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[/] [yifive/] [trunk/] [caravel_yifive/] [verilog/] [rtl/] [sdram_ctrl/] [src/] [core/] [sdrc_req_gen.v] - Rev 21
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/********************************************************************* SDRAM Controller Request Generation This file is part of the sdram controller project http://www.opencores.org/cores/sdr_ctrl/ Description: SDRAM Controller Reguest Generation Address Generation Based on cfg_colbits cfg_colbits= 2'b00 Address[7:0] - Column Address Address[9:8] - Bank Address Address[22:10] - Row Address cfg_colbits= 2'b01 Address[8:0] - Column Address Address[10:9] - Bank Address Address[23:11] - Row Address cfg_colbits= 2'b10 Address[9:0] - Column Address Address[11:10] - Bank Address Address[24:12] - Row Address cfg_colbits= 2'b11 Address[10:0] - Column Address Address[12:11] - Bank Address Address[25:13] - Row Address The SDRAMs are operated in 4 beat burst mode. If Wrap = 0; If the current burst cross the page boundary, then this block split the request into two coressponding change in address and request length if the current burst cross the page boundar. This module takes requests from the memory controller, chops them to page boundaries if wrap=0, and passes the request to bank_ctl Note: With Wrap = 0, each request from Application layer will be splited into two request, if the current burst cross the page boundary. To Do: nothing Author(s): - Dinesh Annayya, dinesha@opencores.org Version : 0.0 - 8th Jan 2012 0.1 - 5th Feb 2012, column/row/bank address are register to improve the timing issue in FPGA synthesis Copyright (C) 2000 Authors and OPENCORES.ORG This source file may be used and distributed without restriction provided that this copyright statement is not removed from the file and that any derivative work contains the original copyright notice and the associated disclaimer. This source file is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. This source is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with this source; if not, download it from http://www.opencores.org/lgpl.shtml *******************************************************************/ `include "sdrc_define.v" module sdrc_req_gen (clk, reset_n, cfg_colbits, sdr_width, /* Request from app */ req, // Transfer Request req_id, // ID for this transfer req_addr, // SDRAM Address req_len, // Burst Length (in 32 bit words) req_wrap, // Wrap mode request (xfr_len = 4) req_wr_n, // 0 => Write request, 1 => read req req_ack, // Request has been accepted /* Req to xfr_ctl */ r2x_idle, /* Req to bank_ctl */ r2b_req, // request r2b_req_id, // ID r2b_start, // First chunk of burst r2b_last, // Last chunk of burst r2b_wrap, // Wrap Mode r2b_ba, // bank address r2b_raddr, // row address r2b_caddr, // col address r2b_len, // length r2b_write, // write request b2r_ack, b2r_arb_ok ); parameter APP_AW = 26; // Application Address Width parameter APP_DW = 32; // Application Data Width parameter APP_BW = 4; // Application Byte Width parameter APP_RW = 9; // Application Request Width parameter SDR_DW = 16; // SDR Data Width parameter SDR_BW = 2; // SDR Byte Width input clk ; input reset_n ; input [1:0] cfg_colbits ; // 2'b00 - 8 Bit column address, 2'b01 - 9 Bit, 10 - 10 bit, 11 - 11Bits /* Request from app */ input req ; // Request input [`SDR_REQ_ID_W-1:0] req_id ; // Request ID input [APP_AW-1:0] req_addr ; // Request Address input [APP_RW-1:0] req_len ; // Request length input req_wr_n ; // 0 -Write, 1 - Read input req_wrap ; // 1 - Wrap the Address on page boundary output req_ack ; // Request Ack /* Req to bank_ctl */ output r2x_idle ; output r2b_req ; // Request output r2b_start ; // First Junk of the Burst Access output r2b_last ; // Last Junk of the Burst Access output r2b_write ; // 1 - Write, 0 - Read output r2b_wrap ; // 1 - Wrap the Address at the page boundary. output [`SDR_REQ_ID_W-1:0] r2b_req_id; output [1:0] r2b_ba ; // Bank Address output [12:0] r2b_raddr ; // Row Address output [12:0] r2b_caddr ; // Column Address output [`REQ_BW-1:0] r2b_len ; // Burst Length input b2r_ack ; // Request Ack input b2r_arb_ok ; // Bank controller fifo is not full and ready to accept the command // input [1:0] sdr_width; // 2'b00 - 32 Bit, 2'b01 - 16 Bit, 2'b1x - 8Bit /****************************************************************************/ // Internal Nets `define REQ_IDLE 2'b00 `define REQ_ACTIVE 2'b01 `define REQ_PAGE_WRAP 2'b10 reg [1:0] req_st, next_req_st; reg r2x_idle, req_ack, r2b_req, r2b_start, r2b_write, req_idle, req_ld, lcl_wrap; reg [`SDR_REQ_ID_W-1:0] r2b_req_id; reg [`REQ_BW-1:0] lcl_req_len; wire r2b_last, page_ovflw; reg page_ovflw_r; wire [`REQ_BW-1:0] r2b_len, next_req_len; wire [12:0] max_r2b_len; reg [12:0] max_r2b_len_r; reg [1:0] r2b_ba; reg [12:0] r2b_raddr; reg [12:0] r2b_caddr; reg [APP_AW-1:0] curr_sdr_addr ; wire [APP_AW-1:0] next_sdr_addr ; //-------------------------------------------------------------------- // Generate the internal Adress and Burst length Based on sdram width //-------------------------------------------------------------------- reg [APP_AW:0] req_addr_int; reg [APP_RW-1:0] req_len_int; always @(*) begin if(sdr_width == 2'b00) begin // 32 Bit SDR Mode req_addr_int = {1'b0,req_addr}; req_len_int = req_len; end else if(sdr_width == 2'b01) begin // 16 Bit SDR Mode // Changed the address and length to match the 16 bit SDR Mode req_addr_int = {req_addr,1'b0}; req_len_int = {req_len,1'b0}; end else begin // 8 Bit SDR Mode // Changed the address and length to match the 16 bit SDR Mode req_addr_int = {req_addr,2'b0}; req_len_int = {req_len,2'b0}; end end // // Identify the page over flow. // Find the Maximum Burst length allowed from the selected column // address, If the requested burst length is more than the allowed Maximum // burst length, then we need to handle the bank cross over case and we // need to split the reuest. // assign max_r2b_len = (cfg_colbits == 2'b00) ? (12'h100 - {4'b0, req_addr_int[7:0]}) : (cfg_colbits == 2'b01) ? (12'h200 - {3'b0, req_addr_int[8:0]}) : (cfg_colbits == 2'b10) ? (12'h400 - {2'b0, req_addr_int[9:0]}) : (12'h800 - {1'b0, req_addr_int[10:0]}); // If the wrap = 0 and current application burst length is crossing the page boundary, // then request will be split into two with corresponding change in request address and request length. // // If the wrap = 0 and current burst length is not crossing the page boundary, // then request from application layer will be transparently passed on the bank control block. // // if the wrap = 1, then this block will not modify the request address and length. // The wrapping functionality will be handle by the bank control module and // column address will rewind back as follows XX -> FF ? 00 ? 1 // // Note: With Wrap = 0, each request from Application layer will be spilited into two request, // if the current burst cross the page boundary. assign page_ovflw = ({1'b0, req_len_int} > max_r2b_len) ? ~r2b_wrap : 1'b0; assign r2b_len = r2b_start ? ((page_ovflw_r) ? max_r2b_len_r : lcl_req_len) : lcl_req_len; assign next_req_len = lcl_req_len - r2b_len; assign next_sdr_addr = curr_sdr_addr + r2b_len; assign r2b_wrap = lcl_wrap; assign r2b_last = (r2b_start & !page_ovflw_r) | (req_st == `REQ_PAGE_WRAP); // // // always @ (posedge clk) begin page_ovflw_r <= (req_ack) ? page_ovflw: 'h0; max_r2b_len_r <= (req_ack) ? max_r2b_len: 'h0; r2b_start <= (req_ack) ? 1'b1 : (b2r_ack) ? 1'b0 : r2b_start; r2b_write <= (req_ack) ? ~req_wr_n : r2b_write; r2b_req_id <= (req_ack) ? req_id : r2b_req_id; lcl_wrap <= (req_ack) ? req_wrap : lcl_wrap; lcl_req_len <= (req_ack) ? req_len_int : (req_ld) ? next_req_len : lcl_req_len; curr_sdr_addr <= (req_ack) ? req_addr_int : (req_ld) ? next_sdr_addr : curr_sdr_addr; end // always @ (posedge clk) always @ (*) begin r2x_idle = 1'b0; req_idle = 1'b0; req_ack = 1'b0; req_ld = 1'b0; r2b_req = 1'b0; next_req_st = `REQ_IDLE; case (req_st) `REQ_IDLE : begin r2x_idle = ~req; req_idle = 1'b1; req_ack = req & b2r_arb_ok; req_ld = 1'b0; r2b_req = 1'b0; next_req_st = (req & b2r_arb_ok) ? `REQ_ACTIVE : `REQ_IDLE; end // case: `REQ_IDLE `REQ_ACTIVE : begin r2x_idle = 1'b0; req_idle = 1'b0; req_ack = 1'b0; req_ld = b2r_ack; r2b_req = 1'b1; // req_gen to bank_req next_req_st = (b2r_ack ) ? ((page_ovflw_r) ? `REQ_PAGE_WRAP :`REQ_IDLE) : `REQ_ACTIVE; end // case: `REQ_ACTIVE `REQ_PAGE_WRAP : begin r2x_idle = 1'b0; req_idle = 1'b0; req_ack = 1'b0; req_ld = b2r_ack; r2b_req = 1'b1; // req_gen to bank_req next_req_st = (b2r_ack) ? `REQ_IDLE : `REQ_PAGE_WRAP; end // case: `REQ_ACTIVE endcase // case(req_st) end // always @ (req_st or ....) always @ (posedge clk) if (~reset_n) begin req_st <= `REQ_IDLE; end // if (~reset_n) else begin req_st <= next_req_st; end // else: !if(~reset_n) // // addrs bits for the bank, row and column // // Register row/column/bank to improve fpga timing issue wire [APP_AW-1:0] map_address ; assign map_address = (req_ack) ? req_addr_int : (req_ld) ? next_sdr_addr : curr_sdr_addr; always @ (posedge clk) begin // Bank Bits are always - 2 Bits r2b_ba <= (cfg_colbits == 2'b00) ? {map_address[9:8]} : (cfg_colbits == 2'b01) ? {map_address[10:9]} : (cfg_colbits == 2'b10) ? {map_address[11:10]} : map_address[12:11]; /******************** * Colbits Mapping: * 2'b00 - 8 Bit * 2'b01 - 16 Bit * 2'b10 - 10 Bit * 2'b11 - 11 Bits ************************/ r2b_caddr <= (cfg_colbits == 2'b00) ? {5'b0, map_address[7:0]} : (cfg_colbits == 2'b01) ? {4'b0, map_address[8:0]} : (cfg_colbits == 2'b10) ? {3'b0, map_address[9:0]} : {2'b0, map_address[10:0]}; r2b_raddr <= (cfg_colbits == 2'b00) ? map_address[22:10] : (cfg_colbits == 2'b01) ? map_address[23:11] : (cfg_colbits == 2'b10) ? map_address[24:12] : map_address[25:13]; end endmodule // sdr_req_gen