CNT_WIDTH-1:0] req_fifo_cnt;
logic [SCR1_FIFO_CNT_WIDTH-1:0] req_fifo_cnt_new;
`endif // SCR1_DMEM_AHB_OUT_BP
logic req_fifo_empty;
logic req_fifo_full;
type_scr1_data_fifo_s data_fifo;
type_scr1_resp_fifo_s resp_fifo;
logic resp_fifo_hready;
//-------------------------------------------------------------------------------
// Interface to Core
//-------------------------------------------------------------------------------
assign dmem_req_ack = ~req_fifo_full;
assign req_fifo_wr = ~req_fifo_full & dmem_req;
assign dmem_rdata = scr1_conv_ahb2mem_rdata(resp_fifo.hwidth, resp_fifo.haddr, resp_fifo.hrdata);
assign dmem_resp = (resp_fifo_hready)
? (resp_fifo.hresp == SCR1_HRESP_OKAY)
? SCR1_MEM_RESP_RDY_OK
: SCR1_MEM_RESP_RDY_ER
: SCR1_MEM_RESP_NOTRDY ;
//-------------------------------------------------------------------------------
// REQ_FIFO
//-------------------------------------------------------------------------------
`ifdef SCR1_DMEM_AHB_OUT_BP
always_ff @(negedge rst_n, posedge clk) begin
if (~rst_n) begin
req_fifo_full <= 1'b0;
end else begin
if (~req_fifo_full) begin
req_fifo_full <= dmem_req & ~req_fifo_rd;
end else begin
req_fifo_full <= ~req_fifo_rd;
end
end
end
assign req_fifo_empty = ~(req_fifo_full | dmem_req);
assign req_fifo_up = ~req_fifo_rd & req_fifo_wr;
always_ff @(posedge clk) begin
if (req_fifo_up) begin
req_fifo_r <= req_fifo_new;
end
end
assign req_fifo_new.hwrite = dmem_req ? (dmem_cmd == SCR1_MEM_CMD_WR) : 1'b0;
assign req_fifo_new.hwidth = dmem_req ? scr1_conv_mem2ahb_width(dmem_width) : '0;
assign req_fifo_new.haddr = dmem_req ? dmem_addr : '0;
assign req_fifo_new.hwdata = (dmem_req & (dmem_cmd == SCR1_MEM_CMD_WR))
? scr1_conv_mem2ahb_wdata(dmem_addr[1:0], dmem_width, dmem_wdata)
: '0;
assign req_fifo[0] = (req_fifo_full) ? req_fifo_r: req_fifo_new;
`else // SCR1_DMEM_AHB_OUT_BP
always_comb begin
req_fifo_up = 1'b0;
req_fifo_cnt_new = req_fifo_cnt;
req_fifo_new = req_fifo;
case ({req_fifo_rd, req_fifo_wr})
2'b00 : begin
// nothing todo
end
2'b01: begin
// FIFO write
req_fifo_up = 1'b1;
req_fifo_new[req_fifo_cnt].hwrite = (dmem_cmd == SCR1_MEM_CMD_WR);
req_fifo_new[req_fifo_cnt].hwidth = scr1_conv_mem2ahb_width(dmem_width);
req_fifo_new[req_fifo_cnt].haddr = dmem_addr;
req_fifo_new[req_fifo_cnt].hwdata = scr1_conv_mem2ahb_wdata(dmem_addr[1:0], dmem_width, dmem_wdata);
req_fifo_cnt_new = req_fifo_cnt + 1'b1;
end
2'b10 : begin
// FIFO read
req_fifo_up = 1'b1;
req_fifo_new[0] = req_fifo_new[1];
req_fifo_new[1].hwrite = 1'b0;
req_fifo_new[1].hwidth = SCR1_HSIZE_32B;
req_fifo_new[1].haddr = 'x;
req_fifo_new[1].hwdata = 'x;
req_fifo_cnt_new = req_fifo_cnt - 1'b1;
end
2'b11 : begin
// Read and Write FIFO. It is possible only when fifo_cnt = 1
req_fifo_up = 1'b1;
req_fifo_new[0].hwrite = (dmem_cmd == SCR1_MEM_CMD_WR);
req_fifo_new[0].hwidth = scr1_conv_mem2ahb_width(dmem_width);
req_fifo_new[0].haddr = dmem_addr;
req_fifo_new[0].hwdata = scr1_conv_mem2ahb_wdata(dmem_addr[1:0], dmem_width, dmem_wdata);
end
default : begin
req_fifo_up = 'x;
req_fifo_cnt_new = 'x;
req_fifo_new = 'x;
end
endcase
end
always_ff @(negedge rst_n, posedge clk) begin
if (~rst_n) begin
req_fifo_cnt <= '0;
end else begin
if (req_fifo_up) begin
req_fifo_cnt <= req_fifo_cnt_new;
end
end
end
assign req_fifo_full = (req_fifo_cnt == SCR1_FIFO_WIDTH);
assign req_fifo_empty = ~(|req_fifo_cnt);
always_ff @(posedge clk) begin
if (req_fifo_up) begin
req_fifo <= req_fifo_new;
end
end
`endif // SCR1_DMEM_AHB_OUT_BP
//-------------------------------------------------------------------------------
// FSM
//-------------------------------------------------------------------------------
always_ff @(negedge rst_n, posedge clk) begin
if (~rst_n) begin
fsm <= SCR1_FSM_ADDR;
end else begin
case (fsm)
SCR1_FSM_ADDR : begin
if (hready) begin
fsm <= (req_fifo_empty) ? SCR1_FSM_ADDR : SCR1_FSM_DATA;
end
end
SCR1_FSM_DATA : begin
if (hready) begin
if (hresp == SCR1_HRESP_OKAY) begin
fsm <= (req_fifo_empty) ? SCR1_FSM_ADDR : SCR1_FSM_DATA;
end else begin
fsm <= SCR1_FSM_ADDR;
end
end
end
default : begin
fsm <= SCR1_FSM_ERR;
end
endcase
end
end
always_comb begin
req_fifo_rd = 1'b0;
case (fsm)
SCR1_FSM_ADDR : begin
if (hready) begin
req_fifo_rd = ~req_fifo_empty;
end
end
SCR1_FSM_DATA : begin
if (hready) begin
req_fifo_rd = ~req_fifo_empty & (hresp == SCR1_HRESP_OKAY);
end
end
default : begin
req_fifo_rd = 1'bx;
end
endcase
end
//-------------------------------------------------------------------------------
// FIFO data
//-------------------------------------------------------------------------------
always_ff @(posedge clk) begin
case (fsm)
SCR1_FSM_ADDR : begin
if (~req_fifo_empty) begin
data_fifo.hwrite <= req_fifo[0].hwrite;
data_fifo.hwidth <= req_fifo[0].hwidth;
data_fifo.haddr <= req_fifo[0].haddr[1:0];
data_fifo.hwdata <= req_fifo[0].hwdata;
end
end
SCR1_FSM_DATA : begin
if (hready) begin
if (hresp == SCR1_HRESP_OKAY) begin
if (~req_fifo_empty) begin
data_fifo.hwrite <= req_fifo[0].hwrite;
data_fifo.hwidth <= req_fifo[0].hwidth;
data_fifo.haddr <= req_fifo[0].haddr[1:0];
data_fifo.hwdata <= req_fifo[0].hwdata;
end
end
end
end
default : begin
end
endcase
end
//-------------------------------------------------------------------------------
// FIFO response
//-------------------------------------------------------------------------------
`ifdef SCR1_DMEM_AHB_IN_BP
assign resp_fifo_hready = (fsm == SCR1_FSM_DATA) ? hready : 1'b0;
assign resp_fifo.hresp = hresp;
assign resp_fifo.hwidth = data_fifo.hwidth;
assign resp_fifo.haddr = data_fifo.haddr;
assign resp_fifo.hrdata = hrdata;
`else // SCR1_DMEM_AHB_IN_BP
always_ff @(negedge rst_n, posedge clk) begin
if (~rst_n) begin
resp_fifo_hready <= 1'b0;
end else begin
resp_fifo_hready <= (fsm == SCR1_FSM_DATA) ? hready : 1'b0;
end
end
always_ff @(posedge clk) begin
if (hready & (fsm == SCR1_FSM_DATA)) begin
resp_fifo.hresp <= hresp;
resp_fifo.hwidth <= data_fifo.hwidth;
resp_fifo.haddr <= data_fifo.haddr;
resp_fifo.hrdata <= hrdata;
end
end
`endif // SCR1_DMEM_AHB_IN_BP
//-------------------------------------------------------------------------------
// Interface to AHB
//-------------------------------------------------------------------------------
assign hprot[SCR1_HPROT_DATA] = 1'b1;
assign hprot[SCR1_HPROT_PRV] = 1'b0;
assign hprot[SCR1_HPROT_BUF] = 1'b0;
assign hprot[SCR1_HPROT_CACHE] = 1'b0;
assign hburst = SCR1_HBURST_SINGLE;
assign hsize = req_fifo[0].hwidth;
assign hmastlock = 1'b0;
always_comb begin
htrans = SCR1_HTRANS_IDLE;
case (fsm)
SCR1_FSM_ADDR : begin
if (~req_fifo_empty) begin
htrans = SCR1_HTRANS_NONSEQ;
end
end
SCR1_FSM_DATA : begin
if (hready) begin
if (hresp == SCR1_HRESP_OKAY) begin
if (~req_fifo_empty) begin
htrans = SCR1_HTRANS_NONSEQ;
end
end
end
end
default : begin
htrans = SCR1_HTRANS_ERR;
end
endcase
end
assign haddr = req_fifo[0].haddr;
assign hwrite = req_fifo[0].hwrite;
assign hwdata = data_fifo.hwdata;
endmodule : scr1_dmem_ahb