abstractaccelerator/Flow/design/lsu/el2_lsu_dccm_mem.sv

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2022-05-10 21:06:26 +08:00
// SPDX-License-Identifier: Apache-2.0
// Copyright 2020 Western Digital Corporation or its affiliates.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the 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.
//********************************************************************************
// $Id$
//
//
// Owner:
// Function: DCCM for LSU pipe
// Comments: Single ported memory
//
//
// DC1 -> DC2 -> DC3 -> DC4 (Commit)
//
// //********************************************************************************
2022-05-23 22:16:04 +08:00
`define EL2_LOCAL_DCCM_RAM_TEST_PORTS .TEST1(dccm_ext_in_pkt[i].TEST1),\
.RME(dccm_ext_in_pkt[i].RME),\
.RM(dccm_ext_in_pkt[i].RM),\
.LS(dccm_ext_in_pkt[i].LS),\
.DS(dccm_ext_in_pkt[i].DS),\
.SD(dccm_ext_in_pkt[i].SD),\
.TEST_RNM(dccm_ext_in_pkt[i].TEST_RNM),\
.BC1(dccm_ext_in_pkt[i].BC1),.BC2(dccm_ext_in_pkt[i].BC2),
2022-05-10 21:06:26 +08:00
module el2_lsu_dccm_mem
import el2_pkg::*;
#(
`include "el2_param.vh"
)(
input logic clk, // Clock only while core active. Through one clock header. For flops with second clock header built in. Connected to ACTIVE_L2CLK.
input logic active_clk, // Clock only while core active. Through two clock headers. For flops without second clock header built in.
input logic rst_l, // reset, active low
input logic clk_override, // Override non-functional clock gating
input logic dccm_wren, // write enable
input logic dccm_rden, // read enable
input logic [pt.DCCM_BITS-1:0] dccm_wr_addr_lo, // write address
input logic [pt.DCCM_BITS-1:0] dccm_wr_addr_hi, // write address
input logic [pt.DCCM_BITS-1:0] dccm_rd_addr_lo, // read address
input logic [pt.DCCM_BITS-1:0] dccm_rd_addr_hi, // read address for the upper bank in case of a misaligned access
input logic [pt.DCCM_FDATA_WIDTH-1:0] dccm_wr_data_lo, // write data
input logic [pt.DCCM_FDATA_WIDTH-1:0] dccm_wr_data_hi, // write data
input el2_dccm_ext_in_pkt_t [pt.DCCM_NUM_BANKS-1:0] dccm_ext_in_pkt, // the dccm packet from the soc
output logic [pt.DCCM_FDATA_WIDTH-1:0] dccm_rd_data_lo, // read data from the lo bank
output logic [pt.DCCM_FDATA_WIDTH-1:0] dccm_rd_data_hi, // read data from the hi bank
input logic scan_mode
);
localparam DCCM_WIDTH_BITS = $clog2(pt.DCCM_BYTE_WIDTH);
localparam DCCM_INDEX_BITS = (pt.DCCM_BITS - pt.DCCM_BANK_BITS - pt.DCCM_WIDTH_BITS);
localparam DCCM_INDEX_DEPTH = ((pt.DCCM_SIZE)*1024)/((pt.DCCM_BYTE_WIDTH)*(pt.DCCM_NUM_BANKS)); // Depth of memory bank
logic [pt.DCCM_NUM_BANKS-1:0] wren_bank;
logic [pt.DCCM_NUM_BANKS-1:0] rden_bank;
logic [pt.DCCM_NUM_BANKS-1:0] [pt.DCCM_BITS-1:(pt.DCCM_BANK_BITS+2)] addr_bank;
logic [pt.DCCM_BITS-1:(pt.DCCM_BANK_BITS+DCCM_WIDTH_BITS)] rd_addr_even, rd_addr_odd;
logic rd_unaligned, wr_unaligned;
logic [pt.DCCM_NUM_BANKS-1:0] [pt.DCCM_FDATA_WIDTH-1:0] dccm_bank_dout;
logic [pt.DCCM_FDATA_WIDTH-1:0] wrdata;
logic [pt.DCCM_NUM_BANKS-1:0][pt.DCCM_FDATA_WIDTH-1:0] wr_data_bank;
logic [(DCCM_WIDTH_BITS+pt.DCCM_BANK_BITS-1):DCCM_WIDTH_BITS] dccm_rd_addr_lo_q;
logic [(DCCM_WIDTH_BITS+pt.DCCM_BANK_BITS-1):DCCM_WIDTH_BITS] dccm_rd_addr_hi_q;
logic [pt.DCCM_NUM_BANKS-1:0] dccm_clken;
assign rd_unaligned = (dccm_rd_addr_lo[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS] != dccm_rd_addr_hi[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS]);
assign wr_unaligned = (dccm_wr_addr_lo[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS] != dccm_wr_addr_hi[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS]);
// Align the read data
assign dccm_rd_data_lo[pt.DCCM_FDATA_WIDTH-1:0] = dccm_bank_dout[dccm_rd_addr_lo_q[pt.DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS]][pt.DCCM_FDATA_WIDTH-1:0];
assign dccm_rd_data_hi[pt.DCCM_FDATA_WIDTH-1:0] = dccm_bank_dout[dccm_rd_addr_hi_q[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS]][pt.DCCM_FDATA_WIDTH-1:0];
// 8 Banks, 16KB each (2048 x 72)
for (genvar i=0; i<pt.DCCM_NUM_BANKS; i++) begin: mem_bank
assign wren_bank[i] = dccm_wren & ((dccm_wr_addr_hi[2+:pt.DCCM_BANK_BITS] == i) | (dccm_wr_addr_lo[2+:pt.DCCM_BANK_BITS] == i));
assign rden_bank[i] = dccm_rden & ((dccm_rd_addr_hi[2+:pt.DCCM_BANK_BITS] == i) | (dccm_rd_addr_lo[2+:pt.DCCM_BANK_BITS] == i));
assign addr_bank[i][(pt.DCCM_BANK_BITS+DCCM_WIDTH_BITS)+:DCCM_INDEX_BITS] = wren_bank[i] ? (((dccm_wr_addr_hi[2+:pt.DCCM_BANK_BITS] == i) & wr_unaligned) ?
dccm_wr_addr_hi[(pt.DCCM_BANK_BITS+DCCM_WIDTH_BITS)+:DCCM_INDEX_BITS] :
dccm_wr_addr_lo[(pt.DCCM_BANK_BITS+DCCM_WIDTH_BITS)+:DCCM_INDEX_BITS]) :
(((dccm_rd_addr_hi[2+:pt.DCCM_BANK_BITS] == i) & rd_unaligned) ?
dccm_rd_addr_hi[(pt.DCCM_BANK_BITS+DCCM_WIDTH_BITS)+:DCCM_INDEX_BITS] :
dccm_rd_addr_lo[(pt.DCCM_BANK_BITS+DCCM_WIDTH_BITS)+:DCCM_INDEX_BITS]);
assign wr_data_bank[i] = ((dccm_wr_addr_hi[2+:pt.DCCM_BANK_BITS] == i) & wr_unaligned) ? dccm_wr_data_hi[pt.DCCM_FDATA_WIDTH-1:0] : dccm_wr_data_lo[pt.DCCM_FDATA_WIDTH-1:0];
// clock gating section
assign dccm_clken[i] = (wren_bank[i] | rden_bank[i] | clk_override) ;
// end clock gating section
`ifdef VERILATOR
el2_ram #(DCCM_INDEX_DEPTH,39) ram (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
`else
if (DCCM_INDEX_DEPTH == 32768) begin : dccm
ram_32768x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 16384) begin : dccm
ram_16384x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 8192) begin : dccm
ram_8192x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 4096) begin : dccm
ram_4096x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 3072) begin : dccm
ram_3072x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 2048) begin : dccm
ram_2048x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 1024) begin : dccm
ram_1024x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 512) begin : dccm
ram_512x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 256) begin : dccm
ram_256x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
else if (DCCM_INDEX_DEPTH == 128) begin : dccm
ram_128x39 dccm_bank (
// Primary ports
.ME(dccm_clken[i]),
.CLK(clk),
.WE(wren_bank[i]),
.ADR(addr_bank[i]),
.D(wr_data_bank[i][pt.DCCM_FDATA_WIDTH-1:0]),
.Q(dccm_bank_dout[i][pt.DCCM_FDATA_WIDTH-1:0]),
.ROP ( ),
// These are used by SoC
`EL2_LOCAL_DCCM_RAM_TEST_PORTS
.*
);
end
`endif
end : mem_bank
// Flops
rvdff #(pt.DCCM_BANK_BITS) rd_addr_lo_ff (.*, .din(dccm_rd_addr_lo[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS]), .dout(dccm_rd_addr_lo_q[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS]), .clk(active_clk));
rvdff #(pt.DCCM_BANK_BITS) rd_addr_hi_ff (.*, .din(dccm_rd_addr_hi[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS]), .dout(dccm_rd_addr_hi_q[DCCM_WIDTH_BITS+:pt.DCCM_BANK_BITS]), .clk(active_clk));
`undef EL2_LOCAL_DCCM_RAM_TEST_PORTS
endmodule // el2_lsu_dccm_mem